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Aplastic Anemia: Current Treatment
Aplastic anemia is a rare hematologic disorder marked by pancytopenia and a hypocellular marrow. Aplastic anemia results from either inherited or acquired causes, and the treatment approach varies significantly between the 2 causes. This article reviews the treatment of inherited and acquired forms of aplastic anemia. The approach to evaluation and diagnosis of aplastic anemia is reviewed in a separate article.
Inherited Aplastic Anemia
First-line treatment options for patients with inherited marrow failure syndromes (IMFS) are androgen therapy and hematopoietic stem cell transplant (HSCT). When evaluating patients for HSCT, it is critical to identify the presence of an IMFS, as the risk and mortality associated with the conditioning regimen, stem cell source, graft-versus-host disease (GVHD), and secondary malignancies differ between patients with IMFS and those with acquired marrow failure syndromes or hematologic malignancies.
Potential sibling donors need to be screened for donor candidacy as well as for the inherited defect.1 Among patients with Fanconi anemia or a telomere biology disorder, the stem cell source must be considered, with bone marrow demonstrating lower rates of acute GVHD than a peripheral blood stem cell source.2-4 In IMFS patients, the donor cell type may affect the choice of conditioning regimen.5,6 Reduced-intensity conditioning in lieu of myeloablative conditioning without total body irradiation has proved feasible in patients with Fanconi anemia, and is associated with a reduced risk of secondary malignancies.5,6 Incorporation of fludarabine in the conditioning regimen of patients without a matched sibling donor is associated with superior engraftment and survival2,5,7 compared to cyclophosphamide conditioning, which was historically used in matched related donors.6,8 The addition of fludarabine appears to be especially beneficial in older patients, in whom its use is associated with lower rates of graft failure, likely due to increased immunosuppression at the time of engraftment.7,9 Fludarabine has also been incorporated into conditioning regimens for patients with a telomere biology disorder, but outcomes data is limited.5
For patients presenting with acute myeloid leukemia (AML) or a high-risk myelodysplastic syndrome (MDS) who are subsequently diagnosed with an IMFS, treatment can be more complex, as these patients are at high risk for toxicity from standard chemotherapy. Limited data suggests that induction therapy and transplantation are feasible in this group of patients, and this approach is associated with increased overall survival (OS) despite lower OS rates than those of IMFS patients who present prior to the development of MDS or AML.10,11 Further work is needed to determine the optimal induction regimen that balances the risks of treatment-related mortality and complications associated with conditioning regimens, risk of relapse, and risk of secondary malignancies, especially in the cohort of patients diagnosed at an older age.
Acquired Aplastic Anemia
Supportive Care
While the workup and treatment plan is being established, attention should be directed at supportive care for prevention of complications. The most common complications leading to death in patients with significant pancytopenia and neutropenia are opportunistic infections and hemorrhagic complications.12
Transfusion support is critical to avoid symptomatic anemia and hemorrhagic complications related to thrombocytopenia, which typically occur with platelet counts lower than 10,000 cells/µL. However, transfusion carries the risk of alloimmunization (which may persist for years following transfusion) and transfusion-related graft versus host disease (trGVHD), and thus use of transfusion should be minimized when possible.13,14 Transfusion support is often required to prevent complications associated with thrombocytopenia and anemia; all blood products given to patients with aplastic anemia should be irradiated and leukoreduced to reduce the risk of both alloimmunization and trGVHD. Guidelines from the British Society for Haematology recommend routine screening for Rh and Kell antibodies to reduce the risk of alloimmunization.15 Infectious complications remain a common cause of morbidity and mortality in patients with aplastic anemia who have prolonged neutropenia (defined as an absolute neutrophil count [ANC] < 500 cells/µL).16-19 Therefore, patients should receive broad-spectrum antibiotics with antipseudomonal coverage. In a study by Tichelli and colleagues evaluating the role of granulocyte-colony stimulating factor (G-CSF) in patients with SAA receiving immunosuppressive therapy, 55% of all patient deaths were secondary to infection.20 There was no OS benefit seen in patients who received G-CSF, though a significantly lower rate of infection was observed in the G-CSF arm compared to those not receiving G-CSF (56% versus 81%, P = 0.006).This difference was largely driven by a decrease in infectious episodes in patients with very severe aplastic anemia (VSAA) treated with G-CSF as compared to those who did not receive this therapy (22% versus 48%, P = 0.014).20
Angio-invasive pulmonary aspergillosis and Zygomycetes (eg, Rhizopus, Mucor species) remain major causes of mortality related to opportunistic mycotic infections in patients with aplastic anemia.18 The infectious risk is directly related to the duration and severity of neutropenia, with one study demonstrating a significant increase in risk in AML patients with neutropenia lasting longer than 3 weeks.21 Invasive fungal infections carry a high mortality in patients with severe neutropenia, though due to earlier recognition and empiric antifungal therapy with extended-spectrum azoles, overall mortality secondary to invasive fungal infections is declining.19,22
While neutropenia related to cytotoxic chemotherapy is commonly associated with gram-negative bacteria due to disruption of mucosal barriers, patients with aplastic anemia have an increased incidence of gram-positive bacteremia with staphylococcal species compared to other neutropenic populations.18,19 This appears to be changing with time. Valdez and colleagues demonstrated a decrease in prevalence of coagulase-negative staphylococcal infections, increased prevalence of gram-positive bacilli bacteremia, and no change in prevalence of gram-negative bacteremia in patients with aplastic anemia treated between 1989 and 2008.22 Gram-negative bacteremia caused by Stenotrophomonas maltophila, Escherichia coli, Klebsiella pneumoniae, Citrobacter, and Proteus has also been reported.19 Despite a lack of clinical trials investigating the role of antifungal and antibacterial prophylaxis for patients with aplastic anemia, most centers initiate antifungal prophylaxis in patients with severe aplastic anema (SAA) or VSAA with an anti-mold agent such as voriconazole or posaconazole (which has the additional benefit compared to voriconazole of covering Mucor species).17,23 This is especially true for patients who have received ATG or undergone HSCT. For antimicrobial prophylaxis, a fluoroquinolone antibiotic with a spectrum of activity against Pseudomonas should be considered for patients with an ANC < 500 cells/µL.17 Acyclovir or valacyclovir prophylaxis is recommended for varicella-zoster virus and herpes simplex virus. Cytomegalovirus reactivation is minimal in patients with aplastic anemia, unless multiple courses of ATG are used.
Iron overload is another complication the provider must be aware of in the setting of increased transfusions in aplastic anemia patients. Lee and colleagues demonstrated that iron chelation therapy using deferasirox is effective at reducing serum ferritin levels in patients with aplastic anemia (median ferritin level: 3254 ng/mL prior to therapy, 1854 ng/mL following), and is associated with no serious adverse events (most common adverse events included nausea, diarrhea, vomiting, and rash).24 Approximately 25% of patients in this trial demonstrated an increase in creatinine, with patients taking concomitant cyclosporine more affected than those on chelation therapy alone.24 For patients following HSCT or with improved hematopoiesis following immunosuppressive therapy, phlebotomy can be used to treat iron overload in lieu of chelation therapy.15
Approach to Therapy
The main treatment options for SAA and VSAA include allogeneic bone marrow transplant and immunosuppression. The deciding factors as to which treatment is best initially depends on the availability of HLA-matched related donors and age (Figure 1 and Figure 2). Survival is decreased in patients with SAA or VSAA who delay initiation of therapy, and therefore prompt referral for HLA typing and evaluation for bone marrow transplant is a very important first step in managing aplastic anemia.
Matched Sibling Donor Transplant
Current standards of care recommend HLA-matched sibling donor transplant for patients with SAA or VSAA who are younger than 50 years of age, with the caveat that integration of fludarabine and reduced cyclophosphamide dosing along with ATG shows the best overall outcomes. Locasciulli and colleagues examined outcomes in patients given either immunosuppressive therapy or sibling HSCT between 1991-1996 and 1997-2002, respectively, and found that sibling HSCT was associated with a superior 10-year OS compared to immunosuppressive therapy (73% versus 68%).25 Interestingly in this study, there was no OS improvement seen with immunosuppressive therapy alone (69% versus 73%) between the 2 time periods, despite increased OS in both sibling HSCT (74% and 80%) and matched unrelated donor HSCT (38% and 65%).25 Though total body irradiation has been used in the past, it is typically not included in current conditioning regimens for matched related donor transplants.26
Current conditioning regimens typically use a combination of cyclophosphamide and ATG27,28 with or without fludarabine. Fludarabine-based conditioning regimens have shown promise in patients undergoing sibling HSCT. Maury and colleagues evaluated the role of fludarabine in addition to low-dose cyclophosphamide and ATG compared to cyclophosphamide alone or in combination with ATG in patients over age 30 undergoing sibling HSCT.9 There was a nonsignificant improvement in 5-year OS in the fludarabine arm compared to controls (77% ± 8% versus 60% ± 3%, P = 0.14) in the pooled analysis, but when adjusted for age the fludarabine arm had a significantly lower relative risk (RR) of death (RR, 0.44; P = 0.04) compared to the control arm. Shin et al reported outcomes with fludarabine/cyclophosphamide/ATG, with excellent overall outcomes and no difference in patients older or younger than 40 years.29 In addition, Kim et al evaluated their experience with patients older than 40 years of age receiving matched related donors, finding comparable outcomes in those aged 41 to 50 years compared to younger patients. Outcomes did decline in those over the age of 50 years.30 Long-term data for matched related donor transplant for aplastic anemia shows excellent long-term outcomes, with minimal chronic GVHD and good performance status.31 Hence, these factors support the role of matched related donor transplant as the initial treatment in SAA and VSAA.
Regarding the role of transplant for patients who lack a matched related donor, a growing body of literature demonstrating identical outcomes between matched related and matched unrelated donor (MUD) transplants for pediatric patients32,33 supports recent recommendations for upfront unrelated donor transplantation for aplastic anemia.34,35
Immunosuppressive Therapy
For patients without an HLA-matched sibling donor or those who are older than 50 years of age, immunosuppressive therapy is the first-line therapy. ATG and cyclosporine A are the treatments of choice.36 The potential effectiveness of immunosuppressive therapy in treating aplastic anemia was initially observed in patients in whom autologous transplant failed but who still experienced hematopoietic reconstitution despite the failed graft; this observation led to the hypothesis that the conditioning regimen may have an effect on hematopoiesis.16,36,37
Anti-thymocyte globulin. Immunosuppressive therapy with ATG has been used for the treatment of aplastic anemia since the 1980s.38 Historically, rabbit ATG had been used, but a 2011 study of horse ATG demonstrated superior hematological response at 6 months compared to rabbit ATG (68% versus 37%).16 Superior survival was also seen with horse ATG compared to rabbit ATG (3-year OS: 96% versus 76%). Due to these results, horse ATG is preferred over rabbit ATG. ATG should be used in combination with cyclosporine A to optimize outcomes.
Cyclosporine A. Early studies also demonstrated the efficacy of cyclosporine A in the treatment of aplastic anemia, with response rates equivalent to that of ATG monotherapy.39 Recent publications still note the efficacy of cyclosporine A in the treatment of aplastic anemia. Its role as an affordable option for single-agent therapy in developing countries is intriguing.39
The combination of the ATG and cyclosporine A was proven superior to either agent alone in a study by Frickhofen et al.37 In this study patients were randomly assigned to a control arm that received ATG plus methylprednisolone or to an arm that received ATG plus cyclosporine A and methylprednisolone. At 6 months, 70% of patients in the cyclosporine A arm had a complete remission (CR) or partial remission compared to 46% in the control arm.40 Further work confirmed the long-term efficacy of this regimen, reporting a 7-year OS of 55%.41 Among a pediatric population, immunosuppressive therapy was associated with an 83% 10-year OS.42
It is recommended that patients remain on cyclosporine therapy for a minimum of 6 months, after which a gradual taper may be considered, although there is variation among practitioners, with some continuing immunosuppressive therapy for a minimum of 12 months due to a proportion of patients being cyclosporine dependent.42,43 A study found that within a population of patients who responded to immunosuppressive therapy, 18% became cyclosporine dependent.42 The median duration of cyclosporine A treatment at full dose was 12 months, with tapering completed over a median of 19 months after patients had been in a stable CR for a minimum of 3 months. Relapse occurred more often when patients were tapered quickly (decrease ≥ 0.8 mg/kg/month) compared to slowly (0.4-0.7 mg/kg/month) or very slowly (< 0.3 mg/kg/month).
Immunosuppressive therapy plus eltrombopag. Townsley and colleagues recently investigated incorporating the use of the thrombopoietin receptor agonist eltrombopag with immunosuppressive therapy as first-line therapy in aplastic anemia.44 When given at a dose of 150 mg daily in patients aged 12 years and older or 75 mg daily in patients younger than 12 years, in conjunction with cyclosporine A and ATG, patients demonstrated markedly improved hematological response compared to historical treatment with standard immunosuppressive therapy alone.44 In the patient cohort administered eltrombopag starting on day 1 and continuing for 6 months, the complete response rate was 58%. Eltrombopag led to improvement in all cell lines among all treatment subgroups, and OS (censored for patients who proceeded to transplant) was 99% at 2 years.45 Overall, toxicities associated with this therapy were low, with liver enzyme elevations most commonly observed.44 Recently, a phase 2 trial of immunosuppressive therapy with or without eltrombopag was reported. Of the 38 patients enrolled, overall response, complete response, and time to response were not statistically different.46 With this recent finding, the role of eltrombopag in addition to immunosuppressive therapy is not clearly defined, and further studies are warranted.
OS for patients who do not respond to immunosuppressive therapy is approximately 57% at 5 years, largely due to improved supportive measures among this patient population.4,22 Therefore, it is important to recognize those patients who have a low chance of response so that second-line therapy can be pursued to improve outcomes.
Matched Unrelated Donor Transplant
For patients with refractory disease following immunosuppressive therapy who lack a matched sibling donor, MUD HSCT is considered standard therapy given the marked improvement in overall outcomes with modulating conditioning regimens and high-resolution HLA typing. A European Society for Blood and Marrow Transplantation analysis comparing matched sibling HSCT to MUD HSCT noted significantly higher rates of acute grade II-IV and grade III-V GVHD (grade II-IV 13% versus 25%, grade III-IV 5% versus 10%) among patients undergoing MUD transplant.47 Chronic GVHD rates were 14% in the sibling group, as compared to 26% in the MUD group. Additional benefits seen in this analysis included improved survival when transplanted under age 20 years (84% versus 72%), when transplanted within 6 months of diagnosis (85% versus 72%), the use of ATG in the conditioning regimen (81% versus 73%), and when the donor and recipient were cytomegalovirus-negative compared to other combinations (82% versus 76%).47 Interestingly, this study demonstrated that OS was not significantly increased when using a sibling HSCT compared to a MUD HSCT, likely as a result of improved understanding of conditioning regimens, GVHD prophylaxis, and supportive care.
Additional studies of MUD HSCT have shown outcomes similar to those seen in sibling HSCT.4,43 A French study found a significant increase in survival in patients undergoing MUD HSCT compared to historical cohorts (2000-2005: OS 52%; 2006-2012: OS 74%).33 The majority of patients underwent conditioning with cyclophosphamide or a combination of busulfan and cyclophosphamide, with or without fludarabine; 81% of patients included underwent in vivo T-cell depletion, and a bone marrow donor source was utilized. OS was significantly lower in patients over age 30 years undergoing MUD HSCT (57%) compared to those under age 30 years (70%). Improved OS was also seen when patients underwent transplant within 1 year of diagnosis and when a 10/10 matched donor (compared to a 9/10 mismatched donor) was utilized.4 A 2015 study investigated the role of MUD HSCT as frontline therapy instead of immunosuppressive therapy in patients without a matched sibling donor.33 The 2-year OS was 96% in the MUD HSCT cohort compared to 91%, 94%, and 74% in historical cohorts of sibling HSCT, frontline immunosuppressive therapy, and second-line MUD HSCT following failed immunosuppressive therapy, respectively. Additionally, event-free survival in the MUD HSCT cohort (defined by the authors as death, lack of response, relapse, occurrence of clonal evolution/clinical paroxysmal nocturnal hemoglobinuria, malignancies developing over follow‐up, and transplant for patients receiving immunosuppressive therapy frontline) was similar compared to sibling HSCT and superior to frontline immunosuppressive therapy and second-line MUD HSCT. Furthermore, Samarasinghe et al highlighted the importance of in vivo T-cell depletion with either ATG or alemtuzumab (anti-CD52 monoclonal antibody) in the prevention of acute and chronic GVHD in both sibling HSCT and MUD HSCT.48
With continued improvement of less toxic and more immunomodulating conditioning regimens, utilization of bone marrow as a donor cell source, in vivo T-cell depletion, and use of GVHD and antimicrobial prophylaxis, more clinical evidence supports elevating MUD HSCT in the treatment plan for patients without a matched sibling donor.49 However, there is still a large population of patients without matched sibling or unrelated donor options. In an effort to expand the transplant pool and thus avoid clonal hematopoiesis, clinically significant paroxysmal nocturnal hemoglobinuria, and relapsed aplastic anemia, more work continues to recognize the expanding role of alternative donor transplants (cord blood and haploidentical) as another viable treatment strategy for aplastic anemia after immunosuppressive therapy failure.50
Summary
Aplastic anemia is a rare but potentially life-threatening disorder characterized by pancytopenia and a marked reduction in the hematopoietic stem cell compartment. Treatment should be instituted as soon as the dignosis of aplastic anemia is established. Treatment outcomes are excellent with modern supportive care and the current approach to allogeneic transplantation, and therefore referral to a bone marrow transplant program to evaluate for early transplantation is the new standard of care.
1. Peffault De Latour R, Le Rademacher J, Antin JH, et al. Allogeneic hematopoietic stem cell transplantation in Fanconi anemia: the European Group for Blood and Marrow Transplantation experience.” Blood. 2013;122:4279-4286.
2. Auerbach AD. Diagnosis of Fanconi anemia by diepoxybutane analysis. Curr Protoc Hum Genet. 2015;85:8.7.1-17.
3. Eapen M, et al. Effect of stem cell source on outcomes after unrelated donor transplantation in severe aplastic anemia. Blood. 2011;118:2618-2621.
4. Devillier R, Dalle JH, Kulasekararaj A, et al. Unrelated alternative donor transplantation for severe acquired aplastic anemia: a study from the French Society of Bone Marrow Transplantation and Cell Therapies and the Severe Aplastic Anemia Working Party of EBMT. Haematologica. 2016;101:884-890.
5. Peffault de Latour R, Peters C, Gibson B, et al. Recommendations on hematopoietic stem cell transplantation for inherited bone marrow failure syndromes.” Bone Marrow Transplant. 2015;50:1168-1172.
6. De Medeiros CR, Zanis-Neto J, Pasquini R. Bone marrow transplantation for patients with Fanconi anemia: reduced doses of cyclophosphamide without irradiation as conditioning. Bone Marrow Transplant. 1999;24:849-852.
7. Mohanan E, Panetta JC, Lakshmi KM, et al. Population pharmacokinetics of fludarabine in patients with aplastic anemia and Fanconi anemia undergoing allogeneic hematopoietic stem cell transplantation. Bone Marrow Transplant. 2017;52:977-983.
8 Gluckman E, Auerbach AD, Horowitz MM, et al. Bone marrow transplantation for Fanconi anemia. Blood. 1995;86:2856-2862.
9. Maury S, Bacigalupo A, Anderlini P, et al. Improved outcome of patients older than 30 years receiving HLA-identical sibling hematopoietic stem cell transplantation for severe acquired aplastic anemia using fludarabine-based conditioning: a comparison with conventional conditioning regimen. Haematologica. 2009;94:1312-1315.
10. Talbot A, Peffault de Latour R, Raffoux E, et al. Sequential treatment for allogeneic hematopoietic stem cell transplantation in Fanconi anemia with acute myeloid leukemia. Haematologica. 2014;99:e199-200.
11. Ayas M, Saber W, Davies SM, et al. Allogeneic hematopoietic cell transplantation for fanconi anemia in patients with pretransplantation cytogenetic abnormalities, myelodysplastic syndrome, or acute leukemia. J Clin Oncol. 2013;31:1669-1676.
12. Vaht K, Göransson M, Carlson K, et al. Incidence and outcome of acquired aplastic anemia: real-world data from patients diagnosed in Sweden from 2000–2011. Haematologica. 2017;102:1683-1690.
13. Passweg JR, Marsh JC. Aplastic anemia: first-line treatment by immunosuppression and sibling marrow transplantation. Hematology Am Soc Hematol Educ Program. 2010;2010:36-42.
14. Laundy GJ, Bradley BA, Rees BM, et al. Incidence and specificity of HLA antibodies in multitransfused patients with acquired aplastic anemia. Transfusion. 2004;44:814-825.
15. Killick SB, Bown N, Cavenagh J, et al. Guidelines for the diagnosis and management of adult aplastic anaemia. Br J Haematol. 2016;172:187-207.
16. Scheinberg P, Nunez O, Weinstein B, et al. Horse versus rabbit antithymocyte globulin in acquired aplastic anemia. N Eng J Med. 2011;365:430-438.
17. Höchsmann B, Moicean A, Risitano A, et al. Supportive care in severe and very severe aplastic anemia. Bone Marrow Transplant. 2013;48:168-173.
18. Valdez JM, Scheinberg P, Young NS, Walsh TJ. Infections in patients with aplastic anemia. Sem Hematol. 2009;46:269-276.
19. Torres HA, Bodey GP, Rolston KV, et al. Infections in patients with aplastic anemia: experience at a tertiary care cancer center. Cancer. 2003;98:86-93.
20. Tichelli A, Schrezenmeier H, Socié G, et al. A randomized controlled study in patients with newly diagnosed severe aplastic anemia receiving antithymocyte globulin (ATG), cyclosporine, with or without G-CSF: a study of the SAA Working Party of the European Group for Blood and Marrow Transplantation. Blood. 2011;117:4434-4441.
21. Gerson SL, Talbot GH, Hurwitz S, et al. Prolonged granulocytopenia: the major risk factor for invasive pulmonary aspergillosis in patients with acute leukemia. Ann Intern Med. 1984;100:345-351.
22. Valdez JM, Scheinberg P, Nunez O, et al. Decreased infection-related mortality and improved survival in severe aplastic anemia in the past two decades. Clin Infect Dis. 2011;52:726-735.
23. Robenshtok E, Gafter-Gvili A, Goldberg E, et al. Antifungal prophylaxis in cancer patients after chemotherapy or hematopoietic stem-cell transplantation: systematic review and meta-analysis. J Clin Oncol. 2007;25:5471-5489.
24. Lee JW, Yoon SS, Shen ZX, et al. Iron chelation therapy with deferasirox in patients with aplastic anemia: a subgroup analysis of 116 patients from the EPIC trial. Blood. 2010;116:2448-2554.
25. Locasciulli A, Oneto R, Bacigalupo A, et al. Outcome of patients with acquired aplastic anemia given first line bone marrow transplantation or immunosuppressive treatment in the last decade: a report from the European Group for Blood and Marrow Transplantation. Haematologica. 2007;92:11-8.
26. Deeg HJ, Amylon MD, Harris RE, et al. Marrow transplants from unrelated donors for patients with aplastic anemia: minimum effective dose of total body irradiation. Biol Blood Marrow Transplant. 2001;7:208-215.
27. Kahl C, Leisenring W, Joachim Deeg H, et al. Cyclophosphamide and antithymocyte globulin as a conditioning regimen for allogeneic marrow transplantation in patients with aplastic anaemia: a long‐term follow‐up. Br J Haematol. 2005;130:747-751.
28. Socié G. Allogeneic BM transplantation for the treatment of aplastic anemia: current results and expanding donor possibilities. ASH Education Program Book. 2013;2013:82-86.
29. Shin SH, Jeon YW, Yoon JH, et al. Comparable outcomes between younger (<40 years) and older (>40 years) adult patients with severe aplastic anemia after HLA-matched sibling stem cell transplantation using fludarabine-based conditioning. Bone Marrow Transplant. 2016;51:1456-1463.
30. Kim H, Lee KH, Yoon SS, et al; Korean Society of Blood and Marrow Transplantation. Allogeneic hematopoietic stem cell transplant for adults over 40 years old with acquired aplastic anemia. Biol Blood Marrow Transplant. 2012;18:1500-1508.
31. Mortensen BK, Jacobsen N, Heilmann C, Sengelov H. Allogeneic hematopoietic cell transplantation for severe aplastic anemia: similar long-term overall survival after transplantation with related donors compared to unrelated donors. Bone Marrow Transplant. 2016;51:288-290.
32. Dufour C, Svahn J, Bacigalupo A. Front-line immunosuppressive treatment of acquired aplastic anemia. Bone Marrow Transplant. 2013;48:174-177.
33. Dufour C, Veys P, Carraro E, et al. Similar outcome of upfront-unrelated and matched sibling stem cell transplantation in idiopathic paediatric aplastic anaemia. A study on the behalf of the UK Paediatric BMT Working Party, Paediatric Diseases Working Party and Severe Aplastic Anaemia Working Party of the EBMT. Br. J Haematol. 2015;151:585-594.
34. Georges GE, Doney K, Storb R. Severe aplastic anemia: allogeneic bone marrow transplantation as first-line treatment. Blood Adv. 2018;2:2020-2028.
35. Yoshida N, Kojima S. Updated guidelines for the treatment of acquired aplastic anemia in children. Curr Oncol Rep. 2018;20:67.
36. Mathe G, Amiel JL, Schwarzenberg L, et al. Bone marrow graft in man after conditioning by antilymphocytic serum. Br Med J. 1970;2:131-136.
37. Frickhofen N, Kaltwasser JP, Schrezenmeier H, et al, German Aplastic Anemia Study Group. Treatment of aplastic anemia with antilymphocyte globulin and methylprednisolone with or without cyclosporine. N Engl J Med. 1991;324:1297-1304.
38. Speck B, Gratwohl A, Nissen C, et al. Treatment of severe aplastic anaemia with antilymphocyte globulin or bone-marrow transplantation. Br Med J. 1981;282:860-863.
39. Al-Ghazaly J, Al-Dubai W, Al-Jahafi AK, et al. Cyclosporine monotherapy for severe aplastic anemia: a developing country experience. Ann Saudi Med. 2005;25:375-379.
40. Scheinberg P, Young NS. How I treat acquired aplastic anemia. Blood. 2012;120:1185-1196.
41. Rosenfeld S, Follmann D, Nunez O, Young NS. Antithymocyte globulin and cyclosporine for severe aplastic anemia: association between hematologic response and long-term outcome. JAMA. 2003;289:1130-1135.
42. Saracco P, Quarello P, Iori AP, et al. Cyclosporin A response and dependence in children with acquired aplastic anaemia: a multicentre retrospective study with long‐term observation follow‐up. Br J Haematol. 2008;140:197-205.
43. Bacigalupo A. How I treat acquired aplastic anemia. Blood. 2017;129:1428-1436.
44. Townsley DM, Scheinberg P, Winkler T, et al. Eltrombopag added to standard immunosuppression for aplastic anemia. N Engl J Med. 2017;376:1540-1550.
45. Olnes MJ, Scheinberg P, Calvo KR, et al. Eltrombopag and improved hematopoiesis in refractory aplastic anemia. N Engl J Med. 2012;367:11-19.
46. Assi R, Garcia-Manero G, Ravandi F, et al. Addition of eltrombopag to immunosuppressive therapy in patients with newly diagnosed aplastic anemia. Cancer. 2018 Oct 11. doi: 10.1002/cncr.31658.
47. Bacigalupo A, Socié G, Hamladji RM, et al. Current outcome of HLA identical sibling vs. unrelated donor transplants in severe aplastic anemia: an EBMT analysis. Haematologica. 2015;100:696-702.
48. Samarasinghe S, Iacobelli S, Knol C, et al. Impact of different in vivo T cell depletion strategies on outcomes following hematopoietic stem cell transplantation for idiopathic aplastic anaemia: a study on behalf of the EBMT SAA Working Party. 2018Oct 17. doi: 10.1002/ajh.25314.
49. Clesham K, Dowse R, Samarasinghe S. Upfront matched unrelated donor transplantation in aplastic anemia. Hematol Oncol Clin North Am. 2018;32:619-628.
50. DeZern AE, Brodsky RA. Haploidentical donor bone marrow transplantation for severe aplastic anemia. Hematol Oncol Clin North Am. 2018;32:629-642.
Aplastic anemia is a rare hematologic disorder marked by pancytopenia and a hypocellular marrow. Aplastic anemia results from either inherited or acquired causes, and the treatment approach varies significantly between the 2 causes. This article reviews the treatment of inherited and acquired forms of aplastic anemia. The approach to evaluation and diagnosis of aplastic anemia is reviewed in a separate article.
Inherited Aplastic Anemia
First-line treatment options for patients with inherited marrow failure syndromes (IMFS) are androgen therapy and hematopoietic stem cell transplant (HSCT). When evaluating patients for HSCT, it is critical to identify the presence of an IMFS, as the risk and mortality associated with the conditioning regimen, stem cell source, graft-versus-host disease (GVHD), and secondary malignancies differ between patients with IMFS and those with acquired marrow failure syndromes or hematologic malignancies.
Potential sibling donors need to be screened for donor candidacy as well as for the inherited defect.1 Among patients with Fanconi anemia or a telomere biology disorder, the stem cell source must be considered, with bone marrow demonstrating lower rates of acute GVHD than a peripheral blood stem cell source.2-4 In IMFS patients, the donor cell type may affect the choice of conditioning regimen.5,6 Reduced-intensity conditioning in lieu of myeloablative conditioning without total body irradiation has proved feasible in patients with Fanconi anemia, and is associated with a reduced risk of secondary malignancies.5,6 Incorporation of fludarabine in the conditioning regimen of patients without a matched sibling donor is associated with superior engraftment and survival2,5,7 compared to cyclophosphamide conditioning, which was historically used in matched related donors.6,8 The addition of fludarabine appears to be especially beneficial in older patients, in whom its use is associated with lower rates of graft failure, likely due to increased immunosuppression at the time of engraftment.7,9 Fludarabine has also been incorporated into conditioning regimens for patients with a telomere biology disorder, but outcomes data is limited.5
For patients presenting with acute myeloid leukemia (AML) or a high-risk myelodysplastic syndrome (MDS) who are subsequently diagnosed with an IMFS, treatment can be more complex, as these patients are at high risk for toxicity from standard chemotherapy. Limited data suggests that induction therapy and transplantation are feasible in this group of patients, and this approach is associated with increased overall survival (OS) despite lower OS rates than those of IMFS patients who present prior to the development of MDS or AML.10,11 Further work is needed to determine the optimal induction regimen that balances the risks of treatment-related mortality and complications associated with conditioning regimens, risk of relapse, and risk of secondary malignancies, especially in the cohort of patients diagnosed at an older age.
Acquired Aplastic Anemia
Supportive Care
While the workup and treatment plan is being established, attention should be directed at supportive care for prevention of complications. The most common complications leading to death in patients with significant pancytopenia and neutropenia are opportunistic infections and hemorrhagic complications.12
Transfusion support is critical to avoid symptomatic anemia and hemorrhagic complications related to thrombocytopenia, which typically occur with platelet counts lower than 10,000 cells/µL. However, transfusion carries the risk of alloimmunization (which may persist for years following transfusion) and transfusion-related graft versus host disease (trGVHD), and thus use of transfusion should be minimized when possible.13,14 Transfusion support is often required to prevent complications associated with thrombocytopenia and anemia; all blood products given to patients with aplastic anemia should be irradiated and leukoreduced to reduce the risk of both alloimmunization and trGVHD. Guidelines from the British Society for Haematology recommend routine screening for Rh and Kell antibodies to reduce the risk of alloimmunization.15 Infectious complications remain a common cause of morbidity and mortality in patients with aplastic anemia who have prolonged neutropenia (defined as an absolute neutrophil count [ANC] < 500 cells/µL).16-19 Therefore, patients should receive broad-spectrum antibiotics with antipseudomonal coverage. In a study by Tichelli and colleagues evaluating the role of granulocyte-colony stimulating factor (G-CSF) in patients with SAA receiving immunosuppressive therapy, 55% of all patient deaths were secondary to infection.20 There was no OS benefit seen in patients who received G-CSF, though a significantly lower rate of infection was observed in the G-CSF arm compared to those not receiving G-CSF (56% versus 81%, P = 0.006).This difference was largely driven by a decrease in infectious episodes in patients with very severe aplastic anemia (VSAA) treated with G-CSF as compared to those who did not receive this therapy (22% versus 48%, P = 0.014).20
Angio-invasive pulmonary aspergillosis and Zygomycetes (eg, Rhizopus, Mucor species) remain major causes of mortality related to opportunistic mycotic infections in patients with aplastic anemia.18 The infectious risk is directly related to the duration and severity of neutropenia, with one study demonstrating a significant increase in risk in AML patients with neutropenia lasting longer than 3 weeks.21 Invasive fungal infections carry a high mortality in patients with severe neutropenia, though due to earlier recognition and empiric antifungal therapy with extended-spectrum azoles, overall mortality secondary to invasive fungal infections is declining.19,22
While neutropenia related to cytotoxic chemotherapy is commonly associated with gram-negative bacteria due to disruption of mucosal barriers, patients with aplastic anemia have an increased incidence of gram-positive bacteremia with staphylococcal species compared to other neutropenic populations.18,19 This appears to be changing with time. Valdez and colleagues demonstrated a decrease in prevalence of coagulase-negative staphylococcal infections, increased prevalence of gram-positive bacilli bacteremia, and no change in prevalence of gram-negative bacteremia in patients with aplastic anemia treated between 1989 and 2008.22 Gram-negative bacteremia caused by Stenotrophomonas maltophila, Escherichia coli, Klebsiella pneumoniae, Citrobacter, and Proteus has also been reported.19 Despite a lack of clinical trials investigating the role of antifungal and antibacterial prophylaxis for patients with aplastic anemia, most centers initiate antifungal prophylaxis in patients with severe aplastic anema (SAA) or VSAA with an anti-mold agent such as voriconazole or posaconazole (which has the additional benefit compared to voriconazole of covering Mucor species).17,23 This is especially true for patients who have received ATG or undergone HSCT. For antimicrobial prophylaxis, a fluoroquinolone antibiotic with a spectrum of activity against Pseudomonas should be considered for patients with an ANC < 500 cells/µL.17 Acyclovir or valacyclovir prophylaxis is recommended for varicella-zoster virus and herpes simplex virus. Cytomegalovirus reactivation is minimal in patients with aplastic anemia, unless multiple courses of ATG are used.
Iron overload is another complication the provider must be aware of in the setting of increased transfusions in aplastic anemia patients. Lee and colleagues demonstrated that iron chelation therapy using deferasirox is effective at reducing serum ferritin levels in patients with aplastic anemia (median ferritin level: 3254 ng/mL prior to therapy, 1854 ng/mL following), and is associated with no serious adverse events (most common adverse events included nausea, diarrhea, vomiting, and rash).24 Approximately 25% of patients in this trial demonstrated an increase in creatinine, with patients taking concomitant cyclosporine more affected than those on chelation therapy alone.24 For patients following HSCT or with improved hematopoiesis following immunosuppressive therapy, phlebotomy can be used to treat iron overload in lieu of chelation therapy.15
Approach to Therapy
The main treatment options for SAA and VSAA include allogeneic bone marrow transplant and immunosuppression. The deciding factors as to which treatment is best initially depends on the availability of HLA-matched related donors and age (Figure 1 and Figure 2). Survival is decreased in patients with SAA or VSAA who delay initiation of therapy, and therefore prompt referral for HLA typing and evaluation for bone marrow transplant is a very important first step in managing aplastic anemia.
Matched Sibling Donor Transplant
Current standards of care recommend HLA-matched sibling donor transplant for patients with SAA or VSAA who are younger than 50 years of age, with the caveat that integration of fludarabine and reduced cyclophosphamide dosing along with ATG shows the best overall outcomes. Locasciulli and colleagues examined outcomes in patients given either immunosuppressive therapy or sibling HSCT between 1991-1996 and 1997-2002, respectively, and found that sibling HSCT was associated with a superior 10-year OS compared to immunosuppressive therapy (73% versus 68%).25 Interestingly in this study, there was no OS improvement seen with immunosuppressive therapy alone (69% versus 73%) between the 2 time periods, despite increased OS in both sibling HSCT (74% and 80%) and matched unrelated donor HSCT (38% and 65%).25 Though total body irradiation has been used in the past, it is typically not included in current conditioning regimens for matched related donor transplants.26
Current conditioning regimens typically use a combination of cyclophosphamide and ATG27,28 with or without fludarabine. Fludarabine-based conditioning regimens have shown promise in patients undergoing sibling HSCT. Maury and colleagues evaluated the role of fludarabine in addition to low-dose cyclophosphamide and ATG compared to cyclophosphamide alone or in combination with ATG in patients over age 30 undergoing sibling HSCT.9 There was a nonsignificant improvement in 5-year OS in the fludarabine arm compared to controls (77% ± 8% versus 60% ± 3%, P = 0.14) in the pooled analysis, but when adjusted for age the fludarabine arm had a significantly lower relative risk (RR) of death (RR, 0.44; P = 0.04) compared to the control arm. Shin et al reported outcomes with fludarabine/cyclophosphamide/ATG, with excellent overall outcomes and no difference in patients older or younger than 40 years.29 In addition, Kim et al evaluated their experience with patients older than 40 years of age receiving matched related donors, finding comparable outcomes in those aged 41 to 50 years compared to younger patients. Outcomes did decline in those over the age of 50 years.30 Long-term data for matched related donor transplant for aplastic anemia shows excellent long-term outcomes, with minimal chronic GVHD and good performance status.31 Hence, these factors support the role of matched related donor transplant as the initial treatment in SAA and VSAA.
Regarding the role of transplant for patients who lack a matched related donor, a growing body of literature demonstrating identical outcomes between matched related and matched unrelated donor (MUD) transplants for pediatric patients32,33 supports recent recommendations for upfront unrelated donor transplantation for aplastic anemia.34,35
Immunosuppressive Therapy
For patients without an HLA-matched sibling donor or those who are older than 50 years of age, immunosuppressive therapy is the first-line therapy. ATG and cyclosporine A are the treatments of choice.36 The potential effectiveness of immunosuppressive therapy in treating aplastic anemia was initially observed in patients in whom autologous transplant failed but who still experienced hematopoietic reconstitution despite the failed graft; this observation led to the hypothesis that the conditioning regimen may have an effect on hematopoiesis.16,36,37
Anti-thymocyte globulin. Immunosuppressive therapy with ATG has been used for the treatment of aplastic anemia since the 1980s.38 Historically, rabbit ATG had been used, but a 2011 study of horse ATG demonstrated superior hematological response at 6 months compared to rabbit ATG (68% versus 37%).16 Superior survival was also seen with horse ATG compared to rabbit ATG (3-year OS: 96% versus 76%). Due to these results, horse ATG is preferred over rabbit ATG. ATG should be used in combination with cyclosporine A to optimize outcomes.
Cyclosporine A. Early studies also demonstrated the efficacy of cyclosporine A in the treatment of aplastic anemia, with response rates equivalent to that of ATG monotherapy.39 Recent publications still note the efficacy of cyclosporine A in the treatment of aplastic anemia. Its role as an affordable option for single-agent therapy in developing countries is intriguing.39
The combination of the ATG and cyclosporine A was proven superior to either agent alone in a study by Frickhofen et al.37 In this study patients were randomly assigned to a control arm that received ATG plus methylprednisolone or to an arm that received ATG plus cyclosporine A and methylprednisolone. At 6 months, 70% of patients in the cyclosporine A arm had a complete remission (CR) or partial remission compared to 46% in the control arm.40 Further work confirmed the long-term efficacy of this regimen, reporting a 7-year OS of 55%.41 Among a pediatric population, immunosuppressive therapy was associated with an 83% 10-year OS.42
It is recommended that patients remain on cyclosporine therapy for a minimum of 6 months, after which a gradual taper may be considered, although there is variation among practitioners, with some continuing immunosuppressive therapy for a minimum of 12 months due to a proportion of patients being cyclosporine dependent.42,43 A study found that within a population of patients who responded to immunosuppressive therapy, 18% became cyclosporine dependent.42 The median duration of cyclosporine A treatment at full dose was 12 months, with tapering completed over a median of 19 months after patients had been in a stable CR for a minimum of 3 months. Relapse occurred more often when patients were tapered quickly (decrease ≥ 0.8 mg/kg/month) compared to slowly (0.4-0.7 mg/kg/month) or very slowly (< 0.3 mg/kg/month).
Immunosuppressive therapy plus eltrombopag. Townsley and colleagues recently investigated incorporating the use of the thrombopoietin receptor agonist eltrombopag with immunosuppressive therapy as first-line therapy in aplastic anemia.44 When given at a dose of 150 mg daily in patients aged 12 years and older or 75 mg daily in patients younger than 12 years, in conjunction with cyclosporine A and ATG, patients demonstrated markedly improved hematological response compared to historical treatment with standard immunosuppressive therapy alone.44 In the patient cohort administered eltrombopag starting on day 1 and continuing for 6 months, the complete response rate was 58%. Eltrombopag led to improvement in all cell lines among all treatment subgroups, and OS (censored for patients who proceeded to transplant) was 99% at 2 years.45 Overall, toxicities associated with this therapy were low, with liver enzyme elevations most commonly observed.44 Recently, a phase 2 trial of immunosuppressive therapy with or without eltrombopag was reported. Of the 38 patients enrolled, overall response, complete response, and time to response were not statistically different.46 With this recent finding, the role of eltrombopag in addition to immunosuppressive therapy is not clearly defined, and further studies are warranted.
OS for patients who do not respond to immunosuppressive therapy is approximately 57% at 5 years, largely due to improved supportive measures among this patient population.4,22 Therefore, it is important to recognize those patients who have a low chance of response so that second-line therapy can be pursued to improve outcomes.
Matched Unrelated Donor Transplant
For patients with refractory disease following immunosuppressive therapy who lack a matched sibling donor, MUD HSCT is considered standard therapy given the marked improvement in overall outcomes with modulating conditioning regimens and high-resolution HLA typing. A European Society for Blood and Marrow Transplantation analysis comparing matched sibling HSCT to MUD HSCT noted significantly higher rates of acute grade II-IV and grade III-V GVHD (grade II-IV 13% versus 25%, grade III-IV 5% versus 10%) among patients undergoing MUD transplant.47 Chronic GVHD rates were 14% in the sibling group, as compared to 26% in the MUD group. Additional benefits seen in this analysis included improved survival when transplanted under age 20 years (84% versus 72%), when transplanted within 6 months of diagnosis (85% versus 72%), the use of ATG in the conditioning regimen (81% versus 73%), and when the donor and recipient were cytomegalovirus-negative compared to other combinations (82% versus 76%).47 Interestingly, this study demonstrated that OS was not significantly increased when using a sibling HSCT compared to a MUD HSCT, likely as a result of improved understanding of conditioning regimens, GVHD prophylaxis, and supportive care.
Additional studies of MUD HSCT have shown outcomes similar to those seen in sibling HSCT.4,43 A French study found a significant increase in survival in patients undergoing MUD HSCT compared to historical cohorts (2000-2005: OS 52%; 2006-2012: OS 74%).33 The majority of patients underwent conditioning with cyclophosphamide or a combination of busulfan and cyclophosphamide, with or without fludarabine; 81% of patients included underwent in vivo T-cell depletion, and a bone marrow donor source was utilized. OS was significantly lower in patients over age 30 years undergoing MUD HSCT (57%) compared to those under age 30 years (70%). Improved OS was also seen when patients underwent transplant within 1 year of diagnosis and when a 10/10 matched donor (compared to a 9/10 mismatched donor) was utilized.4 A 2015 study investigated the role of MUD HSCT as frontline therapy instead of immunosuppressive therapy in patients without a matched sibling donor.33 The 2-year OS was 96% in the MUD HSCT cohort compared to 91%, 94%, and 74% in historical cohorts of sibling HSCT, frontline immunosuppressive therapy, and second-line MUD HSCT following failed immunosuppressive therapy, respectively. Additionally, event-free survival in the MUD HSCT cohort (defined by the authors as death, lack of response, relapse, occurrence of clonal evolution/clinical paroxysmal nocturnal hemoglobinuria, malignancies developing over follow‐up, and transplant for patients receiving immunosuppressive therapy frontline) was similar compared to sibling HSCT and superior to frontline immunosuppressive therapy and second-line MUD HSCT. Furthermore, Samarasinghe et al highlighted the importance of in vivo T-cell depletion with either ATG or alemtuzumab (anti-CD52 monoclonal antibody) in the prevention of acute and chronic GVHD in both sibling HSCT and MUD HSCT.48
With continued improvement of less toxic and more immunomodulating conditioning regimens, utilization of bone marrow as a donor cell source, in vivo T-cell depletion, and use of GVHD and antimicrobial prophylaxis, more clinical evidence supports elevating MUD HSCT in the treatment plan for patients without a matched sibling donor.49 However, there is still a large population of patients without matched sibling or unrelated donor options. In an effort to expand the transplant pool and thus avoid clonal hematopoiesis, clinically significant paroxysmal nocturnal hemoglobinuria, and relapsed aplastic anemia, more work continues to recognize the expanding role of alternative donor transplants (cord blood and haploidentical) as another viable treatment strategy for aplastic anemia after immunosuppressive therapy failure.50
Summary
Aplastic anemia is a rare but potentially life-threatening disorder characterized by pancytopenia and a marked reduction in the hematopoietic stem cell compartment. Treatment should be instituted as soon as the dignosis of aplastic anemia is established. Treatment outcomes are excellent with modern supportive care and the current approach to allogeneic transplantation, and therefore referral to a bone marrow transplant program to evaluate for early transplantation is the new standard of care.
Aplastic anemia is a rare hematologic disorder marked by pancytopenia and a hypocellular marrow. Aplastic anemia results from either inherited or acquired causes, and the treatment approach varies significantly between the 2 causes. This article reviews the treatment of inherited and acquired forms of aplastic anemia. The approach to evaluation and diagnosis of aplastic anemia is reviewed in a separate article.
Inherited Aplastic Anemia
First-line treatment options for patients with inherited marrow failure syndromes (IMFS) are androgen therapy and hematopoietic stem cell transplant (HSCT). When evaluating patients for HSCT, it is critical to identify the presence of an IMFS, as the risk and mortality associated with the conditioning regimen, stem cell source, graft-versus-host disease (GVHD), and secondary malignancies differ between patients with IMFS and those with acquired marrow failure syndromes or hematologic malignancies.
Potential sibling donors need to be screened for donor candidacy as well as for the inherited defect.1 Among patients with Fanconi anemia or a telomere biology disorder, the stem cell source must be considered, with bone marrow demonstrating lower rates of acute GVHD than a peripheral blood stem cell source.2-4 In IMFS patients, the donor cell type may affect the choice of conditioning regimen.5,6 Reduced-intensity conditioning in lieu of myeloablative conditioning without total body irradiation has proved feasible in patients with Fanconi anemia, and is associated with a reduced risk of secondary malignancies.5,6 Incorporation of fludarabine in the conditioning regimen of patients without a matched sibling donor is associated with superior engraftment and survival2,5,7 compared to cyclophosphamide conditioning, which was historically used in matched related donors.6,8 The addition of fludarabine appears to be especially beneficial in older patients, in whom its use is associated with lower rates of graft failure, likely due to increased immunosuppression at the time of engraftment.7,9 Fludarabine has also been incorporated into conditioning regimens for patients with a telomere biology disorder, but outcomes data is limited.5
For patients presenting with acute myeloid leukemia (AML) or a high-risk myelodysplastic syndrome (MDS) who are subsequently diagnosed with an IMFS, treatment can be more complex, as these patients are at high risk for toxicity from standard chemotherapy. Limited data suggests that induction therapy and transplantation are feasible in this group of patients, and this approach is associated with increased overall survival (OS) despite lower OS rates than those of IMFS patients who present prior to the development of MDS or AML.10,11 Further work is needed to determine the optimal induction regimen that balances the risks of treatment-related mortality and complications associated with conditioning regimens, risk of relapse, and risk of secondary malignancies, especially in the cohort of patients diagnosed at an older age.
Acquired Aplastic Anemia
Supportive Care
While the workup and treatment plan is being established, attention should be directed at supportive care for prevention of complications. The most common complications leading to death in patients with significant pancytopenia and neutropenia are opportunistic infections and hemorrhagic complications.12
Transfusion support is critical to avoid symptomatic anemia and hemorrhagic complications related to thrombocytopenia, which typically occur with platelet counts lower than 10,000 cells/µL. However, transfusion carries the risk of alloimmunization (which may persist for years following transfusion) and transfusion-related graft versus host disease (trGVHD), and thus use of transfusion should be minimized when possible.13,14 Transfusion support is often required to prevent complications associated with thrombocytopenia and anemia; all blood products given to patients with aplastic anemia should be irradiated and leukoreduced to reduce the risk of both alloimmunization and trGVHD. Guidelines from the British Society for Haematology recommend routine screening for Rh and Kell antibodies to reduce the risk of alloimmunization.15 Infectious complications remain a common cause of morbidity and mortality in patients with aplastic anemia who have prolonged neutropenia (defined as an absolute neutrophil count [ANC] < 500 cells/µL).16-19 Therefore, patients should receive broad-spectrum antibiotics with antipseudomonal coverage. In a study by Tichelli and colleagues evaluating the role of granulocyte-colony stimulating factor (G-CSF) in patients with SAA receiving immunosuppressive therapy, 55% of all patient deaths were secondary to infection.20 There was no OS benefit seen in patients who received G-CSF, though a significantly lower rate of infection was observed in the G-CSF arm compared to those not receiving G-CSF (56% versus 81%, P = 0.006).This difference was largely driven by a decrease in infectious episodes in patients with very severe aplastic anemia (VSAA) treated with G-CSF as compared to those who did not receive this therapy (22% versus 48%, P = 0.014).20
Angio-invasive pulmonary aspergillosis and Zygomycetes (eg, Rhizopus, Mucor species) remain major causes of mortality related to opportunistic mycotic infections in patients with aplastic anemia.18 The infectious risk is directly related to the duration and severity of neutropenia, with one study demonstrating a significant increase in risk in AML patients with neutropenia lasting longer than 3 weeks.21 Invasive fungal infections carry a high mortality in patients with severe neutropenia, though due to earlier recognition and empiric antifungal therapy with extended-spectrum azoles, overall mortality secondary to invasive fungal infections is declining.19,22
While neutropenia related to cytotoxic chemotherapy is commonly associated with gram-negative bacteria due to disruption of mucosal barriers, patients with aplastic anemia have an increased incidence of gram-positive bacteremia with staphylococcal species compared to other neutropenic populations.18,19 This appears to be changing with time. Valdez and colleagues demonstrated a decrease in prevalence of coagulase-negative staphylococcal infections, increased prevalence of gram-positive bacilli bacteremia, and no change in prevalence of gram-negative bacteremia in patients with aplastic anemia treated between 1989 and 2008.22 Gram-negative bacteremia caused by Stenotrophomonas maltophila, Escherichia coli, Klebsiella pneumoniae, Citrobacter, and Proteus has also been reported.19 Despite a lack of clinical trials investigating the role of antifungal and antibacterial prophylaxis for patients with aplastic anemia, most centers initiate antifungal prophylaxis in patients with severe aplastic anema (SAA) or VSAA with an anti-mold agent such as voriconazole or posaconazole (which has the additional benefit compared to voriconazole of covering Mucor species).17,23 This is especially true for patients who have received ATG or undergone HSCT. For antimicrobial prophylaxis, a fluoroquinolone antibiotic with a spectrum of activity against Pseudomonas should be considered for patients with an ANC < 500 cells/µL.17 Acyclovir or valacyclovir prophylaxis is recommended for varicella-zoster virus and herpes simplex virus. Cytomegalovirus reactivation is minimal in patients with aplastic anemia, unless multiple courses of ATG are used.
Iron overload is another complication the provider must be aware of in the setting of increased transfusions in aplastic anemia patients. Lee and colleagues demonstrated that iron chelation therapy using deferasirox is effective at reducing serum ferritin levels in patients with aplastic anemia (median ferritin level: 3254 ng/mL prior to therapy, 1854 ng/mL following), and is associated with no serious adverse events (most common adverse events included nausea, diarrhea, vomiting, and rash).24 Approximately 25% of patients in this trial demonstrated an increase in creatinine, with patients taking concomitant cyclosporine more affected than those on chelation therapy alone.24 For patients following HSCT or with improved hematopoiesis following immunosuppressive therapy, phlebotomy can be used to treat iron overload in lieu of chelation therapy.15
Approach to Therapy
The main treatment options for SAA and VSAA include allogeneic bone marrow transplant and immunosuppression. The deciding factors as to which treatment is best initially depends on the availability of HLA-matched related donors and age (Figure 1 and Figure 2). Survival is decreased in patients with SAA or VSAA who delay initiation of therapy, and therefore prompt referral for HLA typing and evaluation for bone marrow transplant is a very important first step in managing aplastic anemia.
Matched Sibling Donor Transplant
Current standards of care recommend HLA-matched sibling donor transplant for patients with SAA or VSAA who are younger than 50 years of age, with the caveat that integration of fludarabine and reduced cyclophosphamide dosing along with ATG shows the best overall outcomes. Locasciulli and colleagues examined outcomes in patients given either immunosuppressive therapy or sibling HSCT between 1991-1996 and 1997-2002, respectively, and found that sibling HSCT was associated with a superior 10-year OS compared to immunosuppressive therapy (73% versus 68%).25 Interestingly in this study, there was no OS improvement seen with immunosuppressive therapy alone (69% versus 73%) between the 2 time periods, despite increased OS in both sibling HSCT (74% and 80%) and matched unrelated donor HSCT (38% and 65%).25 Though total body irradiation has been used in the past, it is typically not included in current conditioning regimens for matched related donor transplants.26
Current conditioning regimens typically use a combination of cyclophosphamide and ATG27,28 with or without fludarabine. Fludarabine-based conditioning regimens have shown promise in patients undergoing sibling HSCT. Maury and colleagues evaluated the role of fludarabine in addition to low-dose cyclophosphamide and ATG compared to cyclophosphamide alone or in combination with ATG in patients over age 30 undergoing sibling HSCT.9 There was a nonsignificant improvement in 5-year OS in the fludarabine arm compared to controls (77% ± 8% versus 60% ± 3%, P = 0.14) in the pooled analysis, but when adjusted for age the fludarabine arm had a significantly lower relative risk (RR) of death (RR, 0.44; P = 0.04) compared to the control arm. Shin et al reported outcomes with fludarabine/cyclophosphamide/ATG, with excellent overall outcomes and no difference in patients older or younger than 40 years.29 In addition, Kim et al evaluated their experience with patients older than 40 years of age receiving matched related donors, finding comparable outcomes in those aged 41 to 50 years compared to younger patients. Outcomes did decline in those over the age of 50 years.30 Long-term data for matched related donor transplant for aplastic anemia shows excellent long-term outcomes, with minimal chronic GVHD and good performance status.31 Hence, these factors support the role of matched related donor transplant as the initial treatment in SAA and VSAA.
Regarding the role of transplant for patients who lack a matched related donor, a growing body of literature demonstrating identical outcomes between matched related and matched unrelated donor (MUD) transplants for pediatric patients32,33 supports recent recommendations for upfront unrelated donor transplantation for aplastic anemia.34,35
Immunosuppressive Therapy
For patients without an HLA-matched sibling donor or those who are older than 50 years of age, immunosuppressive therapy is the first-line therapy. ATG and cyclosporine A are the treatments of choice.36 The potential effectiveness of immunosuppressive therapy in treating aplastic anemia was initially observed in patients in whom autologous transplant failed but who still experienced hematopoietic reconstitution despite the failed graft; this observation led to the hypothesis that the conditioning regimen may have an effect on hematopoiesis.16,36,37
Anti-thymocyte globulin. Immunosuppressive therapy with ATG has been used for the treatment of aplastic anemia since the 1980s.38 Historically, rabbit ATG had been used, but a 2011 study of horse ATG demonstrated superior hematological response at 6 months compared to rabbit ATG (68% versus 37%).16 Superior survival was also seen with horse ATG compared to rabbit ATG (3-year OS: 96% versus 76%). Due to these results, horse ATG is preferred over rabbit ATG. ATG should be used in combination with cyclosporine A to optimize outcomes.
Cyclosporine A. Early studies also demonstrated the efficacy of cyclosporine A in the treatment of aplastic anemia, with response rates equivalent to that of ATG monotherapy.39 Recent publications still note the efficacy of cyclosporine A in the treatment of aplastic anemia. Its role as an affordable option for single-agent therapy in developing countries is intriguing.39
The combination of the ATG and cyclosporine A was proven superior to either agent alone in a study by Frickhofen et al.37 In this study patients were randomly assigned to a control arm that received ATG plus methylprednisolone or to an arm that received ATG plus cyclosporine A and methylprednisolone. At 6 months, 70% of patients in the cyclosporine A arm had a complete remission (CR) or partial remission compared to 46% in the control arm.40 Further work confirmed the long-term efficacy of this regimen, reporting a 7-year OS of 55%.41 Among a pediatric population, immunosuppressive therapy was associated with an 83% 10-year OS.42
It is recommended that patients remain on cyclosporine therapy for a minimum of 6 months, after which a gradual taper may be considered, although there is variation among practitioners, with some continuing immunosuppressive therapy for a minimum of 12 months due to a proportion of patients being cyclosporine dependent.42,43 A study found that within a population of patients who responded to immunosuppressive therapy, 18% became cyclosporine dependent.42 The median duration of cyclosporine A treatment at full dose was 12 months, with tapering completed over a median of 19 months after patients had been in a stable CR for a minimum of 3 months. Relapse occurred more often when patients were tapered quickly (decrease ≥ 0.8 mg/kg/month) compared to slowly (0.4-0.7 mg/kg/month) or very slowly (< 0.3 mg/kg/month).
Immunosuppressive therapy plus eltrombopag. Townsley and colleagues recently investigated incorporating the use of the thrombopoietin receptor agonist eltrombopag with immunosuppressive therapy as first-line therapy in aplastic anemia.44 When given at a dose of 150 mg daily in patients aged 12 years and older or 75 mg daily in patients younger than 12 years, in conjunction with cyclosporine A and ATG, patients demonstrated markedly improved hematological response compared to historical treatment with standard immunosuppressive therapy alone.44 In the patient cohort administered eltrombopag starting on day 1 and continuing for 6 months, the complete response rate was 58%. Eltrombopag led to improvement in all cell lines among all treatment subgroups, and OS (censored for patients who proceeded to transplant) was 99% at 2 years.45 Overall, toxicities associated with this therapy were low, with liver enzyme elevations most commonly observed.44 Recently, a phase 2 trial of immunosuppressive therapy with or without eltrombopag was reported. Of the 38 patients enrolled, overall response, complete response, and time to response were not statistically different.46 With this recent finding, the role of eltrombopag in addition to immunosuppressive therapy is not clearly defined, and further studies are warranted.
OS for patients who do not respond to immunosuppressive therapy is approximately 57% at 5 years, largely due to improved supportive measures among this patient population.4,22 Therefore, it is important to recognize those patients who have a low chance of response so that second-line therapy can be pursued to improve outcomes.
Matched Unrelated Donor Transplant
For patients with refractory disease following immunosuppressive therapy who lack a matched sibling donor, MUD HSCT is considered standard therapy given the marked improvement in overall outcomes with modulating conditioning regimens and high-resolution HLA typing. A European Society for Blood and Marrow Transplantation analysis comparing matched sibling HSCT to MUD HSCT noted significantly higher rates of acute grade II-IV and grade III-V GVHD (grade II-IV 13% versus 25%, grade III-IV 5% versus 10%) among patients undergoing MUD transplant.47 Chronic GVHD rates were 14% in the sibling group, as compared to 26% in the MUD group. Additional benefits seen in this analysis included improved survival when transplanted under age 20 years (84% versus 72%), when transplanted within 6 months of diagnosis (85% versus 72%), the use of ATG in the conditioning regimen (81% versus 73%), and when the donor and recipient were cytomegalovirus-negative compared to other combinations (82% versus 76%).47 Interestingly, this study demonstrated that OS was not significantly increased when using a sibling HSCT compared to a MUD HSCT, likely as a result of improved understanding of conditioning regimens, GVHD prophylaxis, and supportive care.
Additional studies of MUD HSCT have shown outcomes similar to those seen in sibling HSCT.4,43 A French study found a significant increase in survival in patients undergoing MUD HSCT compared to historical cohorts (2000-2005: OS 52%; 2006-2012: OS 74%).33 The majority of patients underwent conditioning with cyclophosphamide or a combination of busulfan and cyclophosphamide, with or without fludarabine; 81% of patients included underwent in vivo T-cell depletion, and a bone marrow donor source was utilized. OS was significantly lower in patients over age 30 years undergoing MUD HSCT (57%) compared to those under age 30 years (70%). Improved OS was also seen when patients underwent transplant within 1 year of diagnosis and when a 10/10 matched donor (compared to a 9/10 mismatched donor) was utilized.4 A 2015 study investigated the role of MUD HSCT as frontline therapy instead of immunosuppressive therapy in patients without a matched sibling donor.33 The 2-year OS was 96% in the MUD HSCT cohort compared to 91%, 94%, and 74% in historical cohorts of sibling HSCT, frontline immunosuppressive therapy, and second-line MUD HSCT following failed immunosuppressive therapy, respectively. Additionally, event-free survival in the MUD HSCT cohort (defined by the authors as death, lack of response, relapse, occurrence of clonal evolution/clinical paroxysmal nocturnal hemoglobinuria, malignancies developing over follow‐up, and transplant for patients receiving immunosuppressive therapy frontline) was similar compared to sibling HSCT and superior to frontline immunosuppressive therapy and second-line MUD HSCT. Furthermore, Samarasinghe et al highlighted the importance of in vivo T-cell depletion with either ATG or alemtuzumab (anti-CD52 monoclonal antibody) in the prevention of acute and chronic GVHD in both sibling HSCT and MUD HSCT.48
With continued improvement of less toxic and more immunomodulating conditioning regimens, utilization of bone marrow as a donor cell source, in vivo T-cell depletion, and use of GVHD and antimicrobial prophylaxis, more clinical evidence supports elevating MUD HSCT in the treatment plan for patients without a matched sibling donor.49 However, there is still a large population of patients without matched sibling or unrelated donor options. In an effort to expand the transplant pool and thus avoid clonal hematopoiesis, clinically significant paroxysmal nocturnal hemoglobinuria, and relapsed aplastic anemia, more work continues to recognize the expanding role of alternative donor transplants (cord blood and haploidentical) as another viable treatment strategy for aplastic anemia after immunosuppressive therapy failure.50
Summary
Aplastic anemia is a rare but potentially life-threatening disorder characterized by pancytopenia and a marked reduction in the hematopoietic stem cell compartment. Treatment should be instituted as soon as the dignosis of aplastic anemia is established. Treatment outcomes are excellent with modern supportive care and the current approach to allogeneic transplantation, and therefore referral to a bone marrow transplant program to evaluate for early transplantation is the new standard of care.
1. Peffault De Latour R, Le Rademacher J, Antin JH, et al. Allogeneic hematopoietic stem cell transplantation in Fanconi anemia: the European Group for Blood and Marrow Transplantation experience.” Blood. 2013;122:4279-4286.
2. Auerbach AD. Diagnosis of Fanconi anemia by diepoxybutane analysis. Curr Protoc Hum Genet. 2015;85:8.7.1-17.
3. Eapen M, et al. Effect of stem cell source on outcomes after unrelated donor transplantation in severe aplastic anemia. Blood. 2011;118:2618-2621.
4. Devillier R, Dalle JH, Kulasekararaj A, et al. Unrelated alternative donor transplantation for severe acquired aplastic anemia: a study from the French Society of Bone Marrow Transplantation and Cell Therapies and the Severe Aplastic Anemia Working Party of EBMT. Haematologica. 2016;101:884-890.
5. Peffault de Latour R, Peters C, Gibson B, et al. Recommendations on hematopoietic stem cell transplantation for inherited bone marrow failure syndromes.” Bone Marrow Transplant. 2015;50:1168-1172.
6. De Medeiros CR, Zanis-Neto J, Pasquini R. Bone marrow transplantation for patients with Fanconi anemia: reduced doses of cyclophosphamide without irradiation as conditioning. Bone Marrow Transplant. 1999;24:849-852.
7. Mohanan E, Panetta JC, Lakshmi KM, et al. Population pharmacokinetics of fludarabine in patients with aplastic anemia and Fanconi anemia undergoing allogeneic hematopoietic stem cell transplantation. Bone Marrow Transplant. 2017;52:977-983.
8 Gluckman E, Auerbach AD, Horowitz MM, et al. Bone marrow transplantation for Fanconi anemia. Blood. 1995;86:2856-2862.
9. Maury S, Bacigalupo A, Anderlini P, et al. Improved outcome of patients older than 30 years receiving HLA-identical sibling hematopoietic stem cell transplantation for severe acquired aplastic anemia using fludarabine-based conditioning: a comparison with conventional conditioning regimen. Haematologica. 2009;94:1312-1315.
10. Talbot A, Peffault de Latour R, Raffoux E, et al. Sequential treatment for allogeneic hematopoietic stem cell transplantation in Fanconi anemia with acute myeloid leukemia. Haematologica. 2014;99:e199-200.
11. Ayas M, Saber W, Davies SM, et al. Allogeneic hematopoietic cell transplantation for fanconi anemia in patients with pretransplantation cytogenetic abnormalities, myelodysplastic syndrome, or acute leukemia. J Clin Oncol. 2013;31:1669-1676.
12. Vaht K, Göransson M, Carlson K, et al. Incidence and outcome of acquired aplastic anemia: real-world data from patients diagnosed in Sweden from 2000–2011. Haematologica. 2017;102:1683-1690.
13. Passweg JR, Marsh JC. Aplastic anemia: first-line treatment by immunosuppression and sibling marrow transplantation. Hematology Am Soc Hematol Educ Program. 2010;2010:36-42.
14. Laundy GJ, Bradley BA, Rees BM, et al. Incidence and specificity of HLA antibodies in multitransfused patients with acquired aplastic anemia. Transfusion. 2004;44:814-825.
15. Killick SB, Bown N, Cavenagh J, et al. Guidelines for the diagnosis and management of adult aplastic anaemia. Br J Haematol. 2016;172:187-207.
16. Scheinberg P, Nunez O, Weinstein B, et al. Horse versus rabbit antithymocyte globulin in acquired aplastic anemia. N Eng J Med. 2011;365:430-438.
17. Höchsmann B, Moicean A, Risitano A, et al. Supportive care in severe and very severe aplastic anemia. Bone Marrow Transplant. 2013;48:168-173.
18. Valdez JM, Scheinberg P, Young NS, Walsh TJ. Infections in patients with aplastic anemia. Sem Hematol. 2009;46:269-276.
19. Torres HA, Bodey GP, Rolston KV, et al. Infections in patients with aplastic anemia: experience at a tertiary care cancer center. Cancer. 2003;98:86-93.
20. Tichelli A, Schrezenmeier H, Socié G, et al. A randomized controlled study in patients with newly diagnosed severe aplastic anemia receiving antithymocyte globulin (ATG), cyclosporine, with or without G-CSF: a study of the SAA Working Party of the European Group for Blood and Marrow Transplantation. Blood. 2011;117:4434-4441.
21. Gerson SL, Talbot GH, Hurwitz S, et al. Prolonged granulocytopenia: the major risk factor for invasive pulmonary aspergillosis in patients with acute leukemia. Ann Intern Med. 1984;100:345-351.
22. Valdez JM, Scheinberg P, Nunez O, et al. Decreased infection-related mortality and improved survival in severe aplastic anemia in the past two decades. Clin Infect Dis. 2011;52:726-735.
23. Robenshtok E, Gafter-Gvili A, Goldberg E, et al. Antifungal prophylaxis in cancer patients after chemotherapy or hematopoietic stem-cell transplantation: systematic review and meta-analysis. J Clin Oncol. 2007;25:5471-5489.
24. Lee JW, Yoon SS, Shen ZX, et al. Iron chelation therapy with deferasirox in patients with aplastic anemia: a subgroup analysis of 116 patients from the EPIC trial. Blood. 2010;116:2448-2554.
25. Locasciulli A, Oneto R, Bacigalupo A, et al. Outcome of patients with acquired aplastic anemia given first line bone marrow transplantation or immunosuppressive treatment in the last decade: a report from the European Group for Blood and Marrow Transplantation. Haematologica. 2007;92:11-8.
26. Deeg HJ, Amylon MD, Harris RE, et al. Marrow transplants from unrelated donors for patients with aplastic anemia: minimum effective dose of total body irradiation. Biol Blood Marrow Transplant. 2001;7:208-215.
27. Kahl C, Leisenring W, Joachim Deeg H, et al. Cyclophosphamide and antithymocyte globulin as a conditioning regimen for allogeneic marrow transplantation in patients with aplastic anaemia: a long‐term follow‐up. Br J Haematol. 2005;130:747-751.
28. Socié G. Allogeneic BM transplantation for the treatment of aplastic anemia: current results and expanding donor possibilities. ASH Education Program Book. 2013;2013:82-86.
29. Shin SH, Jeon YW, Yoon JH, et al. Comparable outcomes between younger (<40 years) and older (>40 years) adult patients with severe aplastic anemia after HLA-matched sibling stem cell transplantation using fludarabine-based conditioning. Bone Marrow Transplant. 2016;51:1456-1463.
30. Kim H, Lee KH, Yoon SS, et al; Korean Society of Blood and Marrow Transplantation. Allogeneic hematopoietic stem cell transplant for adults over 40 years old with acquired aplastic anemia. Biol Blood Marrow Transplant. 2012;18:1500-1508.
31. Mortensen BK, Jacobsen N, Heilmann C, Sengelov H. Allogeneic hematopoietic cell transplantation for severe aplastic anemia: similar long-term overall survival after transplantation with related donors compared to unrelated donors. Bone Marrow Transplant. 2016;51:288-290.
32. Dufour C, Svahn J, Bacigalupo A. Front-line immunosuppressive treatment of acquired aplastic anemia. Bone Marrow Transplant. 2013;48:174-177.
33. Dufour C, Veys P, Carraro E, et al. Similar outcome of upfront-unrelated and matched sibling stem cell transplantation in idiopathic paediatric aplastic anaemia. A study on the behalf of the UK Paediatric BMT Working Party, Paediatric Diseases Working Party and Severe Aplastic Anaemia Working Party of the EBMT. Br. J Haematol. 2015;151:585-594.
34. Georges GE, Doney K, Storb R. Severe aplastic anemia: allogeneic bone marrow transplantation as first-line treatment. Blood Adv. 2018;2:2020-2028.
35. Yoshida N, Kojima S. Updated guidelines for the treatment of acquired aplastic anemia in children. Curr Oncol Rep. 2018;20:67.
36. Mathe G, Amiel JL, Schwarzenberg L, et al. Bone marrow graft in man after conditioning by antilymphocytic serum. Br Med J. 1970;2:131-136.
37. Frickhofen N, Kaltwasser JP, Schrezenmeier H, et al, German Aplastic Anemia Study Group. Treatment of aplastic anemia with antilymphocyte globulin and methylprednisolone with or without cyclosporine. N Engl J Med. 1991;324:1297-1304.
38. Speck B, Gratwohl A, Nissen C, et al. Treatment of severe aplastic anaemia with antilymphocyte globulin or bone-marrow transplantation. Br Med J. 1981;282:860-863.
39. Al-Ghazaly J, Al-Dubai W, Al-Jahafi AK, et al. Cyclosporine monotherapy for severe aplastic anemia: a developing country experience. Ann Saudi Med. 2005;25:375-379.
40. Scheinberg P, Young NS. How I treat acquired aplastic anemia. Blood. 2012;120:1185-1196.
41. Rosenfeld S, Follmann D, Nunez O, Young NS. Antithymocyte globulin and cyclosporine for severe aplastic anemia: association between hematologic response and long-term outcome. JAMA. 2003;289:1130-1135.
42. Saracco P, Quarello P, Iori AP, et al. Cyclosporin A response and dependence in children with acquired aplastic anaemia: a multicentre retrospective study with long‐term observation follow‐up. Br J Haematol. 2008;140:197-205.
43. Bacigalupo A. How I treat acquired aplastic anemia. Blood. 2017;129:1428-1436.
44. Townsley DM, Scheinberg P, Winkler T, et al. Eltrombopag added to standard immunosuppression for aplastic anemia. N Engl J Med. 2017;376:1540-1550.
45. Olnes MJ, Scheinberg P, Calvo KR, et al. Eltrombopag and improved hematopoiesis in refractory aplastic anemia. N Engl J Med. 2012;367:11-19.
46. Assi R, Garcia-Manero G, Ravandi F, et al. Addition of eltrombopag to immunosuppressive therapy in patients with newly diagnosed aplastic anemia. Cancer. 2018 Oct 11. doi: 10.1002/cncr.31658.
47. Bacigalupo A, Socié G, Hamladji RM, et al. Current outcome of HLA identical sibling vs. unrelated donor transplants in severe aplastic anemia: an EBMT analysis. Haematologica. 2015;100:696-702.
48. Samarasinghe S, Iacobelli S, Knol C, et al. Impact of different in vivo T cell depletion strategies on outcomes following hematopoietic stem cell transplantation for idiopathic aplastic anaemia: a study on behalf of the EBMT SAA Working Party. 2018Oct 17. doi: 10.1002/ajh.25314.
49. Clesham K, Dowse R, Samarasinghe S. Upfront matched unrelated donor transplantation in aplastic anemia. Hematol Oncol Clin North Am. 2018;32:619-628.
50. DeZern AE, Brodsky RA. Haploidentical donor bone marrow transplantation for severe aplastic anemia. Hematol Oncol Clin North Am. 2018;32:629-642.
1. Peffault De Latour R, Le Rademacher J, Antin JH, et al. Allogeneic hematopoietic stem cell transplantation in Fanconi anemia: the European Group for Blood and Marrow Transplantation experience.” Blood. 2013;122:4279-4286.
2. Auerbach AD. Diagnosis of Fanconi anemia by diepoxybutane analysis. Curr Protoc Hum Genet. 2015;85:8.7.1-17.
3. Eapen M, et al. Effect of stem cell source on outcomes after unrelated donor transplantation in severe aplastic anemia. Blood. 2011;118:2618-2621.
4. Devillier R, Dalle JH, Kulasekararaj A, et al. Unrelated alternative donor transplantation for severe acquired aplastic anemia: a study from the French Society of Bone Marrow Transplantation and Cell Therapies and the Severe Aplastic Anemia Working Party of EBMT. Haematologica. 2016;101:884-890.
5. Peffault de Latour R, Peters C, Gibson B, et al. Recommendations on hematopoietic stem cell transplantation for inherited bone marrow failure syndromes.” Bone Marrow Transplant. 2015;50:1168-1172.
6. De Medeiros CR, Zanis-Neto J, Pasquini R. Bone marrow transplantation for patients with Fanconi anemia: reduced doses of cyclophosphamide without irradiation as conditioning. Bone Marrow Transplant. 1999;24:849-852.
7. Mohanan E, Panetta JC, Lakshmi KM, et al. Population pharmacokinetics of fludarabine in patients with aplastic anemia and Fanconi anemia undergoing allogeneic hematopoietic stem cell transplantation. Bone Marrow Transplant. 2017;52:977-983.
8 Gluckman E, Auerbach AD, Horowitz MM, et al. Bone marrow transplantation for Fanconi anemia. Blood. 1995;86:2856-2862.
9. Maury S, Bacigalupo A, Anderlini P, et al. Improved outcome of patients older than 30 years receiving HLA-identical sibling hematopoietic stem cell transplantation for severe acquired aplastic anemia using fludarabine-based conditioning: a comparison with conventional conditioning regimen. Haematologica. 2009;94:1312-1315.
10. Talbot A, Peffault de Latour R, Raffoux E, et al. Sequential treatment for allogeneic hematopoietic stem cell transplantation in Fanconi anemia with acute myeloid leukemia. Haematologica. 2014;99:e199-200.
11. Ayas M, Saber W, Davies SM, et al. Allogeneic hematopoietic cell transplantation for fanconi anemia in patients with pretransplantation cytogenetic abnormalities, myelodysplastic syndrome, or acute leukemia. J Clin Oncol. 2013;31:1669-1676.
12. Vaht K, Göransson M, Carlson K, et al. Incidence and outcome of acquired aplastic anemia: real-world data from patients diagnosed in Sweden from 2000–2011. Haematologica. 2017;102:1683-1690.
13. Passweg JR, Marsh JC. Aplastic anemia: first-line treatment by immunosuppression and sibling marrow transplantation. Hematology Am Soc Hematol Educ Program. 2010;2010:36-42.
14. Laundy GJ, Bradley BA, Rees BM, et al. Incidence and specificity of HLA antibodies in multitransfused patients with acquired aplastic anemia. Transfusion. 2004;44:814-825.
15. Killick SB, Bown N, Cavenagh J, et al. Guidelines for the diagnosis and management of adult aplastic anaemia. Br J Haematol. 2016;172:187-207.
16. Scheinberg P, Nunez O, Weinstein B, et al. Horse versus rabbit antithymocyte globulin in acquired aplastic anemia. N Eng J Med. 2011;365:430-438.
17. Höchsmann B, Moicean A, Risitano A, et al. Supportive care in severe and very severe aplastic anemia. Bone Marrow Transplant. 2013;48:168-173.
18. Valdez JM, Scheinberg P, Young NS, Walsh TJ. Infections in patients with aplastic anemia. Sem Hematol. 2009;46:269-276.
19. Torres HA, Bodey GP, Rolston KV, et al. Infections in patients with aplastic anemia: experience at a tertiary care cancer center. Cancer. 2003;98:86-93.
20. Tichelli A, Schrezenmeier H, Socié G, et al. A randomized controlled study in patients with newly diagnosed severe aplastic anemia receiving antithymocyte globulin (ATG), cyclosporine, with or without G-CSF: a study of the SAA Working Party of the European Group for Blood and Marrow Transplantation. Blood. 2011;117:4434-4441.
21. Gerson SL, Talbot GH, Hurwitz S, et al. Prolonged granulocytopenia: the major risk factor for invasive pulmonary aspergillosis in patients with acute leukemia. Ann Intern Med. 1984;100:345-351.
22. Valdez JM, Scheinberg P, Nunez O, et al. Decreased infection-related mortality and improved survival in severe aplastic anemia in the past two decades. Clin Infect Dis. 2011;52:726-735.
23. Robenshtok E, Gafter-Gvili A, Goldberg E, et al. Antifungal prophylaxis in cancer patients after chemotherapy or hematopoietic stem-cell transplantation: systematic review and meta-analysis. J Clin Oncol. 2007;25:5471-5489.
24. Lee JW, Yoon SS, Shen ZX, et al. Iron chelation therapy with deferasirox in patients with aplastic anemia: a subgroup analysis of 116 patients from the EPIC trial. Blood. 2010;116:2448-2554.
25. Locasciulli A, Oneto R, Bacigalupo A, et al. Outcome of patients with acquired aplastic anemia given first line bone marrow transplantation or immunosuppressive treatment in the last decade: a report from the European Group for Blood and Marrow Transplantation. Haematologica. 2007;92:11-8.
26. Deeg HJ, Amylon MD, Harris RE, et al. Marrow transplants from unrelated donors for patients with aplastic anemia: minimum effective dose of total body irradiation. Biol Blood Marrow Transplant. 2001;7:208-215.
27. Kahl C, Leisenring W, Joachim Deeg H, et al. Cyclophosphamide and antithymocyte globulin as a conditioning regimen for allogeneic marrow transplantation in patients with aplastic anaemia: a long‐term follow‐up. Br J Haematol. 2005;130:747-751.
28. Socié G. Allogeneic BM transplantation for the treatment of aplastic anemia: current results and expanding donor possibilities. ASH Education Program Book. 2013;2013:82-86.
29. Shin SH, Jeon YW, Yoon JH, et al. Comparable outcomes between younger (<40 years) and older (>40 years) adult patients with severe aplastic anemia after HLA-matched sibling stem cell transplantation using fludarabine-based conditioning. Bone Marrow Transplant. 2016;51:1456-1463.
30. Kim H, Lee KH, Yoon SS, et al; Korean Society of Blood and Marrow Transplantation. Allogeneic hematopoietic stem cell transplant for adults over 40 years old with acquired aplastic anemia. Biol Blood Marrow Transplant. 2012;18:1500-1508.
31. Mortensen BK, Jacobsen N, Heilmann C, Sengelov H. Allogeneic hematopoietic cell transplantation for severe aplastic anemia: similar long-term overall survival after transplantation with related donors compared to unrelated donors. Bone Marrow Transplant. 2016;51:288-290.
32. Dufour C, Svahn J, Bacigalupo A. Front-line immunosuppressive treatment of acquired aplastic anemia. Bone Marrow Transplant. 2013;48:174-177.
33. Dufour C, Veys P, Carraro E, et al. Similar outcome of upfront-unrelated and matched sibling stem cell transplantation in idiopathic paediatric aplastic anaemia. A study on the behalf of the UK Paediatric BMT Working Party, Paediatric Diseases Working Party and Severe Aplastic Anaemia Working Party of the EBMT. Br. J Haematol. 2015;151:585-594.
34. Georges GE, Doney K, Storb R. Severe aplastic anemia: allogeneic bone marrow transplantation as first-line treatment. Blood Adv. 2018;2:2020-2028.
35. Yoshida N, Kojima S. Updated guidelines for the treatment of acquired aplastic anemia in children. Curr Oncol Rep. 2018;20:67.
36. Mathe G, Amiel JL, Schwarzenberg L, et al. Bone marrow graft in man after conditioning by antilymphocytic serum. Br Med J. 1970;2:131-136.
37. Frickhofen N, Kaltwasser JP, Schrezenmeier H, et al, German Aplastic Anemia Study Group. Treatment of aplastic anemia with antilymphocyte globulin and methylprednisolone with or without cyclosporine. N Engl J Med. 1991;324:1297-1304.
38. Speck B, Gratwohl A, Nissen C, et al. Treatment of severe aplastic anaemia with antilymphocyte globulin or bone-marrow transplantation. Br Med J. 1981;282:860-863.
39. Al-Ghazaly J, Al-Dubai W, Al-Jahafi AK, et al. Cyclosporine monotherapy for severe aplastic anemia: a developing country experience. Ann Saudi Med. 2005;25:375-379.
40. Scheinberg P, Young NS. How I treat acquired aplastic anemia. Blood. 2012;120:1185-1196.
41. Rosenfeld S, Follmann D, Nunez O, Young NS. Antithymocyte globulin and cyclosporine for severe aplastic anemia: association between hematologic response and long-term outcome. JAMA. 2003;289:1130-1135.
42. Saracco P, Quarello P, Iori AP, et al. Cyclosporin A response and dependence in children with acquired aplastic anaemia: a multicentre retrospective study with long‐term observation follow‐up. Br J Haematol. 2008;140:197-205.
43. Bacigalupo A. How I treat acquired aplastic anemia. Blood. 2017;129:1428-1436.
44. Townsley DM, Scheinberg P, Winkler T, et al. Eltrombopag added to standard immunosuppression for aplastic anemia. N Engl J Med. 2017;376:1540-1550.
45. Olnes MJ, Scheinberg P, Calvo KR, et al. Eltrombopag and improved hematopoiesis in refractory aplastic anemia. N Engl J Med. 2012;367:11-19.
46. Assi R, Garcia-Manero G, Ravandi F, et al. Addition of eltrombopag to immunosuppressive therapy in patients with newly diagnosed aplastic anemia. Cancer. 2018 Oct 11. doi: 10.1002/cncr.31658.
47. Bacigalupo A, Socié G, Hamladji RM, et al. Current outcome of HLA identical sibling vs. unrelated donor transplants in severe aplastic anemia: an EBMT analysis. Haematologica. 2015;100:696-702.
48. Samarasinghe S, Iacobelli S, Knol C, et al. Impact of different in vivo T cell depletion strategies on outcomes following hematopoietic stem cell transplantation for idiopathic aplastic anaemia: a study on behalf of the EBMT SAA Working Party. 2018Oct 17. doi: 10.1002/ajh.25314.
49. Clesham K, Dowse R, Samarasinghe S. Upfront matched unrelated donor transplantation in aplastic anemia. Hematol Oncol Clin North Am. 2018;32:619-628.
50. DeZern AE, Brodsky RA. Haploidentical donor bone marrow transplantation for severe aplastic anemia. Hematol Oncol Clin North Am. 2018;32:629-642.
Matched transplant improves stroke risk indicator in sickle cell anemia
, suggesting that this intervention may improve outcomes related to cerebral vasculopathy.
Matched sibling donor hematopoietic stem cell transplantation (MSD-HSCT) was linked to significantly lower transcranial Doppler (TCD) velocities at one year compared to standard care in the 9-center study, investigators reported in JAMA.
The study enrolled children with sickle cell anemia who required chronic transfusion due to persistently high TCD velocities, which are associated with increased stroke risk, researchers said.
“Further research is warranted to assess the effects of MSD-HSCT on clinical outcomes and over longer follow-up,” said the researchers, led by Françoise Bernaudin, MD, of Centre Hospitalier Intercommunal de Créteil, Créteil, France
In the non-randomized, prospective DREPAGREFFE study by Dr. Bernaudin and colleagues, 32 children with sickle cell anemia who had a matched sibling donor underwent transplantation, while another 35 children received standard therapy. The primary end point of the study was time-averaged mean of maximum velocities (TAMV) in cerebral arteries at one year.
The highest TAMV at one year was on average 129.6 cm/s in the MSD-HSCT group, versus 170.4 cm/s in the standard care group, for a difference of -40.8 cm/s (P less than .001), Dr. Bernaudin and co-investigators reported.
The improvement persisted at 3 years, with a TAMV of 112.4 cm/s in the transplantation group and 156.7 cm/s in the standard care group (P less than .001), which they also reported as a secondary outcome of the study.
These findings indicate that MSD-HSCT may allow patients with a history of abnormal TCD velocities to stop transfusions and hydroxyurea, Dr. Bernaudin and colleagues said.
The improvement in TCD velocities may be due in part to anemia correction, but also to the “exclusive presence” of normal red blood cells following transplantation, as opposed to simultaneous presence of normal and sickled cells as would be seen after transfusion, they added.
This study wasn’t powered to determine whether a 40 cm/s reduction in TCD velocities would translate into clinical benefits such as reduction in stenosis and silent infarct, or improved cognitive function, they said. Even so, there were no infarcts or stenoses in the MSD-HSCT group, whereas those event occurred in 9% and 6% of patients in the standard care group, respectively, they added.
Dr. Bernaudin reported disclosures related to Addmedica and bluebird bio. Co-authors reported disclosures with Addmedica, Novartis, Alexion, Amgen, Jazz Pharmaceuticals, and others.
SOURCE: Bernaudin F, et al. JAMA. 2019;321(3):266-276.
Results of DREPAGREFFE illustrate the benefits of matched sibling donor hematopoietic stem cell transplantation (HSCT) for a select group of children with sickle cell anemia, according to the author of an editorial on the study.
Matched sibling donor HSCT was well-tolerated in the study and linked to improved control of transcranial Doppler velocities compared to standard care, Janet L. Kwiatkowski, MD, said in the editorial.
“As a curative therapy, it also obviates the need for long-term treatment wrought with adherence challenges with the potential consequence of stroke, and morbidity from iron overload with transfusion therapy,” wrote Dr. Kwiatkowski.
Only a certain proportion of patients have matched sibling donor HSCT as a potential treatment choice, however, she added.
In this particular study, conducted at 9 sites in France, a higher-than-expected 48% of children with sickle cell anemia had a matched sibling donor, whereas in the United States, she said, less than 1 out of 5 such children would be expected to have an HLA-identical sibling donor.
Because many children don’t have an appropriate matched sibling donor, additional studies are needed not only to evaluate the role of HSCT using matched unrelated and haploidentical donors, Dr. Kwiatkowski said, but also to assess how gene therapy interventions impact cerebrovascular outcomes.
These comments are taken from the accompanying editorial in JAMA by Janet L. Kwiatkowski, MD, MSCE, of Children’s Hospital of Philadelphia, and the Department of Pediatrics at Perelman School of Medicine, University of Pennsylvania, Philadelphia. Dr. Kwiatowski disclosed relationships with bluebird bio, Apopharma, and Novartis.
Results of DREPAGREFFE illustrate the benefits of matched sibling donor hematopoietic stem cell transplantation (HSCT) for a select group of children with sickle cell anemia, according to the author of an editorial on the study.
Matched sibling donor HSCT was well-tolerated in the study and linked to improved control of transcranial Doppler velocities compared to standard care, Janet L. Kwiatkowski, MD, said in the editorial.
“As a curative therapy, it also obviates the need for long-term treatment wrought with adherence challenges with the potential consequence of stroke, and morbidity from iron overload with transfusion therapy,” wrote Dr. Kwiatkowski.
Only a certain proportion of patients have matched sibling donor HSCT as a potential treatment choice, however, she added.
In this particular study, conducted at 9 sites in France, a higher-than-expected 48% of children with sickle cell anemia had a matched sibling donor, whereas in the United States, she said, less than 1 out of 5 such children would be expected to have an HLA-identical sibling donor.
Because many children don’t have an appropriate matched sibling donor, additional studies are needed not only to evaluate the role of HSCT using matched unrelated and haploidentical donors, Dr. Kwiatkowski said, but also to assess how gene therapy interventions impact cerebrovascular outcomes.
These comments are taken from the accompanying editorial in JAMA by Janet L. Kwiatkowski, MD, MSCE, of Children’s Hospital of Philadelphia, and the Department of Pediatrics at Perelman School of Medicine, University of Pennsylvania, Philadelphia. Dr. Kwiatowski disclosed relationships with bluebird bio, Apopharma, and Novartis.
Results of DREPAGREFFE illustrate the benefits of matched sibling donor hematopoietic stem cell transplantation (HSCT) for a select group of children with sickle cell anemia, according to the author of an editorial on the study.
Matched sibling donor HSCT was well-tolerated in the study and linked to improved control of transcranial Doppler velocities compared to standard care, Janet L. Kwiatkowski, MD, said in the editorial.
“As a curative therapy, it also obviates the need for long-term treatment wrought with adherence challenges with the potential consequence of stroke, and morbidity from iron overload with transfusion therapy,” wrote Dr. Kwiatkowski.
Only a certain proportion of patients have matched sibling donor HSCT as a potential treatment choice, however, she added.
In this particular study, conducted at 9 sites in France, a higher-than-expected 48% of children with sickle cell anemia had a matched sibling donor, whereas in the United States, she said, less than 1 out of 5 such children would be expected to have an HLA-identical sibling donor.
Because many children don’t have an appropriate matched sibling donor, additional studies are needed not only to evaluate the role of HSCT using matched unrelated and haploidentical donors, Dr. Kwiatkowski said, but also to assess how gene therapy interventions impact cerebrovascular outcomes.
These comments are taken from the accompanying editorial in JAMA by Janet L. Kwiatkowski, MD, MSCE, of Children’s Hospital of Philadelphia, and the Department of Pediatrics at Perelman School of Medicine, University of Pennsylvania, Philadelphia. Dr. Kwiatowski disclosed relationships with bluebird bio, Apopharma, and Novartis.
, suggesting that this intervention may improve outcomes related to cerebral vasculopathy.
Matched sibling donor hematopoietic stem cell transplantation (MSD-HSCT) was linked to significantly lower transcranial Doppler (TCD) velocities at one year compared to standard care in the 9-center study, investigators reported in JAMA.
The study enrolled children with sickle cell anemia who required chronic transfusion due to persistently high TCD velocities, which are associated with increased stroke risk, researchers said.
“Further research is warranted to assess the effects of MSD-HSCT on clinical outcomes and over longer follow-up,” said the researchers, led by Françoise Bernaudin, MD, of Centre Hospitalier Intercommunal de Créteil, Créteil, France
In the non-randomized, prospective DREPAGREFFE study by Dr. Bernaudin and colleagues, 32 children with sickle cell anemia who had a matched sibling donor underwent transplantation, while another 35 children received standard therapy. The primary end point of the study was time-averaged mean of maximum velocities (TAMV) in cerebral arteries at one year.
The highest TAMV at one year was on average 129.6 cm/s in the MSD-HSCT group, versus 170.4 cm/s in the standard care group, for a difference of -40.8 cm/s (P less than .001), Dr. Bernaudin and co-investigators reported.
The improvement persisted at 3 years, with a TAMV of 112.4 cm/s in the transplantation group and 156.7 cm/s in the standard care group (P less than .001), which they also reported as a secondary outcome of the study.
These findings indicate that MSD-HSCT may allow patients with a history of abnormal TCD velocities to stop transfusions and hydroxyurea, Dr. Bernaudin and colleagues said.
The improvement in TCD velocities may be due in part to anemia correction, but also to the “exclusive presence” of normal red blood cells following transplantation, as opposed to simultaneous presence of normal and sickled cells as would be seen after transfusion, they added.
This study wasn’t powered to determine whether a 40 cm/s reduction in TCD velocities would translate into clinical benefits such as reduction in stenosis and silent infarct, or improved cognitive function, they said. Even so, there were no infarcts or stenoses in the MSD-HSCT group, whereas those event occurred in 9% and 6% of patients in the standard care group, respectively, they added.
Dr. Bernaudin reported disclosures related to Addmedica and bluebird bio. Co-authors reported disclosures with Addmedica, Novartis, Alexion, Amgen, Jazz Pharmaceuticals, and others.
SOURCE: Bernaudin F, et al. JAMA. 2019;321(3):266-276.
, suggesting that this intervention may improve outcomes related to cerebral vasculopathy.
Matched sibling donor hematopoietic stem cell transplantation (MSD-HSCT) was linked to significantly lower transcranial Doppler (TCD) velocities at one year compared to standard care in the 9-center study, investigators reported in JAMA.
The study enrolled children with sickle cell anemia who required chronic transfusion due to persistently high TCD velocities, which are associated with increased stroke risk, researchers said.
“Further research is warranted to assess the effects of MSD-HSCT on clinical outcomes and over longer follow-up,” said the researchers, led by Françoise Bernaudin, MD, of Centre Hospitalier Intercommunal de Créteil, Créteil, France
In the non-randomized, prospective DREPAGREFFE study by Dr. Bernaudin and colleagues, 32 children with sickle cell anemia who had a matched sibling donor underwent transplantation, while another 35 children received standard therapy. The primary end point of the study was time-averaged mean of maximum velocities (TAMV) in cerebral arteries at one year.
The highest TAMV at one year was on average 129.6 cm/s in the MSD-HSCT group, versus 170.4 cm/s in the standard care group, for a difference of -40.8 cm/s (P less than .001), Dr. Bernaudin and co-investigators reported.
The improvement persisted at 3 years, with a TAMV of 112.4 cm/s in the transplantation group and 156.7 cm/s in the standard care group (P less than .001), which they also reported as a secondary outcome of the study.
These findings indicate that MSD-HSCT may allow patients with a history of abnormal TCD velocities to stop transfusions and hydroxyurea, Dr. Bernaudin and colleagues said.
The improvement in TCD velocities may be due in part to anemia correction, but also to the “exclusive presence” of normal red blood cells following transplantation, as opposed to simultaneous presence of normal and sickled cells as would be seen after transfusion, they added.
This study wasn’t powered to determine whether a 40 cm/s reduction in TCD velocities would translate into clinical benefits such as reduction in stenosis and silent infarct, or improved cognitive function, they said. Even so, there were no infarcts or stenoses in the MSD-HSCT group, whereas those event occurred in 9% and 6% of patients in the standard care group, respectively, they added.
Dr. Bernaudin reported disclosures related to Addmedica and bluebird bio. Co-authors reported disclosures with Addmedica, Novartis, Alexion, Amgen, Jazz Pharmaceuticals, and others.
SOURCE: Bernaudin F, et al. JAMA. 2019;321(3):266-276.
FROM JAMA
Key clinical point: In children with sickle cell anemia, matched sibling donor hematopoietic stem cell transplants (HSCT) reduced an indicator of stroke risk, suggesting that the intervention may improve cerebrovascular outcomes.
Major finding: The primary end point, time-averaged mean of maximum velocities in cerebral arteries at one year, was on average 129.6 cm/s in the MSD-HSCT group, versus 170.4 cm/s in the standard care group (P less than .001).
Study details: A multicenter, non-randomized, prospective study (DREPAGREFFE) including 32 children with sickle cell anemia who underwent MSD-HSCT and 35 who received standard therapy.
Disclosures: Study authors provided disclosures related to Addmedica, bluebird bio, Novartis, Alexion, Amgen, Jazz Pharmaceuticals, and others.
Source: Bernaudin F, et al. JAMA. 2019;321(3):266-276.
Aplastic Anemia: Evaluation and Diagnosis
Aplastic anemia is a clinical and pathological entity of bone marrow failure that causes progressive loss of hematopoietic progenitor stem cells (HPSC), resulting in pancytopenia.1 Patients may present along a spectrum, ranging from being asymptomatic with incidental findings on peripheral blood testing to having life-threatening neutropenic infections or bleeding. Aplastic anemia results from either inherited or acquired causes, and the pathophysiology and treatment approach vary significantly between these 2 causes. Therefore, recognition of inherited marrow failure diseases, such as Fanconi anemia and telomere biology disorders, is critical to establish
Epidemiology
Aplastic anemia is a rare disorder, with an incidence of approximately 1.5 to 7 cases per million individuals per year.2,3 A recent Scandinavian study reported that the incidence of aplastic anemia among the Swedish population is 2.3 cases per million individuals per year, with a median age at diagnosis of 60 years and a slight female predominance (52% versus 48%, respectively).2 This data is congruent with prior observations made in Barcelona, where the incidence was 2.34 cases per million individuals per year, albeit with a slightly higher incidence in males compared to females (2.54 versus 2.16, respectively).4 The incidence of aplastic anemia varies globally, with a disproportionate increase in incidence seen among Asian populations, with rates as high as 8.8 per million individuals per year.3-5 This variation in incidence in Asia versus other countries has not been well explained. There appears to be a bimodal distribution, with incidence peaks seen in young adults and in older adults.2,3,6
Pathophysiology
Acquired Aplastic Anemia
The leading hypothesis as to the cause of most cases of acquired aplastic anemia is that a dysregulated immune system destroys hematopoietic progenitor cells. Inciting etiologies implicated in the development of acquired aplastic anemia include pregnancy, infection, medications, and exposure to certain chemicals, such as benzene.1,7 The historical understanding of acquired aplastic anemia implicates cytotoxic T-lymphocyte–mediated destruction of CD34+ hematopoietic stem cells.1,8,9 This hypothesis served as the basis for treatment of acquired aplastic anemia with immunosuppressive therapy, predominantly anti-thymocyte globulin (ATG) combined with cyclosporine A.1,8 More recent work has focused on cytokine interactions, particularly the suppressive role of interferon (IFN)-γ on hematopoietic stem cells independent of T-lymphocyte–mediated hematopoietic destruction, which has been demonstrated in a murine model.8 The interaction of IFN-γ with the hematopoietic stem cells pool is dynamic. IFN-γ levels are elevated during an acute inflammatory response such as a viral infection, providing further basis for the immune-mediated nature of the acquired disease.10 Specifically, in vitro studies suggest the effects of IFN-γ on HPSC may be secondary to interruption of thrombopoietin and its respective signaling pathways, which play a key role in hematopoietic stem cell renewal.11 Eltrombopag, a thrombopoietin receptor antagonist, has shown promise in the treatment of refractory aplastic anemia, with studies indicating that its effectiveness is independent of IFN-γ levels.11,12
Inherited Aplastic Anemia
The inherited marrow failure syndromes (IMFSs) are a group of disorders characterized by cellular maintenance and repair defects, leading to cytopenias, increased cancer risk, structural defects, and risk of end organ damage, such as liver cirrhosis and pulmonary fibrosis.13-15 The most common diseases include Fanconi anemia, dyskeratosis congenita/telomere biology disorders, Diamond-Blackfan anemia, and Shwachman-Diamond syndrome, but with the advent of whole exome sequencing new syndromes continue to be discovered. While classically these disorders present in children, adult presentations of these syndromes are now commonplace. Broadly, the pathophysiology of inherited aplastic anemia relates to the defective hematopoietic progenitor cells and an accelerated decline of the hematopoietic stem cell compartment.
The most common IMFS, Fanconi anemia and telomere biology disorders, are associated with numerous mutations in DNA damage repair pathways and telomere maintenance pathways. TERT, DKC, and TERC mutations are most commonly associated with dyskeratosis congenita, but may also be found infrequently in patients with aplastic anemia presenting at an older age in the absence of the classic phenotypical features.1,16,17 The recognition of an underlying genetic disorder or telomere biology disorder leading to constitutional aplastic anemia is significant, as these conditions are associated not only with marrow failure, but also endocrinopathies, organ fibrosis, and solid organ malignancies.13-15 In particular, mutations in the TERT and TERC genes have been associated with dyskeratosis congenita as well as pulmonary fibrosis and cirrhosis.18,19 The implications of early diagnosis of an IMFS lie in the approach to treatment and prognosis.
Clonal Disorders and Secondary Malignancies
Myelodysplastic syndrome (MDS) and secondary acute myeloid leukemia (AML) are 2 clonal disorders that may arise from a background of aplastic anemia.9,20,21 Hypoplastic MDS can be difficult to differentiate from aplastic anemia at diagnosis based on morphology alone, although recent work has demonstrated that molecular testing for somatic mutations in ASXL1, DNMT3A, and BCOR can aid in differentiating a subset of aplastic anemia patients who are more likely to progress to MDS.21 Clonal populations of cells harboring 6p uniparental disomy are seen in more than 10% of patients with aplastic anemia on cytogenetic analysis, which can help differentiate the diseases.9 Yoshizato and colleagues found lower rates of ASXL1 and DNMT3A mutations in patients with aplastic anemia as compared with patients with MDS or AML. In this study, patients with aplastic anemia had higher rates of mutations in PIGA (reflecting the increased paroxysmal nocturnal hemoglobinuria [PNH] clonality seen in aplastic anemia) and BCOR.9 Mutations were also found in genes commonly mutated in MDS and AML, including TET2, RUNX1, TP53, and JAK2, albeit at lower frequencies.9 These mutations as a whole have not predicted response to therapy or prognosis. However, when performing survival analysis in patients with specific mutations, those commonly encountered in MDS/AML (ASXL1, DNMT3A, TP53, RUNX1, CSMD1) are associated with faster progression to overt MDS/AML and decreased overall survival (OS),20,21 suggesting these mutations may represent early clonality that can lead to clonal evolution and the development of secondary malignancies. Conversely, mutations in BCOR and BCORL appear to identify patients who may have a favorable outcome in response to immunosuppressive therapy and, similar to patients with PIGA mutations, improved OS.9
Paroxysmal Nocturnal Hemoglobinuria
In addition to having an increased risk of myelodysplasia and malignancy due to the development of a dominant pre-malignant clone, patients with aplastic anemia often harbor progenitor cell clones associated with PNH.1,17 PNH clones have been identified in more than 50% of patients with aplastic anemia.22,23 PNH represents a clonal disorder of hematopoiesis in which cells harbor X-linked somatic mutations in the PIGA gene; this gene encodes a protein responsible for the synthesis of glycosylphosphatidylinositol (GPI) anchors on the cell surface.22,24 The lack of these cell surface proteins, specifically CD55 (also known as decay accelerating factor) and CD59 (also known as membrane inhibitor of reactive lysis), predisposes red cells to increased complement-mediated lysis.25 The exact mechanism for the development of these clones in patients with aplastic anemia is not fully understood. Current theories hypothesize that these clones are protected from the immune-mediated destruction of normal hematopoietic stem cells due to the absence of the cell surface proteins.1,20 The role of these clones over time in patients with aplastic anemia is less clear, though recent work demonstrated that despite differences in clonality over the disease course, aplastic anemia patients with small PNH clones are less likely to develop overt hemolysis and larger PNH clones compared to patients harboring larger (≥ 50%) PNH clones at diagnosis.23,26,27 Additionally, PNH clones in patients with aplastic anemia infrequently become clinically significant.27 It should be noted that these conditions exist along a continuum; that is, patients with aplastic anemia may develop PNH clones, while conversely patients with PNH may develop aplastic anemia.20 Patients with PNH clones should be followed via peripheral blood flow cytometry in addition to complete blood count to track clonal stability and identify clinically significant PNH among aplastic anemia patients.28
Clinical Presentation
Patients with aplastic anemia typically are diagnosed either due to asymptomatic cytopenias found on peripheral blood sampling, symptomatic anemia, bleeding secondary to thrombocytopenia, or wound healing and infectious complications related to neutropenia.29 A thorough history to understand the timing of symptoms, recent infectious symptoms/exposure, habits, and chemical or toxin exposures (including medications, travel, and supplements) helps guide diagnostic testing. Family history is also critical, with attention given to premature graying, pulmonary, renal, and liver disease, and blood disorders.
Patients with an IMFS, (eg, Fanconi anemia or dyskeratosis congenita) may have associated phenotypical findings such as urogenital abnormalities or short stature; in addition, those with dyskeratosis congenita may present with the classic triad of oral leukoplakia, lacy skin pigmentation, and dystrophic nails.7 However, in patients with IMFS, classic phenotypical findings may be lacking in up to 30% to 40% of patients.7 As described previously, while congenital malformations are common in Fanconi anemia and dyskeratosis congenita, a third of patients may have no or only subtle phenotypical abnormalities, including alterations in skin or hair pigmentation, skeletal and growth abnormalities, and endocrine disorders.30 The International Fanconi Anemia Registry identified central nervous system, genitourinary, skin and musculoskeletal, ophthalmic, and gastrointestinal system malformations among children with Fanconi anemia.31,32 Patients with dyskeratosis congenita may present with pulmonary fibrosis, hepatic cirrhosis, or premature graying, as highlighted in a recent study by DiNardo and colleagues.33 Therefore, physicians must have a heightened index of suspicion in patients with subtle phenotypical findings and associated cytopenias.
Diagnosis
Differential Diagnosis
The diagnosis of aplastic anemia should be suspected in any patient presenting with pancytopenia. Aplastic anemia is a diagnosis of exclusion.34 Other conditions associated with peripheral blood pancytopenia should be considered including infections (HIV, hepatitis, parvovirus B19, cytomegalovirus, Epstein-Barr virus, varicella-zoster virus), nutritional deficiencies (vitamin B12, folate, copper, zinc), autoimmune disease (systemic lupus erythematosus, rheumatoid arthritis, hemophagocytic lymphohistiocytosis), hypersplenism, marrow-occupying diseases (eg, leukemia, lymphoma, MDS), solid malignancies, and fibrosis (Table).7
Diagnostic Evaluation
The workup for aplastic anemia should include a thorough history and physical exam to search simultaneously for alternative diagnoses and clues pointing to potential etiologic agents.7 Diagnostic tests to be performed include a complete blood count with differential, reticulocyte count, immature platelet fraction, flow cytometry (to rule out lymphoproliferative disorders and atypical myeloid cells and to evaluate for PNH), and bone marrow biopsy with subsequent cytogenetic, immunohistochemical, and molecular testing.35 The typical findings in aplastic anemia include peripheral blood pancytopenia without dysplastic features and bone marrow biopsy demonstrating a hypocellular marrow.7 A relative lymphocytosis in the peripheral blood is common.7 In patients with a significant PNH clone, a macrocytosis along with elevated lactate dehydrogenase and elevated reticulocyte and granulocyte counts may be present.36
The diagnosis (based on the Camitta criteria37 and modified Camitta criteria38 for severe aplastic anemia) requires 2 of the following findings on peripheral blood samples:
- Absolute neutrophil count (ANC) < 500 cells/µL
- Platelet count < 20,000 cells/µL
- Reticulocyte count < 1% corrected or < 20,000 cells/µL.35
In addition to peripheral blood findings, bone marrow biopsy is essential for the diagnosis, and should demonstrate a markedly hypocellular marrow (cellularity < 25%), occasionally with an increase in T lymphocytes.7,39 Because marrow cellularity varies with age and can be challenging to assess, additional biopsies may be needed to confirm the diagnosis.29 A 1- to 2-cm core biopsy is necessary to confirm hypocellularity, as small areas of residual hematopoiesis may be present and obscure the diagnosis.35
Excluding Hypocellular MDS and IMFS
A diagnostic challenge is the exclusion of hypocellular MDS, especially in the older adult presenting with aplastic anemia, as patients with aplastic anemia may have some degree of erythroid dysplasia on bone marrow morphology.36 The presence of a PNH clone on flow cytometry can aid in diagnosing aplastic anemia and excluding MDS,34 although PNH clones can be present in refractory anemia MDS. Patients with aplastic anemia have a lower ratio of CD34+ cells compared to those with hypoplastic MDS, with one study demonstrating a mean CD34+ percentage of < 0.5% in aplastic anemia versus 3.7% in hypoplastic MDS.40 Cytogenetic and molecular testing can also aid in making this distinction by identifying mutations commonly implicated in MDS.7 The presence of monosomy 7 (-7) in aplastic anemia patients is associated with a poor overall prognosis.34,41
Peripheral blood screening using chromosome breakage analysis (done using either mitomycin C or diepoxybutane as in vitro DNA-crosslinking agents) and telomere length testing (of peripheral blood leukocytes) is necessary to exclude the main IMFS, Fanconi anemia and telomere biology disorders, respectively. Ruling out these conditions is imperative, as the approach to treatment varies significantly between IMFS and aplastic anemia. Patients with shortened telomeres should undergo genetic screening for mutations in the telomere maintenance genes to evaluate the underlying defect leading to shortened telomeres. Patients with increased peripheral blood breakage should have genetic testing to detect mutations associated with Fanconi anemia.
Classification
Once the diagnosis of aplastic anemia has been made, the patient should be classified according to the severity of their disease. Disease severity is determined based on peripheral blood ANC:34 non-severe aplastic anemia (NSAA), ANC > 500 polymorphonuclear neutrophils (PMNs)/µL; severe aplastic anemia (SAA), 200–500 PMNs/µL; and very severe (VSAA), 0–200 PMNs/µL.4,34 Disease classification is important, as VSAA is associated with a decreased OS compared to SAA.2 Disease classification may affect treatment decisions, as patients with NSAA may be observed for a short period of time, while conversely patients with SAA have a worse prognosis with delays in therapy.42-44
Summary
Aplastic anemia is a rare but potentially life-threatening disorder characterized by pancytopenia and a marked reduction in the hematopoietic stem cell compartment. It can be acquired or associated with an IMFS, and the treatment and prognosis vary dramatically between these 2 etiologies. Work-up and diagnosis involves investigating IMFSs and ruling out malignant or infectious etiologies for pancytopenia. After aplastic anemia has been diagnosed, the patient should be classified according to the severity of their disease based on peripheral blood ANC.
1. Young NS, Calado RT, Scheinberg P. Current concepts in the pathophysiology and treatment of aplastic anemia. Blood. 2006;108:2509-2519.
2. Vaht K, Göransson M, Carlson K, et al. Incidence and outcome of acquired aplastic anemia: real-world data from patients diagnosed in Sweden from 2000–2011. Haematologica. 2017;102:1683-1690.
3. Incidence of aplastic anemia: the relevance of diagnostic criteria. By the International Agranulocytosis and Aplastic Anemia Study. Blood. 1987;70:1718-1721.
4. Montané E, Ibanez L, Vidal X, et al. Epidemiology of aplastic anemia: a prospective multicenter study. Haematologica. 2008;93:518-523.
5. Ohta A, Nagai M, Nishina M, et al. Incidence of aplastic anemia in Japan: analysis of data from a nationwide registration system. Int J Epidemiol. 2015; 44(suppl_1):i178.
6. Passweg JR, Marsh JC. Aplastic anemia: first-line treatment by immunosuppression and sibling marrow transplantation. Hematology Am Soc Hematol Educ Program. 2010;2010:36-42.
7. Weinzierl EP, Arber DA. The differential diagnosis and bone marrow evaluation of new-onset pancytopenia. Am J Clin Pathol. 2013;139:9-29.
8. Lin FC, Karwan M, Saleh B, et al. IFN-γ causes aplastic anemia by altering hematopoiesis stem/progenitor cell composition and disrupting lineage differentiation. Blood. 2014;124:3699-3708.
9. Yoshizato T, Dumitriu B, Hosokawa K, et al. Somatic mutations and clonal hematopoiesis in aplastic anemia. N Engl J Med. 2015;373:35-47.
10. de Bruin AM, Voermans C, Nolte MA. Impact of interferon-γ on hematopoiesis. Blood. 2014;124:2479-2486.
11. Cheng H, Cheruku PS, Alvarado L, et al. Interferon-γ perturbs key signaling pathways induced by thrombopoietin, but not eltrombopag, in human hematopoietic stem/progenitor cells. Blood. 2016;128:3870.
12. Olnes MJ, Scheinberg P, Calvo KR, et al. Eltrombopag and improved hematopoiesis in refractory aplastic anemia. N Engl J Med. 2012;367:11-19.
13. Townsley DM, Dumitriu B, Young NS, et al. Danazol treatment for telomere diseases. N Engl J Med. 2016;374:1922-1931.
14. Feurstein S, Drazer MW, Godley LA. Genetic predisposition to leukemia and other hematologic malignancies. Sem Oncol. 2016;43:598-608.
15. Townsley DM, Dumitriu B, Young NS. Bone marrow failure and the telomeropathies. Blood. 2014;124:2775-2783.
16. Young NS, Bacigalupo A, Marsh JC. Aplastic anemia: pathophysiology and treatment. Biol Blood Marrow Transplant. 2010;16:S119-125.
17. Calado RT, Young NS. Telomere maintenance and human bone marrow failure. Blood. 2008;111:4446-4455.
18. DiNardo CD, Bannon SA, Routbort M, et al. Evaluation of patients and families with concern for predispositions to hematologic malignancies within the Hereditary Hematologic Malignancy Clinic (HHMC). Clin Lymphoma Myeloma Leuk. 2016;16:417-428.
19. Borie R, Tabèze L, Thabut G, et al. Prevalence and characteristics of TERT and TERC mutations in suspected genetic pulmonary fibrosis. Eur Resp J. 2016;48:1721-1731.
20. Ogawa S. Clonal hematopoiesis in acquired aplastic anemia. Blood. 2016;128:337-347.
21. Kulasekararaj AG, Jiang J, Smith AE, et al. Somatic mutations identify a sub-group of aplastic anemia patients that progress to myelodysplastic syndrome. Blood. 2014; 124:2698-2704.
22. Mukhina GL, Buckley JT, Barber JP, et al. Multilineage glycosylphosphatidylinositol anchor‐deficient haematopoiesis in untreated aplastic anaemia. Br J Haematol. 2001;115:476-482.
23. Pu JJ, Mukhina G, Wang H, et al. Natural history of paroxysmal nocturnal hemoglobinuria clones in patients presenting as aplastic anemia. Eur J Haematol. 2011;87:37-45.
24. Hall SE, Rosse WF. The use of monoclonal antibodies and flow cytometry in the diagnosis of paroxysmal nocturnal hemoglobinuria. Blood. 1996;87:5332-5340.
25. Devalet B, Mullier F, Chatelain B, et al. Pathophysiology, diagnosis, and treatment of paroxysmal nocturnal hemoglobinuria: a review. Eur J Haematol. 2015;95:190-198.
26. Sugimori C, Chuhjo T, Feng X, et al. Minor population of CD55-CD59-blood cells predicts response to immunosuppressive therapy and prognosis in patients with aplastic anemia. Blood. 2006;107:1308-1314.
27. Scheinberg P, Marte M, Nunez O, Young NS. Paroxysmal nocturnal hemoglobinuria clones in severe aplastic anemia patients treated with horse anti-thymocyte globulin plus cyclosporine. Haematologica. 2010;95:1075-1080.
28. Parker C, Omine M, Richards S, et al. Diagnosis and management of paroxysmal nocturnal hemoglobinuria. Blood. 2005;106:3699-3709.
29. Guinan EC. Diagnosis and management of aplastic anemia. Hematology Am Soc Hematol Educ Program. 2011;2011:76-81.
30. Giampietro PF, Verlander PC, Davis JG, Auerbach AD. Diagnosis of Fanconi anemia in patients without congenital malformations: an international Fanconi Anemia Registry Study. Am J Med Genetics. 1997;68:58-61.
31. Auerbach AD. Fanconi anemia and its diagnosis. Mutat Res. 2009;668:4-10.
32. Giampietro PF, Davis JG, Adler-Brecher B, et al. The need for more accurate and timely diagnosis in Fanconi anemia: a report from the International Fanconi Anemia Registry. Pediatrics. 1993;91:1116-1120.
33. DiNardo CD, Bannon SA, Routbort M, et al. Evaluation of patients and families with concern for predispositions to hematologic malignancies within the Hereditary Hematologic Malignancy Clinic (HHMC). Clin Lymphoma Myeloma Leuk. 2016;16:417-428.
34. Bacigalupo A. How I treat acquired aplastic anemia. Blood. 2017;129:1428-1436.
35. DeZern AE, Brodsky RA. Clinical management of aplastic anemia. Expert Rev Hematol. 2011;4:221-230.
36. Tichelli A, Gratwohl A, Nissen C, et al. Morphology in patients with severe aplastic anemia treated with antilymphocyte globulin. Blood. 1992;80:337-345.
37. Camitta BM, Storb R, Thomas ED. Aplastic anemia: pathogenesis, diagnosis, treatment, and prognosis. N Engl J Med. 1982;306:645-652.
38. Bacigalupo A, Hows J, Gluckman E, et al. Bone marrow transplantation (BMT) versus immunosuppression for the treatment of severe aplastic anaemia (SAA): a report of the EBMT SAA working party. Br J Haematol. 1988:70:177-182.
39. Brodsky RA, Chen AR, Dorr D, et al. High-dose cyclophosphamide for severe aplastic anemia: long-term follow-up. Blood. 2010;115:2136-2141.
40. Matsui WH, Brodsky RA, Smith BD, et al. Quantitative analysis of bone marrow CD34 cells in aplastic anemia and hypoplastic myelodysplastic syndromes. Leukemia. 2006;20:458-462.
41. Maciejewski JP, Risitano AM, Nunez O, Young NS. Distinct clinical outcomes for cytogenetic abnormalities evolving from aplastic anemia. Blood. 2002;99:3129-3135.
42. Locasciulli A, Oneto R, Bacigalupo A, et al. Outcome of patients with acquired aplastic anemia given first line bone marrow transplantation or immunosuppressive treatment in the last decade: a report from the European Group for Blood and Marrow Transplantation. Haematologica. 2007;92:11-8.
43. Passweg JR, Socié G, Hinterberger W, et al. Bone marrow transplantation for severe aplastic anemia: has outcome improved? Blood. 1997;90:858-864.
44. Gupta V, Eapen M, Brazauskas R, et al. Impact of age on outcomes after transplantation for acquired aplastic anemia using HLA-identical sibling donors. Haematologica. 2010;95:2119-2125.
Aplastic anemia is a clinical and pathological entity of bone marrow failure that causes progressive loss of hematopoietic progenitor stem cells (HPSC), resulting in pancytopenia.1 Patients may present along a spectrum, ranging from being asymptomatic with incidental findings on peripheral blood testing to having life-threatening neutropenic infections or bleeding. Aplastic anemia results from either inherited or acquired causes, and the pathophysiology and treatment approach vary significantly between these 2 causes. Therefore, recognition of inherited marrow failure diseases, such as Fanconi anemia and telomere biology disorders, is critical to establish
Epidemiology
Aplastic anemia is a rare disorder, with an incidence of approximately 1.5 to 7 cases per million individuals per year.2,3 A recent Scandinavian study reported that the incidence of aplastic anemia among the Swedish population is 2.3 cases per million individuals per year, with a median age at diagnosis of 60 years and a slight female predominance (52% versus 48%, respectively).2 This data is congruent with prior observations made in Barcelona, where the incidence was 2.34 cases per million individuals per year, albeit with a slightly higher incidence in males compared to females (2.54 versus 2.16, respectively).4 The incidence of aplastic anemia varies globally, with a disproportionate increase in incidence seen among Asian populations, with rates as high as 8.8 per million individuals per year.3-5 This variation in incidence in Asia versus other countries has not been well explained. There appears to be a bimodal distribution, with incidence peaks seen in young adults and in older adults.2,3,6
Pathophysiology
Acquired Aplastic Anemia
The leading hypothesis as to the cause of most cases of acquired aplastic anemia is that a dysregulated immune system destroys hematopoietic progenitor cells. Inciting etiologies implicated in the development of acquired aplastic anemia include pregnancy, infection, medications, and exposure to certain chemicals, such as benzene.1,7 The historical understanding of acquired aplastic anemia implicates cytotoxic T-lymphocyte–mediated destruction of CD34+ hematopoietic stem cells.1,8,9 This hypothesis served as the basis for treatment of acquired aplastic anemia with immunosuppressive therapy, predominantly anti-thymocyte globulin (ATG) combined with cyclosporine A.1,8 More recent work has focused on cytokine interactions, particularly the suppressive role of interferon (IFN)-γ on hematopoietic stem cells independent of T-lymphocyte–mediated hematopoietic destruction, which has been demonstrated in a murine model.8 The interaction of IFN-γ with the hematopoietic stem cells pool is dynamic. IFN-γ levels are elevated during an acute inflammatory response such as a viral infection, providing further basis for the immune-mediated nature of the acquired disease.10 Specifically, in vitro studies suggest the effects of IFN-γ on HPSC may be secondary to interruption of thrombopoietin and its respective signaling pathways, which play a key role in hematopoietic stem cell renewal.11 Eltrombopag, a thrombopoietin receptor antagonist, has shown promise in the treatment of refractory aplastic anemia, with studies indicating that its effectiveness is independent of IFN-γ levels.11,12
Inherited Aplastic Anemia
The inherited marrow failure syndromes (IMFSs) are a group of disorders characterized by cellular maintenance and repair defects, leading to cytopenias, increased cancer risk, structural defects, and risk of end organ damage, such as liver cirrhosis and pulmonary fibrosis.13-15 The most common diseases include Fanconi anemia, dyskeratosis congenita/telomere biology disorders, Diamond-Blackfan anemia, and Shwachman-Diamond syndrome, but with the advent of whole exome sequencing new syndromes continue to be discovered. While classically these disorders present in children, adult presentations of these syndromes are now commonplace. Broadly, the pathophysiology of inherited aplastic anemia relates to the defective hematopoietic progenitor cells and an accelerated decline of the hematopoietic stem cell compartment.
The most common IMFS, Fanconi anemia and telomere biology disorders, are associated with numerous mutations in DNA damage repair pathways and telomere maintenance pathways. TERT, DKC, and TERC mutations are most commonly associated with dyskeratosis congenita, but may also be found infrequently in patients with aplastic anemia presenting at an older age in the absence of the classic phenotypical features.1,16,17 The recognition of an underlying genetic disorder or telomere biology disorder leading to constitutional aplastic anemia is significant, as these conditions are associated not only with marrow failure, but also endocrinopathies, organ fibrosis, and solid organ malignancies.13-15 In particular, mutations in the TERT and TERC genes have been associated with dyskeratosis congenita as well as pulmonary fibrosis and cirrhosis.18,19 The implications of early diagnosis of an IMFS lie in the approach to treatment and prognosis.
Clonal Disorders and Secondary Malignancies
Myelodysplastic syndrome (MDS) and secondary acute myeloid leukemia (AML) are 2 clonal disorders that may arise from a background of aplastic anemia.9,20,21 Hypoplastic MDS can be difficult to differentiate from aplastic anemia at diagnosis based on morphology alone, although recent work has demonstrated that molecular testing for somatic mutations in ASXL1, DNMT3A, and BCOR can aid in differentiating a subset of aplastic anemia patients who are more likely to progress to MDS.21 Clonal populations of cells harboring 6p uniparental disomy are seen in more than 10% of patients with aplastic anemia on cytogenetic analysis, which can help differentiate the diseases.9 Yoshizato and colleagues found lower rates of ASXL1 and DNMT3A mutations in patients with aplastic anemia as compared with patients with MDS or AML. In this study, patients with aplastic anemia had higher rates of mutations in PIGA (reflecting the increased paroxysmal nocturnal hemoglobinuria [PNH] clonality seen in aplastic anemia) and BCOR.9 Mutations were also found in genes commonly mutated in MDS and AML, including TET2, RUNX1, TP53, and JAK2, albeit at lower frequencies.9 These mutations as a whole have not predicted response to therapy or prognosis. However, when performing survival analysis in patients with specific mutations, those commonly encountered in MDS/AML (ASXL1, DNMT3A, TP53, RUNX1, CSMD1) are associated with faster progression to overt MDS/AML and decreased overall survival (OS),20,21 suggesting these mutations may represent early clonality that can lead to clonal evolution and the development of secondary malignancies. Conversely, mutations in BCOR and BCORL appear to identify patients who may have a favorable outcome in response to immunosuppressive therapy and, similar to patients with PIGA mutations, improved OS.9
Paroxysmal Nocturnal Hemoglobinuria
In addition to having an increased risk of myelodysplasia and malignancy due to the development of a dominant pre-malignant clone, patients with aplastic anemia often harbor progenitor cell clones associated with PNH.1,17 PNH clones have been identified in more than 50% of patients with aplastic anemia.22,23 PNH represents a clonal disorder of hematopoiesis in which cells harbor X-linked somatic mutations in the PIGA gene; this gene encodes a protein responsible for the synthesis of glycosylphosphatidylinositol (GPI) anchors on the cell surface.22,24 The lack of these cell surface proteins, specifically CD55 (also known as decay accelerating factor) and CD59 (also known as membrane inhibitor of reactive lysis), predisposes red cells to increased complement-mediated lysis.25 The exact mechanism for the development of these clones in patients with aplastic anemia is not fully understood. Current theories hypothesize that these clones are protected from the immune-mediated destruction of normal hematopoietic stem cells due to the absence of the cell surface proteins.1,20 The role of these clones over time in patients with aplastic anemia is less clear, though recent work demonstrated that despite differences in clonality over the disease course, aplastic anemia patients with small PNH clones are less likely to develop overt hemolysis and larger PNH clones compared to patients harboring larger (≥ 50%) PNH clones at diagnosis.23,26,27 Additionally, PNH clones in patients with aplastic anemia infrequently become clinically significant.27 It should be noted that these conditions exist along a continuum; that is, patients with aplastic anemia may develop PNH clones, while conversely patients with PNH may develop aplastic anemia.20 Patients with PNH clones should be followed via peripheral blood flow cytometry in addition to complete blood count to track clonal stability and identify clinically significant PNH among aplastic anemia patients.28
Clinical Presentation
Patients with aplastic anemia typically are diagnosed either due to asymptomatic cytopenias found on peripheral blood sampling, symptomatic anemia, bleeding secondary to thrombocytopenia, or wound healing and infectious complications related to neutropenia.29 A thorough history to understand the timing of symptoms, recent infectious symptoms/exposure, habits, and chemical or toxin exposures (including medications, travel, and supplements) helps guide diagnostic testing. Family history is also critical, with attention given to premature graying, pulmonary, renal, and liver disease, and blood disorders.
Patients with an IMFS, (eg, Fanconi anemia or dyskeratosis congenita) may have associated phenotypical findings such as urogenital abnormalities or short stature; in addition, those with dyskeratosis congenita may present with the classic triad of oral leukoplakia, lacy skin pigmentation, and dystrophic nails.7 However, in patients with IMFS, classic phenotypical findings may be lacking in up to 30% to 40% of patients.7 As described previously, while congenital malformations are common in Fanconi anemia and dyskeratosis congenita, a third of patients may have no or only subtle phenotypical abnormalities, including alterations in skin or hair pigmentation, skeletal and growth abnormalities, and endocrine disorders.30 The International Fanconi Anemia Registry identified central nervous system, genitourinary, skin and musculoskeletal, ophthalmic, and gastrointestinal system malformations among children with Fanconi anemia.31,32 Patients with dyskeratosis congenita may present with pulmonary fibrosis, hepatic cirrhosis, or premature graying, as highlighted in a recent study by DiNardo and colleagues.33 Therefore, physicians must have a heightened index of suspicion in patients with subtle phenotypical findings and associated cytopenias.
Diagnosis
Differential Diagnosis
The diagnosis of aplastic anemia should be suspected in any patient presenting with pancytopenia. Aplastic anemia is a diagnosis of exclusion.34 Other conditions associated with peripheral blood pancytopenia should be considered including infections (HIV, hepatitis, parvovirus B19, cytomegalovirus, Epstein-Barr virus, varicella-zoster virus), nutritional deficiencies (vitamin B12, folate, copper, zinc), autoimmune disease (systemic lupus erythematosus, rheumatoid arthritis, hemophagocytic lymphohistiocytosis), hypersplenism, marrow-occupying diseases (eg, leukemia, lymphoma, MDS), solid malignancies, and fibrosis (Table).7
Diagnostic Evaluation
The workup for aplastic anemia should include a thorough history and physical exam to search simultaneously for alternative diagnoses and clues pointing to potential etiologic agents.7 Diagnostic tests to be performed include a complete blood count with differential, reticulocyte count, immature platelet fraction, flow cytometry (to rule out lymphoproliferative disorders and atypical myeloid cells and to evaluate for PNH), and bone marrow biopsy with subsequent cytogenetic, immunohistochemical, and molecular testing.35 The typical findings in aplastic anemia include peripheral blood pancytopenia without dysplastic features and bone marrow biopsy demonstrating a hypocellular marrow.7 A relative lymphocytosis in the peripheral blood is common.7 In patients with a significant PNH clone, a macrocytosis along with elevated lactate dehydrogenase and elevated reticulocyte and granulocyte counts may be present.36
The diagnosis (based on the Camitta criteria37 and modified Camitta criteria38 for severe aplastic anemia) requires 2 of the following findings on peripheral blood samples:
- Absolute neutrophil count (ANC) < 500 cells/µL
- Platelet count < 20,000 cells/µL
- Reticulocyte count < 1% corrected or < 20,000 cells/µL.35
In addition to peripheral blood findings, bone marrow biopsy is essential for the diagnosis, and should demonstrate a markedly hypocellular marrow (cellularity < 25%), occasionally with an increase in T lymphocytes.7,39 Because marrow cellularity varies with age and can be challenging to assess, additional biopsies may be needed to confirm the diagnosis.29 A 1- to 2-cm core biopsy is necessary to confirm hypocellularity, as small areas of residual hematopoiesis may be present and obscure the diagnosis.35
Excluding Hypocellular MDS and IMFS
A diagnostic challenge is the exclusion of hypocellular MDS, especially in the older adult presenting with aplastic anemia, as patients with aplastic anemia may have some degree of erythroid dysplasia on bone marrow morphology.36 The presence of a PNH clone on flow cytometry can aid in diagnosing aplastic anemia and excluding MDS,34 although PNH clones can be present in refractory anemia MDS. Patients with aplastic anemia have a lower ratio of CD34+ cells compared to those with hypoplastic MDS, with one study demonstrating a mean CD34+ percentage of < 0.5% in aplastic anemia versus 3.7% in hypoplastic MDS.40 Cytogenetic and molecular testing can also aid in making this distinction by identifying mutations commonly implicated in MDS.7 The presence of monosomy 7 (-7) in aplastic anemia patients is associated with a poor overall prognosis.34,41
Peripheral blood screening using chromosome breakage analysis (done using either mitomycin C or diepoxybutane as in vitro DNA-crosslinking agents) and telomere length testing (of peripheral blood leukocytes) is necessary to exclude the main IMFS, Fanconi anemia and telomere biology disorders, respectively. Ruling out these conditions is imperative, as the approach to treatment varies significantly between IMFS and aplastic anemia. Patients with shortened telomeres should undergo genetic screening for mutations in the telomere maintenance genes to evaluate the underlying defect leading to shortened telomeres. Patients with increased peripheral blood breakage should have genetic testing to detect mutations associated with Fanconi anemia.
Classification
Once the diagnosis of aplastic anemia has been made, the patient should be classified according to the severity of their disease. Disease severity is determined based on peripheral blood ANC:34 non-severe aplastic anemia (NSAA), ANC > 500 polymorphonuclear neutrophils (PMNs)/µL; severe aplastic anemia (SAA), 200–500 PMNs/µL; and very severe (VSAA), 0–200 PMNs/µL.4,34 Disease classification is important, as VSAA is associated with a decreased OS compared to SAA.2 Disease classification may affect treatment decisions, as patients with NSAA may be observed for a short period of time, while conversely patients with SAA have a worse prognosis with delays in therapy.42-44
Summary
Aplastic anemia is a rare but potentially life-threatening disorder characterized by pancytopenia and a marked reduction in the hematopoietic stem cell compartment. It can be acquired or associated with an IMFS, and the treatment and prognosis vary dramatically between these 2 etiologies. Work-up and diagnosis involves investigating IMFSs and ruling out malignant or infectious etiologies for pancytopenia. After aplastic anemia has been diagnosed, the patient should be classified according to the severity of their disease based on peripheral blood ANC.
Aplastic anemia is a clinical and pathological entity of bone marrow failure that causes progressive loss of hematopoietic progenitor stem cells (HPSC), resulting in pancytopenia.1 Patients may present along a spectrum, ranging from being asymptomatic with incidental findings on peripheral blood testing to having life-threatening neutropenic infections or bleeding. Aplastic anemia results from either inherited or acquired causes, and the pathophysiology and treatment approach vary significantly between these 2 causes. Therefore, recognition of inherited marrow failure diseases, such as Fanconi anemia and telomere biology disorders, is critical to establish
Epidemiology
Aplastic anemia is a rare disorder, with an incidence of approximately 1.5 to 7 cases per million individuals per year.2,3 A recent Scandinavian study reported that the incidence of aplastic anemia among the Swedish population is 2.3 cases per million individuals per year, with a median age at diagnosis of 60 years and a slight female predominance (52% versus 48%, respectively).2 This data is congruent with prior observations made in Barcelona, where the incidence was 2.34 cases per million individuals per year, albeit with a slightly higher incidence in males compared to females (2.54 versus 2.16, respectively).4 The incidence of aplastic anemia varies globally, with a disproportionate increase in incidence seen among Asian populations, with rates as high as 8.8 per million individuals per year.3-5 This variation in incidence in Asia versus other countries has not been well explained. There appears to be a bimodal distribution, with incidence peaks seen in young adults and in older adults.2,3,6
Pathophysiology
Acquired Aplastic Anemia
The leading hypothesis as to the cause of most cases of acquired aplastic anemia is that a dysregulated immune system destroys hematopoietic progenitor cells. Inciting etiologies implicated in the development of acquired aplastic anemia include pregnancy, infection, medications, and exposure to certain chemicals, such as benzene.1,7 The historical understanding of acquired aplastic anemia implicates cytotoxic T-lymphocyte–mediated destruction of CD34+ hematopoietic stem cells.1,8,9 This hypothesis served as the basis for treatment of acquired aplastic anemia with immunosuppressive therapy, predominantly anti-thymocyte globulin (ATG) combined with cyclosporine A.1,8 More recent work has focused on cytokine interactions, particularly the suppressive role of interferon (IFN)-γ on hematopoietic stem cells independent of T-lymphocyte–mediated hematopoietic destruction, which has been demonstrated in a murine model.8 The interaction of IFN-γ with the hematopoietic stem cells pool is dynamic. IFN-γ levels are elevated during an acute inflammatory response such as a viral infection, providing further basis for the immune-mediated nature of the acquired disease.10 Specifically, in vitro studies suggest the effects of IFN-γ on HPSC may be secondary to interruption of thrombopoietin and its respective signaling pathways, which play a key role in hematopoietic stem cell renewal.11 Eltrombopag, a thrombopoietin receptor antagonist, has shown promise in the treatment of refractory aplastic anemia, with studies indicating that its effectiveness is independent of IFN-γ levels.11,12
Inherited Aplastic Anemia
The inherited marrow failure syndromes (IMFSs) are a group of disorders characterized by cellular maintenance and repair defects, leading to cytopenias, increased cancer risk, structural defects, and risk of end organ damage, such as liver cirrhosis and pulmonary fibrosis.13-15 The most common diseases include Fanconi anemia, dyskeratosis congenita/telomere biology disorders, Diamond-Blackfan anemia, and Shwachman-Diamond syndrome, but with the advent of whole exome sequencing new syndromes continue to be discovered. While classically these disorders present in children, adult presentations of these syndromes are now commonplace. Broadly, the pathophysiology of inherited aplastic anemia relates to the defective hematopoietic progenitor cells and an accelerated decline of the hematopoietic stem cell compartment.
The most common IMFS, Fanconi anemia and telomere biology disorders, are associated with numerous mutations in DNA damage repair pathways and telomere maintenance pathways. TERT, DKC, and TERC mutations are most commonly associated with dyskeratosis congenita, but may also be found infrequently in patients with aplastic anemia presenting at an older age in the absence of the classic phenotypical features.1,16,17 The recognition of an underlying genetic disorder or telomere biology disorder leading to constitutional aplastic anemia is significant, as these conditions are associated not only with marrow failure, but also endocrinopathies, organ fibrosis, and solid organ malignancies.13-15 In particular, mutations in the TERT and TERC genes have been associated with dyskeratosis congenita as well as pulmonary fibrosis and cirrhosis.18,19 The implications of early diagnosis of an IMFS lie in the approach to treatment and prognosis.
Clonal Disorders and Secondary Malignancies
Myelodysplastic syndrome (MDS) and secondary acute myeloid leukemia (AML) are 2 clonal disorders that may arise from a background of aplastic anemia.9,20,21 Hypoplastic MDS can be difficult to differentiate from aplastic anemia at diagnosis based on morphology alone, although recent work has demonstrated that molecular testing for somatic mutations in ASXL1, DNMT3A, and BCOR can aid in differentiating a subset of aplastic anemia patients who are more likely to progress to MDS.21 Clonal populations of cells harboring 6p uniparental disomy are seen in more than 10% of patients with aplastic anemia on cytogenetic analysis, which can help differentiate the diseases.9 Yoshizato and colleagues found lower rates of ASXL1 and DNMT3A mutations in patients with aplastic anemia as compared with patients with MDS or AML. In this study, patients with aplastic anemia had higher rates of mutations in PIGA (reflecting the increased paroxysmal nocturnal hemoglobinuria [PNH] clonality seen in aplastic anemia) and BCOR.9 Mutations were also found in genes commonly mutated in MDS and AML, including TET2, RUNX1, TP53, and JAK2, albeit at lower frequencies.9 These mutations as a whole have not predicted response to therapy or prognosis. However, when performing survival analysis in patients with specific mutations, those commonly encountered in MDS/AML (ASXL1, DNMT3A, TP53, RUNX1, CSMD1) are associated with faster progression to overt MDS/AML and decreased overall survival (OS),20,21 suggesting these mutations may represent early clonality that can lead to clonal evolution and the development of secondary malignancies. Conversely, mutations in BCOR and BCORL appear to identify patients who may have a favorable outcome in response to immunosuppressive therapy and, similar to patients with PIGA mutations, improved OS.9
Paroxysmal Nocturnal Hemoglobinuria
In addition to having an increased risk of myelodysplasia and malignancy due to the development of a dominant pre-malignant clone, patients with aplastic anemia often harbor progenitor cell clones associated with PNH.1,17 PNH clones have been identified in more than 50% of patients with aplastic anemia.22,23 PNH represents a clonal disorder of hematopoiesis in which cells harbor X-linked somatic mutations in the PIGA gene; this gene encodes a protein responsible for the synthesis of glycosylphosphatidylinositol (GPI) anchors on the cell surface.22,24 The lack of these cell surface proteins, specifically CD55 (also known as decay accelerating factor) and CD59 (also known as membrane inhibitor of reactive lysis), predisposes red cells to increased complement-mediated lysis.25 The exact mechanism for the development of these clones in patients with aplastic anemia is not fully understood. Current theories hypothesize that these clones are protected from the immune-mediated destruction of normal hematopoietic stem cells due to the absence of the cell surface proteins.1,20 The role of these clones over time in patients with aplastic anemia is less clear, though recent work demonstrated that despite differences in clonality over the disease course, aplastic anemia patients with small PNH clones are less likely to develop overt hemolysis and larger PNH clones compared to patients harboring larger (≥ 50%) PNH clones at diagnosis.23,26,27 Additionally, PNH clones in patients with aplastic anemia infrequently become clinically significant.27 It should be noted that these conditions exist along a continuum; that is, patients with aplastic anemia may develop PNH clones, while conversely patients with PNH may develop aplastic anemia.20 Patients with PNH clones should be followed via peripheral blood flow cytometry in addition to complete blood count to track clonal stability and identify clinically significant PNH among aplastic anemia patients.28
Clinical Presentation
Patients with aplastic anemia typically are diagnosed either due to asymptomatic cytopenias found on peripheral blood sampling, symptomatic anemia, bleeding secondary to thrombocytopenia, or wound healing and infectious complications related to neutropenia.29 A thorough history to understand the timing of symptoms, recent infectious symptoms/exposure, habits, and chemical or toxin exposures (including medications, travel, and supplements) helps guide diagnostic testing. Family history is also critical, with attention given to premature graying, pulmonary, renal, and liver disease, and blood disorders.
Patients with an IMFS, (eg, Fanconi anemia or dyskeratosis congenita) may have associated phenotypical findings such as urogenital abnormalities or short stature; in addition, those with dyskeratosis congenita may present with the classic triad of oral leukoplakia, lacy skin pigmentation, and dystrophic nails.7 However, in patients with IMFS, classic phenotypical findings may be lacking in up to 30% to 40% of patients.7 As described previously, while congenital malformations are common in Fanconi anemia and dyskeratosis congenita, a third of patients may have no or only subtle phenotypical abnormalities, including alterations in skin or hair pigmentation, skeletal and growth abnormalities, and endocrine disorders.30 The International Fanconi Anemia Registry identified central nervous system, genitourinary, skin and musculoskeletal, ophthalmic, and gastrointestinal system malformations among children with Fanconi anemia.31,32 Patients with dyskeratosis congenita may present with pulmonary fibrosis, hepatic cirrhosis, or premature graying, as highlighted in a recent study by DiNardo and colleagues.33 Therefore, physicians must have a heightened index of suspicion in patients with subtle phenotypical findings and associated cytopenias.
Diagnosis
Differential Diagnosis
The diagnosis of aplastic anemia should be suspected in any patient presenting with pancytopenia. Aplastic anemia is a diagnosis of exclusion.34 Other conditions associated with peripheral blood pancytopenia should be considered including infections (HIV, hepatitis, parvovirus B19, cytomegalovirus, Epstein-Barr virus, varicella-zoster virus), nutritional deficiencies (vitamin B12, folate, copper, zinc), autoimmune disease (systemic lupus erythematosus, rheumatoid arthritis, hemophagocytic lymphohistiocytosis), hypersplenism, marrow-occupying diseases (eg, leukemia, lymphoma, MDS), solid malignancies, and fibrosis (Table).7
Diagnostic Evaluation
The workup for aplastic anemia should include a thorough history and physical exam to search simultaneously for alternative diagnoses and clues pointing to potential etiologic agents.7 Diagnostic tests to be performed include a complete blood count with differential, reticulocyte count, immature platelet fraction, flow cytometry (to rule out lymphoproliferative disorders and atypical myeloid cells and to evaluate for PNH), and bone marrow biopsy with subsequent cytogenetic, immunohistochemical, and molecular testing.35 The typical findings in aplastic anemia include peripheral blood pancytopenia without dysplastic features and bone marrow biopsy demonstrating a hypocellular marrow.7 A relative lymphocytosis in the peripheral blood is common.7 In patients with a significant PNH clone, a macrocytosis along with elevated lactate dehydrogenase and elevated reticulocyte and granulocyte counts may be present.36
The diagnosis (based on the Camitta criteria37 and modified Camitta criteria38 for severe aplastic anemia) requires 2 of the following findings on peripheral blood samples:
- Absolute neutrophil count (ANC) < 500 cells/µL
- Platelet count < 20,000 cells/µL
- Reticulocyte count < 1% corrected or < 20,000 cells/µL.35
In addition to peripheral blood findings, bone marrow biopsy is essential for the diagnosis, and should demonstrate a markedly hypocellular marrow (cellularity < 25%), occasionally with an increase in T lymphocytes.7,39 Because marrow cellularity varies with age and can be challenging to assess, additional biopsies may be needed to confirm the diagnosis.29 A 1- to 2-cm core biopsy is necessary to confirm hypocellularity, as small areas of residual hematopoiesis may be present and obscure the diagnosis.35
Excluding Hypocellular MDS and IMFS
A diagnostic challenge is the exclusion of hypocellular MDS, especially in the older adult presenting with aplastic anemia, as patients with aplastic anemia may have some degree of erythroid dysplasia on bone marrow morphology.36 The presence of a PNH clone on flow cytometry can aid in diagnosing aplastic anemia and excluding MDS,34 although PNH clones can be present in refractory anemia MDS. Patients with aplastic anemia have a lower ratio of CD34+ cells compared to those with hypoplastic MDS, with one study demonstrating a mean CD34+ percentage of < 0.5% in aplastic anemia versus 3.7% in hypoplastic MDS.40 Cytogenetic and molecular testing can also aid in making this distinction by identifying mutations commonly implicated in MDS.7 The presence of monosomy 7 (-7) in aplastic anemia patients is associated with a poor overall prognosis.34,41
Peripheral blood screening using chromosome breakage analysis (done using either mitomycin C or diepoxybutane as in vitro DNA-crosslinking agents) and telomere length testing (of peripheral blood leukocytes) is necessary to exclude the main IMFS, Fanconi anemia and telomere biology disorders, respectively. Ruling out these conditions is imperative, as the approach to treatment varies significantly between IMFS and aplastic anemia. Patients with shortened telomeres should undergo genetic screening for mutations in the telomere maintenance genes to evaluate the underlying defect leading to shortened telomeres. Patients with increased peripheral blood breakage should have genetic testing to detect mutations associated with Fanconi anemia.
Classification
Once the diagnosis of aplastic anemia has been made, the patient should be classified according to the severity of their disease. Disease severity is determined based on peripheral blood ANC:34 non-severe aplastic anemia (NSAA), ANC > 500 polymorphonuclear neutrophils (PMNs)/µL; severe aplastic anemia (SAA), 200–500 PMNs/µL; and very severe (VSAA), 0–200 PMNs/µL.4,34 Disease classification is important, as VSAA is associated with a decreased OS compared to SAA.2 Disease classification may affect treatment decisions, as patients with NSAA may be observed for a short period of time, while conversely patients with SAA have a worse prognosis with delays in therapy.42-44
Summary
Aplastic anemia is a rare but potentially life-threatening disorder characterized by pancytopenia and a marked reduction in the hematopoietic stem cell compartment. It can be acquired or associated with an IMFS, and the treatment and prognosis vary dramatically between these 2 etiologies. Work-up and diagnosis involves investigating IMFSs and ruling out malignant or infectious etiologies for pancytopenia. After aplastic anemia has been diagnosed, the patient should be classified according to the severity of their disease based on peripheral blood ANC.
1. Young NS, Calado RT, Scheinberg P. Current concepts in the pathophysiology and treatment of aplastic anemia. Blood. 2006;108:2509-2519.
2. Vaht K, Göransson M, Carlson K, et al. Incidence and outcome of acquired aplastic anemia: real-world data from patients diagnosed in Sweden from 2000–2011. Haematologica. 2017;102:1683-1690.
3. Incidence of aplastic anemia: the relevance of diagnostic criteria. By the International Agranulocytosis and Aplastic Anemia Study. Blood. 1987;70:1718-1721.
4. Montané E, Ibanez L, Vidal X, et al. Epidemiology of aplastic anemia: a prospective multicenter study. Haematologica. 2008;93:518-523.
5. Ohta A, Nagai M, Nishina M, et al. Incidence of aplastic anemia in Japan: analysis of data from a nationwide registration system. Int J Epidemiol. 2015; 44(suppl_1):i178.
6. Passweg JR, Marsh JC. Aplastic anemia: first-line treatment by immunosuppression and sibling marrow transplantation. Hematology Am Soc Hematol Educ Program. 2010;2010:36-42.
7. Weinzierl EP, Arber DA. The differential diagnosis and bone marrow evaluation of new-onset pancytopenia. Am J Clin Pathol. 2013;139:9-29.
8. Lin FC, Karwan M, Saleh B, et al. IFN-γ causes aplastic anemia by altering hematopoiesis stem/progenitor cell composition and disrupting lineage differentiation. Blood. 2014;124:3699-3708.
9. Yoshizato T, Dumitriu B, Hosokawa K, et al. Somatic mutations and clonal hematopoiesis in aplastic anemia. N Engl J Med. 2015;373:35-47.
10. de Bruin AM, Voermans C, Nolte MA. Impact of interferon-γ on hematopoiesis. Blood. 2014;124:2479-2486.
11. Cheng H, Cheruku PS, Alvarado L, et al. Interferon-γ perturbs key signaling pathways induced by thrombopoietin, but not eltrombopag, in human hematopoietic stem/progenitor cells. Blood. 2016;128:3870.
12. Olnes MJ, Scheinberg P, Calvo KR, et al. Eltrombopag and improved hematopoiesis in refractory aplastic anemia. N Engl J Med. 2012;367:11-19.
13. Townsley DM, Dumitriu B, Young NS, et al. Danazol treatment for telomere diseases. N Engl J Med. 2016;374:1922-1931.
14. Feurstein S, Drazer MW, Godley LA. Genetic predisposition to leukemia and other hematologic malignancies. Sem Oncol. 2016;43:598-608.
15. Townsley DM, Dumitriu B, Young NS. Bone marrow failure and the telomeropathies. Blood. 2014;124:2775-2783.
16. Young NS, Bacigalupo A, Marsh JC. Aplastic anemia: pathophysiology and treatment. Biol Blood Marrow Transplant. 2010;16:S119-125.
17. Calado RT, Young NS. Telomere maintenance and human bone marrow failure. Blood. 2008;111:4446-4455.
18. DiNardo CD, Bannon SA, Routbort M, et al. Evaluation of patients and families with concern for predispositions to hematologic malignancies within the Hereditary Hematologic Malignancy Clinic (HHMC). Clin Lymphoma Myeloma Leuk. 2016;16:417-428.
19. Borie R, Tabèze L, Thabut G, et al. Prevalence and characteristics of TERT and TERC mutations in suspected genetic pulmonary fibrosis. Eur Resp J. 2016;48:1721-1731.
20. Ogawa S. Clonal hematopoiesis in acquired aplastic anemia. Blood. 2016;128:337-347.
21. Kulasekararaj AG, Jiang J, Smith AE, et al. Somatic mutations identify a sub-group of aplastic anemia patients that progress to myelodysplastic syndrome. Blood. 2014; 124:2698-2704.
22. Mukhina GL, Buckley JT, Barber JP, et al. Multilineage glycosylphosphatidylinositol anchor‐deficient haematopoiesis in untreated aplastic anaemia. Br J Haematol. 2001;115:476-482.
23. Pu JJ, Mukhina G, Wang H, et al. Natural history of paroxysmal nocturnal hemoglobinuria clones in patients presenting as aplastic anemia. Eur J Haematol. 2011;87:37-45.
24. Hall SE, Rosse WF. The use of monoclonal antibodies and flow cytometry in the diagnosis of paroxysmal nocturnal hemoglobinuria. Blood. 1996;87:5332-5340.
25. Devalet B, Mullier F, Chatelain B, et al. Pathophysiology, diagnosis, and treatment of paroxysmal nocturnal hemoglobinuria: a review. Eur J Haematol. 2015;95:190-198.
26. Sugimori C, Chuhjo T, Feng X, et al. Minor population of CD55-CD59-blood cells predicts response to immunosuppressive therapy and prognosis in patients with aplastic anemia. Blood. 2006;107:1308-1314.
27. Scheinberg P, Marte M, Nunez O, Young NS. Paroxysmal nocturnal hemoglobinuria clones in severe aplastic anemia patients treated with horse anti-thymocyte globulin plus cyclosporine. Haematologica. 2010;95:1075-1080.
28. Parker C, Omine M, Richards S, et al. Diagnosis and management of paroxysmal nocturnal hemoglobinuria. Blood. 2005;106:3699-3709.
29. Guinan EC. Diagnosis and management of aplastic anemia. Hematology Am Soc Hematol Educ Program. 2011;2011:76-81.
30. Giampietro PF, Verlander PC, Davis JG, Auerbach AD. Diagnosis of Fanconi anemia in patients without congenital malformations: an international Fanconi Anemia Registry Study. Am J Med Genetics. 1997;68:58-61.
31. Auerbach AD. Fanconi anemia and its diagnosis. Mutat Res. 2009;668:4-10.
32. Giampietro PF, Davis JG, Adler-Brecher B, et al. The need for more accurate and timely diagnosis in Fanconi anemia: a report from the International Fanconi Anemia Registry. Pediatrics. 1993;91:1116-1120.
33. DiNardo CD, Bannon SA, Routbort M, et al. Evaluation of patients and families with concern for predispositions to hematologic malignancies within the Hereditary Hematologic Malignancy Clinic (HHMC). Clin Lymphoma Myeloma Leuk. 2016;16:417-428.
34. Bacigalupo A. How I treat acquired aplastic anemia. Blood. 2017;129:1428-1436.
35. DeZern AE, Brodsky RA. Clinical management of aplastic anemia. Expert Rev Hematol. 2011;4:221-230.
36. Tichelli A, Gratwohl A, Nissen C, et al. Morphology in patients with severe aplastic anemia treated with antilymphocyte globulin. Blood. 1992;80:337-345.
37. Camitta BM, Storb R, Thomas ED. Aplastic anemia: pathogenesis, diagnosis, treatment, and prognosis. N Engl J Med. 1982;306:645-652.
38. Bacigalupo A, Hows J, Gluckman E, et al. Bone marrow transplantation (BMT) versus immunosuppression for the treatment of severe aplastic anaemia (SAA): a report of the EBMT SAA working party. Br J Haematol. 1988:70:177-182.
39. Brodsky RA, Chen AR, Dorr D, et al. High-dose cyclophosphamide for severe aplastic anemia: long-term follow-up. Blood. 2010;115:2136-2141.
40. Matsui WH, Brodsky RA, Smith BD, et al. Quantitative analysis of bone marrow CD34 cells in aplastic anemia and hypoplastic myelodysplastic syndromes. Leukemia. 2006;20:458-462.
41. Maciejewski JP, Risitano AM, Nunez O, Young NS. Distinct clinical outcomes for cytogenetic abnormalities evolving from aplastic anemia. Blood. 2002;99:3129-3135.
42. Locasciulli A, Oneto R, Bacigalupo A, et al. Outcome of patients with acquired aplastic anemia given first line bone marrow transplantation or immunosuppressive treatment in the last decade: a report from the European Group for Blood and Marrow Transplantation. Haematologica. 2007;92:11-8.
43. Passweg JR, Socié G, Hinterberger W, et al. Bone marrow transplantation for severe aplastic anemia: has outcome improved? Blood. 1997;90:858-864.
44. Gupta V, Eapen M, Brazauskas R, et al. Impact of age on outcomes after transplantation for acquired aplastic anemia using HLA-identical sibling donors. Haematologica. 2010;95:2119-2125.
1. Young NS, Calado RT, Scheinberg P. Current concepts in the pathophysiology and treatment of aplastic anemia. Blood. 2006;108:2509-2519.
2. Vaht K, Göransson M, Carlson K, et al. Incidence and outcome of acquired aplastic anemia: real-world data from patients diagnosed in Sweden from 2000–2011. Haematologica. 2017;102:1683-1690.
3. Incidence of aplastic anemia: the relevance of diagnostic criteria. By the International Agranulocytosis and Aplastic Anemia Study. Blood. 1987;70:1718-1721.
4. Montané E, Ibanez L, Vidal X, et al. Epidemiology of aplastic anemia: a prospective multicenter study. Haematologica. 2008;93:518-523.
5. Ohta A, Nagai M, Nishina M, et al. Incidence of aplastic anemia in Japan: analysis of data from a nationwide registration system. Int J Epidemiol. 2015; 44(suppl_1):i178.
6. Passweg JR, Marsh JC. Aplastic anemia: first-line treatment by immunosuppression and sibling marrow transplantation. Hematology Am Soc Hematol Educ Program. 2010;2010:36-42.
7. Weinzierl EP, Arber DA. The differential diagnosis and bone marrow evaluation of new-onset pancytopenia. Am J Clin Pathol. 2013;139:9-29.
8. Lin FC, Karwan M, Saleh B, et al. IFN-γ causes aplastic anemia by altering hematopoiesis stem/progenitor cell composition and disrupting lineage differentiation. Blood. 2014;124:3699-3708.
9. Yoshizato T, Dumitriu B, Hosokawa K, et al. Somatic mutations and clonal hematopoiesis in aplastic anemia. N Engl J Med. 2015;373:35-47.
10. de Bruin AM, Voermans C, Nolte MA. Impact of interferon-γ on hematopoiesis. Blood. 2014;124:2479-2486.
11. Cheng H, Cheruku PS, Alvarado L, et al. Interferon-γ perturbs key signaling pathways induced by thrombopoietin, but not eltrombopag, in human hematopoietic stem/progenitor cells. Blood. 2016;128:3870.
12. Olnes MJ, Scheinberg P, Calvo KR, et al. Eltrombopag and improved hematopoiesis in refractory aplastic anemia. N Engl J Med. 2012;367:11-19.
13. Townsley DM, Dumitriu B, Young NS, et al. Danazol treatment for telomere diseases. N Engl J Med. 2016;374:1922-1931.
14. Feurstein S, Drazer MW, Godley LA. Genetic predisposition to leukemia and other hematologic malignancies. Sem Oncol. 2016;43:598-608.
15. Townsley DM, Dumitriu B, Young NS. Bone marrow failure and the telomeropathies. Blood. 2014;124:2775-2783.
16. Young NS, Bacigalupo A, Marsh JC. Aplastic anemia: pathophysiology and treatment. Biol Blood Marrow Transplant. 2010;16:S119-125.
17. Calado RT, Young NS. Telomere maintenance and human bone marrow failure. Blood. 2008;111:4446-4455.
18. DiNardo CD, Bannon SA, Routbort M, et al. Evaluation of patients and families with concern for predispositions to hematologic malignancies within the Hereditary Hematologic Malignancy Clinic (HHMC). Clin Lymphoma Myeloma Leuk. 2016;16:417-428.
19. Borie R, Tabèze L, Thabut G, et al. Prevalence and characteristics of TERT and TERC mutations in suspected genetic pulmonary fibrosis. Eur Resp J. 2016;48:1721-1731.
20. Ogawa S. Clonal hematopoiesis in acquired aplastic anemia. Blood. 2016;128:337-347.
21. Kulasekararaj AG, Jiang J, Smith AE, et al. Somatic mutations identify a sub-group of aplastic anemia patients that progress to myelodysplastic syndrome. Blood. 2014; 124:2698-2704.
22. Mukhina GL, Buckley JT, Barber JP, et al. Multilineage glycosylphosphatidylinositol anchor‐deficient haematopoiesis in untreated aplastic anaemia. Br J Haematol. 2001;115:476-482.
23. Pu JJ, Mukhina G, Wang H, et al. Natural history of paroxysmal nocturnal hemoglobinuria clones in patients presenting as aplastic anemia. Eur J Haematol. 2011;87:37-45.
24. Hall SE, Rosse WF. The use of monoclonal antibodies and flow cytometry in the diagnosis of paroxysmal nocturnal hemoglobinuria. Blood. 1996;87:5332-5340.
25. Devalet B, Mullier F, Chatelain B, et al. Pathophysiology, diagnosis, and treatment of paroxysmal nocturnal hemoglobinuria: a review. Eur J Haematol. 2015;95:190-198.
26. Sugimori C, Chuhjo T, Feng X, et al. Minor population of CD55-CD59-blood cells predicts response to immunosuppressive therapy and prognosis in patients with aplastic anemia. Blood. 2006;107:1308-1314.
27. Scheinberg P, Marte M, Nunez O, Young NS. Paroxysmal nocturnal hemoglobinuria clones in severe aplastic anemia patients treated with horse anti-thymocyte globulin plus cyclosporine. Haematologica. 2010;95:1075-1080.
28. Parker C, Omine M, Richards S, et al. Diagnosis and management of paroxysmal nocturnal hemoglobinuria. Blood. 2005;106:3699-3709.
29. Guinan EC. Diagnosis and management of aplastic anemia. Hematology Am Soc Hematol Educ Program. 2011;2011:76-81.
30. Giampietro PF, Verlander PC, Davis JG, Auerbach AD. Diagnosis of Fanconi anemia in patients without congenital malformations: an international Fanconi Anemia Registry Study. Am J Med Genetics. 1997;68:58-61.
31. Auerbach AD. Fanconi anemia and its diagnosis. Mutat Res. 2009;668:4-10.
32. Giampietro PF, Davis JG, Adler-Brecher B, et al. The need for more accurate and timely diagnosis in Fanconi anemia: a report from the International Fanconi Anemia Registry. Pediatrics. 1993;91:1116-1120.
33. DiNardo CD, Bannon SA, Routbort M, et al. Evaluation of patients and families with concern for predispositions to hematologic malignancies within the Hereditary Hematologic Malignancy Clinic (HHMC). Clin Lymphoma Myeloma Leuk. 2016;16:417-428.
34. Bacigalupo A. How I treat acquired aplastic anemia. Blood. 2017;129:1428-1436.
35. DeZern AE, Brodsky RA. Clinical management of aplastic anemia. Expert Rev Hematol. 2011;4:221-230.
36. Tichelli A, Gratwohl A, Nissen C, et al. Morphology in patients with severe aplastic anemia treated with antilymphocyte globulin. Blood. 1992;80:337-345.
37. Camitta BM, Storb R, Thomas ED. Aplastic anemia: pathogenesis, diagnosis, treatment, and prognosis. N Engl J Med. 1982;306:645-652.
38. Bacigalupo A, Hows J, Gluckman E, et al. Bone marrow transplantation (BMT) versus immunosuppression for the treatment of severe aplastic anaemia (SAA): a report of the EBMT SAA working party. Br J Haematol. 1988:70:177-182.
39. Brodsky RA, Chen AR, Dorr D, et al. High-dose cyclophosphamide for severe aplastic anemia: long-term follow-up. Blood. 2010;115:2136-2141.
40. Matsui WH, Brodsky RA, Smith BD, et al. Quantitative analysis of bone marrow CD34 cells in aplastic anemia and hypoplastic myelodysplastic syndromes. Leukemia. 2006;20:458-462.
41. Maciejewski JP, Risitano AM, Nunez O, Young NS. Distinct clinical outcomes for cytogenetic abnormalities evolving from aplastic anemia. Blood. 2002;99:3129-3135.
42. Locasciulli A, Oneto R, Bacigalupo A, et al. Outcome of patients with acquired aplastic anemia given first line bone marrow transplantation or immunosuppressive treatment in the last decade: a report from the European Group for Blood and Marrow Transplantation. Haematologica. 2007;92:11-8.
43. Passweg JR, Socié G, Hinterberger W, et al. Bone marrow transplantation for severe aplastic anemia: has outcome improved? Blood. 1997;90:858-864.
44. Gupta V, Eapen M, Brazauskas R, et al. Impact of age on outcomes after transplantation for acquired aplastic anemia using HLA-identical sibling donors. Haematologica. 2010;95:2119-2125.
Plerixafor produced dramatic responses in severe WHIM syndrome
Low-dose treatment with plerixafor, a CXC chemokine receptor 4 antagonist, was well tolerated and markedly improved severe presentations of warts, hypogammaglobulinemia, infections, and myelokathexis (WHIM) syndrome in three patients who could not receive granulocyte colony-stimulating factor therapy, investigators reported.
“Myelofibrosis, panleukopenia, anemia, and thrombocytopenia were ameliorated, the wart burden and frequency of infection declined, human papillomavirus–associated oropharyngeal squamous-cell carcinoma stabilized, and quality of life improved markedly,” David H. McDermott, MD, of the National Institute of Allergy and Infectious Diseases and his colleagues wrote in the New England Journal of Medicine.
WHIM syndrome is a primary immunodeficiency disorder characterized by panleukopenia and caused by autosomal dominant gain-of-function mutations in CXC chemokine receptor 4 (CXCR4). Granulocyte colony-stimulating factor (G-CSF) therapy improves neutropenia in these patients, but not other cytopenias.
Previously, the investigators treated three WHIM syndrome patients with plerixafor (Mozobil), which was well tolerated and led to sustained increases in circulating neutrophils, lymphocytes, and monocytes. The current report is of three patients with advanced WHIM syndrome who received open-label plerixafor because they were ineligible for a randomized trial of this drug.
After treatment initiation, infection frequency dropped by 85% in one patient and declined markedly in all three patients. Lymphocyte counts improved the most in two patients while neutrophils were most responsive in the third patient. Warts partially resolved in two patients, of which one patient also experienced partial resolution of head and neck squamous cell carcinoma. This patient later died of a multidrug-resistant Pseudomonas aeruginosa infection after undergoing a 9-hour surgery.
In the third patient, plerixafor therapy led to clearance of TSPyV and 17 human papillomavirus (HPV) infections, with consequent resolution of chronic, progressive, multifocal eczematoid and follicular lesions, the researchers reported. The study dose was relatively low – about 10% of the stem-cell mobilization dose – and did not cause bone pain or other treatment-emergent adverse events, despite the relatively long treatment course (19-52 months).
A separate, phase 3 trial (NCT02231879) has enrolled 19 patients. Primary results are expected in 2020.
The National Institutes of Health funded the work. Dr. McDermott reported a pending patent to reduce CXCR4 expression and/or function to enhance engraftment of hematopoietic stem cells.
SOURCE: McDermott DH et al. N Engl J Med. 2019;380:163-70.
Low-dose treatment with plerixafor, a CXC chemokine receptor 4 antagonist, was well tolerated and markedly improved severe presentations of warts, hypogammaglobulinemia, infections, and myelokathexis (WHIM) syndrome in three patients who could not receive granulocyte colony-stimulating factor therapy, investigators reported.
“Myelofibrosis, panleukopenia, anemia, and thrombocytopenia were ameliorated, the wart burden and frequency of infection declined, human papillomavirus–associated oropharyngeal squamous-cell carcinoma stabilized, and quality of life improved markedly,” David H. McDermott, MD, of the National Institute of Allergy and Infectious Diseases and his colleagues wrote in the New England Journal of Medicine.
WHIM syndrome is a primary immunodeficiency disorder characterized by panleukopenia and caused by autosomal dominant gain-of-function mutations in CXC chemokine receptor 4 (CXCR4). Granulocyte colony-stimulating factor (G-CSF) therapy improves neutropenia in these patients, but not other cytopenias.
Previously, the investigators treated three WHIM syndrome patients with plerixafor (Mozobil), which was well tolerated and led to sustained increases in circulating neutrophils, lymphocytes, and monocytes. The current report is of three patients with advanced WHIM syndrome who received open-label plerixafor because they were ineligible for a randomized trial of this drug.
After treatment initiation, infection frequency dropped by 85% in one patient and declined markedly in all three patients. Lymphocyte counts improved the most in two patients while neutrophils were most responsive in the third patient. Warts partially resolved in two patients, of which one patient also experienced partial resolution of head and neck squamous cell carcinoma. This patient later died of a multidrug-resistant Pseudomonas aeruginosa infection after undergoing a 9-hour surgery.
In the third patient, plerixafor therapy led to clearance of TSPyV and 17 human papillomavirus (HPV) infections, with consequent resolution of chronic, progressive, multifocal eczematoid and follicular lesions, the researchers reported. The study dose was relatively low – about 10% of the stem-cell mobilization dose – and did not cause bone pain or other treatment-emergent adverse events, despite the relatively long treatment course (19-52 months).
A separate, phase 3 trial (NCT02231879) has enrolled 19 patients. Primary results are expected in 2020.
The National Institutes of Health funded the work. Dr. McDermott reported a pending patent to reduce CXCR4 expression and/or function to enhance engraftment of hematopoietic stem cells.
SOURCE: McDermott DH et al. N Engl J Med. 2019;380:163-70.
Low-dose treatment with plerixafor, a CXC chemokine receptor 4 antagonist, was well tolerated and markedly improved severe presentations of warts, hypogammaglobulinemia, infections, and myelokathexis (WHIM) syndrome in three patients who could not receive granulocyte colony-stimulating factor therapy, investigators reported.
“Myelofibrosis, panleukopenia, anemia, and thrombocytopenia were ameliorated, the wart burden and frequency of infection declined, human papillomavirus–associated oropharyngeal squamous-cell carcinoma stabilized, and quality of life improved markedly,” David H. McDermott, MD, of the National Institute of Allergy and Infectious Diseases and his colleagues wrote in the New England Journal of Medicine.
WHIM syndrome is a primary immunodeficiency disorder characterized by panleukopenia and caused by autosomal dominant gain-of-function mutations in CXC chemokine receptor 4 (CXCR4). Granulocyte colony-stimulating factor (G-CSF) therapy improves neutropenia in these patients, but not other cytopenias.
Previously, the investigators treated three WHIM syndrome patients with plerixafor (Mozobil), which was well tolerated and led to sustained increases in circulating neutrophils, lymphocytes, and monocytes. The current report is of three patients with advanced WHIM syndrome who received open-label plerixafor because they were ineligible for a randomized trial of this drug.
After treatment initiation, infection frequency dropped by 85% in one patient and declined markedly in all three patients. Lymphocyte counts improved the most in two patients while neutrophils were most responsive in the third patient. Warts partially resolved in two patients, of which one patient also experienced partial resolution of head and neck squamous cell carcinoma. This patient later died of a multidrug-resistant Pseudomonas aeruginosa infection after undergoing a 9-hour surgery.
In the third patient, plerixafor therapy led to clearance of TSPyV and 17 human papillomavirus (HPV) infections, with consequent resolution of chronic, progressive, multifocal eczematoid and follicular lesions, the researchers reported. The study dose was relatively low – about 10% of the stem-cell mobilization dose – and did not cause bone pain or other treatment-emergent adverse events, despite the relatively long treatment course (19-52 months).
A separate, phase 3 trial (NCT02231879) has enrolled 19 patients. Primary results are expected in 2020.
The National Institutes of Health funded the work. Dr. McDermott reported a pending patent to reduce CXCR4 expression and/or function to enhance engraftment of hematopoietic stem cells.
SOURCE: McDermott DH et al. N Engl J Med. 2019;380:163-70.
FROM THE NEW ENGLAND JOURNAL OF MEDICINE
Key clinical point:
Major finding: Infection frequency dropped by 85% in one patient and showed marked declines in all three patients.
Study details: Open-label study of three patients who were ineligible to receive G-CSF therapy.
Disclosures: The National Institutes of Health funded the work. Dr. McDermott reported a pending patent on reducing CXCR4 expression and/or function to enhance engraftment of hematopoietic stem cells.
Source: McDermott DH et al. N Engl J Med. 2019;380:163-70.
Sickle cell infusion gains FDA breakthrough designation
The in patients with sickle cell disease of all genotypes.
The designation allows the treatment to be reviewed on an expedited schedule.
Crizanlizumab, marketed by Novartis, is a humanized anti–P-selectin monoclonal antibody that has been shown to inhibit interactions between endothelial cells, platelets, red blood cells, sickled red blood cells, and leukocytes.
In the phase 2 SUSTAIN trial, crizanlizumab reduced the median annual rate of vasoocclusive crises that resulted in health care visits by about 45%, compared with placebo (1.63 vs. 2.98; P = .010). The drug also increased the percentage of patients who did not experience any vasoocclusive crises, compared with placebo (35.8% vs. 16.9%; P = .010).
The rates of treatment-emergent and serious adverse events was similar in the drug and placebo arms of the trial.
The in patients with sickle cell disease of all genotypes.
The designation allows the treatment to be reviewed on an expedited schedule.
Crizanlizumab, marketed by Novartis, is a humanized anti–P-selectin monoclonal antibody that has been shown to inhibit interactions between endothelial cells, platelets, red blood cells, sickled red blood cells, and leukocytes.
In the phase 2 SUSTAIN trial, crizanlizumab reduced the median annual rate of vasoocclusive crises that resulted in health care visits by about 45%, compared with placebo (1.63 vs. 2.98; P = .010). The drug also increased the percentage of patients who did not experience any vasoocclusive crises, compared with placebo (35.8% vs. 16.9%; P = .010).
The rates of treatment-emergent and serious adverse events was similar in the drug and placebo arms of the trial.
The in patients with sickle cell disease of all genotypes.
The designation allows the treatment to be reviewed on an expedited schedule.
Crizanlizumab, marketed by Novartis, is a humanized anti–P-selectin monoclonal antibody that has been shown to inhibit interactions between endothelial cells, platelets, red blood cells, sickled red blood cells, and leukocytes.
In the phase 2 SUSTAIN trial, crizanlizumab reduced the median annual rate of vasoocclusive crises that resulted in health care visits by about 45%, compared with placebo (1.63 vs. 2.98; P = .010). The drug also increased the percentage of patients who did not experience any vasoocclusive crises, compared with placebo (35.8% vs. 16.9%; P = .010).
The rates of treatment-emergent and serious adverse events was similar in the drug and placebo arms of the trial.
Chemo for solid tumors and risk of tMDS/AML
Chemotherapy for solid tumors is associated with an increased risk of therapy-related myelodysplastic syndromes or acute myeloid leukemia (tMDS/AML), according to a retrospective analysis.
Long-term, population-based cohort data showed the risk of tMDS/AML was significantly elevated after chemotherapy for 22 solid tumor types.
The relative risk of tMDS/AML was 1.5- to 39.0-fold greater among patients treated for these tumors than among the general population.
Lindsay M. Morton, PhD, of the National Institutes of Health in Rockville, Maryland, and her colleagues reported these findings in JAMA Oncology.
“We undertook an investigation to quantify tMDS/AML risks after chemotherapy for solid tumors in the modern treatment era, 2000-2014, using United States cancer registry data from the National Cancer Institute’s Surveillance, Epidemiology, and End Results Program,” the investigators wrote.
They retrospectively analyzed data from 1619 patients with tMDS/AML who were diagnosed with an initial primary solid tumor from 2000 to 2013.
Patients were given initial chemotherapy and lived for at least 1 year after treatment. Subsequently, Dr. Morton and her colleagues linked patient database records with Medicare insurance claim information to confirm the accuracy of chemotherapy data.
“Because registry data do not include treatment details, we used an alternative database to provide descriptive information on population-based patterns of chemotherapeutic drug use,” the investigators noted.
The team found the risk of developing tMDS/AML was significantly increased following chemotherapy administration for 22 of 23 solid tumor types, excluding colon cancer.
The standardized incidence ratio (SIR) for tMDS/AML ranged from 1.5 to 39.0, and the excess absolute risk (EAR) ranged from 1.4 to 23.6 cases per 10,000 person-years.
SIRs were greatest in patients who received chemotherapy for malignancy of the bone (SIR=39.0, EAR=23.6), testis (SIR, 12.3, EAR=4.4), soft tissue (SIR=10.4, EAR=12.6), fallopian tube (SIR=8.7, EAR=16.0), small cell lung (SIR=8.1, EAR=19.9), peritoneum (SIR=7.5, EAR=15.8), brain or central nervous system (SIR=7.2, EAR=6.0), and ovary (SIR=5.8, EAR=8.2).
The investigators also found that patients who were given chemotherapy at a young age had the highest risk of developing tMDS/AML.
“For patients treated with chemotherapy at the present time, approximately three-quarters of tMDS/AML cases expected to occur within the next 5 years will be attributable to chemotherapy,” the investigators said.
They acknowledged a key limitation of this study was the limited data on patient-specific chemotherapy and dosing information. Given these limitations, Dr. Morton and her colleagues said, “the exact magnitude of our risk estimates, including the proportions of excess cases, should therefore be interpreted cautiously.”
This study was supported by the Intramural Research Program of the National Institutes of Health, National Cancer Institute, and the California Department of Public Health. The authors reported no conflicts of interest.
Chemotherapy for solid tumors is associated with an increased risk of therapy-related myelodysplastic syndromes or acute myeloid leukemia (tMDS/AML), according to a retrospective analysis.
Long-term, population-based cohort data showed the risk of tMDS/AML was significantly elevated after chemotherapy for 22 solid tumor types.
The relative risk of tMDS/AML was 1.5- to 39.0-fold greater among patients treated for these tumors than among the general population.
Lindsay M. Morton, PhD, of the National Institutes of Health in Rockville, Maryland, and her colleagues reported these findings in JAMA Oncology.
“We undertook an investigation to quantify tMDS/AML risks after chemotherapy for solid tumors in the modern treatment era, 2000-2014, using United States cancer registry data from the National Cancer Institute’s Surveillance, Epidemiology, and End Results Program,” the investigators wrote.
They retrospectively analyzed data from 1619 patients with tMDS/AML who were diagnosed with an initial primary solid tumor from 2000 to 2013.
Patients were given initial chemotherapy and lived for at least 1 year after treatment. Subsequently, Dr. Morton and her colleagues linked patient database records with Medicare insurance claim information to confirm the accuracy of chemotherapy data.
“Because registry data do not include treatment details, we used an alternative database to provide descriptive information on population-based patterns of chemotherapeutic drug use,” the investigators noted.
The team found the risk of developing tMDS/AML was significantly increased following chemotherapy administration for 22 of 23 solid tumor types, excluding colon cancer.
The standardized incidence ratio (SIR) for tMDS/AML ranged from 1.5 to 39.0, and the excess absolute risk (EAR) ranged from 1.4 to 23.6 cases per 10,000 person-years.
SIRs were greatest in patients who received chemotherapy for malignancy of the bone (SIR=39.0, EAR=23.6), testis (SIR, 12.3, EAR=4.4), soft tissue (SIR=10.4, EAR=12.6), fallopian tube (SIR=8.7, EAR=16.0), small cell lung (SIR=8.1, EAR=19.9), peritoneum (SIR=7.5, EAR=15.8), brain or central nervous system (SIR=7.2, EAR=6.0), and ovary (SIR=5.8, EAR=8.2).
The investigators also found that patients who were given chemotherapy at a young age had the highest risk of developing tMDS/AML.
“For patients treated with chemotherapy at the present time, approximately three-quarters of tMDS/AML cases expected to occur within the next 5 years will be attributable to chemotherapy,” the investigators said.
They acknowledged a key limitation of this study was the limited data on patient-specific chemotherapy and dosing information. Given these limitations, Dr. Morton and her colleagues said, “the exact magnitude of our risk estimates, including the proportions of excess cases, should therefore be interpreted cautiously.”
This study was supported by the Intramural Research Program of the National Institutes of Health, National Cancer Institute, and the California Department of Public Health. The authors reported no conflicts of interest.
Chemotherapy for solid tumors is associated with an increased risk of therapy-related myelodysplastic syndromes or acute myeloid leukemia (tMDS/AML), according to a retrospective analysis.
Long-term, population-based cohort data showed the risk of tMDS/AML was significantly elevated after chemotherapy for 22 solid tumor types.
The relative risk of tMDS/AML was 1.5- to 39.0-fold greater among patients treated for these tumors than among the general population.
Lindsay M. Morton, PhD, of the National Institutes of Health in Rockville, Maryland, and her colleagues reported these findings in JAMA Oncology.
“We undertook an investigation to quantify tMDS/AML risks after chemotherapy for solid tumors in the modern treatment era, 2000-2014, using United States cancer registry data from the National Cancer Institute’s Surveillance, Epidemiology, and End Results Program,” the investigators wrote.
They retrospectively analyzed data from 1619 patients with tMDS/AML who were diagnosed with an initial primary solid tumor from 2000 to 2013.
Patients were given initial chemotherapy and lived for at least 1 year after treatment. Subsequently, Dr. Morton and her colleagues linked patient database records with Medicare insurance claim information to confirm the accuracy of chemotherapy data.
“Because registry data do not include treatment details, we used an alternative database to provide descriptive information on population-based patterns of chemotherapeutic drug use,” the investigators noted.
The team found the risk of developing tMDS/AML was significantly increased following chemotherapy administration for 22 of 23 solid tumor types, excluding colon cancer.
The standardized incidence ratio (SIR) for tMDS/AML ranged from 1.5 to 39.0, and the excess absolute risk (EAR) ranged from 1.4 to 23.6 cases per 10,000 person-years.
SIRs were greatest in patients who received chemotherapy for malignancy of the bone (SIR=39.0, EAR=23.6), testis (SIR, 12.3, EAR=4.4), soft tissue (SIR=10.4, EAR=12.6), fallopian tube (SIR=8.7, EAR=16.0), small cell lung (SIR=8.1, EAR=19.9), peritoneum (SIR=7.5, EAR=15.8), brain or central nervous system (SIR=7.2, EAR=6.0), and ovary (SIR=5.8, EAR=8.2).
The investigators also found that patients who were given chemotherapy at a young age had the highest risk of developing tMDS/AML.
“For patients treated with chemotherapy at the present time, approximately three-quarters of tMDS/AML cases expected to occur within the next 5 years will be attributable to chemotherapy,” the investigators said.
They acknowledged a key limitation of this study was the limited data on patient-specific chemotherapy and dosing information. Given these limitations, Dr. Morton and her colleagues said, “the exact magnitude of our risk estimates, including the proportions of excess cases, should therefore be interpreted cautiously.”
This study was supported by the Intramural Research Program of the National Institutes of Health, National Cancer Institute, and the California Department of Public Health. The authors reported no conflicts of interest.
Potential treatment on the horizon for cold agglutinin disease
In a first-in-human trial, sutimlimab rapidly halted hemolysis, corrected anemia, precluded the need for transfusion, and caused no serious adverse effects in patients with cold agglutinin disease.
Sutimlimab also “induced clinically meaningful increases in hemoglobin levels, even in patients with multiple previous lines of therapy,” according to investigators.
The European Medicines Agency and the U.S. Food and Drug Administration (FDA) awarded sutimlimab orphan drug status based on these results. The FDA also granted sutimlimab breakthrough therapy designation.
Sutimlimab is a humanized anti-C1s IgG4 monoclonal antibody that blocks the classical complement pathway–specific protease C1s and prevents further hemolysis in patients with cold agglutinin disease.
Cold agglutinin disease is a rare, acquired chronic autoimmune hemolytic condition that destroys red blood cells. It leads to chronic anemia, severe fatigue, and potentially fatal thrombotic events. No drug has yet been approved to treat cold agglutinin disease.
The phase 1 trial of sutimlimab (formerly BIVV009 and TNT009) in cold agglutinin disease was conducted at the Medical University of Vienna in Austria and reported in Blood.
The study (NCT02502903) involved 10 patients, ages 56 to 76, who were previously treated with multiple lines of therapy, including two patients who failed treatment with eculizumab.
Of the 10 patients, eight were female, eight were Caucasian, one was Asian, and one was Hispanic. Patients had cold agglutinin disease for a median of 5 years (range, 1 – 20).
At baseline, the median hemoglobin level was 7.8 g/dL, the median number of reticulocytes was 133 x 109/L, the median bilirubin was 2.0 mg/dL, and the median haptoglobin was less than 12 mg/dL.
The patients received an initial dose of 10 mg/kg intravenous sutimlimab as a test dose to allow rapid wash-out of the drug if unforeseen adverse effects occurred with the first infusion.
One to 4 days later, they received the full dose of 60 mg/kg, followed by three additional weekly doses.
Investigators observed the patients for 49 to 53 days.
Results
Within the first week, patients’ median hemoglobin levels increased by 1.6 g/dL (P=0.007), and the median best response was an increase of 3.9 g/dL (P=0.005) after 6 weeks.
Seven patients had increased hemoglobin levels by more than 2 g/dL, and this included those who recently failed to respond or relapsed after rituximab, rituximab plus bendamustine, or eculizumab.
In five patients, hemoglobin increased by 4 g/dL or more. In four patients, it completely normalized to 12 g/dL.
In the first 24 hours after sutimlimab infusion, reticulocyte counts increased by a median of 41% and then gradually declined as hemoglobin levels rose.
In four patients, haptoglobin levels normalized within 1 to 2 weeks. In eight patients who had abnormal bilirubin levels at baseline, sutimlimab decreased the median bilirubin levels by 61%, normalizing levels in most patients within 24 hours of the first infusion (P=0.007).
When sutimlimab was washed out, bilirubin levels increased again, which demonstrated the recurrence of hemolysis.
Approximately 3 to 4 weeks after the last dose of sutimlimab, hemolysis and anemia recurred in all responders.
When patients were re-exposed to sutimlimab, rapid and complete inhibition of hemolysis occurred once again.
None of the patients required packed red blood cell transfusions during treatment.
Safety
The investigators reported that all infusions were well tolerated without premedication and without relevant drug-related adverse effects.
They reported few adverse events during the trial. All were mild or moderate in severity, and most were considered unrelated or unlikely related to sutimlimab.
Two adverse events—one mild purpural rash on both hands and one case of moderate hair loss (each occurring in one patient)—were possibly related to sutimlimab.
While the investigators considered the safety data encouraging, they recommended interpreting the data “cautiously in light of the limited duration of the trial.”
“Provided that safety results remain positive, sutimlimab could become the first approved treatment for cold agglutinin disease,” said corresponding author Bernd Jilma, MD, of the Medical University of Vienna in Austria.
“The drug clearly addresses an unmet medical need, as we have seen rapid, strong responses in patients for whom multiple prior therapies have failed.”
This study was funded by True North Therapeutics, Inc, now part of Bioverativ, a Sanofi company.
Some of the authors disclosed financial relationships, including employment, with True North Therapeutics and Bioverativ.
A phase 3 trial of sutimlimab is underway with top-line results due in 2019.
In a first-in-human trial, sutimlimab rapidly halted hemolysis, corrected anemia, precluded the need for transfusion, and caused no serious adverse effects in patients with cold agglutinin disease.
Sutimlimab also “induced clinically meaningful increases in hemoglobin levels, even in patients with multiple previous lines of therapy,” according to investigators.
The European Medicines Agency and the U.S. Food and Drug Administration (FDA) awarded sutimlimab orphan drug status based on these results. The FDA also granted sutimlimab breakthrough therapy designation.
Sutimlimab is a humanized anti-C1s IgG4 monoclonal antibody that blocks the classical complement pathway–specific protease C1s and prevents further hemolysis in patients with cold agglutinin disease.
Cold agglutinin disease is a rare, acquired chronic autoimmune hemolytic condition that destroys red blood cells. It leads to chronic anemia, severe fatigue, and potentially fatal thrombotic events. No drug has yet been approved to treat cold agglutinin disease.
The phase 1 trial of sutimlimab (formerly BIVV009 and TNT009) in cold agglutinin disease was conducted at the Medical University of Vienna in Austria and reported in Blood.
The study (NCT02502903) involved 10 patients, ages 56 to 76, who were previously treated with multiple lines of therapy, including two patients who failed treatment with eculizumab.
Of the 10 patients, eight were female, eight were Caucasian, one was Asian, and one was Hispanic. Patients had cold agglutinin disease for a median of 5 years (range, 1 – 20).
At baseline, the median hemoglobin level was 7.8 g/dL, the median number of reticulocytes was 133 x 109/L, the median bilirubin was 2.0 mg/dL, and the median haptoglobin was less than 12 mg/dL.
The patients received an initial dose of 10 mg/kg intravenous sutimlimab as a test dose to allow rapid wash-out of the drug if unforeseen adverse effects occurred with the first infusion.
One to 4 days later, they received the full dose of 60 mg/kg, followed by three additional weekly doses.
Investigators observed the patients for 49 to 53 days.
Results
Within the first week, patients’ median hemoglobin levels increased by 1.6 g/dL (P=0.007), and the median best response was an increase of 3.9 g/dL (P=0.005) after 6 weeks.
Seven patients had increased hemoglobin levels by more than 2 g/dL, and this included those who recently failed to respond or relapsed after rituximab, rituximab plus bendamustine, or eculizumab.
In five patients, hemoglobin increased by 4 g/dL or more. In four patients, it completely normalized to 12 g/dL.
In the first 24 hours after sutimlimab infusion, reticulocyte counts increased by a median of 41% and then gradually declined as hemoglobin levels rose.
In four patients, haptoglobin levels normalized within 1 to 2 weeks. In eight patients who had abnormal bilirubin levels at baseline, sutimlimab decreased the median bilirubin levels by 61%, normalizing levels in most patients within 24 hours of the first infusion (P=0.007).
When sutimlimab was washed out, bilirubin levels increased again, which demonstrated the recurrence of hemolysis.
Approximately 3 to 4 weeks after the last dose of sutimlimab, hemolysis and anemia recurred in all responders.
When patients were re-exposed to sutimlimab, rapid and complete inhibition of hemolysis occurred once again.
None of the patients required packed red blood cell transfusions during treatment.
Safety
The investigators reported that all infusions were well tolerated without premedication and without relevant drug-related adverse effects.
They reported few adverse events during the trial. All were mild or moderate in severity, and most were considered unrelated or unlikely related to sutimlimab.
Two adverse events—one mild purpural rash on both hands and one case of moderate hair loss (each occurring in one patient)—were possibly related to sutimlimab.
While the investigators considered the safety data encouraging, they recommended interpreting the data “cautiously in light of the limited duration of the trial.”
“Provided that safety results remain positive, sutimlimab could become the first approved treatment for cold agglutinin disease,” said corresponding author Bernd Jilma, MD, of the Medical University of Vienna in Austria.
“The drug clearly addresses an unmet medical need, as we have seen rapid, strong responses in patients for whom multiple prior therapies have failed.”
This study was funded by True North Therapeutics, Inc, now part of Bioverativ, a Sanofi company.
Some of the authors disclosed financial relationships, including employment, with True North Therapeutics and Bioverativ.
A phase 3 trial of sutimlimab is underway with top-line results due in 2019.
In a first-in-human trial, sutimlimab rapidly halted hemolysis, corrected anemia, precluded the need for transfusion, and caused no serious adverse effects in patients with cold agglutinin disease.
Sutimlimab also “induced clinically meaningful increases in hemoglobin levels, even in patients with multiple previous lines of therapy,” according to investigators.
The European Medicines Agency and the U.S. Food and Drug Administration (FDA) awarded sutimlimab orphan drug status based on these results. The FDA also granted sutimlimab breakthrough therapy designation.
Sutimlimab is a humanized anti-C1s IgG4 monoclonal antibody that blocks the classical complement pathway–specific protease C1s and prevents further hemolysis in patients with cold agglutinin disease.
Cold agglutinin disease is a rare, acquired chronic autoimmune hemolytic condition that destroys red blood cells. It leads to chronic anemia, severe fatigue, and potentially fatal thrombotic events. No drug has yet been approved to treat cold agglutinin disease.
The phase 1 trial of sutimlimab (formerly BIVV009 and TNT009) in cold agglutinin disease was conducted at the Medical University of Vienna in Austria and reported in Blood.
The study (NCT02502903) involved 10 patients, ages 56 to 76, who were previously treated with multiple lines of therapy, including two patients who failed treatment with eculizumab.
Of the 10 patients, eight were female, eight were Caucasian, one was Asian, and one was Hispanic. Patients had cold agglutinin disease for a median of 5 years (range, 1 – 20).
At baseline, the median hemoglobin level was 7.8 g/dL, the median number of reticulocytes was 133 x 109/L, the median bilirubin was 2.0 mg/dL, and the median haptoglobin was less than 12 mg/dL.
The patients received an initial dose of 10 mg/kg intravenous sutimlimab as a test dose to allow rapid wash-out of the drug if unforeseen adverse effects occurred with the first infusion.
One to 4 days later, they received the full dose of 60 mg/kg, followed by three additional weekly doses.
Investigators observed the patients for 49 to 53 days.
Results
Within the first week, patients’ median hemoglobin levels increased by 1.6 g/dL (P=0.007), and the median best response was an increase of 3.9 g/dL (P=0.005) after 6 weeks.
Seven patients had increased hemoglobin levels by more than 2 g/dL, and this included those who recently failed to respond or relapsed after rituximab, rituximab plus bendamustine, or eculizumab.
In five patients, hemoglobin increased by 4 g/dL or more. In four patients, it completely normalized to 12 g/dL.
In the first 24 hours after sutimlimab infusion, reticulocyte counts increased by a median of 41% and then gradually declined as hemoglobin levels rose.
In four patients, haptoglobin levels normalized within 1 to 2 weeks. In eight patients who had abnormal bilirubin levels at baseline, sutimlimab decreased the median bilirubin levels by 61%, normalizing levels in most patients within 24 hours of the first infusion (P=0.007).
When sutimlimab was washed out, bilirubin levels increased again, which demonstrated the recurrence of hemolysis.
Approximately 3 to 4 weeks after the last dose of sutimlimab, hemolysis and anemia recurred in all responders.
When patients were re-exposed to sutimlimab, rapid and complete inhibition of hemolysis occurred once again.
None of the patients required packed red blood cell transfusions during treatment.
Safety
The investigators reported that all infusions were well tolerated without premedication and without relevant drug-related adverse effects.
They reported few adverse events during the trial. All were mild or moderate in severity, and most were considered unrelated or unlikely related to sutimlimab.
Two adverse events—one mild purpural rash on both hands and one case of moderate hair loss (each occurring in one patient)—were possibly related to sutimlimab.
While the investigators considered the safety data encouraging, they recommended interpreting the data “cautiously in light of the limited duration of the trial.”
“Provided that safety results remain positive, sutimlimab could become the first approved treatment for cold agglutinin disease,” said corresponding author Bernd Jilma, MD, of the Medical University of Vienna in Austria.
“The drug clearly addresses an unmet medical need, as we have seen rapid, strong responses in patients for whom multiple prior therapies have failed.”
This study was funded by True North Therapeutics, Inc, now part of Bioverativ, a Sanofi company.
Some of the authors disclosed financial relationships, including employment, with True North Therapeutics and Bioverativ.
A phase 3 trial of sutimlimab is underway with top-line results due in 2019.
Team reports long-term effects of blood management
An initiative that reduced red blood cell (RBC) transfusions and increased moderate anemia in hospital did not adversely impact patients long-term, according to an analysis.
Researchers found that an increase in moderate in-hospital anemia did not increase subsequent RBC use, readmission, or mortality over the next 6 months.
However, authors of a related editorial argued that additional factors must be assessed to truly determine the effects of moderate anemia on patient outcomes.
The study and the editorial were published in the Annals of Internal Medicine.
Study: Long-term outcomes
Nareg H. Roubinian, MD, of Kaiser Permanente Northern California in Oakland, and colleagues sought to evaluate the impact of blood management programs—starting in 2010—that included blood-sparing surgical and medical techniques, increased use of hemostatic and cell salvage agents, and treatment of suboptimal iron stores before surgery.
In previous retrospective cohort studies, the researchers had found that blood conservation strategies did not impact in-hospital or 30-day mortality rates, which was consistent with short-term safety data from clinical trials and other observational studies.
Their new report on longer-term outcomes was based on data from Kaiser Permanente Northern California for 445,371 adults who had 801,261 hospitalizations with discharges between 2010 and 2014.
In this cohort, moderate anemia (hemoglobin between 7 g/dL and 10 g/dL) at discharge occurred in 119,489 patients (27%) and 187,440 hospitalizations overall (23%).
Over the 2010-2014 period, RBC transfusions decreased by more than 25% in the inpatient and outpatient settings. In parallel, the prevalence of moderate anemia at hospital discharge increased from 20% to 25%.
However, the risks of subsequent RBC transfusions and rehospitalization after discharge with anemia decreased during the study period, and mortality rates stayed steady or decreased slightly.
Among patients with moderate anemia, the proportion with subsequent RBC transfusions within 6 months decreased from 18.9% in 2010 to 16.8% in 2014 (P<0.001), while the rate of rehospitalization within 6 months decreased from 36.5% to 32.8% over that same time period (P<0.001).
The adjusted 6-month mortality rate likewise decreased from 16.1% to 15.6% (P=0.004) over that time period among patients with moderate anemia.
“These data support the efficacy and safety of practice recommendations to limit red blood cell transfusion in patients with anemia during and after hospitalization,” the researchers wrote.
However, they also said additional studies are needed to guide anemia management, particularly since persistent anemia has impacts on quality of life that are “likely to be substantial” and linked to the severity of that anemia.
This study was supported by a grant from the National Heart, Lung, and Blood Institute. Dr. Roubinian and several coauthors reported grants from the National Institutes of Health.
Editorial: Aim to treat anemia, not tolerate it
Dr. Roubinian and his colleagues’ findings warrant some scrutiny, according to Aryeh Shander, MD, of Englewood Hospital and Medical Center in New Jersey, and Lawrence Tim Goodnough, MD, of Stanford University in California.
“Missing here is a wide spectrum of morbidity outcomes and issues related to diminished quality of life that do not reach the level of severity that would necessitate admission but nonetheless detract from patients’ health and well-being,” Drs. Shander and Goodnough wrote in a related editorial.
They also noted that transfusion rate is not a clinical outcome, adding that readmission and mortality are important outcomes, but they do not accurately or fully reflect patient well-being.
While blood management initiatives may be a safe practice, as the study suggests, proper management of anemia after discharge may actually improve outcomes, given the many consequences of anemia, Drs. Shander and Goodnough wrote.
The pair suggested that, instead of again testing whether restricting transfusions is acceptable because of lack of impact on outcomes, future studies could evaluate a “more sensible” hypothesis that proper anemia management, especially post-discharge, could improve outcomes.
“Let’s increase efforts to prevent and treat anemia properly, rather than requiring patients to tolerate it,” Drs. Shander and Goodnough wrote.
Dr. Shander reported consulting fees from Vifor and AMAG. Dr. Goodnough reported having no relevant financial disclosures.
An initiative that reduced red blood cell (RBC) transfusions and increased moderate anemia in hospital did not adversely impact patients long-term, according to an analysis.
Researchers found that an increase in moderate in-hospital anemia did not increase subsequent RBC use, readmission, or mortality over the next 6 months.
However, authors of a related editorial argued that additional factors must be assessed to truly determine the effects of moderate anemia on patient outcomes.
The study and the editorial were published in the Annals of Internal Medicine.
Study: Long-term outcomes
Nareg H. Roubinian, MD, of Kaiser Permanente Northern California in Oakland, and colleagues sought to evaluate the impact of blood management programs—starting in 2010—that included blood-sparing surgical and medical techniques, increased use of hemostatic and cell salvage agents, and treatment of suboptimal iron stores before surgery.
In previous retrospective cohort studies, the researchers had found that blood conservation strategies did not impact in-hospital or 30-day mortality rates, which was consistent with short-term safety data from clinical trials and other observational studies.
Their new report on longer-term outcomes was based on data from Kaiser Permanente Northern California for 445,371 adults who had 801,261 hospitalizations with discharges between 2010 and 2014.
In this cohort, moderate anemia (hemoglobin between 7 g/dL and 10 g/dL) at discharge occurred in 119,489 patients (27%) and 187,440 hospitalizations overall (23%).
Over the 2010-2014 period, RBC transfusions decreased by more than 25% in the inpatient and outpatient settings. In parallel, the prevalence of moderate anemia at hospital discharge increased from 20% to 25%.
However, the risks of subsequent RBC transfusions and rehospitalization after discharge with anemia decreased during the study period, and mortality rates stayed steady or decreased slightly.
Among patients with moderate anemia, the proportion with subsequent RBC transfusions within 6 months decreased from 18.9% in 2010 to 16.8% in 2014 (P<0.001), while the rate of rehospitalization within 6 months decreased from 36.5% to 32.8% over that same time period (P<0.001).
The adjusted 6-month mortality rate likewise decreased from 16.1% to 15.6% (P=0.004) over that time period among patients with moderate anemia.
“These data support the efficacy and safety of practice recommendations to limit red blood cell transfusion in patients with anemia during and after hospitalization,” the researchers wrote.
However, they also said additional studies are needed to guide anemia management, particularly since persistent anemia has impacts on quality of life that are “likely to be substantial” and linked to the severity of that anemia.
This study was supported by a grant from the National Heart, Lung, and Blood Institute. Dr. Roubinian and several coauthors reported grants from the National Institutes of Health.
Editorial: Aim to treat anemia, not tolerate it
Dr. Roubinian and his colleagues’ findings warrant some scrutiny, according to Aryeh Shander, MD, of Englewood Hospital and Medical Center in New Jersey, and Lawrence Tim Goodnough, MD, of Stanford University in California.
“Missing here is a wide spectrum of morbidity outcomes and issues related to diminished quality of life that do not reach the level of severity that would necessitate admission but nonetheless detract from patients’ health and well-being,” Drs. Shander and Goodnough wrote in a related editorial.
They also noted that transfusion rate is not a clinical outcome, adding that readmission and mortality are important outcomes, but they do not accurately or fully reflect patient well-being.
While blood management initiatives may be a safe practice, as the study suggests, proper management of anemia after discharge may actually improve outcomes, given the many consequences of anemia, Drs. Shander and Goodnough wrote.
The pair suggested that, instead of again testing whether restricting transfusions is acceptable because of lack of impact on outcomes, future studies could evaluate a “more sensible” hypothesis that proper anemia management, especially post-discharge, could improve outcomes.
“Let’s increase efforts to prevent and treat anemia properly, rather than requiring patients to tolerate it,” Drs. Shander and Goodnough wrote.
Dr. Shander reported consulting fees from Vifor and AMAG. Dr. Goodnough reported having no relevant financial disclosures.
An initiative that reduced red blood cell (RBC) transfusions and increased moderate anemia in hospital did not adversely impact patients long-term, according to an analysis.
Researchers found that an increase in moderate in-hospital anemia did not increase subsequent RBC use, readmission, or mortality over the next 6 months.
However, authors of a related editorial argued that additional factors must be assessed to truly determine the effects of moderate anemia on patient outcomes.
The study and the editorial were published in the Annals of Internal Medicine.
Study: Long-term outcomes
Nareg H. Roubinian, MD, of Kaiser Permanente Northern California in Oakland, and colleagues sought to evaluate the impact of blood management programs—starting in 2010—that included blood-sparing surgical and medical techniques, increased use of hemostatic and cell salvage agents, and treatment of suboptimal iron stores before surgery.
In previous retrospective cohort studies, the researchers had found that blood conservation strategies did not impact in-hospital or 30-day mortality rates, which was consistent with short-term safety data from clinical trials and other observational studies.
Their new report on longer-term outcomes was based on data from Kaiser Permanente Northern California for 445,371 adults who had 801,261 hospitalizations with discharges between 2010 and 2014.
In this cohort, moderate anemia (hemoglobin between 7 g/dL and 10 g/dL) at discharge occurred in 119,489 patients (27%) and 187,440 hospitalizations overall (23%).
Over the 2010-2014 period, RBC transfusions decreased by more than 25% in the inpatient and outpatient settings. In parallel, the prevalence of moderate anemia at hospital discharge increased from 20% to 25%.
However, the risks of subsequent RBC transfusions and rehospitalization after discharge with anemia decreased during the study period, and mortality rates stayed steady or decreased slightly.
Among patients with moderate anemia, the proportion with subsequent RBC transfusions within 6 months decreased from 18.9% in 2010 to 16.8% in 2014 (P<0.001), while the rate of rehospitalization within 6 months decreased from 36.5% to 32.8% over that same time period (P<0.001).
The adjusted 6-month mortality rate likewise decreased from 16.1% to 15.6% (P=0.004) over that time period among patients with moderate anemia.
“These data support the efficacy and safety of practice recommendations to limit red blood cell transfusion in patients with anemia during and after hospitalization,” the researchers wrote.
However, they also said additional studies are needed to guide anemia management, particularly since persistent anemia has impacts on quality of life that are “likely to be substantial” and linked to the severity of that anemia.
This study was supported by a grant from the National Heart, Lung, and Blood Institute. Dr. Roubinian and several coauthors reported grants from the National Institutes of Health.
Editorial: Aim to treat anemia, not tolerate it
Dr. Roubinian and his colleagues’ findings warrant some scrutiny, according to Aryeh Shander, MD, of Englewood Hospital and Medical Center in New Jersey, and Lawrence Tim Goodnough, MD, of Stanford University in California.
“Missing here is a wide spectrum of morbidity outcomes and issues related to diminished quality of life that do not reach the level of severity that would necessitate admission but nonetheless detract from patients’ health and well-being,” Drs. Shander and Goodnough wrote in a related editorial.
They also noted that transfusion rate is not a clinical outcome, adding that readmission and mortality are important outcomes, but they do not accurately or fully reflect patient well-being.
While blood management initiatives may be a safe practice, as the study suggests, proper management of anemia after discharge may actually improve outcomes, given the many consequences of anemia, Drs. Shander and Goodnough wrote.
The pair suggested that, instead of again testing whether restricting transfusions is acceptable because of lack of impact on outcomes, future studies could evaluate a “more sensible” hypothesis that proper anemia management, especially post-discharge, could improve outcomes.
“Let’s increase efforts to prevent and treat anemia properly, rather than requiring patients to tolerate it,” Drs. Shander and Goodnough wrote.
Dr. Shander reported consulting fees from Vifor and AMAG. Dr. Goodnough reported having no relevant financial disclosures.
FDA approves ravulizumab for PNH
The U.S. Food and Drug Administration (FDA) has approved ravulizumab-cwvz (Ultomiris) to treat adults with paroxysmal nocturnal hemoglobinuria (PNH).
Ravulizumab is a long-acting C5 complement inhibitor, administered every 8 weeks, that has been shown to prevent hemolysis.
The prescribing information for ravulizumab includes a boxed warning stating that meningococcal infections/sepsis have occurred in patients treated with the drug, and these adverse effects can become life-threatening or fatal if not recognized and treated early.
Ravulizumab is available only through a restricted program under a Risk Evaluation and Mitigation Strategy.
The FDA previously granted the application for ravulizumab priority review, and the product received orphan drug designation from the FDA.
The FDA granted the approval of ravulizumab to Alexion Pharmaceuticals.
The FDA’s approval of ravulizumab is based on results from two phase 3 studies, one in patients who had previously received treatment with a complement inhibitor and one in patients who were complement-inhibitor-naïve. Both studies were recently published in Blood.
Efficacy in inhibitor-experienced patients
In one study (NCT03056040), researchers compared ravulizumab administered every 8 weeks to eculizumab administered every 2 weeks in complement-inhibitor-experienced patients.
The trial included 195 PNH patients who were taking eculizumab for more than 6 months. They were randomized to switch to ravulizumab (n=97) or continue on eculizumab (n=98).
Ravulizumab proved noninferior to eculizumab for all endpoints studied (P<0.0006), including:
- Percentage change in lactate dehydrogenase (LDH): difference, 9.21% (95% CI: -0.42 to 18.84; P=0.058 for superiority)
- Breakthrough hemolysis: difference, 5.1 (95% CI: -8.89 to 18.99)
- Change in FACIT-Fatigue score: difference, 1.47 (95% CI: -0.21 to 3.15)
- Transfusion avoidance: difference, 5.5 (95% CI: -4.27 to 15.68)
- Stabilized hemoglobin: difference, 1.4 (95% CI: -10.41 to 13.31).
Efficacy in inhibitor-naïve patients
In another study (NCT02946463), researchers compared ravulizumab and eculizumab in 246 PNH patients who had not previously received a complement inhibitor.
Ravulizumab was noninferior to eculizumab for all endpoints (P<0.0001), including:
- Transfusion avoidance: 73.6% vs 66.1%; difference of 6.8% (95% CI: -4.66 to 18.14)
- LDH normalization: 53.6% vs 49.4%; odds ratio=1.19 (95% CI: 0.80 to 1.77)
- Percent reduction in LDH: -76.8% vs -76.0%; difference of -0.83% (95% CI: -5.21 to 3.56)
- Change in FACIT-Fatigue score: 7.07 vs 6.40; difference of 0.67 (95% CI: -1.21 to 2.55)
- Breakthrough hemolysis: 4.0% vs 10.7%; difference of -6.7% (95% CI: -14.21 to 0.18)
- Stabilized hemoglobin: 68.0% vs 64.5%; difference of 2.9 (95% CI: -8.80 to 14.64).
Safety in both trials
The safety data from both trials included 441 adults who received ravulizumab (n=222) or eculizumab (n=219) for a median of 6 months.
The most frequent adverse events in both arms (ravulizumab and eculizumab, respectively) were upper respiratory tract infection (39% and 39%) and headache (32% and 26%).
Serious adverse events occurred in 15 (6.8%) patients treated with ravulizumab. These events included hyperthermia and pyrexia.
There was one fatal case of sepsis in a patient treated with ravulizumab.
The U.S. Food and Drug Administration (FDA) has approved ravulizumab-cwvz (Ultomiris) to treat adults with paroxysmal nocturnal hemoglobinuria (PNH).
Ravulizumab is a long-acting C5 complement inhibitor, administered every 8 weeks, that has been shown to prevent hemolysis.
The prescribing information for ravulizumab includes a boxed warning stating that meningococcal infections/sepsis have occurred in patients treated with the drug, and these adverse effects can become life-threatening or fatal if not recognized and treated early.
Ravulizumab is available only through a restricted program under a Risk Evaluation and Mitigation Strategy.
The FDA previously granted the application for ravulizumab priority review, and the product received orphan drug designation from the FDA.
The FDA granted the approval of ravulizumab to Alexion Pharmaceuticals.
The FDA’s approval of ravulizumab is based on results from two phase 3 studies, one in patients who had previously received treatment with a complement inhibitor and one in patients who were complement-inhibitor-naïve. Both studies were recently published in Blood.
Efficacy in inhibitor-experienced patients
In one study (NCT03056040), researchers compared ravulizumab administered every 8 weeks to eculizumab administered every 2 weeks in complement-inhibitor-experienced patients.
The trial included 195 PNH patients who were taking eculizumab for more than 6 months. They were randomized to switch to ravulizumab (n=97) or continue on eculizumab (n=98).
Ravulizumab proved noninferior to eculizumab for all endpoints studied (P<0.0006), including:
- Percentage change in lactate dehydrogenase (LDH): difference, 9.21% (95% CI: -0.42 to 18.84; P=0.058 for superiority)
- Breakthrough hemolysis: difference, 5.1 (95% CI: -8.89 to 18.99)
- Change in FACIT-Fatigue score: difference, 1.47 (95% CI: -0.21 to 3.15)
- Transfusion avoidance: difference, 5.5 (95% CI: -4.27 to 15.68)
- Stabilized hemoglobin: difference, 1.4 (95% CI: -10.41 to 13.31).
Efficacy in inhibitor-naïve patients
In another study (NCT02946463), researchers compared ravulizumab and eculizumab in 246 PNH patients who had not previously received a complement inhibitor.
Ravulizumab was noninferior to eculizumab for all endpoints (P<0.0001), including:
- Transfusion avoidance: 73.6% vs 66.1%; difference of 6.8% (95% CI: -4.66 to 18.14)
- LDH normalization: 53.6% vs 49.4%; odds ratio=1.19 (95% CI: 0.80 to 1.77)
- Percent reduction in LDH: -76.8% vs -76.0%; difference of -0.83% (95% CI: -5.21 to 3.56)
- Change in FACIT-Fatigue score: 7.07 vs 6.40; difference of 0.67 (95% CI: -1.21 to 2.55)
- Breakthrough hemolysis: 4.0% vs 10.7%; difference of -6.7% (95% CI: -14.21 to 0.18)
- Stabilized hemoglobin: 68.0% vs 64.5%; difference of 2.9 (95% CI: -8.80 to 14.64).
Safety in both trials
The safety data from both trials included 441 adults who received ravulizumab (n=222) or eculizumab (n=219) for a median of 6 months.
The most frequent adverse events in both arms (ravulizumab and eculizumab, respectively) were upper respiratory tract infection (39% and 39%) and headache (32% and 26%).
Serious adverse events occurred in 15 (6.8%) patients treated with ravulizumab. These events included hyperthermia and pyrexia.
There was one fatal case of sepsis in a patient treated with ravulizumab.
The U.S. Food and Drug Administration (FDA) has approved ravulizumab-cwvz (Ultomiris) to treat adults with paroxysmal nocturnal hemoglobinuria (PNH).
Ravulizumab is a long-acting C5 complement inhibitor, administered every 8 weeks, that has been shown to prevent hemolysis.
The prescribing information for ravulizumab includes a boxed warning stating that meningococcal infections/sepsis have occurred in patients treated with the drug, and these adverse effects can become life-threatening or fatal if not recognized and treated early.
Ravulizumab is available only through a restricted program under a Risk Evaluation and Mitigation Strategy.
The FDA previously granted the application for ravulizumab priority review, and the product received orphan drug designation from the FDA.
The FDA granted the approval of ravulizumab to Alexion Pharmaceuticals.
The FDA’s approval of ravulizumab is based on results from two phase 3 studies, one in patients who had previously received treatment with a complement inhibitor and one in patients who were complement-inhibitor-naïve. Both studies were recently published in Blood.
Efficacy in inhibitor-experienced patients
In one study (NCT03056040), researchers compared ravulizumab administered every 8 weeks to eculizumab administered every 2 weeks in complement-inhibitor-experienced patients.
The trial included 195 PNH patients who were taking eculizumab for more than 6 months. They were randomized to switch to ravulizumab (n=97) or continue on eculizumab (n=98).
Ravulizumab proved noninferior to eculizumab for all endpoints studied (P<0.0006), including:
- Percentage change in lactate dehydrogenase (LDH): difference, 9.21% (95% CI: -0.42 to 18.84; P=0.058 for superiority)
- Breakthrough hemolysis: difference, 5.1 (95% CI: -8.89 to 18.99)
- Change in FACIT-Fatigue score: difference, 1.47 (95% CI: -0.21 to 3.15)
- Transfusion avoidance: difference, 5.5 (95% CI: -4.27 to 15.68)
- Stabilized hemoglobin: difference, 1.4 (95% CI: -10.41 to 13.31).
Efficacy in inhibitor-naïve patients
In another study (NCT02946463), researchers compared ravulizumab and eculizumab in 246 PNH patients who had not previously received a complement inhibitor.
Ravulizumab was noninferior to eculizumab for all endpoints (P<0.0001), including:
- Transfusion avoidance: 73.6% vs 66.1%; difference of 6.8% (95% CI: -4.66 to 18.14)
- LDH normalization: 53.6% vs 49.4%; odds ratio=1.19 (95% CI: 0.80 to 1.77)
- Percent reduction in LDH: -76.8% vs -76.0%; difference of -0.83% (95% CI: -5.21 to 3.56)
- Change in FACIT-Fatigue score: 7.07 vs 6.40; difference of 0.67 (95% CI: -1.21 to 2.55)
- Breakthrough hemolysis: 4.0% vs 10.7%; difference of -6.7% (95% CI: -14.21 to 0.18)
- Stabilized hemoglobin: 68.0% vs 64.5%; difference of 2.9 (95% CI: -8.80 to 14.64).
Safety in both trials
The safety data from both trials included 441 adults who received ravulizumab (n=222) or eculizumab (n=219) for a median of 6 months.
The most frequent adverse events in both arms (ravulizumab and eculizumab, respectively) were upper respiratory tract infection (39% and 39%) and headache (32% and 26%).
Serious adverse events occurred in 15 (6.8%) patients treated with ravulizumab. These events included hyperthermia and pyrexia.
There was one fatal case of sepsis in a patient treated with ravulizumab.
FDA approves ravulizumab for treatment of paroxysmal nocturnal hemoglobinuria
The Food and Drug Administration has approved ravulizumab (Ultomiris) injection for the treatment of adult patients with paroxysmal nocturnal hemoglobinuria (PNH).
“The approval of Ultomiris will change the way that patients with PNH are treated. Prior to this approval, the only approved therapy for PNH required treatment every 2 weeks, which can be burdensome for patients and their families. Ultomiris uses a novel formulation so patients only need treatment every 8 weeks, without compromising efficacy,” Richard Pazdur, MD, director of the FDA’s Oncology Center of Excellence, said in a press release from the agency.
Patients with PNH, a rare disorder, lack a protein which protects red blood cells from being destroyed in the immune system. Episodes can be triggered by stresses on the body such as infection or physical exertion, and symptoms include severe anemia, profound fatigue, shortness of breath, intermittent episodes of dark-colored urine, kidney disease, or recurrent pain.
FDA approval for ravulizumab is based on results from a pair of clinical trials. In the first, 246 treatment-naive PNH patients received either ravulizumab or eculizumab, the current standard of care; ravulizumab was noninferior, with no patients undergoing a transfusion and all patients having similar incidence of hemolysis. In the second trial, 195 patients who had clinically stable PNH after receiving eculizumab for 6 months were randomized to receive ravulizumab or continue eculizumab; again, ravulizumab was noninferior.
The most common adverse events associated with ravulizumab were headache and respiratory tract infection. Caution is recommended when prescribing ravulizumab to patients with any type of infection.
Find the full press release on the FDA website.
The Food and Drug Administration has approved ravulizumab (Ultomiris) injection for the treatment of adult patients with paroxysmal nocturnal hemoglobinuria (PNH).
“The approval of Ultomiris will change the way that patients with PNH are treated. Prior to this approval, the only approved therapy for PNH required treatment every 2 weeks, which can be burdensome for patients and their families. Ultomiris uses a novel formulation so patients only need treatment every 8 weeks, without compromising efficacy,” Richard Pazdur, MD, director of the FDA’s Oncology Center of Excellence, said in a press release from the agency.
Patients with PNH, a rare disorder, lack a protein which protects red blood cells from being destroyed in the immune system. Episodes can be triggered by stresses on the body such as infection or physical exertion, and symptoms include severe anemia, profound fatigue, shortness of breath, intermittent episodes of dark-colored urine, kidney disease, or recurrent pain.
FDA approval for ravulizumab is based on results from a pair of clinical trials. In the first, 246 treatment-naive PNH patients received either ravulizumab or eculizumab, the current standard of care; ravulizumab was noninferior, with no patients undergoing a transfusion and all patients having similar incidence of hemolysis. In the second trial, 195 patients who had clinically stable PNH after receiving eculizumab for 6 months were randomized to receive ravulizumab or continue eculizumab; again, ravulizumab was noninferior.
The most common adverse events associated with ravulizumab were headache and respiratory tract infection. Caution is recommended when prescribing ravulizumab to patients with any type of infection.
Find the full press release on the FDA website.
The Food and Drug Administration has approved ravulizumab (Ultomiris) injection for the treatment of adult patients with paroxysmal nocturnal hemoglobinuria (PNH).
“The approval of Ultomiris will change the way that patients with PNH are treated. Prior to this approval, the only approved therapy for PNH required treatment every 2 weeks, which can be burdensome for patients and their families. Ultomiris uses a novel formulation so patients only need treatment every 8 weeks, without compromising efficacy,” Richard Pazdur, MD, director of the FDA’s Oncology Center of Excellence, said in a press release from the agency.
Patients with PNH, a rare disorder, lack a protein which protects red blood cells from being destroyed in the immune system. Episodes can be triggered by stresses on the body such as infection or physical exertion, and symptoms include severe anemia, profound fatigue, shortness of breath, intermittent episodes of dark-colored urine, kidney disease, or recurrent pain.
FDA approval for ravulizumab is based on results from a pair of clinical trials. In the first, 246 treatment-naive PNH patients received either ravulizumab or eculizumab, the current standard of care; ravulizumab was noninferior, with no patients undergoing a transfusion and all patients having similar incidence of hemolysis. In the second trial, 195 patients who had clinically stable PNH after receiving eculizumab for 6 months were randomized to receive ravulizumab or continue eculizumab; again, ravulizumab was noninferior.
The most common adverse events associated with ravulizumab were headache and respiratory tract infection. Caution is recommended when prescribing ravulizumab to patients with any type of infection.
Find the full press release on the FDA website.