User login
The Evolving Treatment Paradigm for Diffuse Large B-Cell Lymphoma
Non-Hodgkin lymphomas (NHLs) are cancers that arise in a type of white blood cell called the lymphocyte. NHLs are divided into B- and T-cell subtypes, as well as aggressive and indolent forms. Management varies widely depending on the disease type. We will focus on the most common type of NHL, diffuse large B-cell lymphoma (DLBCL), for which there have been significant treatment advances in recent years.
DLBCL is curable in about two-thirds of patients using chemoimmunotherapy. The longstanding frontline treatment for this disease has been R-CHOP (rituximab, cyclophosphamide, doxorubicin, vincristine, prednisone). In 2023, an antibody-drug conjugate against the B-cell surface protein CD79b, polatuzumab vedotin, was approved by the US Food and Drug Administration (FDA) in combination with R-CHP (rituximab, cyclophosphamide, doxorubicin, prednisone) for newly diagnosed DLBCL based on an improvement in progression-free survival at 2 years in patients with high-risk disease features enrolled in the POLARIX study.
For patients who do not respond to the initial treatment or in whom the disease recurs, the historical standard of care treatment strategy was high-dose chemotherapy followed by autologous stem cell transplant (ASCT). Unfortunately, this approach is not feasible or not successful in a significant percentage of patients with relapsed or refractory DLBCL.
A newer strategy for DLBCL is chimeric antigen receptor (CAR) T-cell therapy. In this treatment, T cells are collected from a patient and genetically modified to target a protein on the lymphoma cells called CD19. This type of treatment was initially approved in the third-line setting for DLBCL based on the ZUMA-1 (axi-cel), JULIET (tisa-cel), and TRANSCEND (liso-cel) clinical trials. More recently, in 2022, 2 of these agents received approval in the second-line setting in patients who relapse or are refractory to initial treatment within 1 year; axi-cel was approved based on the ZUMA-7 trial and liso-cel was approved based on the TRANSFORM trial.
Unfortunately, not all patients are eligible for ASCT and CAR T-cell therapy due to factors including age, comorbidities, and disease characteristics. Some patients prefer alternative therapies based on the potential side effects of CAR T-cell therapy and ASCT. Toxicities associated with CAR T-cell therapy include an inflammatory response called cytokine release syndrome and neurologic events.
For patients who are not eligible for or who relapse after ASCT or CAR T-cell therapy, several alternative treatment options are FDA approved. Novel strategies include polatuzumab vedotin with bendamustine and rituximab and tafasitamab plus lenalidomide. Tafasitamab is a monoclonal antibody against CD19 and lenalidomide is an oral anticancer agent originally approved for use in multiple myeloma. Lenalidomide is also effective and commonly used in other NHL subtypes.
In 2023, a new category of treatment called bispecific antibodies was approved in patients with DLBCL in whom the disease recurs after 2 lines of therapy. These drugs (epcoritamab and glofitamab) are a form of immunotherapy that connects B cells with T cells to enable a person’s own immune system to better fight the lymphoma. While these drugs can have similar toxicities as CAR T-cell therapy, the severity and incidence are much lower. In contrast to CAR T-cell therapy, which requires only 1 infusion, these drugs are given regularly in either subcutaneous or intravenous form for several months.
Two other FDA-approved treatment options for relapsed and refractory DLBCL are loncastuximab tesirine, an antibody-drug conjugate targeting CD19 with approval based on the results of the LOTIS-2 trial, and the oral selective inhibitor of nuclear export called selinexor, based on the results from the SADAL trial. Selinexor is a fully synthetic small-molecule compound, developed by means of a structure-based drug design process known as induced-fit docking. It binds to a cysteine residue in the nuclear export signal groove of exportin 1. Selinexor is approved for use in adults with relapsed or refractory DLBCL who have received at least 2 types of systemic therapy. Trials investigating these agents in combination with other novel treatments are ongoing.
The treatment landscape for DLBCL has changed markedly over the past several years. Therapies can be tailored for individual patients based on their disease status and characteristics, comorbidities, and treatment preferences. Research with novel strategies continues with the goal of a cure for all patients diagnosed with DLBCL.
Non-Hodgkin lymphomas (NHLs) are cancers that arise in a type of white blood cell called the lymphocyte. NHLs are divided into B- and T-cell subtypes, as well as aggressive and indolent forms. Management varies widely depending on the disease type. We will focus on the most common type of NHL, diffuse large B-cell lymphoma (DLBCL), for which there have been significant treatment advances in recent years.
DLBCL is curable in about two-thirds of patients using chemoimmunotherapy. The longstanding frontline treatment for this disease has been R-CHOP (rituximab, cyclophosphamide, doxorubicin, vincristine, prednisone). In 2023, an antibody-drug conjugate against the B-cell surface protein CD79b, polatuzumab vedotin, was approved by the US Food and Drug Administration (FDA) in combination with R-CHP (rituximab, cyclophosphamide, doxorubicin, prednisone) for newly diagnosed DLBCL based on an improvement in progression-free survival at 2 years in patients with high-risk disease features enrolled in the POLARIX study.
For patients who do not respond to the initial treatment or in whom the disease recurs, the historical standard of care treatment strategy was high-dose chemotherapy followed by autologous stem cell transplant (ASCT). Unfortunately, this approach is not feasible or not successful in a significant percentage of patients with relapsed or refractory DLBCL.
A newer strategy for DLBCL is chimeric antigen receptor (CAR) T-cell therapy. In this treatment, T cells are collected from a patient and genetically modified to target a protein on the lymphoma cells called CD19. This type of treatment was initially approved in the third-line setting for DLBCL based on the ZUMA-1 (axi-cel), JULIET (tisa-cel), and TRANSCEND (liso-cel) clinical trials. More recently, in 2022, 2 of these agents received approval in the second-line setting in patients who relapse or are refractory to initial treatment within 1 year; axi-cel was approved based on the ZUMA-7 trial and liso-cel was approved based on the TRANSFORM trial.
Unfortunately, not all patients are eligible for ASCT and CAR T-cell therapy due to factors including age, comorbidities, and disease characteristics. Some patients prefer alternative therapies based on the potential side effects of CAR T-cell therapy and ASCT. Toxicities associated with CAR T-cell therapy include an inflammatory response called cytokine release syndrome and neurologic events.
For patients who are not eligible for or who relapse after ASCT or CAR T-cell therapy, several alternative treatment options are FDA approved. Novel strategies include polatuzumab vedotin with bendamustine and rituximab and tafasitamab plus lenalidomide. Tafasitamab is a monoclonal antibody against CD19 and lenalidomide is an oral anticancer agent originally approved for use in multiple myeloma. Lenalidomide is also effective and commonly used in other NHL subtypes.
In 2023, a new category of treatment called bispecific antibodies was approved in patients with DLBCL in whom the disease recurs after 2 lines of therapy. These drugs (epcoritamab and glofitamab) are a form of immunotherapy that connects B cells with T cells to enable a person’s own immune system to better fight the lymphoma. While these drugs can have similar toxicities as CAR T-cell therapy, the severity and incidence are much lower. In contrast to CAR T-cell therapy, which requires only 1 infusion, these drugs are given regularly in either subcutaneous or intravenous form for several months.
Two other FDA-approved treatment options for relapsed and refractory DLBCL are loncastuximab tesirine, an antibody-drug conjugate targeting CD19 with approval based on the results of the LOTIS-2 trial, and the oral selective inhibitor of nuclear export called selinexor, based on the results from the SADAL trial. Selinexor is a fully synthetic small-molecule compound, developed by means of a structure-based drug design process known as induced-fit docking. It binds to a cysteine residue in the nuclear export signal groove of exportin 1. Selinexor is approved for use in adults with relapsed or refractory DLBCL who have received at least 2 types of systemic therapy. Trials investigating these agents in combination with other novel treatments are ongoing.
The treatment landscape for DLBCL has changed markedly over the past several years. Therapies can be tailored for individual patients based on their disease status and characteristics, comorbidities, and treatment preferences. Research with novel strategies continues with the goal of a cure for all patients diagnosed with DLBCL.
Non-Hodgkin lymphomas (NHLs) are cancers that arise in a type of white blood cell called the lymphocyte. NHLs are divided into B- and T-cell subtypes, as well as aggressive and indolent forms. Management varies widely depending on the disease type. We will focus on the most common type of NHL, diffuse large B-cell lymphoma (DLBCL), for which there have been significant treatment advances in recent years.
DLBCL is curable in about two-thirds of patients using chemoimmunotherapy. The longstanding frontline treatment for this disease has been R-CHOP (rituximab, cyclophosphamide, doxorubicin, vincristine, prednisone). In 2023, an antibody-drug conjugate against the B-cell surface protein CD79b, polatuzumab vedotin, was approved by the US Food and Drug Administration (FDA) in combination with R-CHP (rituximab, cyclophosphamide, doxorubicin, prednisone) for newly diagnosed DLBCL based on an improvement in progression-free survival at 2 years in patients with high-risk disease features enrolled in the POLARIX study.
For patients who do not respond to the initial treatment or in whom the disease recurs, the historical standard of care treatment strategy was high-dose chemotherapy followed by autologous stem cell transplant (ASCT). Unfortunately, this approach is not feasible or not successful in a significant percentage of patients with relapsed or refractory DLBCL.
A newer strategy for DLBCL is chimeric antigen receptor (CAR) T-cell therapy. In this treatment, T cells are collected from a patient and genetically modified to target a protein on the lymphoma cells called CD19. This type of treatment was initially approved in the third-line setting for DLBCL based on the ZUMA-1 (axi-cel), JULIET (tisa-cel), and TRANSCEND (liso-cel) clinical trials. More recently, in 2022, 2 of these agents received approval in the second-line setting in patients who relapse or are refractory to initial treatment within 1 year; axi-cel was approved based on the ZUMA-7 trial and liso-cel was approved based on the TRANSFORM trial.
Unfortunately, not all patients are eligible for ASCT and CAR T-cell therapy due to factors including age, comorbidities, and disease characteristics. Some patients prefer alternative therapies based on the potential side effects of CAR T-cell therapy and ASCT. Toxicities associated with CAR T-cell therapy include an inflammatory response called cytokine release syndrome and neurologic events.
For patients who are not eligible for or who relapse after ASCT or CAR T-cell therapy, several alternative treatment options are FDA approved. Novel strategies include polatuzumab vedotin with bendamustine and rituximab and tafasitamab plus lenalidomide. Tafasitamab is a monoclonal antibody against CD19 and lenalidomide is an oral anticancer agent originally approved for use in multiple myeloma. Lenalidomide is also effective and commonly used in other NHL subtypes.
In 2023, a new category of treatment called bispecific antibodies was approved in patients with DLBCL in whom the disease recurs after 2 lines of therapy. These drugs (epcoritamab and glofitamab) are a form of immunotherapy that connects B cells with T cells to enable a person’s own immune system to better fight the lymphoma. While these drugs can have similar toxicities as CAR T-cell therapy, the severity and incidence are much lower. In contrast to CAR T-cell therapy, which requires only 1 infusion, these drugs are given regularly in either subcutaneous or intravenous form for several months.
Two other FDA-approved treatment options for relapsed and refractory DLBCL are loncastuximab tesirine, an antibody-drug conjugate targeting CD19 with approval based on the results of the LOTIS-2 trial, and the oral selective inhibitor of nuclear export called selinexor, based on the results from the SADAL trial. Selinexor is a fully synthetic small-molecule compound, developed by means of a structure-based drug design process known as induced-fit docking. It binds to a cysteine residue in the nuclear export signal groove of exportin 1. Selinexor is approved for use in adults with relapsed or refractory DLBCL who have received at least 2 types of systemic therapy. Trials investigating these agents in combination with other novel treatments are ongoing.
The treatment landscape for DLBCL has changed markedly over the past several years. Therapies can be tailored for individual patients based on their disease status and characteristics, comorbidities, and treatment preferences. Research with novel strategies continues with the goal of a cure for all patients diagnosed with DLBCL.
Commentary: Bendamustine, PET/CT Biomarkers, and BTKi in B-Cell Lymphoma, December 2023
While chimeric antigen receptor (CAR) T-cell therapy has transformed the management of large B-cell lymphoma (LBCL), the majority of patients will ultimately relapse. Efforts to identify predictors of response remain an active area of investigation. One key variable that has been postulated to influence CAR T-cell outcomes is pretreatment bendamustine exposure. Specifically, there has been concern that the lymphodepleting effects of bendamustine could affect T-cell fitness, thus impairing CAR T-cell response. While consensus guidelines have recommended avoiding bendamustine prior to lymphocyte collection, clear data have been lacking. A recent retrospective, multicenter study, which included patients from seven European sites, reported outcomes based on prior bendamustine exposure (Iacoboni et al). In this study, 439 patients with relapsed or refractory LBCL, who received anti-CD19 commercial CAR T-cell therapy after two or more prior treatment lines of therapy, were included. Of these patients, 80 had received prior bendamustine. The authors found that patients recently exposed to bendamustine (< 9 months), vs bendamustine-naive patients, had a significantly lower overall response rate (40% vs 66%; P = .01), overall survival (OS; adjusted hazard ratio [aHR] 2.11; P < .01), and progression-free survival (PFS; aHR 1.82; P < .01) after CAR T-cell infusion. These differences remained significant after inverse probability treatment weighting and propensity score matching. Of note, the authors did not find that the cumulative dose of bendamustine affected outcomes. The authors also identified that, while the risk for cytokine release syndrome and immune effector cell–associated neurotoxicity syndrome was similar between the groups, hematologic toxicity and severe infections were increased in the bendamustine-exposed patients. These data support the recommendation to avoid bendamustine treatment prior to CAR T-cell apheresis. While treatment regimens such as polatuzumab plus bendamustine and rituximab are available in the relapsed setting for LBCL,1 this regimen should be reserved for post CAR T-cell relapse or for patients not planning to proceed with cellular therapy. The impact of bendamustine exposure on other immune-mediated therapies, such as bispecific antibodies, remains unknown.
Quantitative PET/CT biomarkers have also emerged as predictors of response in diffuse large B-cell lymphoma (DLBCL). A key variable of interest includes total metabolic tumor volume (MTV), which refers to the total volume of tumor with metabolic uptake. While prior studies have demonstrated a correlation of MTV on outcomes following treatment with chemotherapy and CAR T-cell therapy,2,3 the effect of PET/CT biomarkers on outcomes with other novel agents remains poorly described. A recent study by Alderuccio and colleagues explored the predictive power of PET/CT biomarkers on outcomes in a clinical trial cohort of patients treated with the antibody drug conjugate loncastuximab tesirine. This post hoc analysis reviewed the screening PET/CT scans of 138 patients with relapsed or refractory DLBCL treated with two or more prior systemic therapy lines who received loncastuximab tesirine in LOTIS-2<.4 The authors found that an MTV ≥ 96 mL was significantly associated with failure to achieve a complete metabolic response (adjusted odds ratio 5.42; P = .002). Patients with an MTV ≥ 96 mL vs < 96 mL also had a shorter PFS (aHR 2.68; P = .002) and OS (aHR 3.09; P < .0001). In line with prior studies, this analysis demonstrates that baseline MTV has the potential to provide robust risk-stratification and confirms the value of PET/CT biomarkers in DLBCL across treatment types.
This month, the results of the phase 2 TARMAC study, which evaluated treatment with ibrutinib in combination with tisagenlecleucel, were also published. This study included 20 patients with relapsed/refractory mantle cell lymphoma (MCL) who had received one or more prior lines of therapy, including 50% with prior Bruton tyrosine kinase inhibitor (BTKi) exposure. Ibrutinib was initiated prior to leukapheresis and continued through CAR T-cell manufacturing and for at least 6 months post tisagenlecleucel infusion. At 4 months post infusion, the overall and complete response rates were 80% each. Patients without and with prior BTKi exposure had complete response rates of 90% and 70%, respectively. At a median follow-up of 13 months, the estimated 12-month PFS was 75% and OS was 100%. Grades 1-2 and grade 3 cytokine-release syndrome rates were 55% and 20%, respectively, and grade 1-2 immune effector cell–associated neurotoxicity syndrome was seen in 10% of patients. The authors also demonstrated that markers of T-cell exhaustion were decreased in patients with longer ibrutinib exposure prior to leukapheresis. Also of note, the three patients with recent bendamustine therapy did not receive a durable response. Although this is a small study without a control arm, this study provides rationale for the potential advantage of combining BTKi with CAR T-cell therapy, even among patients with prior BTKi exposure.
Additional References
1. Sehn LH, Hertzberg M, Opat S, et al. Polatuzumab vedotin plus bendamustine and rituximab in relapsed/refractory DLBCL: survival update and new extension cohort data. Blood Adv. 2022;6(2):533-543. doi: 10.1182/bloodadvances.2021005794
2. Vercellino L, Cottereau AS, Casasnovas O, et al. High total metabolic tumor volume at baseline predicts survival independent of response to therapy. Blood. 2020;135(16):1396-1405. doi: 10.1182/blood.2019003526
3. Dean EA, Mhaskar RS, Lu H, et al. High metabolic tumor volume is associated with decreased efficacy of axicabtagene ciloleucel in large B-cell lymphoma. Blood Adv. 2020;4(14):3268-3276. doi: 10.1182/bloodadvances.2020001900
4. Caimi PF, Ai W, Alderuccio JP, et al. Loncastuximab tesirine in relapsed or refractory diffuse large B-cell lymphoma (LOTIS-2): a multicentre, open-label, single-arm, phase 2 trial. Lancet Oncol. 2021;22(6):790-800. doi:
While chimeric antigen receptor (CAR) T-cell therapy has transformed the management of large B-cell lymphoma (LBCL), the majority of patients will ultimately relapse. Efforts to identify predictors of response remain an active area of investigation. One key variable that has been postulated to influence CAR T-cell outcomes is pretreatment bendamustine exposure. Specifically, there has been concern that the lymphodepleting effects of bendamustine could affect T-cell fitness, thus impairing CAR T-cell response. While consensus guidelines have recommended avoiding bendamustine prior to lymphocyte collection, clear data have been lacking. A recent retrospective, multicenter study, which included patients from seven European sites, reported outcomes based on prior bendamustine exposure (Iacoboni et al). In this study, 439 patients with relapsed or refractory LBCL, who received anti-CD19 commercial CAR T-cell therapy after two or more prior treatment lines of therapy, were included. Of these patients, 80 had received prior bendamustine. The authors found that patients recently exposed to bendamustine (< 9 months), vs bendamustine-naive patients, had a significantly lower overall response rate (40% vs 66%; P = .01), overall survival (OS; adjusted hazard ratio [aHR] 2.11; P < .01), and progression-free survival (PFS; aHR 1.82; P < .01) after CAR T-cell infusion. These differences remained significant after inverse probability treatment weighting and propensity score matching. Of note, the authors did not find that the cumulative dose of bendamustine affected outcomes. The authors also identified that, while the risk for cytokine release syndrome and immune effector cell–associated neurotoxicity syndrome was similar between the groups, hematologic toxicity and severe infections were increased in the bendamustine-exposed patients. These data support the recommendation to avoid bendamustine treatment prior to CAR T-cell apheresis. While treatment regimens such as polatuzumab plus bendamustine and rituximab are available in the relapsed setting for LBCL,1 this regimen should be reserved for post CAR T-cell relapse or for patients not planning to proceed with cellular therapy. The impact of bendamustine exposure on other immune-mediated therapies, such as bispecific antibodies, remains unknown.
Quantitative PET/CT biomarkers have also emerged as predictors of response in diffuse large B-cell lymphoma (DLBCL). A key variable of interest includes total metabolic tumor volume (MTV), which refers to the total volume of tumor with metabolic uptake. While prior studies have demonstrated a correlation of MTV on outcomes following treatment with chemotherapy and CAR T-cell therapy,2,3 the effect of PET/CT biomarkers on outcomes with other novel agents remains poorly described. A recent study by Alderuccio and colleagues explored the predictive power of PET/CT biomarkers on outcomes in a clinical trial cohort of patients treated with the antibody drug conjugate loncastuximab tesirine. This post hoc analysis reviewed the screening PET/CT scans of 138 patients with relapsed or refractory DLBCL treated with two or more prior systemic therapy lines who received loncastuximab tesirine in LOTIS-2<.4 The authors found that an MTV ≥ 96 mL was significantly associated with failure to achieve a complete metabolic response (adjusted odds ratio 5.42; P = .002). Patients with an MTV ≥ 96 mL vs < 96 mL also had a shorter PFS (aHR 2.68; P = .002) and OS (aHR 3.09; P < .0001). In line with prior studies, this analysis demonstrates that baseline MTV has the potential to provide robust risk-stratification and confirms the value of PET/CT biomarkers in DLBCL across treatment types.
This month, the results of the phase 2 TARMAC study, which evaluated treatment with ibrutinib in combination with tisagenlecleucel, were also published. This study included 20 patients with relapsed/refractory mantle cell lymphoma (MCL) who had received one or more prior lines of therapy, including 50% with prior Bruton tyrosine kinase inhibitor (BTKi) exposure. Ibrutinib was initiated prior to leukapheresis and continued through CAR T-cell manufacturing and for at least 6 months post tisagenlecleucel infusion. At 4 months post infusion, the overall and complete response rates were 80% each. Patients without and with prior BTKi exposure had complete response rates of 90% and 70%, respectively. At a median follow-up of 13 months, the estimated 12-month PFS was 75% and OS was 100%. Grades 1-2 and grade 3 cytokine-release syndrome rates were 55% and 20%, respectively, and grade 1-2 immune effector cell–associated neurotoxicity syndrome was seen in 10% of patients. The authors also demonstrated that markers of T-cell exhaustion were decreased in patients with longer ibrutinib exposure prior to leukapheresis. Also of note, the three patients with recent bendamustine therapy did not receive a durable response. Although this is a small study without a control arm, this study provides rationale for the potential advantage of combining BTKi with CAR T-cell therapy, even among patients with prior BTKi exposure.
Additional References
1. Sehn LH, Hertzberg M, Opat S, et al. Polatuzumab vedotin plus bendamustine and rituximab in relapsed/refractory DLBCL: survival update and new extension cohort data. Blood Adv. 2022;6(2):533-543. doi: 10.1182/bloodadvances.2021005794
2. Vercellino L, Cottereau AS, Casasnovas O, et al. High total metabolic tumor volume at baseline predicts survival independent of response to therapy. Blood. 2020;135(16):1396-1405. doi: 10.1182/blood.2019003526
3. Dean EA, Mhaskar RS, Lu H, et al. High metabolic tumor volume is associated with decreased efficacy of axicabtagene ciloleucel in large B-cell lymphoma. Blood Adv. 2020;4(14):3268-3276. doi: 10.1182/bloodadvances.2020001900
4. Caimi PF, Ai W, Alderuccio JP, et al. Loncastuximab tesirine in relapsed or refractory diffuse large B-cell lymphoma (LOTIS-2): a multicentre, open-label, single-arm, phase 2 trial. Lancet Oncol. 2021;22(6):790-800. doi:
While chimeric antigen receptor (CAR) T-cell therapy has transformed the management of large B-cell lymphoma (LBCL), the majority of patients will ultimately relapse. Efforts to identify predictors of response remain an active area of investigation. One key variable that has been postulated to influence CAR T-cell outcomes is pretreatment bendamustine exposure. Specifically, there has been concern that the lymphodepleting effects of bendamustine could affect T-cell fitness, thus impairing CAR T-cell response. While consensus guidelines have recommended avoiding bendamustine prior to lymphocyte collection, clear data have been lacking. A recent retrospective, multicenter study, which included patients from seven European sites, reported outcomes based on prior bendamustine exposure (Iacoboni et al). In this study, 439 patients with relapsed or refractory LBCL, who received anti-CD19 commercial CAR T-cell therapy after two or more prior treatment lines of therapy, were included. Of these patients, 80 had received prior bendamustine. The authors found that patients recently exposed to bendamustine (< 9 months), vs bendamustine-naive patients, had a significantly lower overall response rate (40% vs 66%; P = .01), overall survival (OS; adjusted hazard ratio [aHR] 2.11; P < .01), and progression-free survival (PFS; aHR 1.82; P < .01) after CAR T-cell infusion. These differences remained significant after inverse probability treatment weighting and propensity score matching. Of note, the authors did not find that the cumulative dose of bendamustine affected outcomes. The authors also identified that, while the risk for cytokine release syndrome and immune effector cell–associated neurotoxicity syndrome was similar between the groups, hematologic toxicity and severe infections were increased in the bendamustine-exposed patients. These data support the recommendation to avoid bendamustine treatment prior to CAR T-cell apheresis. While treatment regimens such as polatuzumab plus bendamustine and rituximab are available in the relapsed setting for LBCL,1 this regimen should be reserved for post CAR T-cell relapse or for patients not planning to proceed with cellular therapy. The impact of bendamustine exposure on other immune-mediated therapies, such as bispecific antibodies, remains unknown.
Quantitative PET/CT biomarkers have also emerged as predictors of response in diffuse large B-cell lymphoma (DLBCL). A key variable of interest includes total metabolic tumor volume (MTV), which refers to the total volume of tumor with metabolic uptake. While prior studies have demonstrated a correlation of MTV on outcomes following treatment with chemotherapy and CAR T-cell therapy,2,3 the effect of PET/CT biomarkers on outcomes with other novel agents remains poorly described. A recent study by Alderuccio and colleagues explored the predictive power of PET/CT biomarkers on outcomes in a clinical trial cohort of patients treated with the antibody drug conjugate loncastuximab tesirine. This post hoc analysis reviewed the screening PET/CT scans of 138 patients with relapsed or refractory DLBCL treated with two or more prior systemic therapy lines who received loncastuximab tesirine in LOTIS-2<.4 The authors found that an MTV ≥ 96 mL was significantly associated with failure to achieve a complete metabolic response (adjusted odds ratio 5.42; P = .002). Patients with an MTV ≥ 96 mL vs < 96 mL also had a shorter PFS (aHR 2.68; P = .002) and OS (aHR 3.09; P < .0001). In line with prior studies, this analysis demonstrates that baseline MTV has the potential to provide robust risk-stratification and confirms the value of PET/CT biomarkers in DLBCL across treatment types.
This month, the results of the phase 2 TARMAC study, which evaluated treatment with ibrutinib in combination with tisagenlecleucel, were also published. This study included 20 patients with relapsed/refractory mantle cell lymphoma (MCL) who had received one or more prior lines of therapy, including 50% with prior Bruton tyrosine kinase inhibitor (BTKi) exposure. Ibrutinib was initiated prior to leukapheresis and continued through CAR T-cell manufacturing and for at least 6 months post tisagenlecleucel infusion. At 4 months post infusion, the overall and complete response rates were 80% each. Patients without and with prior BTKi exposure had complete response rates of 90% and 70%, respectively. At a median follow-up of 13 months, the estimated 12-month PFS was 75% and OS was 100%. Grades 1-2 and grade 3 cytokine-release syndrome rates were 55% and 20%, respectively, and grade 1-2 immune effector cell–associated neurotoxicity syndrome was seen in 10% of patients. The authors also demonstrated that markers of T-cell exhaustion were decreased in patients with longer ibrutinib exposure prior to leukapheresis. Also of note, the three patients with recent bendamustine therapy did not receive a durable response. Although this is a small study without a control arm, this study provides rationale for the potential advantage of combining BTKi with CAR T-cell therapy, even among patients with prior BTKi exposure.
Additional References
1. Sehn LH, Hertzberg M, Opat S, et al. Polatuzumab vedotin plus bendamustine and rituximab in relapsed/refractory DLBCL: survival update and new extension cohort data. Blood Adv. 2022;6(2):533-543. doi: 10.1182/bloodadvances.2021005794
2. Vercellino L, Cottereau AS, Casasnovas O, et al. High total metabolic tumor volume at baseline predicts survival independent of response to therapy. Blood. 2020;135(16):1396-1405. doi: 10.1182/blood.2019003526
3. Dean EA, Mhaskar RS, Lu H, et al. High metabolic tumor volume is associated with decreased efficacy of axicabtagene ciloleucel in large B-cell lymphoma. Blood Adv. 2020;4(14):3268-3276. doi: 10.1182/bloodadvances.2020001900
4. Caimi PF, Ai W, Alderuccio JP, et al. Loncastuximab tesirine in relapsed or refractory diffuse large B-cell lymphoma (LOTIS-2): a multicentre, open-label, single-arm, phase 2 trial. Lancet Oncol. 2021;22(6):790-800. doi:
CAR T-Cell Therapy: Cure for Systemic Autoimmune Diseases?
A single infusion of autologous CD19-directed CAR T-cell therapy led to persistent, drug-free remission in 15 patients with life-threatening systemic lupus erythematosus, idiopathic inflammatory myositis, or systemic sclerosis, according to research presented at the American Society of Hematology annual meeting.
The responses persisted at 15 months median follow-up, with all patients achieving complete remission, reported Fabian Mueller, MD, of the Bavarian Cancer Research Center and Friedrich-Alexander University of Erlangen-Nuremberg, Bavaria, Germany.
The CAR T-cell treatment appears to provide an “entire reset of B cells,” possibly even a cure, for these 15 patients who had run out of treatment options and had short life expectancies, Dr. Mueller said. “It’s impressive that we have treated these patients.”
Some of the cases have been described previously — including in Annals of the Rheumatic Diseases earlier this year, Nature Medicine in 2022, and the New England Journal of Medicine in 2021.
Now with substantially longer follow-up, the investigators have gained a greater understanding of “the B-cell biology behind our treatment,” Dr. Mueller said. However, “we need longer follow-up to establish how effective the treatment is going to be in the long run.”
All 15 patients included in the analysis were heavily pretreated and had multi-organ involvement. Prior to CAR T-cell therapy, patients had a median disease duration of 3 years, ranging from 1 to as many as 20 years, and had failed a median of five previous treatments. Patients were young — a median age of 36 years — which is much younger than most oncology patients who undergo CAR T-cell therapy, Dr. Mueller said.
The 15 patients underwent typical lymphodepletion and were apheresed and treated with a single infusion of 1 x 106 CD19 CAR T cells per kg of body weight — an established safe dose used in a phase 1 trial of B cell malignancies.
The CAR T cells, manufactured in-house, expanded rapidly, peaking around day 9. B cells disappeared within 7 days and began to reoccur in peripheral blood in all patients between 60 and 180 days. However, no disease flares occurred, Dr. Mueller said.
After 3 months, eight patients with systemic lupus erythematosus showed no sign of disease activity and dramatic improvement in symptoms. Three patients with idiopathic inflammatory myositis experienced major improvements in symptoms and normalization of creatinine kinase levels, the most clinically relevant marker for muscle inflammation. And three of four patients with systemic sclerosis demonstrated major improvements in symptoms and no new disease activity. These responses lasted for a median of 15 months, and all patients stopped taking immunosuppressive drugs.
Patients also tolerated the CAR T-cell treatment well, especially compared with the adverse event profile in oncology patients. Only low-grade inflammatory CAR T-related side effects occurred, and few patients required support for B-cell-derived immune deficiency.
However, infectious complications occurred in 14 patients, including urinary tract and respiratory infections, over the 12-month follow-up. One patient was hospitalized for severe pneumonia a few weeks after CAR T therapy, and two patients experienced herpes zoster reactivations, including one at 6 months and one at 12 months following treatment.
During a press briefing at the ASH conference, Dr. Mueller addressed the “critical question” of patient selection for CAR T-cell therapy, especially in light of the recently announced US Food and Drug Administration investigation exploring whether CAR T cells can cause secondary blood cancers.
Although the T-cell malignancy risk complicates matters, CAR T cells appear to behave differently in patients with autoimmune diseases than those with cancer, he said.
“We don’t understand the biology” related to the malignancy risk yet, Dr. Mueller said, but the benefit for end-of-life patients with no other treatment option likely outweighs the risk. That risk-benefit assessment, however, is more uncertain for those with less severe autoimmune diseases.
For now, it’s important to conduct individual assessments and inform patients about the risk, Dr. Mueller said.
Dr. Mueller disclosed relationships with BMS, AstraZeneca, Gilead, Janssen, Miltenyi Biomedicine, Novartis, Incyte, Abbvie, Sobi, and BeiGene.
A version of this article appeared on Medscape.com.
A single infusion of autologous CD19-directed CAR T-cell therapy led to persistent, drug-free remission in 15 patients with life-threatening systemic lupus erythematosus, idiopathic inflammatory myositis, or systemic sclerosis, according to research presented at the American Society of Hematology annual meeting.
The responses persisted at 15 months median follow-up, with all patients achieving complete remission, reported Fabian Mueller, MD, of the Bavarian Cancer Research Center and Friedrich-Alexander University of Erlangen-Nuremberg, Bavaria, Germany.
The CAR T-cell treatment appears to provide an “entire reset of B cells,” possibly even a cure, for these 15 patients who had run out of treatment options and had short life expectancies, Dr. Mueller said. “It’s impressive that we have treated these patients.”
Some of the cases have been described previously — including in Annals of the Rheumatic Diseases earlier this year, Nature Medicine in 2022, and the New England Journal of Medicine in 2021.
Now with substantially longer follow-up, the investigators have gained a greater understanding of “the B-cell biology behind our treatment,” Dr. Mueller said. However, “we need longer follow-up to establish how effective the treatment is going to be in the long run.”
All 15 patients included in the analysis were heavily pretreated and had multi-organ involvement. Prior to CAR T-cell therapy, patients had a median disease duration of 3 years, ranging from 1 to as many as 20 years, and had failed a median of five previous treatments. Patients were young — a median age of 36 years — which is much younger than most oncology patients who undergo CAR T-cell therapy, Dr. Mueller said.
The 15 patients underwent typical lymphodepletion and were apheresed and treated with a single infusion of 1 x 106 CD19 CAR T cells per kg of body weight — an established safe dose used in a phase 1 trial of B cell malignancies.
The CAR T cells, manufactured in-house, expanded rapidly, peaking around day 9. B cells disappeared within 7 days and began to reoccur in peripheral blood in all patients between 60 and 180 days. However, no disease flares occurred, Dr. Mueller said.
After 3 months, eight patients with systemic lupus erythematosus showed no sign of disease activity and dramatic improvement in symptoms. Three patients with idiopathic inflammatory myositis experienced major improvements in symptoms and normalization of creatinine kinase levels, the most clinically relevant marker for muscle inflammation. And three of four patients with systemic sclerosis demonstrated major improvements in symptoms and no new disease activity. These responses lasted for a median of 15 months, and all patients stopped taking immunosuppressive drugs.
Patients also tolerated the CAR T-cell treatment well, especially compared with the adverse event profile in oncology patients. Only low-grade inflammatory CAR T-related side effects occurred, and few patients required support for B-cell-derived immune deficiency.
However, infectious complications occurred in 14 patients, including urinary tract and respiratory infections, over the 12-month follow-up. One patient was hospitalized for severe pneumonia a few weeks after CAR T therapy, and two patients experienced herpes zoster reactivations, including one at 6 months and one at 12 months following treatment.
During a press briefing at the ASH conference, Dr. Mueller addressed the “critical question” of patient selection for CAR T-cell therapy, especially in light of the recently announced US Food and Drug Administration investigation exploring whether CAR T cells can cause secondary blood cancers.
Although the T-cell malignancy risk complicates matters, CAR T cells appear to behave differently in patients with autoimmune diseases than those with cancer, he said.
“We don’t understand the biology” related to the malignancy risk yet, Dr. Mueller said, but the benefit for end-of-life patients with no other treatment option likely outweighs the risk. That risk-benefit assessment, however, is more uncertain for those with less severe autoimmune diseases.
For now, it’s important to conduct individual assessments and inform patients about the risk, Dr. Mueller said.
Dr. Mueller disclosed relationships with BMS, AstraZeneca, Gilead, Janssen, Miltenyi Biomedicine, Novartis, Incyte, Abbvie, Sobi, and BeiGene.
A version of this article appeared on Medscape.com.
A single infusion of autologous CD19-directed CAR T-cell therapy led to persistent, drug-free remission in 15 patients with life-threatening systemic lupus erythematosus, idiopathic inflammatory myositis, or systemic sclerosis, according to research presented at the American Society of Hematology annual meeting.
The responses persisted at 15 months median follow-up, with all patients achieving complete remission, reported Fabian Mueller, MD, of the Bavarian Cancer Research Center and Friedrich-Alexander University of Erlangen-Nuremberg, Bavaria, Germany.
The CAR T-cell treatment appears to provide an “entire reset of B cells,” possibly even a cure, for these 15 patients who had run out of treatment options and had short life expectancies, Dr. Mueller said. “It’s impressive that we have treated these patients.”
Some of the cases have been described previously — including in Annals of the Rheumatic Diseases earlier this year, Nature Medicine in 2022, and the New England Journal of Medicine in 2021.
Now with substantially longer follow-up, the investigators have gained a greater understanding of “the B-cell biology behind our treatment,” Dr. Mueller said. However, “we need longer follow-up to establish how effective the treatment is going to be in the long run.”
All 15 patients included in the analysis were heavily pretreated and had multi-organ involvement. Prior to CAR T-cell therapy, patients had a median disease duration of 3 years, ranging from 1 to as many as 20 years, and had failed a median of five previous treatments. Patients were young — a median age of 36 years — which is much younger than most oncology patients who undergo CAR T-cell therapy, Dr. Mueller said.
The 15 patients underwent typical lymphodepletion and were apheresed and treated with a single infusion of 1 x 106 CD19 CAR T cells per kg of body weight — an established safe dose used in a phase 1 trial of B cell malignancies.
The CAR T cells, manufactured in-house, expanded rapidly, peaking around day 9. B cells disappeared within 7 days and began to reoccur in peripheral blood in all patients between 60 and 180 days. However, no disease flares occurred, Dr. Mueller said.
After 3 months, eight patients with systemic lupus erythematosus showed no sign of disease activity and dramatic improvement in symptoms. Three patients with idiopathic inflammatory myositis experienced major improvements in symptoms and normalization of creatinine kinase levels, the most clinically relevant marker for muscle inflammation. And three of four patients with systemic sclerosis demonstrated major improvements in symptoms and no new disease activity. These responses lasted for a median of 15 months, and all patients stopped taking immunosuppressive drugs.
Patients also tolerated the CAR T-cell treatment well, especially compared with the adverse event profile in oncology patients. Only low-grade inflammatory CAR T-related side effects occurred, and few patients required support for B-cell-derived immune deficiency.
However, infectious complications occurred in 14 patients, including urinary tract and respiratory infections, over the 12-month follow-up. One patient was hospitalized for severe pneumonia a few weeks after CAR T therapy, and two patients experienced herpes zoster reactivations, including one at 6 months and one at 12 months following treatment.
During a press briefing at the ASH conference, Dr. Mueller addressed the “critical question” of patient selection for CAR T-cell therapy, especially in light of the recently announced US Food and Drug Administration investigation exploring whether CAR T cells can cause secondary blood cancers.
Although the T-cell malignancy risk complicates matters, CAR T cells appear to behave differently in patients with autoimmune diseases than those with cancer, he said.
“We don’t understand the biology” related to the malignancy risk yet, Dr. Mueller said, but the benefit for end-of-life patients with no other treatment option likely outweighs the risk. That risk-benefit assessment, however, is more uncertain for those with less severe autoimmune diseases.
For now, it’s important to conduct individual assessments and inform patients about the risk, Dr. Mueller said.
Dr. Mueller disclosed relationships with BMS, AstraZeneca, Gilead, Janssen, Miltenyi Biomedicine, Novartis, Incyte, Abbvie, Sobi, and BeiGene.
A version of this article appeared on Medscape.com.
FROM ASH 2023
Relapsed DLBCL: With Complete Interim Response, SCT Outperforms CAR T
“In patients with relapsed DLBCL in a complete remission, treatment with auto-HCT is associated with a lower rate of relapse/progression, and a longer progression-free survival [versus CAR T therapy],” said first author Mazyar Shadman, MD, MPH, of the Division of Medical Oncology, University of Washington, Seattle.
“The data support utilization of auto-HCT in patients with relapsed LBCL achieving a complete response,” he said.
The findings were presented at the annual meeting of the American Society of Hematology in San Diego.
While approximately 60% of patients with DLBCL are successfully treated after an initial anthracycline-based and rituximab-containing chemotherapy regimen, those who do not improve have poorer outcomes, and CAR T-cell therapy has emerged as the standard of care for those patients, based on results from the ZUMA-7 and TRANSFORM clinical trials.
But with delays in accessing CAR T quite common, patients will often receive interim chemotherapy while awaiting referral to a CAR T center, and occasionally, usually unexpectedly, some will achieve a partial or complete response.
In previous research involving patients who achieved a partial remission in such interim cases, Dr. Shadman and colleagues demonstrated that auto-HCT had favorable outcomes, compared with those who received CAR T therapy.
For the new retrospective, real-world analysis, the authors compared outcomes with the treatment options among 360 patients between the ages of 18 and 75 who were enrolled in the Center for International Blood & Marrow Transplant Research registry and had received auto-HCT or CAR T therapy after achieving a complete remission following salvage chemotherapy.
Of those receiving CAR-T cell therapy, most (53.2%) received tisagenlecleucel (tisa-cel), followed by axicabtagene ciloleucel (axi-cel, 45.6%) and lisocabtagene maraleucel (liso-cel, 1.3%), between 2018 and 2021, while 281 patients were treated with auto-HCT between 2015 and 2021.
With a median follow-up of 49.7 months (range 3.0-94.4) for auto-HCT and 24.7 months (range 3.3-49.4) for CAR-T, a univariate analysis showed the rate of 2-year progression free survival was 66.2% in the auto-HCT group and 47.8% in the CAR T group (P < .001).
The results also favored auto-HCT for 2-year progression/relapse, with a cumulative incidence of 27.8% with auto-HCT versus 48% with CAR T (P < .001), and the 2-year overall survival was higher with auto-HCT (78.9% vs. 65.6%; P = .037).
After adjustment in multivariable analysis adjusting for relevant clinical variables, auto-HCT versus CAR T remained associated with a lower risk of relapse or progression (HR 2.18; P < .0001) and an improved progression-free survival (HR 1.83; P = .0011), with no significant differences in the risk of treatment-related mortality (HR 0.59; P = .36) or overall survival (HR 1.44; P = .12).
Deaths occurred among 85 patients in the auto-HCT group and 25 in the CAR T cohort, with lymphoma being the main cause of death in both groups (60% and 68%, respectively).
While 37 (13.2%) of auto-HCT patients later received subsequent CAR-T therapy, no patients receiving CAR-T had subsequent auto-HCT.
There were no differences between the CAR-T and auto-HST groups in rates of 2-year treatment-related mortality (4.1% vs. 5.9%; P = .673).
A subanalysis of those who had treatment failure at 12 months, (CAR-T = 57 and auto-HCT = 163) showed that those receiving CAR-T therapy had a higher 2-year relapse rate (46.3% vs. 25%; P < .001); an inferior 2-year progression-free survival rate (48.4% vs. 68.2%; P = .001) compared with auto-HCT, while there were no significant differences between the groups in terms of 2-year overall survival or treatment-related mortality.
After a multivariable analysis adjusting for relevant clinical factors, CAR-T therapy remained associated with higher risk of relapse (HR 2.18; P < .0001) and an inferior progression-free survival (HR 1.83; P = .0011) compared with auto-HCT, with no differences in the risk of treatment-related mortality (HR 0.59; P = .36) or overall survival (HR 1.44; P = .12).
“These results are consistent with our previously reported findings, indicating higher efficacy of auto-HCT compared with CAR T in patients with partial remission,” Dr. Shadman said.
In addition to the study’s being a retrospective analysis, limitations include that more than half of patients in the CAR T cohort received tisa-cel, which could have lower efficacy compared with other approved CAR T therapies, Dr. Shadman noted.
“A repeat analysis by including more patients treated with axi-cel or liso-cel may address this issue in the future,” he said.
Discussing the results in a press briefing, Dr. Shadman underscored that “there is no question the choice of therapy for these DLBCL patients with primary refractory disease should be second-line CAR T therapy — we are not suggesting that those patients should be sent for auto-HCT,” he said.
“What we are saying is, in real-world practice ... patients may need chemotherapy treatment in the interim (awaiting CAR T treatment), and we don’t expect these patients to respond to those cycles because they have already shown us that they don’t do well with chemotherapy — however some do respond and can go into complete remission.”
The question then becomes whether patients at that point will fare better with CAR T or auto-HCT, and the results indicate that “auto-HCT gives those patients a pretty solid remission that looks better than [that with] CAR T therapy.”
Dr. Shadman noted that the results serve to inform or confirm key clinical practices, including “in patients with late relapses, after 12 months, auto-HCT should remain the standard of care.
“In patients with primary refractory disease or early relapse, CAR T should be the goal of therapy and improving access to CAR T should remain a priority.
“In the subset of patients who achieve a CR with interim treatment, a discussion about the possibility of utilizing auto-HCT seems reasonable and can provide another curative option for some patients while keeping CAR-T as a backup treatment plan in case of auto-HCT failure.”
Commenting on the study, Jonathan W. Friedberg, MD, the Samuel Durand Professor of Medicine and director of the Wilmot Cancer Institute, University of Rochester, New York, said, “these findings confirm utility of auto-HCT in patients who achieve a CR.”
However, “the problem is that only a small fraction of patients achieve CR in this situation, and we do not know who they are going to be at time of relapse,” he told this news organization.
He agreed that “given robust randomized trials showing overall survival benefit of CAR-T compared to auto-HCT in patients with high risk relapsed DLBCL, CAR-T treatment should remain the current standard.
“However, these current results help to confirm the strategy for management of low- risk (late) relapses and indicate that auto-HCT still has a place for these patients if they achieve CR with salvage therapy.”
Dr. Shadman reported relationships with ADC therapeutics, Bristol Myers Squibb, Genmab, Lilly, Vincerx, Kite (Gilead), Janssen, Fate Therapeutics, MorphoSys/Incyte, AstraZeneca, BeiGene, Pharmacyclics, Mustang Bio, AbbVie, Genentech, MEI Pharma, Regeneron, and TG Therapeutics. Dr. Friedberg had no disclosures to report.
“In patients with relapsed DLBCL in a complete remission, treatment with auto-HCT is associated with a lower rate of relapse/progression, and a longer progression-free survival [versus CAR T therapy],” said first author Mazyar Shadman, MD, MPH, of the Division of Medical Oncology, University of Washington, Seattle.
“The data support utilization of auto-HCT in patients with relapsed LBCL achieving a complete response,” he said.
The findings were presented at the annual meeting of the American Society of Hematology in San Diego.
While approximately 60% of patients with DLBCL are successfully treated after an initial anthracycline-based and rituximab-containing chemotherapy regimen, those who do not improve have poorer outcomes, and CAR T-cell therapy has emerged as the standard of care for those patients, based on results from the ZUMA-7 and TRANSFORM clinical trials.
But with delays in accessing CAR T quite common, patients will often receive interim chemotherapy while awaiting referral to a CAR T center, and occasionally, usually unexpectedly, some will achieve a partial or complete response.
In previous research involving patients who achieved a partial remission in such interim cases, Dr. Shadman and colleagues demonstrated that auto-HCT had favorable outcomes, compared with those who received CAR T therapy.
For the new retrospective, real-world analysis, the authors compared outcomes with the treatment options among 360 patients between the ages of 18 and 75 who were enrolled in the Center for International Blood & Marrow Transplant Research registry and had received auto-HCT or CAR T therapy after achieving a complete remission following salvage chemotherapy.
Of those receiving CAR-T cell therapy, most (53.2%) received tisagenlecleucel (tisa-cel), followed by axicabtagene ciloleucel (axi-cel, 45.6%) and lisocabtagene maraleucel (liso-cel, 1.3%), between 2018 and 2021, while 281 patients were treated with auto-HCT between 2015 and 2021.
With a median follow-up of 49.7 months (range 3.0-94.4) for auto-HCT and 24.7 months (range 3.3-49.4) for CAR-T, a univariate analysis showed the rate of 2-year progression free survival was 66.2% in the auto-HCT group and 47.8% in the CAR T group (P < .001).
The results also favored auto-HCT for 2-year progression/relapse, with a cumulative incidence of 27.8% with auto-HCT versus 48% with CAR T (P < .001), and the 2-year overall survival was higher with auto-HCT (78.9% vs. 65.6%; P = .037).
After adjustment in multivariable analysis adjusting for relevant clinical variables, auto-HCT versus CAR T remained associated with a lower risk of relapse or progression (HR 2.18; P < .0001) and an improved progression-free survival (HR 1.83; P = .0011), with no significant differences in the risk of treatment-related mortality (HR 0.59; P = .36) or overall survival (HR 1.44; P = .12).
Deaths occurred among 85 patients in the auto-HCT group and 25 in the CAR T cohort, with lymphoma being the main cause of death in both groups (60% and 68%, respectively).
While 37 (13.2%) of auto-HCT patients later received subsequent CAR-T therapy, no patients receiving CAR-T had subsequent auto-HCT.
There were no differences between the CAR-T and auto-HST groups in rates of 2-year treatment-related mortality (4.1% vs. 5.9%; P = .673).
A subanalysis of those who had treatment failure at 12 months, (CAR-T = 57 and auto-HCT = 163) showed that those receiving CAR-T therapy had a higher 2-year relapse rate (46.3% vs. 25%; P < .001); an inferior 2-year progression-free survival rate (48.4% vs. 68.2%; P = .001) compared with auto-HCT, while there were no significant differences between the groups in terms of 2-year overall survival or treatment-related mortality.
After a multivariable analysis adjusting for relevant clinical factors, CAR-T therapy remained associated with higher risk of relapse (HR 2.18; P < .0001) and an inferior progression-free survival (HR 1.83; P = .0011) compared with auto-HCT, with no differences in the risk of treatment-related mortality (HR 0.59; P = .36) or overall survival (HR 1.44; P = .12).
“These results are consistent with our previously reported findings, indicating higher efficacy of auto-HCT compared with CAR T in patients with partial remission,” Dr. Shadman said.
In addition to the study’s being a retrospective analysis, limitations include that more than half of patients in the CAR T cohort received tisa-cel, which could have lower efficacy compared with other approved CAR T therapies, Dr. Shadman noted.
“A repeat analysis by including more patients treated with axi-cel or liso-cel may address this issue in the future,” he said.
Discussing the results in a press briefing, Dr. Shadman underscored that “there is no question the choice of therapy for these DLBCL patients with primary refractory disease should be second-line CAR T therapy — we are not suggesting that those patients should be sent for auto-HCT,” he said.
“What we are saying is, in real-world practice ... patients may need chemotherapy treatment in the interim (awaiting CAR T treatment), and we don’t expect these patients to respond to those cycles because they have already shown us that they don’t do well with chemotherapy — however some do respond and can go into complete remission.”
The question then becomes whether patients at that point will fare better with CAR T or auto-HCT, and the results indicate that “auto-HCT gives those patients a pretty solid remission that looks better than [that with] CAR T therapy.”
Dr. Shadman noted that the results serve to inform or confirm key clinical practices, including “in patients with late relapses, after 12 months, auto-HCT should remain the standard of care.
“In patients with primary refractory disease or early relapse, CAR T should be the goal of therapy and improving access to CAR T should remain a priority.
“In the subset of patients who achieve a CR with interim treatment, a discussion about the possibility of utilizing auto-HCT seems reasonable and can provide another curative option for some patients while keeping CAR-T as a backup treatment plan in case of auto-HCT failure.”
Commenting on the study, Jonathan W. Friedberg, MD, the Samuel Durand Professor of Medicine and director of the Wilmot Cancer Institute, University of Rochester, New York, said, “these findings confirm utility of auto-HCT in patients who achieve a CR.”
However, “the problem is that only a small fraction of patients achieve CR in this situation, and we do not know who they are going to be at time of relapse,” he told this news organization.
He agreed that “given robust randomized trials showing overall survival benefit of CAR-T compared to auto-HCT in patients with high risk relapsed DLBCL, CAR-T treatment should remain the current standard.
“However, these current results help to confirm the strategy for management of low- risk (late) relapses and indicate that auto-HCT still has a place for these patients if they achieve CR with salvage therapy.”
Dr. Shadman reported relationships with ADC therapeutics, Bristol Myers Squibb, Genmab, Lilly, Vincerx, Kite (Gilead), Janssen, Fate Therapeutics, MorphoSys/Incyte, AstraZeneca, BeiGene, Pharmacyclics, Mustang Bio, AbbVie, Genentech, MEI Pharma, Regeneron, and TG Therapeutics. Dr. Friedberg had no disclosures to report.
“In patients with relapsed DLBCL in a complete remission, treatment with auto-HCT is associated with a lower rate of relapse/progression, and a longer progression-free survival [versus CAR T therapy],” said first author Mazyar Shadman, MD, MPH, of the Division of Medical Oncology, University of Washington, Seattle.
“The data support utilization of auto-HCT in patients with relapsed LBCL achieving a complete response,” he said.
The findings were presented at the annual meeting of the American Society of Hematology in San Diego.
While approximately 60% of patients with DLBCL are successfully treated after an initial anthracycline-based and rituximab-containing chemotherapy regimen, those who do not improve have poorer outcomes, and CAR T-cell therapy has emerged as the standard of care for those patients, based on results from the ZUMA-7 and TRANSFORM clinical trials.
But with delays in accessing CAR T quite common, patients will often receive interim chemotherapy while awaiting referral to a CAR T center, and occasionally, usually unexpectedly, some will achieve a partial or complete response.
In previous research involving patients who achieved a partial remission in such interim cases, Dr. Shadman and colleagues demonstrated that auto-HCT had favorable outcomes, compared with those who received CAR T therapy.
For the new retrospective, real-world analysis, the authors compared outcomes with the treatment options among 360 patients between the ages of 18 and 75 who were enrolled in the Center for International Blood & Marrow Transplant Research registry and had received auto-HCT or CAR T therapy after achieving a complete remission following salvage chemotherapy.
Of those receiving CAR-T cell therapy, most (53.2%) received tisagenlecleucel (tisa-cel), followed by axicabtagene ciloleucel (axi-cel, 45.6%) and lisocabtagene maraleucel (liso-cel, 1.3%), between 2018 and 2021, while 281 patients were treated with auto-HCT between 2015 and 2021.
With a median follow-up of 49.7 months (range 3.0-94.4) for auto-HCT and 24.7 months (range 3.3-49.4) for CAR-T, a univariate analysis showed the rate of 2-year progression free survival was 66.2% in the auto-HCT group and 47.8% in the CAR T group (P < .001).
The results also favored auto-HCT for 2-year progression/relapse, with a cumulative incidence of 27.8% with auto-HCT versus 48% with CAR T (P < .001), and the 2-year overall survival was higher with auto-HCT (78.9% vs. 65.6%; P = .037).
After adjustment in multivariable analysis adjusting for relevant clinical variables, auto-HCT versus CAR T remained associated with a lower risk of relapse or progression (HR 2.18; P < .0001) and an improved progression-free survival (HR 1.83; P = .0011), with no significant differences in the risk of treatment-related mortality (HR 0.59; P = .36) or overall survival (HR 1.44; P = .12).
Deaths occurred among 85 patients in the auto-HCT group and 25 in the CAR T cohort, with lymphoma being the main cause of death in both groups (60% and 68%, respectively).
While 37 (13.2%) of auto-HCT patients later received subsequent CAR-T therapy, no patients receiving CAR-T had subsequent auto-HCT.
There were no differences between the CAR-T and auto-HST groups in rates of 2-year treatment-related mortality (4.1% vs. 5.9%; P = .673).
A subanalysis of those who had treatment failure at 12 months, (CAR-T = 57 and auto-HCT = 163) showed that those receiving CAR-T therapy had a higher 2-year relapse rate (46.3% vs. 25%; P < .001); an inferior 2-year progression-free survival rate (48.4% vs. 68.2%; P = .001) compared with auto-HCT, while there were no significant differences between the groups in terms of 2-year overall survival or treatment-related mortality.
After a multivariable analysis adjusting for relevant clinical factors, CAR-T therapy remained associated with higher risk of relapse (HR 2.18; P < .0001) and an inferior progression-free survival (HR 1.83; P = .0011) compared with auto-HCT, with no differences in the risk of treatment-related mortality (HR 0.59; P = .36) or overall survival (HR 1.44; P = .12).
“These results are consistent with our previously reported findings, indicating higher efficacy of auto-HCT compared with CAR T in patients with partial remission,” Dr. Shadman said.
In addition to the study’s being a retrospective analysis, limitations include that more than half of patients in the CAR T cohort received tisa-cel, which could have lower efficacy compared with other approved CAR T therapies, Dr. Shadman noted.
“A repeat analysis by including more patients treated with axi-cel or liso-cel may address this issue in the future,” he said.
Discussing the results in a press briefing, Dr. Shadman underscored that “there is no question the choice of therapy for these DLBCL patients with primary refractory disease should be second-line CAR T therapy — we are not suggesting that those patients should be sent for auto-HCT,” he said.
“What we are saying is, in real-world practice ... patients may need chemotherapy treatment in the interim (awaiting CAR T treatment), and we don’t expect these patients to respond to those cycles because they have already shown us that they don’t do well with chemotherapy — however some do respond and can go into complete remission.”
The question then becomes whether patients at that point will fare better with CAR T or auto-HCT, and the results indicate that “auto-HCT gives those patients a pretty solid remission that looks better than [that with] CAR T therapy.”
Dr. Shadman noted that the results serve to inform or confirm key clinical practices, including “in patients with late relapses, after 12 months, auto-HCT should remain the standard of care.
“In patients with primary refractory disease or early relapse, CAR T should be the goal of therapy and improving access to CAR T should remain a priority.
“In the subset of patients who achieve a CR with interim treatment, a discussion about the possibility of utilizing auto-HCT seems reasonable and can provide another curative option for some patients while keeping CAR-T as a backup treatment plan in case of auto-HCT failure.”
Commenting on the study, Jonathan W. Friedberg, MD, the Samuel Durand Professor of Medicine and director of the Wilmot Cancer Institute, University of Rochester, New York, said, “these findings confirm utility of auto-HCT in patients who achieve a CR.”
However, “the problem is that only a small fraction of patients achieve CR in this situation, and we do not know who they are going to be at time of relapse,” he told this news organization.
He agreed that “given robust randomized trials showing overall survival benefit of CAR-T compared to auto-HCT in patients with high risk relapsed DLBCL, CAR-T treatment should remain the current standard.
“However, these current results help to confirm the strategy for management of low- risk (late) relapses and indicate that auto-HCT still has a place for these patients if they achieve CR with salvage therapy.”
Dr. Shadman reported relationships with ADC therapeutics, Bristol Myers Squibb, Genmab, Lilly, Vincerx, Kite (Gilead), Janssen, Fate Therapeutics, MorphoSys/Incyte, AstraZeneca, BeiGene, Pharmacyclics, Mustang Bio, AbbVie, Genentech, MEI Pharma, Regeneron, and TG Therapeutics. Dr. Friedberg had no disclosures to report.
FROM ASH 2023
ASH 2023: Equity, Sickle Cell, and Real-Life Outcomes
Cynthia E. Dunbar, MD, chief of the Translational Stem Cell Biology Branch at the National Heart, Lung, and Blood Institute and secretary of ASH, added that insight into actual patient experiences also will be a major theme at ASH 2023.
“There is a huge growth in research on outcomes and focusing on using real-world data and how important that is,” Dr. Dunbar said. “Academic research and hematology is really focusing on patient-reported outcomes and how care is delivered in a real-world setting – actually looking at what matters to patients. Are they alive in a certain number of years? And how are they feeling?”
As an example, Dr. Dunbar pointed to an abstract that examined clinical databases in Canada and found that real-world outcomes in multiple myeloma treatments were much worse than those in the original clinical trials for the therapies. Patients reached relapse 44% faster and their overall survival was 75% worse.
In the media briefing, ASH chair of communications Mikkael A. Sekeres, MD, MS, of the Sylvester Comprehensive Cancer Center at the University of Miami, noted that patients in these types of clinical trials “are just these pristine specimens of human beings except for the cancer that’s being treated.”
Dr. Dunbar agreed, noting that “patients who are able to enroll in clinical trials are more likely to be able to show up at the treatment center at the right time and for every dose, have transportation, and afford drugs to prevent side effects. They might stay on the drug for longer, or they have nurses who are always encouraging them of how to make it through a toxicity.”
Hematologists and patients should consider randomized controlled trials to be “the best possible outcome, and perhaps adjust their thinking if an individual patient is older, sicker, or less able to follow a regimen exactly,” she said.
Another highlighted study linked worse outcomes in African-Americans with pediatric acute myeloid leukemia to genetic traits that are more common in that population. The traits “likely explain at least in part the worst outcomes in Black patients in prior studies and on some regimens,” Dr. Dunbar said.
She added that the findings emphasize how testing for genetic variants and biomarkers that impact outcomes should be performed “instead of assuming that a certain dose should be given simply based on perceived or reported race or ethnicity.”
ASH President Robert A. Brodsky, MD, of Johns Hopkins University School of Medicine, Baltimore, highlighted an abstract that reported on the use of AI as a clinical decision support tool to differentiate two easily confused conditions — prefibrotic primary myelofibrosis and essential thrombocythemia.
AI “is a tool that’s going to help pathologists make more accurate and faster diagnoses,” he said. He also spotlighted an abstract about the use of “social media listening” to understand the experiences of patients with SCD and their caregivers. “There can be a lot of misuse and waste of time with social media, but they used this in a way to try and gain insight as to what’s really important to the patients and the caregiver.”
Also, in regard to SCD, Dr. Dunbar pointed to a study that reports on outcomes in patients who received lovotibeglogene autotemcel (lovo-cel) gene therapy for up to 60 months. Both this treatment and a CRISPR-based therapy called exa-cel “appear to result in comparable very impressive efficacy in terms of pain crises and organ dysfunction,” she said. “The hurdle is going to be figuring out how to deliver what will be very expensive and complicated therapies — but likely curative — therapies to patients.”
Another study to be presented at ASH — coauthored by Dr. Brodsky — shows promising results from reduced-intensity haploidentical bone marrow transplantation in adults with severe SCD. Results were similar to those seen with bone marrow from matched siblings, Dr. Sekeres said.
He added that more clarity is needed about new treatment options for SCD, perhaps through a “randomized trial where patients upfront get a haploidentical bone marrow transplant or fully matched bone marrow transplant. Then other patients are randomized to some of these other, newer technology therapies, and we follow them over time. We’re looking not only for overall survival but complications of the therapy itself and how many patients relapse from the treatment.”
Cynthia E. Dunbar, MD, chief of the Translational Stem Cell Biology Branch at the National Heart, Lung, and Blood Institute and secretary of ASH, added that insight into actual patient experiences also will be a major theme at ASH 2023.
“There is a huge growth in research on outcomes and focusing on using real-world data and how important that is,” Dr. Dunbar said. “Academic research and hematology is really focusing on patient-reported outcomes and how care is delivered in a real-world setting – actually looking at what matters to patients. Are they alive in a certain number of years? And how are they feeling?”
As an example, Dr. Dunbar pointed to an abstract that examined clinical databases in Canada and found that real-world outcomes in multiple myeloma treatments were much worse than those in the original clinical trials for the therapies. Patients reached relapse 44% faster and their overall survival was 75% worse.
In the media briefing, ASH chair of communications Mikkael A. Sekeres, MD, MS, of the Sylvester Comprehensive Cancer Center at the University of Miami, noted that patients in these types of clinical trials “are just these pristine specimens of human beings except for the cancer that’s being treated.”
Dr. Dunbar agreed, noting that “patients who are able to enroll in clinical trials are more likely to be able to show up at the treatment center at the right time and for every dose, have transportation, and afford drugs to prevent side effects. They might stay on the drug for longer, or they have nurses who are always encouraging them of how to make it through a toxicity.”
Hematologists and patients should consider randomized controlled trials to be “the best possible outcome, and perhaps adjust their thinking if an individual patient is older, sicker, or less able to follow a regimen exactly,” she said.
Another highlighted study linked worse outcomes in African-Americans with pediatric acute myeloid leukemia to genetic traits that are more common in that population. The traits “likely explain at least in part the worst outcomes in Black patients in prior studies and on some regimens,” Dr. Dunbar said.
She added that the findings emphasize how testing for genetic variants and biomarkers that impact outcomes should be performed “instead of assuming that a certain dose should be given simply based on perceived or reported race or ethnicity.”
ASH President Robert A. Brodsky, MD, of Johns Hopkins University School of Medicine, Baltimore, highlighted an abstract that reported on the use of AI as a clinical decision support tool to differentiate two easily confused conditions — prefibrotic primary myelofibrosis and essential thrombocythemia.
AI “is a tool that’s going to help pathologists make more accurate and faster diagnoses,” he said. He also spotlighted an abstract about the use of “social media listening” to understand the experiences of patients with SCD and their caregivers. “There can be a lot of misuse and waste of time with social media, but they used this in a way to try and gain insight as to what’s really important to the patients and the caregiver.”
Also, in regard to SCD, Dr. Dunbar pointed to a study that reports on outcomes in patients who received lovotibeglogene autotemcel (lovo-cel) gene therapy for up to 60 months. Both this treatment and a CRISPR-based therapy called exa-cel “appear to result in comparable very impressive efficacy in terms of pain crises and organ dysfunction,” she said. “The hurdle is going to be figuring out how to deliver what will be very expensive and complicated therapies — but likely curative — therapies to patients.”
Another study to be presented at ASH — coauthored by Dr. Brodsky — shows promising results from reduced-intensity haploidentical bone marrow transplantation in adults with severe SCD. Results were similar to those seen with bone marrow from matched siblings, Dr. Sekeres said.
He added that more clarity is needed about new treatment options for SCD, perhaps through a “randomized trial where patients upfront get a haploidentical bone marrow transplant or fully matched bone marrow transplant. Then other patients are randomized to some of these other, newer technology therapies, and we follow them over time. We’re looking not only for overall survival but complications of the therapy itself and how many patients relapse from the treatment.”
Cynthia E. Dunbar, MD, chief of the Translational Stem Cell Biology Branch at the National Heart, Lung, and Blood Institute and secretary of ASH, added that insight into actual patient experiences also will be a major theme at ASH 2023.
“There is a huge growth in research on outcomes and focusing on using real-world data and how important that is,” Dr. Dunbar said. “Academic research and hematology is really focusing on patient-reported outcomes and how care is delivered in a real-world setting – actually looking at what matters to patients. Are they alive in a certain number of years? And how are they feeling?”
As an example, Dr. Dunbar pointed to an abstract that examined clinical databases in Canada and found that real-world outcomes in multiple myeloma treatments were much worse than those in the original clinical trials for the therapies. Patients reached relapse 44% faster and their overall survival was 75% worse.
In the media briefing, ASH chair of communications Mikkael A. Sekeres, MD, MS, of the Sylvester Comprehensive Cancer Center at the University of Miami, noted that patients in these types of clinical trials “are just these pristine specimens of human beings except for the cancer that’s being treated.”
Dr. Dunbar agreed, noting that “patients who are able to enroll in clinical trials are more likely to be able to show up at the treatment center at the right time and for every dose, have transportation, and afford drugs to prevent side effects. They might stay on the drug for longer, or they have nurses who are always encouraging them of how to make it through a toxicity.”
Hematologists and patients should consider randomized controlled trials to be “the best possible outcome, and perhaps adjust their thinking if an individual patient is older, sicker, or less able to follow a regimen exactly,” she said.
Another highlighted study linked worse outcomes in African-Americans with pediatric acute myeloid leukemia to genetic traits that are more common in that population. The traits “likely explain at least in part the worst outcomes in Black patients in prior studies and on some regimens,” Dr. Dunbar said.
She added that the findings emphasize how testing for genetic variants and biomarkers that impact outcomes should be performed “instead of assuming that a certain dose should be given simply based on perceived or reported race or ethnicity.”
ASH President Robert A. Brodsky, MD, of Johns Hopkins University School of Medicine, Baltimore, highlighted an abstract that reported on the use of AI as a clinical decision support tool to differentiate two easily confused conditions — prefibrotic primary myelofibrosis and essential thrombocythemia.
AI “is a tool that’s going to help pathologists make more accurate and faster diagnoses,” he said. He also spotlighted an abstract about the use of “social media listening” to understand the experiences of patients with SCD and their caregivers. “There can be a lot of misuse and waste of time with social media, but they used this in a way to try and gain insight as to what’s really important to the patients and the caregiver.”
Also, in regard to SCD, Dr. Dunbar pointed to a study that reports on outcomes in patients who received lovotibeglogene autotemcel (lovo-cel) gene therapy for up to 60 months. Both this treatment and a CRISPR-based therapy called exa-cel “appear to result in comparable very impressive efficacy in terms of pain crises and organ dysfunction,” she said. “The hurdle is going to be figuring out how to deliver what will be very expensive and complicated therapies — but likely curative — therapies to patients.”
Another study to be presented at ASH — coauthored by Dr. Brodsky — shows promising results from reduced-intensity haploidentical bone marrow transplantation in adults with severe SCD. Results were similar to those seen with bone marrow from matched siblings, Dr. Sekeres said.
He added that more clarity is needed about new treatment options for SCD, perhaps through a “randomized trial where patients upfront get a haploidentical bone marrow transplant or fully matched bone marrow transplant. Then other patients are randomized to some of these other, newer technology therapies, and we follow them over time. We’re looking not only for overall survival but complications of the therapy itself and how many patients relapse from the treatment.”
AT ASH 2023
FDA approves pirtobrutinib for previously treated CLL/SLL
The agent was initially approved in January 2023 for patients with mantle cell lymphoma who had previously received a BTK inhibitor.
Like the mantle cell approval, the CLL/SLL approval was based on findings from the open-label, single-arm, phase 1/2 BRUIN study that included adults with at least two prior lines of therapy, including a BTK inhibitor and a BCL-2 inhibitor.
The trial included 108 patients with either CLL or SLL. Overall, patients demonstrated an overall response rate of 72%, all of which were partial responses, and median duration of response of 12.2 months.
Before starting pirtobrutinib, 77% of patients with CLL or SLL had discontinued their last BTK inhibitor for refractory or progressive disease.
“Once patients with CLL or SLL have progressed on covalent BTK inhibitor and BCL-2 inhibitor therapies, treatments are limited and outcomes can be poor, making the approval of Jaypirca a meaningful advance and much-needed new treatment option for these patients,” William G. Wierda, MD, PhD, of the University of Texas MD Anderson Cancer Center, Houston, said in an Eli Lilly press release.
Treatment during the study included the recommended dose of 200 mg given orally once daily until disease progression or unacceptable toxicity. Common adverse reactions that occurred in at least 20% of patients included fatigue, bruising, cough, musculoskeletal pain, COVID-19, diarrhea, pneumonia, abdominal pain, dyspnea, hemorrhage, edema, nausea, pyrexia, and headache. Grade 3 or 4 laboratory abnormalities occurring in more than 10% of patients included decreased neutrophil counts, anemia, and decreased platelet counts.
Serious infections occurred in 32% of patients, including fatal infections in 10% of patients. The prescribing information for pirtobrutinib includes warnings about infections, hemorrhage, cytopenias, cardiac arrhythmias, and secondary primary malignancies.
A version of this article first appeared on Medscape.com.
The agent was initially approved in January 2023 for patients with mantle cell lymphoma who had previously received a BTK inhibitor.
Like the mantle cell approval, the CLL/SLL approval was based on findings from the open-label, single-arm, phase 1/2 BRUIN study that included adults with at least two prior lines of therapy, including a BTK inhibitor and a BCL-2 inhibitor.
The trial included 108 patients with either CLL or SLL. Overall, patients demonstrated an overall response rate of 72%, all of which were partial responses, and median duration of response of 12.2 months.
Before starting pirtobrutinib, 77% of patients with CLL or SLL had discontinued their last BTK inhibitor for refractory or progressive disease.
“Once patients with CLL or SLL have progressed on covalent BTK inhibitor and BCL-2 inhibitor therapies, treatments are limited and outcomes can be poor, making the approval of Jaypirca a meaningful advance and much-needed new treatment option for these patients,” William G. Wierda, MD, PhD, of the University of Texas MD Anderson Cancer Center, Houston, said in an Eli Lilly press release.
Treatment during the study included the recommended dose of 200 mg given orally once daily until disease progression or unacceptable toxicity. Common adverse reactions that occurred in at least 20% of patients included fatigue, bruising, cough, musculoskeletal pain, COVID-19, diarrhea, pneumonia, abdominal pain, dyspnea, hemorrhage, edema, nausea, pyrexia, and headache. Grade 3 or 4 laboratory abnormalities occurring in more than 10% of patients included decreased neutrophil counts, anemia, and decreased platelet counts.
Serious infections occurred in 32% of patients, including fatal infections in 10% of patients. The prescribing information for pirtobrutinib includes warnings about infections, hemorrhage, cytopenias, cardiac arrhythmias, and secondary primary malignancies.
A version of this article first appeared on Medscape.com.
The agent was initially approved in January 2023 for patients with mantle cell lymphoma who had previously received a BTK inhibitor.
Like the mantle cell approval, the CLL/SLL approval was based on findings from the open-label, single-arm, phase 1/2 BRUIN study that included adults with at least two prior lines of therapy, including a BTK inhibitor and a BCL-2 inhibitor.
The trial included 108 patients with either CLL or SLL. Overall, patients demonstrated an overall response rate of 72%, all of which were partial responses, and median duration of response of 12.2 months.
Before starting pirtobrutinib, 77% of patients with CLL or SLL had discontinued their last BTK inhibitor for refractory or progressive disease.
“Once patients with CLL or SLL have progressed on covalent BTK inhibitor and BCL-2 inhibitor therapies, treatments are limited and outcomes can be poor, making the approval of Jaypirca a meaningful advance and much-needed new treatment option for these patients,” William G. Wierda, MD, PhD, of the University of Texas MD Anderson Cancer Center, Houston, said in an Eli Lilly press release.
Treatment during the study included the recommended dose of 200 mg given orally once daily until disease progression or unacceptable toxicity. Common adverse reactions that occurred in at least 20% of patients included fatigue, bruising, cough, musculoskeletal pain, COVID-19, diarrhea, pneumonia, abdominal pain, dyspnea, hemorrhage, edema, nausea, pyrexia, and headache. Grade 3 or 4 laboratory abnormalities occurring in more than 10% of patients included decreased neutrophil counts, anemia, and decreased platelet counts.
Serious infections occurred in 32% of patients, including fatal infections in 10% of patients. The prescribing information for pirtobrutinib includes warnings about infections, hemorrhage, cytopenias, cardiac arrhythmias, and secondary primary malignancies.
A version of this article first appeared on Medscape.com.
FDA OKs new agent to block chemotherapy-induced neutropenia
Efbemalenograstim joins other agents already on the U.S. market, including pegfilgrastim (Neulasta), that aim to reduce the incidence of chemotherapy-induced febrile neutropenia.
The approval of efbemalenograstim was based on two randomized trials. The first included 122 women with either metastatic or nonmetastatic breast cancer who were receiving doxorubicin and docetaxel. These patients were randomly assigned to receive either one subcutaneous injection of efbemalenograstim or placebo on the second day of their first chemotherapy cycle. All patients received efbemalenograstim on the second day of cycles two through four.
The mean duration of grade 4 neutropenia in the first cycle was 1.4 days with efbemalenograstim versus 4.3 days with placebo. Only 4.8% of patients who received efbemalenograstim experienced chemotherapy-induced febrile neutropenia, compared with 25.6% who received the placebo.
The new agent went up against pegfilgrastim in the second trial, which included 393 women who received docetaxel and cyclophosphamide as treatment for nonmetastatic breast cancer. These patients were randomly assigned to receive either a single subcutaneous injection of efbemalenograstim or pegfilgrastim on the second day of each cycle.
During the first cycle, patients in both arms of the trial experienced a mean of 0.2 days of grade 4 neutropenia.
The most common side effects associated with efbemalenograstim were nausea, anemia, and thrombocytopenia. Similar to pegfilgrastim’s label, efbemalenograstim’s label warns of possible splenic rupture, respiratory distress syndrome, sickle cell crisis, and other serious adverse events.
The FDA recommends a dose of 20 mg subcutaneous once per chemotherapy cycle.
A version of this article first appeared on Medscape.com.
Efbemalenograstim joins other agents already on the U.S. market, including pegfilgrastim (Neulasta), that aim to reduce the incidence of chemotherapy-induced febrile neutropenia.
The approval of efbemalenograstim was based on two randomized trials. The first included 122 women with either metastatic or nonmetastatic breast cancer who were receiving doxorubicin and docetaxel. These patients were randomly assigned to receive either one subcutaneous injection of efbemalenograstim or placebo on the second day of their first chemotherapy cycle. All patients received efbemalenograstim on the second day of cycles two through four.
The mean duration of grade 4 neutropenia in the first cycle was 1.4 days with efbemalenograstim versus 4.3 days with placebo. Only 4.8% of patients who received efbemalenograstim experienced chemotherapy-induced febrile neutropenia, compared with 25.6% who received the placebo.
The new agent went up against pegfilgrastim in the second trial, which included 393 women who received docetaxel and cyclophosphamide as treatment for nonmetastatic breast cancer. These patients were randomly assigned to receive either a single subcutaneous injection of efbemalenograstim or pegfilgrastim on the second day of each cycle.
During the first cycle, patients in both arms of the trial experienced a mean of 0.2 days of grade 4 neutropenia.
The most common side effects associated with efbemalenograstim were nausea, anemia, and thrombocytopenia. Similar to pegfilgrastim’s label, efbemalenograstim’s label warns of possible splenic rupture, respiratory distress syndrome, sickle cell crisis, and other serious adverse events.
The FDA recommends a dose of 20 mg subcutaneous once per chemotherapy cycle.
A version of this article first appeared on Medscape.com.
Efbemalenograstim joins other agents already on the U.S. market, including pegfilgrastim (Neulasta), that aim to reduce the incidence of chemotherapy-induced febrile neutropenia.
The approval of efbemalenograstim was based on two randomized trials. The first included 122 women with either metastatic or nonmetastatic breast cancer who were receiving doxorubicin and docetaxel. These patients were randomly assigned to receive either one subcutaneous injection of efbemalenograstim or placebo on the second day of their first chemotherapy cycle. All patients received efbemalenograstim on the second day of cycles two through four.
The mean duration of grade 4 neutropenia in the first cycle was 1.4 days with efbemalenograstim versus 4.3 days with placebo. Only 4.8% of patients who received efbemalenograstim experienced chemotherapy-induced febrile neutropenia, compared with 25.6% who received the placebo.
The new agent went up against pegfilgrastim in the second trial, which included 393 women who received docetaxel and cyclophosphamide as treatment for nonmetastatic breast cancer. These patients were randomly assigned to receive either a single subcutaneous injection of efbemalenograstim or pegfilgrastim on the second day of each cycle.
During the first cycle, patients in both arms of the trial experienced a mean of 0.2 days of grade 4 neutropenia.
The most common side effects associated with efbemalenograstim were nausea, anemia, and thrombocytopenia. Similar to pegfilgrastim’s label, efbemalenograstim’s label warns of possible splenic rupture, respiratory distress syndrome, sickle cell crisis, and other serious adverse events.
The FDA recommends a dose of 20 mg subcutaneous once per chemotherapy cycle.
A version of this article first appeared on Medscape.com.
FDA investigates secondary cancers from CAR T-cell therapies
Secondary cancers are a known risk for this class of immunotherapies, known as B-cell maturation antigen (BCMA)–directed or CD19-directed autologous CAR T-cell therapies, and are included in the prescribing information for these drugs. However, the FDA has received 19 reports of secondary cancers, including CAR-positive lymphoma, since 2017, when the first CAR T-cell treatments were approved, according to Endpoints News.
Most of these reports came from the FDA’s postmarketing adverse event system and others from clinical trial data.
Although the overall benefits of these products continue to outweigh their potential risks, “FDA is investigating the identified risk of T-cell malignancy with serious outcomes, including hospitalization and death, and is evaluating the need for regulatory action,” the agency said in a press release.
Currently approved products in this class include idecabtagene vicleucel (Abecma), lisocabtagene maraleucel (Breyanzi), ciltacabtagene autoleucel (Carvykti), tisagenlecleucel (Kymriah), brexucabtagene autoleucel (Tecartus), and axicabtagene ciloleucel (Yescarta).
“Patients and clinical trial participants receiving treatment with these products should be monitored life-long for new malignancies,” the FDA added.
Suspected adverse events, including T-cell cancers, should be reported by contacting the FDA at 1-800-FDA-1088 or www.fda.gov/medwatch.
A version of this article first appeared on Medscape.com.
Secondary cancers are a known risk for this class of immunotherapies, known as B-cell maturation antigen (BCMA)–directed or CD19-directed autologous CAR T-cell therapies, and are included in the prescribing information for these drugs. However, the FDA has received 19 reports of secondary cancers, including CAR-positive lymphoma, since 2017, when the first CAR T-cell treatments were approved, according to Endpoints News.
Most of these reports came from the FDA’s postmarketing adverse event system and others from clinical trial data.
Although the overall benefits of these products continue to outweigh their potential risks, “FDA is investigating the identified risk of T-cell malignancy with serious outcomes, including hospitalization and death, and is evaluating the need for regulatory action,” the agency said in a press release.
Currently approved products in this class include idecabtagene vicleucel (Abecma), lisocabtagene maraleucel (Breyanzi), ciltacabtagene autoleucel (Carvykti), tisagenlecleucel (Kymriah), brexucabtagene autoleucel (Tecartus), and axicabtagene ciloleucel (Yescarta).
“Patients and clinical trial participants receiving treatment with these products should be monitored life-long for new malignancies,” the FDA added.
Suspected adverse events, including T-cell cancers, should be reported by contacting the FDA at 1-800-FDA-1088 or www.fda.gov/medwatch.
A version of this article first appeared on Medscape.com.
Secondary cancers are a known risk for this class of immunotherapies, known as B-cell maturation antigen (BCMA)–directed or CD19-directed autologous CAR T-cell therapies, and are included in the prescribing information for these drugs. However, the FDA has received 19 reports of secondary cancers, including CAR-positive lymphoma, since 2017, when the first CAR T-cell treatments were approved, according to Endpoints News.
Most of these reports came from the FDA’s postmarketing adverse event system and others from clinical trial data.
Although the overall benefits of these products continue to outweigh their potential risks, “FDA is investigating the identified risk of T-cell malignancy with serious outcomes, including hospitalization and death, and is evaluating the need for regulatory action,” the agency said in a press release.
Currently approved products in this class include idecabtagene vicleucel (Abecma), lisocabtagene maraleucel (Breyanzi), ciltacabtagene autoleucel (Carvykti), tisagenlecleucel (Kymriah), brexucabtagene autoleucel (Tecartus), and axicabtagene ciloleucel (Yescarta).
“Patients and clinical trial participants receiving treatment with these products should be monitored life-long for new malignancies,” the FDA added.
Suspected adverse events, including T-cell cancers, should be reported by contacting the FDA at 1-800-FDA-1088 or www.fda.gov/medwatch.
A version of this article first appeared on Medscape.com.
FDA panel voices concerns over 2 lymphoma accelerated approvals
At a Nov. 16 meeting, the Oncologic Drugs Advisory Committee of the Food and Drug Administration reviewed the reasons for delays in confirmatory trials for pralatrexate (Folotyn) and belinostat (Beleodaq), both now owned by East Windsor, N.J.–based Acrotech. The FDA granted accelerated approval for pralatrexate in 2009 and belinostat in 2014.
“The consensus of the advisory committee is that we have significant concerns about the very prolonged delay and getting these confirmatory studies underway,” said Andy Chen, MD, PhD, of Oregon Health & Science University, Portland, who served as acting ODAC chair for the meeting.
Corporate ownership changes were among the reasons Acrotech cited for the long delays in producing the confirmatory research on pralatrexate and belinostat. Allos Therapeutics won the FDA approval of pralatrexate in 2009. In 2012, Spectrum Pharmaceuticals acquired Acrotech. Spectrum won approval of belinostat in 2014. Acrotech acquired Spectrum in 2019.
The FDA didn’t ask ODAC to take votes on any questions at the meeting. Instead, the FDA sought its expert feedback about how to address the prolonged delays with pralatrexate and belinostat research and, in general, how to promote more timely completion of confirmatory trials for drugs cleared by accelerated approval.
Pralatrexate and belinostat are both used to treat relapsed or refractory peripheral T-cell lymphoma, a rare and aggressive disease affecting about 10,000-15,000 people annually in the United States.
Through the accelerated approval process, the FDA seeks to speed medicines to people with fatal and serious conditions based on promising signs in clinical testing.
The initial pralatrexate and belinostat were based on phase 2, single-arm, monotherapy studies, with about 109 evaluable patients in the key pralatrexate study and 120 evaluable patients in the belinostat study. As is common, these phase 2 tests used measurements of cancer progression, known as the overall response rate.
The FDA then expects companies to show through more extensive testing that medicines cleared with accelerated approvals can deliver significant benefits, such as extending lives. When there are delays in confirmatory trials, patients can be exposed to medicines, often with significant side effects, that are unlikely to benefit them.
For example, the FDA granted an accelerated approval in 2011 for romidepsin for this use for peripheral T-cell lymphoma, the same condition for which pralatrexate and belinostat are used. But in 2021, Bristol-Myers Squibb withdrew the approval for that use of romidepsin when a confirmatory trial failed to meet the primary efficacy endpoint of progression free survival.
At the meeting, Richard Pazdur, MD, who leads oncology medicine at the FDA, urged Acrotech to shorten the time needed to determine whether its medicines deliver significant benefits to patients and thus merit full approval, or whether they too may fall short.
“We’re really in a situation where patients are caught in the middle here,” Dr. Pazdur said. “I feel very bad for that situation and very bad for the patients that they don’t have this information.”
‘Dangerous precedent’
The FDA in recent years has stepped up its efforts to get companies to complete their required studies on drugs cleared by accelerated approvals. The FDA has granted a total of 187 accelerated approvals for cancer drugs. Many of these cover new uses of established drugs and others serve to allow the introduction of new medicines.
For more than half of these cases, 96 of 187, the FDA already has learned that it made the right call in allowing early access to medicines. Companies have presented study results that confirmed the benefit of drugs and thus been able to convert accelerated approvals to traditional approvals.
But 27 of the 187 oncology accelerated approvals have been withdrawn. In these cases, subsequent research failed to establish the expected benefits of these cancer drugs.
And in 95 cases, the FDA and companies are still waiting for the results of studies to confirm the expected benefit of drugs granted accelerated approvals. The FDA classifies these as ongoing accelerated approvals. About 85% of these ongoing approvals were granted in the past 5 years, in contrast to 14 years for pralatrexate and 9 for belinostat.
“It sets a dangerous precedent for the other sponsors and drug companies to have such outliers from the same company,” said ODAC member Toni K. Choueiri, MD, of Harvard Medical School and the Dana-Farber Cancer Institute, both in Boston.
The current agreement between the FDA and Acrotech focuses on a phase 3 trial, SPI-BEL-301 as the confirmatory study. Acrotech’s plan is to start with dose optimization studies in part 1 of the trial, with part 2 meant to see if its medicines provide a significant benefit as measured by progression-free survival.
The plan is to compare treatments. One group of patients would get belinostat plus a common cancer regimen known as CHOP, another group would get pralatrexate plus the COP cancer regimen, which is CHOP without doxorubicin, and a third group would get CHOP.
Acrotech’s current time line is for part 1, which began in October, to finish by December 2025. Then the part 2 timeline would run from 2026 to 2030, with interim progression-free survival possible by 2028.
ODAC member Ashley Rosko, MD, a hematologist from Ohio State University, Columbus, asked Acrotech what steps it will take to try to speed recruitment for the study.
“We are going to implement many strategies,” including what’s called digital amplification, replied Ashish Anvekar, president of Acrotech. This will help identify patients and channel them toward participating clinical sites.
Alexander A. Vinks, PhD, PharmD, who served as a temporary member of ODAC for the Nov. 16 meeting, said many clinicians will not be excited about enrolling patients in this kind of large, traditionally designed study.
Dr. Vinks, who is professor emeritus at Cincinnati Children’s Hospital Medical Center and University of Cincinnati, now works with consultant group NDA, a firm that advises companies on developing drugs.
Dr. Vinks advised Acrotech should try “to pin down what is most likely a smaller study that could be simpler, but still give robust, informative data.”
At a Nov. 16 meeting, the Oncologic Drugs Advisory Committee of the Food and Drug Administration reviewed the reasons for delays in confirmatory trials for pralatrexate (Folotyn) and belinostat (Beleodaq), both now owned by East Windsor, N.J.–based Acrotech. The FDA granted accelerated approval for pralatrexate in 2009 and belinostat in 2014.
“The consensus of the advisory committee is that we have significant concerns about the very prolonged delay and getting these confirmatory studies underway,” said Andy Chen, MD, PhD, of Oregon Health & Science University, Portland, who served as acting ODAC chair for the meeting.
Corporate ownership changes were among the reasons Acrotech cited for the long delays in producing the confirmatory research on pralatrexate and belinostat. Allos Therapeutics won the FDA approval of pralatrexate in 2009. In 2012, Spectrum Pharmaceuticals acquired Acrotech. Spectrum won approval of belinostat in 2014. Acrotech acquired Spectrum in 2019.
The FDA didn’t ask ODAC to take votes on any questions at the meeting. Instead, the FDA sought its expert feedback about how to address the prolonged delays with pralatrexate and belinostat research and, in general, how to promote more timely completion of confirmatory trials for drugs cleared by accelerated approval.
Pralatrexate and belinostat are both used to treat relapsed or refractory peripheral T-cell lymphoma, a rare and aggressive disease affecting about 10,000-15,000 people annually in the United States.
Through the accelerated approval process, the FDA seeks to speed medicines to people with fatal and serious conditions based on promising signs in clinical testing.
The initial pralatrexate and belinostat were based on phase 2, single-arm, monotherapy studies, with about 109 evaluable patients in the key pralatrexate study and 120 evaluable patients in the belinostat study. As is common, these phase 2 tests used measurements of cancer progression, known as the overall response rate.
The FDA then expects companies to show through more extensive testing that medicines cleared with accelerated approvals can deliver significant benefits, such as extending lives. When there are delays in confirmatory trials, patients can be exposed to medicines, often with significant side effects, that are unlikely to benefit them.
For example, the FDA granted an accelerated approval in 2011 for romidepsin for this use for peripheral T-cell lymphoma, the same condition for which pralatrexate and belinostat are used. But in 2021, Bristol-Myers Squibb withdrew the approval for that use of romidepsin when a confirmatory trial failed to meet the primary efficacy endpoint of progression free survival.
At the meeting, Richard Pazdur, MD, who leads oncology medicine at the FDA, urged Acrotech to shorten the time needed to determine whether its medicines deliver significant benefits to patients and thus merit full approval, or whether they too may fall short.
“We’re really in a situation where patients are caught in the middle here,” Dr. Pazdur said. “I feel very bad for that situation and very bad for the patients that they don’t have this information.”
‘Dangerous precedent’
The FDA in recent years has stepped up its efforts to get companies to complete their required studies on drugs cleared by accelerated approvals. The FDA has granted a total of 187 accelerated approvals for cancer drugs. Many of these cover new uses of established drugs and others serve to allow the introduction of new medicines.
For more than half of these cases, 96 of 187, the FDA already has learned that it made the right call in allowing early access to medicines. Companies have presented study results that confirmed the benefit of drugs and thus been able to convert accelerated approvals to traditional approvals.
But 27 of the 187 oncology accelerated approvals have been withdrawn. In these cases, subsequent research failed to establish the expected benefits of these cancer drugs.
And in 95 cases, the FDA and companies are still waiting for the results of studies to confirm the expected benefit of drugs granted accelerated approvals. The FDA classifies these as ongoing accelerated approvals. About 85% of these ongoing approvals were granted in the past 5 years, in contrast to 14 years for pralatrexate and 9 for belinostat.
“It sets a dangerous precedent for the other sponsors and drug companies to have such outliers from the same company,” said ODAC member Toni K. Choueiri, MD, of Harvard Medical School and the Dana-Farber Cancer Institute, both in Boston.
The current agreement between the FDA and Acrotech focuses on a phase 3 trial, SPI-BEL-301 as the confirmatory study. Acrotech’s plan is to start with dose optimization studies in part 1 of the trial, with part 2 meant to see if its medicines provide a significant benefit as measured by progression-free survival.
The plan is to compare treatments. One group of patients would get belinostat plus a common cancer regimen known as CHOP, another group would get pralatrexate plus the COP cancer regimen, which is CHOP without doxorubicin, and a third group would get CHOP.
Acrotech’s current time line is for part 1, which began in October, to finish by December 2025. Then the part 2 timeline would run from 2026 to 2030, with interim progression-free survival possible by 2028.
ODAC member Ashley Rosko, MD, a hematologist from Ohio State University, Columbus, asked Acrotech what steps it will take to try to speed recruitment for the study.
“We are going to implement many strategies,” including what’s called digital amplification, replied Ashish Anvekar, president of Acrotech. This will help identify patients and channel them toward participating clinical sites.
Alexander A. Vinks, PhD, PharmD, who served as a temporary member of ODAC for the Nov. 16 meeting, said many clinicians will not be excited about enrolling patients in this kind of large, traditionally designed study.
Dr. Vinks, who is professor emeritus at Cincinnati Children’s Hospital Medical Center and University of Cincinnati, now works with consultant group NDA, a firm that advises companies on developing drugs.
Dr. Vinks advised Acrotech should try “to pin down what is most likely a smaller study that could be simpler, but still give robust, informative data.”
At a Nov. 16 meeting, the Oncologic Drugs Advisory Committee of the Food and Drug Administration reviewed the reasons for delays in confirmatory trials for pralatrexate (Folotyn) and belinostat (Beleodaq), both now owned by East Windsor, N.J.–based Acrotech. The FDA granted accelerated approval for pralatrexate in 2009 and belinostat in 2014.
“The consensus of the advisory committee is that we have significant concerns about the very prolonged delay and getting these confirmatory studies underway,” said Andy Chen, MD, PhD, of Oregon Health & Science University, Portland, who served as acting ODAC chair for the meeting.
Corporate ownership changes were among the reasons Acrotech cited for the long delays in producing the confirmatory research on pralatrexate and belinostat. Allos Therapeutics won the FDA approval of pralatrexate in 2009. In 2012, Spectrum Pharmaceuticals acquired Acrotech. Spectrum won approval of belinostat in 2014. Acrotech acquired Spectrum in 2019.
The FDA didn’t ask ODAC to take votes on any questions at the meeting. Instead, the FDA sought its expert feedback about how to address the prolonged delays with pralatrexate and belinostat research and, in general, how to promote more timely completion of confirmatory trials for drugs cleared by accelerated approval.
Pralatrexate and belinostat are both used to treat relapsed or refractory peripheral T-cell lymphoma, a rare and aggressive disease affecting about 10,000-15,000 people annually in the United States.
Through the accelerated approval process, the FDA seeks to speed medicines to people with fatal and serious conditions based on promising signs in clinical testing.
The initial pralatrexate and belinostat were based on phase 2, single-arm, monotherapy studies, with about 109 evaluable patients in the key pralatrexate study and 120 evaluable patients in the belinostat study. As is common, these phase 2 tests used measurements of cancer progression, known as the overall response rate.
The FDA then expects companies to show through more extensive testing that medicines cleared with accelerated approvals can deliver significant benefits, such as extending lives. When there are delays in confirmatory trials, patients can be exposed to medicines, often with significant side effects, that are unlikely to benefit them.
For example, the FDA granted an accelerated approval in 2011 for romidepsin for this use for peripheral T-cell lymphoma, the same condition for which pralatrexate and belinostat are used. But in 2021, Bristol-Myers Squibb withdrew the approval for that use of romidepsin when a confirmatory trial failed to meet the primary efficacy endpoint of progression free survival.
At the meeting, Richard Pazdur, MD, who leads oncology medicine at the FDA, urged Acrotech to shorten the time needed to determine whether its medicines deliver significant benefits to patients and thus merit full approval, or whether they too may fall short.
“We’re really in a situation where patients are caught in the middle here,” Dr. Pazdur said. “I feel very bad for that situation and very bad for the patients that they don’t have this information.”
‘Dangerous precedent’
The FDA in recent years has stepped up its efforts to get companies to complete their required studies on drugs cleared by accelerated approvals. The FDA has granted a total of 187 accelerated approvals for cancer drugs. Many of these cover new uses of established drugs and others serve to allow the introduction of new medicines.
For more than half of these cases, 96 of 187, the FDA already has learned that it made the right call in allowing early access to medicines. Companies have presented study results that confirmed the benefit of drugs and thus been able to convert accelerated approvals to traditional approvals.
But 27 of the 187 oncology accelerated approvals have been withdrawn. In these cases, subsequent research failed to establish the expected benefits of these cancer drugs.
And in 95 cases, the FDA and companies are still waiting for the results of studies to confirm the expected benefit of drugs granted accelerated approvals. The FDA classifies these as ongoing accelerated approvals. About 85% of these ongoing approvals were granted in the past 5 years, in contrast to 14 years for pralatrexate and 9 for belinostat.
“It sets a dangerous precedent for the other sponsors and drug companies to have such outliers from the same company,” said ODAC member Toni K. Choueiri, MD, of Harvard Medical School and the Dana-Farber Cancer Institute, both in Boston.
The current agreement between the FDA and Acrotech focuses on a phase 3 trial, SPI-BEL-301 as the confirmatory study. Acrotech’s plan is to start with dose optimization studies in part 1 of the trial, with part 2 meant to see if its medicines provide a significant benefit as measured by progression-free survival.
The plan is to compare treatments. One group of patients would get belinostat plus a common cancer regimen known as CHOP, another group would get pralatrexate plus the COP cancer regimen, which is CHOP without doxorubicin, and a third group would get CHOP.
Acrotech’s current time line is for part 1, which began in October, to finish by December 2025. Then the part 2 timeline would run from 2026 to 2030, with interim progression-free survival possible by 2028.
ODAC member Ashley Rosko, MD, a hematologist from Ohio State University, Columbus, asked Acrotech what steps it will take to try to speed recruitment for the study.
“We are going to implement many strategies,” including what’s called digital amplification, replied Ashish Anvekar, president of Acrotech. This will help identify patients and channel them toward participating clinical sites.
Alexander A. Vinks, PhD, PharmD, who served as a temporary member of ODAC for the Nov. 16 meeting, said many clinicians will not be excited about enrolling patients in this kind of large, traditionally designed study.
Dr. Vinks, who is professor emeritus at Cincinnati Children’s Hospital Medical Center and University of Cincinnati, now works with consultant group NDA, a firm that advises companies on developing drugs.
Dr. Vinks advised Acrotech should try “to pin down what is most likely a smaller study that could be simpler, but still give robust, informative data.”
Patients with MCL more prone to develop secondary malignancies
Key clinical point: Survivors of mantle cell lymphoma (MCL), particularly those treated with rituximab plus bendamustine (R-bendamustine), have an increased risk for secondary malignancies (SM).
Major finding: Patients with MCL vs lymphoma-free comparators had significantly higher rates of SM (adjusted hazard ratio [aHR] 1.6; 95% CI 1.4-1.8), with higher rates being observed across all primary treatment groups, ie, the Nordic-MCL2 protocol; rituximab, cyclophosphamide, doxorubicin, vincristine, prednisone (R-CHOP); R-bendamustine; ibrutinib; lenalidomide; and R-CHOP/cytarabine groups. Treatment with R-bendamustine vs Nordic-MCL2 was independently associated with an increased risk for SM (aHR 2.0; 95% CI 1.3-3.2).
Study details: This population-based retrospective study included adult patients with MCL (n = 1452), each of whom was matched with ≤10 lymphoma-free comparators from the general population (n = 13,992).
Disclosures: This study was funded by the Swedish Cancer Society. I Glimelius and S Eloranta declared receiving research grants, contracts, or support for attending meetings from various sources, including the Swedish Cancer Society. The other authors declared no conflicts of interest.
Source: Abalo KD et al. Secondary malignancies among mantle cell lymphoma patients. Eur J Cancer. 2023;195:113403 (Oct 28). doi: 10.1016/j.ejca.2023.113403
Key clinical point: Survivors of mantle cell lymphoma (MCL), particularly those treated with rituximab plus bendamustine (R-bendamustine), have an increased risk for secondary malignancies (SM).
Major finding: Patients with MCL vs lymphoma-free comparators had significantly higher rates of SM (adjusted hazard ratio [aHR] 1.6; 95% CI 1.4-1.8), with higher rates being observed across all primary treatment groups, ie, the Nordic-MCL2 protocol; rituximab, cyclophosphamide, doxorubicin, vincristine, prednisone (R-CHOP); R-bendamustine; ibrutinib; lenalidomide; and R-CHOP/cytarabine groups. Treatment with R-bendamustine vs Nordic-MCL2 was independently associated with an increased risk for SM (aHR 2.0; 95% CI 1.3-3.2).
Study details: This population-based retrospective study included adult patients with MCL (n = 1452), each of whom was matched with ≤10 lymphoma-free comparators from the general population (n = 13,992).
Disclosures: This study was funded by the Swedish Cancer Society. I Glimelius and S Eloranta declared receiving research grants, contracts, or support for attending meetings from various sources, including the Swedish Cancer Society. The other authors declared no conflicts of interest.
Source: Abalo KD et al. Secondary malignancies among mantle cell lymphoma patients. Eur J Cancer. 2023;195:113403 (Oct 28). doi: 10.1016/j.ejca.2023.113403
Key clinical point: Survivors of mantle cell lymphoma (MCL), particularly those treated with rituximab plus bendamustine (R-bendamustine), have an increased risk for secondary malignancies (SM).
Major finding: Patients with MCL vs lymphoma-free comparators had significantly higher rates of SM (adjusted hazard ratio [aHR] 1.6; 95% CI 1.4-1.8), with higher rates being observed across all primary treatment groups, ie, the Nordic-MCL2 protocol; rituximab, cyclophosphamide, doxorubicin, vincristine, prednisone (R-CHOP); R-bendamustine; ibrutinib; lenalidomide; and R-CHOP/cytarabine groups. Treatment with R-bendamustine vs Nordic-MCL2 was independently associated with an increased risk for SM (aHR 2.0; 95% CI 1.3-3.2).
Study details: This population-based retrospective study included adult patients with MCL (n = 1452), each of whom was matched with ≤10 lymphoma-free comparators from the general population (n = 13,992).
Disclosures: This study was funded by the Swedish Cancer Society. I Glimelius and S Eloranta declared receiving research grants, contracts, or support for attending meetings from various sources, including the Swedish Cancer Society. The other authors declared no conflicts of interest.
Source: Abalo KD et al. Secondary malignancies among mantle cell lymphoma patients. Eur J Cancer. 2023;195:113403 (Oct 28). doi: 10.1016/j.ejca.2023.113403