The Cold, Hard Facts of Cryotherapy in Orthopedics

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ABSTRACT

Cryotherapy is the use of the anti-inflammatory and analgesic properties of ice to facilitate healing. Cryotherapy mediates these salutatory effects by reducing blood flow to the site of injury, down-regulating the production of inflammatory and pain-inducing prostaglandins, and diminishing the conductive ability of nerve endings. It is commonly used postoperatively in orthopedics to decrease analgesic requirements and blood loss as well as to increase range of motion, despite limited literature on its ability to produce such therapeutic effects in clinical practice. This article examines the available literature and the scientific evidence for the use and efficacy of cryotherapy in post-surgical orthopedic patients. It also reviews the potential pitfalls associated with improper use. Overall, this review seeks to provide insight into when, or whether, cryotherapy is appropriate for orthopedic patients during surgical recovery.

Continue to: Cold therapy has been a mainstay of medical treatment...

 

 

Cold therapy has been a mainstay of medical treatment since the days of Hippocrates. Initially used by ancient Egyptians to mitigate inflammation and by Hippocrates himself to treat hemorrhage, the therapeutic applications of ice evolved throughout history to become part of the treatment algorithm for a variety of health conditions.1 Ice made an ideal numbing agent for limb amputations and an anesthetic for certain cancers, but truly became ubiquitous when the first cold pack meant for medicinal use was patented in the early 1970s.1,2 Despite their armamentarium of advanced treatment modalities, physicians in the modern era continue to prescribe cryotherapy for their patients, particularly in the field of orthopedics. Most athletes know the “RICE” (Rest, Ice, Compression, Elevation) protocol and utilize it to minimize inflammation associated with soft tissue injuries.

Inflammation is a physiologic response to noxious stimuli. Cell damage results in the production of inflammatory mediators including prostaglandins, which play a crucial role in the vasodilation and pain associated with inflammation. Vasodilation and increased blood flow manifest as swelling, which can cause pain by putting pressure on nerve endings. The inflammatory prostaglandin E2 (PGE2) causes local increases in temperature and mediates pain.3,4 The application of cold therapy attenuates inflammatory microvascular and hemodynamic changes, reducing some of the deleterious effects of inflammation and minimizing pain. Animal models demonstrate that cryotherapy restores functional capillary density, reverses tumor necrosis factor-α (TNF-α)-induced microvasculature damage, and reduces the production of thrombogenic thromboxanes in injured soft tissue.5 Additionally, cold therapy after knee arthroscopy is associated with lower concentrations of PGE2 in the knee.3 Local cooling acts at the cellular level to decrease edema, reduce pain, and slow blood flow to the affected area, with the overall effect of alleviating inflammation.4,5

Cryotherapy is standard practice in postoperative orthopedic care, but there is limited literature demonstrating its efficacy in this setting. In addition, the advent of more advanced wearable cooling systems necessitates a thorough comparison of the various cryotherapy mechanisms both from healthcare and economic perspectives. The goal of this article is to examine the benefits of cryotherapy in the postoperative management of orthopedic surgical interventions and to review the effectiveness of differing types of cryotherapy. A secondary goal of this article is to review the literature on the adverse effects of cryotherapy in order to increase physician awareness of this issue and highlight the importance of patient education when utilizing cryotherapy postoperatively.

BENEFITS OF CRYOTHERAPY

Three standard types of cryotherapy are prescribed as postoperative therapy in orthopedics: compressive cryotherapy, continuous flow cryotherapy, and the application of ice. All aim to decrease the amount of inflammation of the surgical site, reduce patient pain, and aid in the recovery process. The application of ice or other cooling pack devices without compression is the most commonly used method, likely because it is the most economical and user-friendly cryotherapy option. Compressive cryotherapy is the application of ice or an ice pack secured to the site with a bandage or other device in a manner that also applies pressure to the site of injury. Finally, continuous flow cryotherapy systems are typically connected to a refrigeration control unit and apply compressive cooling through the uninterrupted flow of cold water or gas through a wrap around the injured site. Examples include the Game Ready® (CoolSystems, Inc.), Cryo/Cuff® IC Cooler (DJO Global), and Hilotherm Homecare (Hilotherm GmbH) systems, which are marketed as an improvement over traditional forms of cold therapy, as they are capable of cooling for hours at a time, allow for nighttime use, and provide the operator with temperature control.6-8

Postoperative cryotherapy is prescribed for a wide variety of orthopedic procedures, including anterior cruciate ligament (ACL) reconstruction surgery, rotator cuff surgery, and total knee arthroplasty (TKA). Current literature includes many studies monitoring postoperative outcomes in patients using cryotherapy as part of their treatment regimen, with the primary endpoints being visual analog scale (VAS) scores, analgesic consumption, and range of motion (ROM).9-16 As demonstrated by in Table 1, these studies do not provide conclusive evidence that cryotherapy significantly alters postoperative outcomes, despite its ubiquitous use by the orthopedics community. In fact, the literature reflects a seeming lack of consensus regarding the effect of cryotherapy on analgesic requirements, pain, and joint mobility following procedures. Interestingly, of the studies represented in Table 1, only half analyzed all 3 postoperative measures (analgesic consumption, pain, and ROM). Furthermore, solely Morsi13 concluded that cryotherapy resulted in significant improvements in all 3 outcome measures in a trial involving only 30 patients. Kullenberg and colleagues12 performed the largest study, but still included only 86 patients. In addition, all the studies focused on 1 joint or procedure. Thus, despite evidence that cryotherapy reduces inflammation at a molecular level, current literature does not unequivocally support the common belief that cryotherapy benefits patients in practice. More robust studies that include an analysis of analgesic consumption, VAS scores, and ROM (at minimum) and compare the relative efficacy of cryotherapy across joint types and procedures are necessary to determine whether postoperative cryotherapy in orthopedics is appropriate.

Table 1. Results from Studies that Compared Cryotherapy to Standard Care Within the First 2 Weeks Following Surgery

Author

Joint/Procedure Type

Number of Trial Participants

Cryotherapy Type

Analgesic Consumption

VAS Score

ROM

Yu et al9

Elbow arthrolysis

59

Continuous flow cryotherapy (Cryo/Cuff®; DJO Global)

No significant difference

Cryotherapy significantly decreased scores up to POD 7 (P < 0.05)

No significant difference

Dambros et al10

ACL reconstruction

25

Ice pack

Xa

No significant difference

No significant difference

Leegwater et al11

Hip arthroplasty

30

Continuous flow cryotherapy (Game Ready®; CoolSystems, Inc.)

Trend towards lower use (No significant difference)

No significant difference

Xa

Kullenberg et al12

Knee arthroplasty

86

Continuous flow cryotherapy (Cryo/Cuff®)

No significant difference

No significant difference

Significantly improved at POD 7 and POD 21

Morsi13

Knee arthroplasty

30

Continuous flow cryotherapy

Significantly lower consumption (P < 0.01)

Cryotherapy significantly decreased scores (P < 0.001)

Significantly improved at POD 7; No significant difference 6 weeks postoperative

Singh et al14

Open vs arthroscopic shoulder procedures

70

Continuous flow cryotherapy (Breg Polar Care Glacier® Cold Therapy unit; Breg Inc.)

Xa

Cryotherapy significantly decreased scores at arthroscopic POD 14 (P = 0.043); No significant difference for open procedures

Xa

Saito et al15

Hip arthroplasty

46

Continuous flow cryotherapy (Icing System 2000; Nippon Sigmax Co., Ltd.)

Significantly lower epidural analgesic use (P < 0.001); no significant difference in adjunct analgesic consumption

Cryotherapy significantly decreased scores POD 1-4 (P < 0.05)

Xa

Gibbons et al16

Knee arthroplasty

60

Continuous flow cryotherapy (Cryo/Cuff®)

No significant difference

No significant difference

No significant difference

aX indicates that the study did not include that measurement.
Abbreviations: ACL, anterior cruciate ligament; POD, postoperative day; ROM, range of motion; VAS, visual analog scale.
 

Continue to: ADVANCED CRYOTHERAPY DEVICES...

 

 

ADVANCED CRYOTHERAPY DEVICES

Several recent studies explored the relative postoperative benefits of advanced cryotherapeutics in lieu of the traditional ice pack.6,7,17-21 As reflected in Table 2, these studies, much like the literature comparing cryotherapy to the control, do not reveal significant benefits of continuous flow cryotherapy after surgery. In fact, the only outcome measure that was found to differ significantly in more than 1 study was ROM. Though the makers of advanced cryotherapy systems market them as a vast improvement over traditional forms of cold therapy, there is insufficient evidence to support such claims. Even the most robust study that included 280 patients failed to show significant differences in the analgesic use and ROM after surgery.20 Of note, all but 1 study compared traditional and advanced cryotherapy following procedures on the knee. Additional research exploring outcomes after surgery on other joints is necessary before any conclusions can be made regarding postoperative benefits or risks within orthopedics more generally.

 
Table 2. Results from Studies that Compared Continuous Flow Cryotherapy to the Use of Ice Packs for Analgesic Use Within the First 2 Weeks Following Surgery

Author

Joint / Procedure Type

Number of Trial Participants

Analgesic Consumption

VAS Score

ROM

Kraeutler et al17

Rotator cuff repair or subacromial decompression

46

No significant difference

No significant difference

Xa

Thienpont18

Knee arthroplasty

116

No significant difference

No significant difference

Significant reduction in active flexion with advanced cryotherapy (P = 0.02); No significant difference in other ROM tests

Woolf et al19

Knee arthroplasty

53

Decrease in night pain through POD 2 only

Xa

Xa

Su et al20

Knee arthroplasty

280

Significantly lower use with cryotherapy up to POD 14; No significant difference thereafter

Xa

No difference

Barber21

ACL reconstruction

87

Significantly lower

use with cryotherapy POD 1 and 2 (P = 0.035)

Cryotherapy significantly decreased scores only POD 1 (P < 0.01)

Greater ROM with cryotherapy POD 7 (P < 0.03)

Ruffilli et al6

ACL reconstruction

47

No difference

Xa

Greater ROM with cryotherapy (P < 0.0001)

Kuyucu et al7

Knee arthroplasty

60

Xa

Cryotherapy significantly decreased scores (P < 0.05)

Greater ROM with cryotherapy (P < 0.05)

aX indicates that the study did not include that measurement.Abbreviations: ACL, anterior cruciate ligament; POD, postoperative day; ROM, range of motion; VAS, visual analog scale.

RISKS AND ADVERSE EFFECTS OF CRYOTHERAPY

A rigorous analysis of the benefits of cryotherapy ought to incorporate other factors in addition to improvements in analgesic consumption, VAS score, and ROM. These include the financial and time investment involved in the use of continuous flow cryotherapy, which the majority of studies do not consider. Though many authors acknowledge that continuous flow cryotherapy is expensive, to our knowledge, none have yet performed a formal economic analysis of the cost of advanced cryotherapy to the patient as well as to the healthcare system at large.6,7,13,18,22-24 Dickinson and colleagues24 calculated the total cost of cryotherapy and rehabilitation following rotator cuff repair, but addressed only the up-front cost of the cold therapy system. For context, Table 3 summarizes the retail cost of the most popular cryotherapy devices on the market. Based on this information alone, it seems reasonable to conclude that these systems are associated with significantly more cost than traditional forms of cold therapy, and therefore would be an undesirable option for patients or hospital systems. Nevertheless, cost considerations are more nuanced than a simple comparison of price, necessitating more advanced economic analyses. Substantial savings may be on the table if future studies are able to prove postoperative cryotherapy shortens hospital stays, reduces medication costs, and results in fewer physical therapy sessions. Moreover, if all this is true, patients may experience quicker recovery and have overall greater post-procedure satisfaction.

 

Table 3. Cost of Most Popular Cryotherapy Units

System

Cost

Cryo/Cuff® IC Cooler (DJO Global)

$125

DonJoy IceMan Classic (DJO Global)

$169

The Polar Care Kodiak (Breg, Inc.)

$180

 
 

Patient education required for optimal use of advanced cold therapy is another aspect of cryotherapy that is poorly represented in the literature. As Dickinson and colleagues24 point out, because it eliminates some dependency on the patient to remember to ice appropriately, continuous flow cryotherapy may have a positive impact on compliance and therefore yield improved outcomes.24 Hospital staff may be required to spend additional time with patients. However, this is necessary to ensure proper understanding on how to operate the system and avoid adverse outcomes. Patients may also find the large coolers inconvenient and may therefore be reluctant to use them, finding traditional ice more manageable. Future studies should consider gathering data on patient education, compliance, and overall reception/satisfaction to complete a more holistic investigation of the role of postoperative cryotherapy in orthopedics.

Cryotherapy is not without adverse outcomes, which have been documented primarily in the form of case study reports. Relevant case studies cited adverse outcomes including frostbite/skin loss, compartment syndrome, and perniosis as potential dangers of postoperative cryotherapy in orthopedics (Table 4).25-30 As an example, a patient recovering from patellar-tendon repair experienced bilateral frostbite and skin loss following 2 weeks of uninterrupted use of cryotherapy without any barrier between his skin and the system.29 A similar case study described 2 female patients, one recovering from a TKA and the other from a tibial revision of arthroplasty, who used cryotherapy systems without cessation and experienced frostbite and skin necrosis over the entirety of their knees.26 A third case study exploring 4 incidents of patellar frostbite and necrosis following knee arthroscopies proposed that poor patient understanding of proper cryotherapy use as well as poor recognition of the signs of frostbite contributed to these adverse outcomes. Furthermore, the cryotherapy brace used by all 4 patients included a feature designed to counteract patellar inflammation that also may have increased the likelihood of frostbite in this area due to poor tissue insulation. The authors noted that following the incidents, the makers of the brace removed patellar coverage to prevent future occurrences.30

Table 4. Published Reports of Adverse Effects of Cryotherapy

Author

Adverse Effect

Procedure/Location

Brown and Hahn25

Frostbite

Bunionectomy; hallux valgus correction/feet

Dundon et al26

Skin necrosis

TKA/patella

Khajavi et al27

Compartment syndrome

Arthroscopic osteochondral autograft transfer/calf

King et al28

Perniosis

ACL reconstruction/knee

Lee et al29

Frostbite

Patellar-tendon repair/knees

McGuire and Hendricks30

Frostbite

Knee arthroscopy/patella

Abbreviations: ACL, anterior cruciate ligament; TKA, total knee arthroplasty.

Frostbite linked to cryotherapy has also occurred following orthopedic procedures outside the knee. Brown and Hahn25 described 2 young females who developed skin necrosis following podiatric surgeries and constant cold therapy for roughly a week. Notably, 1 patient had cold sensitivity, which likely put her at an increased baseline risk of experiencing frostbite while using cryotherapy. Tissue necrosis is not the only danger of cold therapy discussed in this study. Surprisingly, 1 patient also developed compartment syndrome.25 Khajavi and colleagues27 also documented postoperative compartment syndrome in a patient following an arthroscopic osteochondral autograft transfer, which they attributed to reperfusion injury in the wake of first-degree frostbite. Hospital personnel also instructed this patient to use his cryotherapy system without interruption at the coldest temperature tolerable, contrary to manufacturer’s instructions.27

Continue to: King and colleagues...

 

 

King and colleagues28 described 2 cases of patients complaining of nodules, papules, and plaques soon after ACL reconstruction and the initiation of cryotherapy. A histological examination of their skin lesions demonstrated the presence of a perivascular and periadnexal superficial and deep lymphocytic infiltrate associated with perniosis. Dermatologists associated the perniosis with the cryotherapy cuff adhesive mechanisms, as their locations matched those of the lesions and symptoms subsided after cessation of cuff usage.28

Cases of adverse effects with perioperative cryotherapy have also occurred at our own institution. The authors obtained informed written consent from the patients to print and publish their images. In 2 separate incidents, patients overdid icing and experienced rather extreme side effects including burns and blisters (Figures 1 and 2). In light of these adverse events, the physicians have questioned whether RICE ought to be part of their standard perioperative recommendations. These physicians are not alone in their uncertainty. Interestingly, even Mirkin,31 who coined the RICE mnemonic, now believes that consistent icing post-injury actually inhibits the body’s natural inflammatory healing response, delaying rather than speeding recovery, and suggests that icing ought to be used for pain control only.

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DISCUSSION

Though there is ample literature supporting the common belief that cryotherapy minimizes inflammation at the cellular level, whether or not it results in meaningful improvements in post-surgical orthopedic outcomes remains unclear. Table 1 reflects a dearth of evidence to support the widespread current practice of cold therapy following orthopedic procedures, but few studies could demonstrate a significant difference in the analgesic use, VAS score, or ROM between cryotherapy and control groups. It is worth noting that these studies used different cryotherapy systems. Though in theory the continuous flow cryotherapy systems are similarly designed, there are potential differences among them that have not been controlled for in this analysis. All studies had <90 participants and focused on a single joint or procedure, making it difficult to draw large scale conclusions about the utility of cold therapy in the postoperative orthopedic population at large. Furthermore, researchers measured endpoints at a range of time intervals that were inconsistent across studies. In some cases, the significance of the impact of cryotherapy on recovery within a single study differed based on the time point at which researchers measured outcomes.12-14 This raises the question as to whether cryotherapy has no benefits, or whether they are simply time-dependent. Future studies should seek to ascertain whether there is a postoperative time window in which cryotherapy could potentially expedite the recovery process.

Similarly, Table 2 shows a lack of consensus regarding the effect of advanced cryotherapy when compared to traditional ice application on pain, analgesic use, and joint mobility after surgery. However, all but 1 of these studies focused on knee procedures. Therefore, our findings may not be applicable to orthopedic surgeries on other joints. Nevertheless, the use of advanced cryotherapy in postoperative orthopedic care may wane if researchers continue to show that it is no more beneficial than its far less expensive counterpart of ice and an ace bandage.

The case studies discussed in this review serve as cautionary tales of the dangers of cryotherapy when used improperly. Though frostbite and subsequent tissue necrosis seem most common, physicians should be made aware that compartment syndrome and perniosis are also possible consequences. Orthopedic patients perhaps have an increased risk of developing these side effects due to the nature of their injuries and the large cutaneous surface area to which cryotherapy is applied. These outcomes could seemingly be avoided with improved educational initiatives targeted at both healthcare personnel and patients. Orthopedic surgeons might consider adding a short, instructive video focusing on proper usage as well as signs of adverse events to their discharge protocol to limit occurrences of these pitfalls associated with cryotherapy.

CONCLUSION

There is inadequate literature to support the of use postoperative cryotherapy of any kind in the field of orthopedics at this time. More robust, standardized studies, and a formidable economic analysis of advanced cold therapy systems are necessary before physicians prescribing cryotherapy can be confident that they are augmenting patient recovery. Nevertheless, as new developments in medicinal cryotherapy occur, it may be possible for the orthopedic community to wield its salutatory effects to limit complications and improve post-surgical outcomes.

References

1. Freiman N, Bouganim N. History of cryotherapy. Dermatol Online J. 2005;11(2):9.

2. Spencer JH, inventor; Nortech Lab Inc, assignee. Device for use as a hot and cold compress. US patent US3780537A. December 25, 1973.

3. Stålman A, Berglund L, Dungnerc E, Arner P, Felländer-Tsai L. Temperature-sensitive release of prostaglandin E₂ and diminished energy requirements in synovial tissue with postoperative cryotherapy: a prospective randomized study after knee arthroscopy. J Bone Joint Surg Am. 2011;93(21):1961-1968. doi:10.2106/JBJS.J.01790.

4. Kawabata A. Prostaglandin E2 and pain--an update. Biol Pharm Bull. 2011;34(8):1170-1173. doi:10.1248/bpb.34.1170.

5. Schaser KD, Stover JF, Melcher I, et al. Local cooling restores microcirculatory hemodynamics after closed soft-tissue trauma in rats. J Trauma. 2006;61(3):642-649. doi:10.1097/01.ta.0000174922.08781.2f.

6. Ruffilli A, Buda R, Castagnini F, et al. Temperature-controlled continuous cold flow device versus traditional icing regimen following anterior cruciate ligament reconstruction: a prospective randomized comparative trial. Arch Orthop Trauma Surg. 2015;135(10):1405-1410. doi:10.1007/s00402-015-2273-z.

7. Kuyucu E, Bülbül M, Kara A, Koçyiğit F, Erdil M. Is cold therapy really efficient after knee arthroplasty? Ann Med Surg. 2015;4(4):475-478. doi:10.1016/j.amsu.2015.10.019.

8. Martin SS, Spindler KP, Tarter JW, Detwiler K, Petersen HA. Cryotherapy: an effective modality for decreasing intraarticular temperature after knee arthroscopy. Am J Sports Med. 2001;29(3):288-291. doi:10.1177/03635465010290030501.

9. Yu SY, Chen S, Yan HD, Fan CY. Effect of cryotherapy after elbow arthrolysis: A prospective, single-blinded, randomized controlled study. Arch Phys Med Rehabil. 2015;96(1):1-6. doi:10.1016/j.apmr.2014.08.011.

10. Dambros C, Martimbianco ALC, Polachini LO, Lahoz GL, Chamlian TR, Cohen M. Effectiveness of cryotherapy after anterior cruciate ligament reconstruction. Acta Ortop Bras. 2012;20(5):285-290. doi:10.1590/S1413-78522012000500008.

11. Leegwater NC, Nolte PA, de Korte N, et al. The efficacy of continuous-flow cryo and cyclic compression therapy after hip fracture surgery on postoperative pain: design of a prospective, open-label, parallel, multicenter, randomized controlled, clinical trial. BMC Musculoskelet Disord. 2016;17(1):153. doi:10.1186/s12891-016-1000-4.

12. Kullenberg B, Ylipää S, Söderlund K, Resch S. Postoperative cryotherapy after total knee arthroplasty: a prospective study of 86 patients. J Arthroplasty. 2006;21(8):1175-1179. doi:10.1016/j.arth.2006.02.159.

13. Morsi E. Continuous-flow cold therapy after total knee arthroplasty. J Arthroplasty. 2002;17(6):718-722. doi:10.1054/arth.2002.33562.

14. Singh H, Osbahr DC, Holovacs TF, Cawley PW, Speer KP. The efficacy of continuous cryotherapy on the postoperative shoulder: A prospective, randomized investigation. J Shoulder Elb Surg. 2001;10(6):522-525. doi:10.1067/mse.2001.118415.

15. Saito N, Horiuchi H, Kobayashi S, Nawata M, Takaoka K. Continuous local cooling for pain relief following total hip arthroplasty. J Arthroplasty. 2004;19(3):334-337. doi:10.1016/j.arth.2003.10.011.

16. Gibbons C, Solan M, Ricketts D, Patterson M. Cryotherapy compared with Robert Jones bandage after total knee replacement: A prospective randomized trial. Int Orthop. 2001;25(4):250-252. doi:10.1007/s002640100227.

17. Kraeutler MJ, Reynolds KA, Long C, McCarty EC. Compressive cryotherapy versus ice-a prospective, randomized study on postoperative pain in patients undergoing arthroscopic rotator cuff repair or subacromial decompression. J Shoulder Elb Surg. 2015;24(6):854-859. doi:10.1016/j.jse.2015.02.004.

18. Thienpont E. Does Advanced Cryotherapy Reduce Pain and Narcotic Consumption After Knee Arthroplasty? Clin Orthop Relat Res. 2014;472(11):3417-3423. doi:10.1007/s11999-014-3810-8.

19. Woolf SK, Barfield WR, Merrill KD, McBryde AM Jr. Comparison of a continuous temperature-controlled cryotherapy device to a simple icing regimen following outpatient knee arthroscopy. J Knee Surg. 2008;21(1):15-19.

20. Su EP, Perna M, Boettner F, et al. A prospective, multi-center, randomised trial to evaluate the efficacy of a cryopneumatic device on total knee arthroplasty recovery. J Bone Joint Surg Br. 2012;94(11 Suppl A):153-156. doi:10.1302/0301-620X.94B11.30832.

21. Barber F. A comparison of crushed ice and continuous flow cold therapy. Am J Knee Surg. 2000;13(2):97-101.

22. Demoulin C, Brouwers M, Darot S, Gillet P, Crielaard JM, Vanderthommen M. Comparison of gaseous cryotherapy with more traditional forms of cryotherapy following total knee arthroplasty. Ann Phys Rehabil Med. 2012;55(4):229-240. doi:10.1016/j.rehab.2012.03.004.

23. Mumith A, Pavlou P, Barrett M, Thurston B, Garrett S. Enhancing postoperative rehabilitation following knee arthroplasty using a new cryotherapy product: a prospective study. Geriatr Orthop Surg Rehabil. 2015;6(4):316-321. doi:10.1177/2151458515609722.

24. Dickinson RN, Kuhn JE, Bergner JL, Rizzone KH. A systematic review of cost-effective treatment of postoperative rotator cuff repairs. J Shoulder Elb Surg. 2017;26(5):915-922. doi:10.1016/j.jse.2017.02.009.

25. Brown WC, Hahn DB. Frostbite of the Feet After Cryotherapy: A Report of Two Cases. J Foot Ankle Surg. 2009;48(5):577-580. doi:10.1053/j.jfas.2009.06.003.

26. Dundon JM, Rymer MC, Johnson RM. Total patellar skin loss from cryotherapy after total knee arthroplasty. J Arthroplasty. 2013;28(2):376.e5-e7. doi:10.1016/j.arth.2012.05.024.

27. Khajavi K, Pavelko T, Mishra A. Compartment syndrome arising from use of an electronic cooling pad. Am J Sports Med. 2004;32(6):1538-1541. doi:10.1177/0363546503262191.

28. King J, Plotner A, Adams B. Perniosis induced by a cold therapy system. Arch Dermatol. 2012;148(9):1101-1102.

29. Lee CK, Pardun J, Buntic R, Kiehn M, Brooks D, Buncke HJ. Severe frostbite of the knees after cryotherapy. Orthopedics. 2007;30(1):63-64.

30. McGuire DA, Hendricks SD. Incidences of frostbite in arthroscopic knee surgery postoperative cryotherapy rehabilitation. Arthroscopy. 2006;22(10):1141.e1-e6. doi:10.1016/j.arthro.2005.06.027.

31. Mirkin G. Why Ice Delays Recovery. http://www.drmirkin.com/fitness/why-ice-delays-recovery.html. Published September 16, 2015. Accessed July 17, 2017.

Author and Disclosure Information

Authors’ Disclosure Statement: The authors report no actual or potential conflict of interest in relation to this article.

Ms. Piana is a Medical Student, University of Tennessee, College of Medicine, Memphis, Tennessee. Ms. Garvey is a Research Assistant, Women’s Sports Medicine, Brigham and Women’s Hospital, Boston, Massachusetts. Ms. Burns was an undergraduate student, Hobart and William Smith Colleges, Geneva, New York. Dr. Matzkin is an Assistant Professor, Department of Orthopaedic Surgery, Harvard Medical School; and Chief of Women’s Sports Medicine, Brigham and Women’s Hospital, Boston, Massachusetts.

Address Correspondence to: Elizabeth G. Matzkin, MD, Brigham and Women’s Hospital, Department of Orthopaedic Surgery, 75 Francis Street, Boston, MA 02115 (tel, 617-525-8500; email, [email protected]).

Lauren E. Piana, MS, BA Kirsten D. Garvey, MA, BA Halle Burns, BSElizabeth G. Matzkin, MD . The Cold, Hard Facts of Cryotherapy in Orthopedics . Am J Orthop.

September 12, 2018

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Author and Disclosure Information

Authors’ Disclosure Statement: The authors report no actual or potential conflict of interest in relation to this article.

Ms. Piana is a Medical Student, University of Tennessee, College of Medicine, Memphis, Tennessee. Ms. Garvey is a Research Assistant, Women’s Sports Medicine, Brigham and Women’s Hospital, Boston, Massachusetts. Ms. Burns was an undergraduate student, Hobart and William Smith Colleges, Geneva, New York. Dr. Matzkin is an Assistant Professor, Department of Orthopaedic Surgery, Harvard Medical School; and Chief of Women’s Sports Medicine, Brigham and Women’s Hospital, Boston, Massachusetts.

Address Correspondence to: Elizabeth G. Matzkin, MD, Brigham and Women’s Hospital, Department of Orthopaedic Surgery, 75 Francis Street, Boston, MA 02115 (tel, 617-525-8500; email, [email protected]).

Lauren E. Piana, MS, BA Kirsten D. Garvey, MA, BA Halle Burns, BSElizabeth G. Matzkin, MD . The Cold, Hard Facts of Cryotherapy in Orthopedics . Am J Orthop.

September 12, 2018

Author and Disclosure Information

Authors’ Disclosure Statement: The authors report no actual or potential conflict of interest in relation to this article.

Ms. Piana is a Medical Student, University of Tennessee, College of Medicine, Memphis, Tennessee. Ms. Garvey is a Research Assistant, Women’s Sports Medicine, Brigham and Women’s Hospital, Boston, Massachusetts. Ms. Burns was an undergraduate student, Hobart and William Smith Colleges, Geneva, New York. Dr. Matzkin is an Assistant Professor, Department of Orthopaedic Surgery, Harvard Medical School; and Chief of Women’s Sports Medicine, Brigham and Women’s Hospital, Boston, Massachusetts.

Address Correspondence to: Elizabeth G. Matzkin, MD, Brigham and Women’s Hospital, Department of Orthopaedic Surgery, 75 Francis Street, Boston, MA 02115 (tel, 617-525-8500; email, [email protected]).

Lauren E. Piana, MS, BA Kirsten D. Garvey, MA, BA Halle Burns, BSElizabeth G. Matzkin, MD . The Cold, Hard Facts of Cryotherapy in Orthopedics . Am J Orthop.

September 12, 2018

ABSTRACT

Cryotherapy is the use of the anti-inflammatory and analgesic properties of ice to facilitate healing. Cryotherapy mediates these salutatory effects by reducing blood flow to the site of injury, down-regulating the production of inflammatory and pain-inducing prostaglandins, and diminishing the conductive ability of nerve endings. It is commonly used postoperatively in orthopedics to decrease analgesic requirements and blood loss as well as to increase range of motion, despite limited literature on its ability to produce such therapeutic effects in clinical practice. This article examines the available literature and the scientific evidence for the use and efficacy of cryotherapy in post-surgical orthopedic patients. It also reviews the potential pitfalls associated with improper use. Overall, this review seeks to provide insight into when, or whether, cryotherapy is appropriate for orthopedic patients during surgical recovery.

Continue to: Cold therapy has been a mainstay of medical treatment...

 

 

Cold therapy has been a mainstay of medical treatment since the days of Hippocrates. Initially used by ancient Egyptians to mitigate inflammation and by Hippocrates himself to treat hemorrhage, the therapeutic applications of ice evolved throughout history to become part of the treatment algorithm for a variety of health conditions.1 Ice made an ideal numbing agent for limb amputations and an anesthetic for certain cancers, but truly became ubiquitous when the first cold pack meant for medicinal use was patented in the early 1970s.1,2 Despite their armamentarium of advanced treatment modalities, physicians in the modern era continue to prescribe cryotherapy for their patients, particularly in the field of orthopedics. Most athletes know the “RICE” (Rest, Ice, Compression, Elevation) protocol and utilize it to minimize inflammation associated with soft tissue injuries.

Inflammation is a physiologic response to noxious stimuli. Cell damage results in the production of inflammatory mediators including prostaglandins, which play a crucial role in the vasodilation and pain associated with inflammation. Vasodilation and increased blood flow manifest as swelling, which can cause pain by putting pressure on nerve endings. The inflammatory prostaglandin E2 (PGE2) causes local increases in temperature and mediates pain.3,4 The application of cold therapy attenuates inflammatory microvascular and hemodynamic changes, reducing some of the deleterious effects of inflammation and minimizing pain. Animal models demonstrate that cryotherapy restores functional capillary density, reverses tumor necrosis factor-α (TNF-α)-induced microvasculature damage, and reduces the production of thrombogenic thromboxanes in injured soft tissue.5 Additionally, cold therapy after knee arthroscopy is associated with lower concentrations of PGE2 in the knee.3 Local cooling acts at the cellular level to decrease edema, reduce pain, and slow blood flow to the affected area, with the overall effect of alleviating inflammation.4,5

Cryotherapy is standard practice in postoperative orthopedic care, but there is limited literature demonstrating its efficacy in this setting. In addition, the advent of more advanced wearable cooling systems necessitates a thorough comparison of the various cryotherapy mechanisms both from healthcare and economic perspectives. The goal of this article is to examine the benefits of cryotherapy in the postoperative management of orthopedic surgical interventions and to review the effectiveness of differing types of cryotherapy. A secondary goal of this article is to review the literature on the adverse effects of cryotherapy in order to increase physician awareness of this issue and highlight the importance of patient education when utilizing cryotherapy postoperatively.

BENEFITS OF CRYOTHERAPY

Three standard types of cryotherapy are prescribed as postoperative therapy in orthopedics: compressive cryotherapy, continuous flow cryotherapy, and the application of ice. All aim to decrease the amount of inflammation of the surgical site, reduce patient pain, and aid in the recovery process. The application of ice or other cooling pack devices without compression is the most commonly used method, likely because it is the most economical and user-friendly cryotherapy option. Compressive cryotherapy is the application of ice or an ice pack secured to the site with a bandage or other device in a manner that also applies pressure to the site of injury. Finally, continuous flow cryotherapy systems are typically connected to a refrigeration control unit and apply compressive cooling through the uninterrupted flow of cold water or gas through a wrap around the injured site. Examples include the Game Ready® (CoolSystems, Inc.), Cryo/Cuff® IC Cooler (DJO Global), and Hilotherm Homecare (Hilotherm GmbH) systems, which are marketed as an improvement over traditional forms of cold therapy, as they are capable of cooling for hours at a time, allow for nighttime use, and provide the operator with temperature control.6-8

Postoperative cryotherapy is prescribed for a wide variety of orthopedic procedures, including anterior cruciate ligament (ACL) reconstruction surgery, rotator cuff surgery, and total knee arthroplasty (TKA). Current literature includes many studies monitoring postoperative outcomes in patients using cryotherapy as part of their treatment regimen, with the primary endpoints being visual analog scale (VAS) scores, analgesic consumption, and range of motion (ROM).9-16 As demonstrated by in Table 1, these studies do not provide conclusive evidence that cryotherapy significantly alters postoperative outcomes, despite its ubiquitous use by the orthopedics community. In fact, the literature reflects a seeming lack of consensus regarding the effect of cryotherapy on analgesic requirements, pain, and joint mobility following procedures. Interestingly, of the studies represented in Table 1, only half analyzed all 3 postoperative measures (analgesic consumption, pain, and ROM). Furthermore, solely Morsi13 concluded that cryotherapy resulted in significant improvements in all 3 outcome measures in a trial involving only 30 patients. Kullenberg and colleagues12 performed the largest study, but still included only 86 patients. In addition, all the studies focused on 1 joint or procedure. Thus, despite evidence that cryotherapy reduces inflammation at a molecular level, current literature does not unequivocally support the common belief that cryotherapy benefits patients in practice. More robust studies that include an analysis of analgesic consumption, VAS scores, and ROM (at minimum) and compare the relative efficacy of cryotherapy across joint types and procedures are necessary to determine whether postoperative cryotherapy in orthopedics is appropriate.

Table 1. Results from Studies that Compared Cryotherapy to Standard Care Within the First 2 Weeks Following Surgery

Author

Joint/Procedure Type

Number of Trial Participants

Cryotherapy Type

Analgesic Consumption

VAS Score

ROM

Yu et al9

Elbow arthrolysis

59

Continuous flow cryotherapy (Cryo/Cuff®; DJO Global)

No significant difference

Cryotherapy significantly decreased scores up to POD 7 (P < 0.05)

No significant difference

Dambros et al10

ACL reconstruction

25

Ice pack

Xa

No significant difference

No significant difference

Leegwater et al11

Hip arthroplasty

30

Continuous flow cryotherapy (Game Ready®; CoolSystems, Inc.)

Trend towards lower use (No significant difference)

No significant difference

Xa

Kullenberg et al12

Knee arthroplasty

86

Continuous flow cryotherapy (Cryo/Cuff®)

No significant difference

No significant difference

Significantly improved at POD 7 and POD 21

Morsi13

Knee arthroplasty

30

Continuous flow cryotherapy

Significantly lower consumption (P < 0.01)

Cryotherapy significantly decreased scores (P < 0.001)

Significantly improved at POD 7; No significant difference 6 weeks postoperative

Singh et al14

Open vs arthroscopic shoulder procedures

70

Continuous flow cryotherapy (Breg Polar Care Glacier® Cold Therapy unit; Breg Inc.)

Xa

Cryotherapy significantly decreased scores at arthroscopic POD 14 (P = 0.043); No significant difference for open procedures

Xa

Saito et al15

Hip arthroplasty

46

Continuous flow cryotherapy (Icing System 2000; Nippon Sigmax Co., Ltd.)

Significantly lower epidural analgesic use (P < 0.001); no significant difference in adjunct analgesic consumption

Cryotherapy significantly decreased scores POD 1-4 (P < 0.05)

Xa

Gibbons et al16

Knee arthroplasty

60

Continuous flow cryotherapy (Cryo/Cuff®)

No significant difference

No significant difference

No significant difference

aX indicates that the study did not include that measurement.
Abbreviations: ACL, anterior cruciate ligament; POD, postoperative day; ROM, range of motion; VAS, visual analog scale.
 

Continue to: ADVANCED CRYOTHERAPY DEVICES...

 

 

ADVANCED CRYOTHERAPY DEVICES

Several recent studies explored the relative postoperative benefits of advanced cryotherapeutics in lieu of the traditional ice pack.6,7,17-21 As reflected in Table 2, these studies, much like the literature comparing cryotherapy to the control, do not reveal significant benefits of continuous flow cryotherapy after surgery. In fact, the only outcome measure that was found to differ significantly in more than 1 study was ROM. Though the makers of advanced cryotherapy systems market them as a vast improvement over traditional forms of cold therapy, there is insufficient evidence to support such claims. Even the most robust study that included 280 patients failed to show significant differences in the analgesic use and ROM after surgery.20 Of note, all but 1 study compared traditional and advanced cryotherapy following procedures on the knee. Additional research exploring outcomes after surgery on other joints is necessary before any conclusions can be made regarding postoperative benefits or risks within orthopedics more generally.

 
Table 2. Results from Studies that Compared Continuous Flow Cryotherapy to the Use of Ice Packs for Analgesic Use Within the First 2 Weeks Following Surgery

Author

Joint / Procedure Type

Number of Trial Participants

Analgesic Consumption

VAS Score

ROM

Kraeutler et al17

Rotator cuff repair or subacromial decompression

46

No significant difference

No significant difference

Xa

Thienpont18

Knee arthroplasty

116

No significant difference

No significant difference

Significant reduction in active flexion with advanced cryotherapy (P = 0.02); No significant difference in other ROM tests

Woolf et al19

Knee arthroplasty

53

Decrease in night pain through POD 2 only

Xa

Xa

Su et al20

Knee arthroplasty

280

Significantly lower use with cryotherapy up to POD 14; No significant difference thereafter

Xa

No difference

Barber21

ACL reconstruction

87

Significantly lower

use with cryotherapy POD 1 and 2 (P = 0.035)

Cryotherapy significantly decreased scores only POD 1 (P < 0.01)

Greater ROM with cryotherapy POD 7 (P < 0.03)

Ruffilli et al6

ACL reconstruction

47

No difference

Xa

Greater ROM with cryotherapy (P < 0.0001)

Kuyucu et al7

Knee arthroplasty

60

Xa

Cryotherapy significantly decreased scores (P < 0.05)

Greater ROM with cryotherapy (P < 0.05)

aX indicates that the study did not include that measurement.Abbreviations: ACL, anterior cruciate ligament; POD, postoperative day; ROM, range of motion; VAS, visual analog scale.

RISKS AND ADVERSE EFFECTS OF CRYOTHERAPY

A rigorous analysis of the benefits of cryotherapy ought to incorporate other factors in addition to improvements in analgesic consumption, VAS score, and ROM. These include the financial and time investment involved in the use of continuous flow cryotherapy, which the majority of studies do not consider. Though many authors acknowledge that continuous flow cryotherapy is expensive, to our knowledge, none have yet performed a formal economic analysis of the cost of advanced cryotherapy to the patient as well as to the healthcare system at large.6,7,13,18,22-24 Dickinson and colleagues24 calculated the total cost of cryotherapy and rehabilitation following rotator cuff repair, but addressed only the up-front cost of the cold therapy system. For context, Table 3 summarizes the retail cost of the most popular cryotherapy devices on the market. Based on this information alone, it seems reasonable to conclude that these systems are associated with significantly more cost than traditional forms of cold therapy, and therefore would be an undesirable option for patients or hospital systems. Nevertheless, cost considerations are more nuanced than a simple comparison of price, necessitating more advanced economic analyses. Substantial savings may be on the table if future studies are able to prove postoperative cryotherapy shortens hospital stays, reduces medication costs, and results in fewer physical therapy sessions. Moreover, if all this is true, patients may experience quicker recovery and have overall greater post-procedure satisfaction.

 

Table 3. Cost of Most Popular Cryotherapy Units

System

Cost

Cryo/Cuff® IC Cooler (DJO Global)

$125

DonJoy IceMan Classic (DJO Global)

$169

The Polar Care Kodiak (Breg, Inc.)

$180

 
 

Patient education required for optimal use of advanced cold therapy is another aspect of cryotherapy that is poorly represented in the literature. As Dickinson and colleagues24 point out, because it eliminates some dependency on the patient to remember to ice appropriately, continuous flow cryotherapy may have a positive impact on compliance and therefore yield improved outcomes.24 Hospital staff may be required to spend additional time with patients. However, this is necessary to ensure proper understanding on how to operate the system and avoid adverse outcomes. Patients may also find the large coolers inconvenient and may therefore be reluctant to use them, finding traditional ice more manageable. Future studies should consider gathering data on patient education, compliance, and overall reception/satisfaction to complete a more holistic investigation of the role of postoperative cryotherapy in orthopedics.

Cryotherapy is not without adverse outcomes, which have been documented primarily in the form of case study reports. Relevant case studies cited adverse outcomes including frostbite/skin loss, compartment syndrome, and perniosis as potential dangers of postoperative cryotherapy in orthopedics (Table 4).25-30 As an example, a patient recovering from patellar-tendon repair experienced bilateral frostbite and skin loss following 2 weeks of uninterrupted use of cryotherapy without any barrier between his skin and the system.29 A similar case study described 2 female patients, one recovering from a TKA and the other from a tibial revision of arthroplasty, who used cryotherapy systems without cessation and experienced frostbite and skin necrosis over the entirety of their knees.26 A third case study exploring 4 incidents of patellar frostbite and necrosis following knee arthroscopies proposed that poor patient understanding of proper cryotherapy use as well as poor recognition of the signs of frostbite contributed to these adverse outcomes. Furthermore, the cryotherapy brace used by all 4 patients included a feature designed to counteract patellar inflammation that also may have increased the likelihood of frostbite in this area due to poor tissue insulation. The authors noted that following the incidents, the makers of the brace removed patellar coverage to prevent future occurrences.30

Table 4. Published Reports of Adverse Effects of Cryotherapy

Author

Adverse Effect

Procedure/Location

Brown and Hahn25

Frostbite

Bunionectomy; hallux valgus correction/feet

Dundon et al26

Skin necrosis

TKA/patella

Khajavi et al27

Compartment syndrome

Arthroscopic osteochondral autograft transfer/calf

King et al28

Perniosis

ACL reconstruction/knee

Lee et al29

Frostbite

Patellar-tendon repair/knees

McGuire and Hendricks30

Frostbite

Knee arthroscopy/patella

Abbreviations: ACL, anterior cruciate ligament; TKA, total knee arthroplasty.

Frostbite linked to cryotherapy has also occurred following orthopedic procedures outside the knee. Brown and Hahn25 described 2 young females who developed skin necrosis following podiatric surgeries and constant cold therapy for roughly a week. Notably, 1 patient had cold sensitivity, which likely put her at an increased baseline risk of experiencing frostbite while using cryotherapy. Tissue necrosis is not the only danger of cold therapy discussed in this study. Surprisingly, 1 patient also developed compartment syndrome.25 Khajavi and colleagues27 also documented postoperative compartment syndrome in a patient following an arthroscopic osteochondral autograft transfer, which they attributed to reperfusion injury in the wake of first-degree frostbite. Hospital personnel also instructed this patient to use his cryotherapy system without interruption at the coldest temperature tolerable, contrary to manufacturer’s instructions.27

Continue to: King and colleagues...

 

 

King and colleagues28 described 2 cases of patients complaining of nodules, papules, and plaques soon after ACL reconstruction and the initiation of cryotherapy. A histological examination of their skin lesions demonstrated the presence of a perivascular and periadnexal superficial and deep lymphocytic infiltrate associated with perniosis. Dermatologists associated the perniosis with the cryotherapy cuff adhesive mechanisms, as their locations matched those of the lesions and symptoms subsided after cessation of cuff usage.28

Cases of adverse effects with perioperative cryotherapy have also occurred at our own institution. The authors obtained informed written consent from the patients to print and publish their images. In 2 separate incidents, patients overdid icing and experienced rather extreme side effects including burns and blisters (Figures 1 and 2). In light of these adverse events, the physicians have questioned whether RICE ought to be part of their standard perioperative recommendations. These physicians are not alone in their uncertainty. Interestingly, even Mirkin,31 who coined the RICE mnemonic, now believes that consistent icing post-injury actually inhibits the body’s natural inflammatory healing response, delaying rather than speeding recovery, and suggests that icing ought to be used for pain control only.

matzkin0918_f1_0

matzkin0918_f2

DISCUSSION

Though there is ample literature supporting the common belief that cryotherapy minimizes inflammation at the cellular level, whether or not it results in meaningful improvements in post-surgical orthopedic outcomes remains unclear. Table 1 reflects a dearth of evidence to support the widespread current practice of cold therapy following orthopedic procedures, but few studies could demonstrate a significant difference in the analgesic use, VAS score, or ROM between cryotherapy and control groups. It is worth noting that these studies used different cryotherapy systems. Though in theory the continuous flow cryotherapy systems are similarly designed, there are potential differences among them that have not been controlled for in this analysis. All studies had <90 participants and focused on a single joint or procedure, making it difficult to draw large scale conclusions about the utility of cold therapy in the postoperative orthopedic population at large. Furthermore, researchers measured endpoints at a range of time intervals that were inconsistent across studies. In some cases, the significance of the impact of cryotherapy on recovery within a single study differed based on the time point at which researchers measured outcomes.12-14 This raises the question as to whether cryotherapy has no benefits, or whether they are simply time-dependent. Future studies should seek to ascertain whether there is a postoperative time window in which cryotherapy could potentially expedite the recovery process.

Similarly, Table 2 shows a lack of consensus regarding the effect of advanced cryotherapy when compared to traditional ice application on pain, analgesic use, and joint mobility after surgery. However, all but 1 of these studies focused on knee procedures. Therefore, our findings may not be applicable to orthopedic surgeries on other joints. Nevertheless, the use of advanced cryotherapy in postoperative orthopedic care may wane if researchers continue to show that it is no more beneficial than its far less expensive counterpart of ice and an ace bandage.

The case studies discussed in this review serve as cautionary tales of the dangers of cryotherapy when used improperly. Though frostbite and subsequent tissue necrosis seem most common, physicians should be made aware that compartment syndrome and perniosis are also possible consequences. Orthopedic patients perhaps have an increased risk of developing these side effects due to the nature of their injuries and the large cutaneous surface area to which cryotherapy is applied. These outcomes could seemingly be avoided with improved educational initiatives targeted at both healthcare personnel and patients. Orthopedic surgeons might consider adding a short, instructive video focusing on proper usage as well as signs of adverse events to their discharge protocol to limit occurrences of these pitfalls associated with cryotherapy.

CONCLUSION

There is inadequate literature to support the of use postoperative cryotherapy of any kind in the field of orthopedics at this time. More robust, standardized studies, and a formidable economic analysis of advanced cold therapy systems are necessary before physicians prescribing cryotherapy can be confident that they are augmenting patient recovery. Nevertheless, as new developments in medicinal cryotherapy occur, it may be possible for the orthopedic community to wield its salutatory effects to limit complications and improve post-surgical outcomes.

ABSTRACT

Cryotherapy is the use of the anti-inflammatory and analgesic properties of ice to facilitate healing. Cryotherapy mediates these salutatory effects by reducing blood flow to the site of injury, down-regulating the production of inflammatory and pain-inducing prostaglandins, and diminishing the conductive ability of nerve endings. It is commonly used postoperatively in orthopedics to decrease analgesic requirements and blood loss as well as to increase range of motion, despite limited literature on its ability to produce such therapeutic effects in clinical practice. This article examines the available literature and the scientific evidence for the use and efficacy of cryotherapy in post-surgical orthopedic patients. It also reviews the potential pitfalls associated with improper use. Overall, this review seeks to provide insight into when, or whether, cryotherapy is appropriate for orthopedic patients during surgical recovery.

Continue to: Cold therapy has been a mainstay of medical treatment...

 

 

Cold therapy has been a mainstay of medical treatment since the days of Hippocrates. Initially used by ancient Egyptians to mitigate inflammation and by Hippocrates himself to treat hemorrhage, the therapeutic applications of ice evolved throughout history to become part of the treatment algorithm for a variety of health conditions.1 Ice made an ideal numbing agent for limb amputations and an anesthetic for certain cancers, but truly became ubiquitous when the first cold pack meant for medicinal use was patented in the early 1970s.1,2 Despite their armamentarium of advanced treatment modalities, physicians in the modern era continue to prescribe cryotherapy for their patients, particularly in the field of orthopedics. Most athletes know the “RICE” (Rest, Ice, Compression, Elevation) protocol and utilize it to minimize inflammation associated with soft tissue injuries.

Inflammation is a physiologic response to noxious stimuli. Cell damage results in the production of inflammatory mediators including prostaglandins, which play a crucial role in the vasodilation and pain associated with inflammation. Vasodilation and increased blood flow manifest as swelling, which can cause pain by putting pressure on nerve endings. The inflammatory prostaglandin E2 (PGE2) causes local increases in temperature and mediates pain.3,4 The application of cold therapy attenuates inflammatory microvascular and hemodynamic changes, reducing some of the deleterious effects of inflammation and minimizing pain. Animal models demonstrate that cryotherapy restores functional capillary density, reverses tumor necrosis factor-α (TNF-α)-induced microvasculature damage, and reduces the production of thrombogenic thromboxanes in injured soft tissue.5 Additionally, cold therapy after knee arthroscopy is associated with lower concentrations of PGE2 in the knee.3 Local cooling acts at the cellular level to decrease edema, reduce pain, and slow blood flow to the affected area, with the overall effect of alleviating inflammation.4,5

Cryotherapy is standard practice in postoperative orthopedic care, but there is limited literature demonstrating its efficacy in this setting. In addition, the advent of more advanced wearable cooling systems necessitates a thorough comparison of the various cryotherapy mechanisms both from healthcare and economic perspectives. The goal of this article is to examine the benefits of cryotherapy in the postoperative management of orthopedic surgical interventions and to review the effectiveness of differing types of cryotherapy. A secondary goal of this article is to review the literature on the adverse effects of cryotherapy in order to increase physician awareness of this issue and highlight the importance of patient education when utilizing cryotherapy postoperatively.

BENEFITS OF CRYOTHERAPY

Three standard types of cryotherapy are prescribed as postoperative therapy in orthopedics: compressive cryotherapy, continuous flow cryotherapy, and the application of ice. All aim to decrease the amount of inflammation of the surgical site, reduce patient pain, and aid in the recovery process. The application of ice or other cooling pack devices without compression is the most commonly used method, likely because it is the most economical and user-friendly cryotherapy option. Compressive cryotherapy is the application of ice or an ice pack secured to the site with a bandage or other device in a manner that also applies pressure to the site of injury. Finally, continuous flow cryotherapy systems are typically connected to a refrigeration control unit and apply compressive cooling through the uninterrupted flow of cold water or gas through a wrap around the injured site. Examples include the Game Ready® (CoolSystems, Inc.), Cryo/Cuff® IC Cooler (DJO Global), and Hilotherm Homecare (Hilotherm GmbH) systems, which are marketed as an improvement over traditional forms of cold therapy, as they are capable of cooling for hours at a time, allow for nighttime use, and provide the operator with temperature control.6-8

Postoperative cryotherapy is prescribed for a wide variety of orthopedic procedures, including anterior cruciate ligament (ACL) reconstruction surgery, rotator cuff surgery, and total knee arthroplasty (TKA). Current literature includes many studies monitoring postoperative outcomes in patients using cryotherapy as part of their treatment regimen, with the primary endpoints being visual analog scale (VAS) scores, analgesic consumption, and range of motion (ROM).9-16 As demonstrated by in Table 1, these studies do not provide conclusive evidence that cryotherapy significantly alters postoperative outcomes, despite its ubiquitous use by the orthopedics community. In fact, the literature reflects a seeming lack of consensus regarding the effect of cryotherapy on analgesic requirements, pain, and joint mobility following procedures. Interestingly, of the studies represented in Table 1, only half analyzed all 3 postoperative measures (analgesic consumption, pain, and ROM). Furthermore, solely Morsi13 concluded that cryotherapy resulted in significant improvements in all 3 outcome measures in a trial involving only 30 patients. Kullenberg and colleagues12 performed the largest study, but still included only 86 patients. In addition, all the studies focused on 1 joint or procedure. Thus, despite evidence that cryotherapy reduces inflammation at a molecular level, current literature does not unequivocally support the common belief that cryotherapy benefits patients in practice. More robust studies that include an analysis of analgesic consumption, VAS scores, and ROM (at minimum) and compare the relative efficacy of cryotherapy across joint types and procedures are necessary to determine whether postoperative cryotherapy in orthopedics is appropriate.

Table 1. Results from Studies that Compared Cryotherapy to Standard Care Within the First 2 Weeks Following Surgery

Author

Joint/Procedure Type

Number of Trial Participants

Cryotherapy Type

Analgesic Consumption

VAS Score

ROM

Yu et al9

Elbow arthrolysis

59

Continuous flow cryotherapy (Cryo/Cuff®; DJO Global)

No significant difference

Cryotherapy significantly decreased scores up to POD 7 (P < 0.05)

No significant difference

Dambros et al10

ACL reconstruction

25

Ice pack

Xa

No significant difference

No significant difference

Leegwater et al11

Hip arthroplasty

30

Continuous flow cryotherapy (Game Ready®; CoolSystems, Inc.)

Trend towards lower use (No significant difference)

No significant difference

Xa

Kullenberg et al12

Knee arthroplasty

86

Continuous flow cryotherapy (Cryo/Cuff®)

No significant difference

No significant difference

Significantly improved at POD 7 and POD 21

Morsi13

Knee arthroplasty

30

Continuous flow cryotherapy

Significantly lower consumption (P < 0.01)

Cryotherapy significantly decreased scores (P < 0.001)

Significantly improved at POD 7; No significant difference 6 weeks postoperative

Singh et al14

Open vs arthroscopic shoulder procedures

70

Continuous flow cryotherapy (Breg Polar Care Glacier® Cold Therapy unit; Breg Inc.)

Xa

Cryotherapy significantly decreased scores at arthroscopic POD 14 (P = 0.043); No significant difference for open procedures

Xa

Saito et al15

Hip arthroplasty

46

Continuous flow cryotherapy (Icing System 2000; Nippon Sigmax Co., Ltd.)

Significantly lower epidural analgesic use (P < 0.001); no significant difference in adjunct analgesic consumption

Cryotherapy significantly decreased scores POD 1-4 (P < 0.05)

Xa

Gibbons et al16

Knee arthroplasty

60

Continuous flow cryotherapy (Cryo/Cuff®)

No significant difference

No significant difference

No significant difference

aX indicates that the study did not include that measurement.
Abbreviations: ACL, anterior cruciate ligament; POD, postoperative day; ROM, range of motion; VAS, visual analog scale.
 

Continue to: ADVANCED CRYOTHERAPY DEVICES...

 

 

ADVANCED CRYOTHERAPY DEVICES

Several recent studies explored the relative postoperative benefits of advanced cryotherapeutics in lieu of the traditional ice pack.6,7,17-21 As reflected in Table 2, these studies, much like the literature comparing cryotherapy to the control, do not reveal significant benefits of continuous flow cryotherapy after surgery. In fact, the only outcome measure that was found to differ significantly in more than 1 study was ROM. Though the makers of advanced cryotherapy systems market them as a vast improvement over traditional forms of cold therapy, there is insufficient evidence to support such claims. Even the most robust study that included 280 patients failed to show significant differences in the analgesic use and ROM after surgery.20 Of note, all but 1 study compared traditional and advanced cryotherapy following procedures on the knee. Additional research exploring outcomes after surgery on other joints is necessary before any conclusions can be made regarding postoperative benefits or risks within orthopedics more generally.

 
Table 2. Results from Studies that Compared Continuous Flow Cryotherapy to the Use of Ice Packs for Analgesic Use Within the First 2 Weeks Following Surgery

Author

Joint / Procedure Type

Number of Trial Participants

Analgesic Consumption

VAS Score

ROM

Kraeutler et al17

Rotator cuff repair or subacromial decompression

46

No significant difference

No significant difference

Xa

Thienpont18

Knee arthroplasty

116

No significant difference

No significant difference

Significant reduction in active flexion with advanced cryotherapy (P = 0.02); No significant difference in other ROM tests

Woolf et al19

Knee arthroplasty

53

Decrease in night pain through POD 2 only

Xa

Xa

Su et al20

Knee arthroplasty

280

Significantly lower use with cryotherapy up to POD 14; No significant difference thereafter

Xa

No difference

Barber21

ACL reconstruction

87

Significantly lower

use with cryotherapy POD 1 and 2 (P = 0.035)

Cryotherapy significantly decreased scores only POD 1 (P < 0.01)

Greater ROM with cryotherapy POD 7 (P < 0.03)

Ruffilli et al6

ACL reconstruction

47

No difference

Xa

Greater ROM with cryotherapy (P < 0.0001)

Kuyucu et al7

Knee arthroplasty

60

Xa

Cryotherapy significantly decreased scores (P < 0.05)

Greater ROM with cryotherapy (P < 0.05)

aX indicates that the study did not include that measurement.Abbreviations: ACL, anterior cruciate ligament; POD, postoperative day; ROM, range of motion; VAS, visual analog scale.

RISKS AND ADVERSE EFFECTS OF CRYOTHERAPY

A rigorous analysis of the benefits of cryotherapy ought to incorporate other factors in addition to improvements in analgesic consumption, VAS score, and ROM. These include the financial and time investment involved in the use of continuous flow cryotherapy, which the majority of studies do not consider. Though many authors acknowledge that continuous flow cryotherapy is expensive, to our knowledge, none have yet performed a formal economic analysis of the cost of advanced cryotherapy to the patient as well as to the healthcare system at large.6,7,13,18,22-24 Dickinson and colleagues24 calculated the total cost of cryotherapy and rehabilitation following rotator cuff repair, but addressed only the up-front cost of the cold therapy system. For context, Table 3 summarizes the retail cost of the most popular cryotherapy devices on the market. Based on this information alone, it seems reasonable to conclude that these systems are associated with significantly more cost than traditional forms of cold therapy, and therefore would be an undesirable option for patients or hospital systems. Nevertheless, cost considerations are more nuanced than a simple comparison of price, necessitating more advanced economic analyses. Substantial savings may be on the table if future studies are able to prove postoperative cryotherapy shortens hospital stays, reduces medication costs, and results in fewer physical therapy sessions. Moreover, if all this is true, patients may experience quicker recovery and have overall greater post-procedure satisfaction.

 

Table 3. Cost of Most Popular Cryotherapy Units

System

Cost

Cryo/Cuff® IC Cooler (DJO Global)

$125

DonJoy IceMan Classic (DJO Global)

$169

The Polar Care Kodiak (Breg, Inc.)

$180

 
 

Patient education required for optimal use of advanced cold therapy is another aspect of cryotherapy that is poorly represented in the literature. As Dickinson and colleagues24 point out, because it eliminates some dependency on the patient to remember to ice appropriately, continuous flow cryotherapy may have a positive impact on compliance and therefore yield improved outcomes.24 Hospital staff may be required to spend additional time with patients. However, this is necessary to ensure proper understanding on how to operate the system and avoid adverse outcomes. Patients may also find the large coolers inconvenient and may therefore be reluctant to use them, finding traditional ice more manageable. Future studies should consider gathering data on patient education, compliance, and overall reception/satisfaction to complete a more holistic investigation of the role of postoperative cryotherapy in orthopedics.

Cryotherapy is not without adverse outcomes, which have been documented primarily in the form of case study reports. Relevant case studies cited adverse outcomes including frostbite/skin loss, compartment syndrome, and perniosis as potential dangers of postoperative cryotherapy in orthopedics (Table 4).25-30 As an example, a patient recovering from patellar-tendon repair experienced bilateral frostbite and skin loss following 2 weeks of uninterrupted use of cryotherapy without any barrier between his skin and the system.29 A similar case study described 2 female patients, one recovering from a TKA and the other from a tibial revision of arthroplasty, who used cryotherapy systems without cessation and experienced frostbite and skin necrosis over the entirety of their knees.26 A third case study exploring 4 incidents of patellar frostbite and necrosis following knee arthroscopies proposed that poor patient understanding of proper cryotherapy use as well as poor recognition of the signs of frostbite contributed to these adverse outcomes. Furthermore, the cryotherapy brace used by all 4 patients included a feature designed to counteract patellar inflammation that also may have increased the likelihood of frostbite in this area due to poor tissue insulation. The authors noted that following the incidents, the makers of the brace removed patellar coverage to prevent future occurrences.30

Table 4. Published Reports of Adverse Effects of Cryotherapy

Author

Adverse Effect

Procedure/Location

Brown and Hahn25

Frostbite

Bunionectomy; hallux valgus correction/feet

Dundon et al26

Skin necrosis

TKA/patella

Khajavi et al27

Compartment syndrome

Arthroscopic osteochondral autograft transfer/calf

King et al28

Perniosis

ACL reconstruction/knee

Lee et al29

Frostbite

Patellar-tendon repair/knees

McGuire and Hendricks30

Frostbite

Knee arthroscopy/patella

Abbreviations: ACL, anterior cruciate ligament; TKA, total knee arthroplasty.

Frostbite linked to cryotherapy has also occurred following orthopedic procedures outside the knee. Brown and Hahn25 described 2 young females who developed skin necrosis following podiatric surgeries and constant cold therapy for roughly a week. Notably, 1 patient had cold sensitivity, which likely put her at an increased baseline risk of experiencing frostbite while using cryotherapy. Tissue necrosis is not the only danger of cold therapy discussed in this study. Surprisingly, 1 patient also developed compartment syndrome.25 Khajavi and colleagues27 also documented postoperative compartment syndrome in a patient following an arthroscopic osteochondral autograft transfer, which they attributed to reperfusion injury in the wake of first-degree frostbite. Hospital personnel also instructed this patient to use his cryotherapy system without interruption at the coldest temperature tolerable, contrary to manufacturer’s instructions.27

Continue to: King and colleagues...

 

 

King and colleagues28 described 2 cases of patients complaining of nodules, papules, and plaques soon after ACL reconstruction and the initiation of cryotherapy. A histological examination of their skin lesions demonstrated the presence of a perivascular and periadnexal superficial and deep lymphocytic infiltrate associated with perniosis. Dermatologists associated the perniosis with the cryotherapy cuff adhesive mechanisms, as their locations matched those of the lesions and symptoms subsided after cessation of cuff usage.28

Cases of adverse effects with perioperative cryotherapy have also occurred at our own institution. The authors obtained informed written consent from the patients to print and publish their images. In 2 separate incidents, patients overdid icing and experienced rather extreme side effects including burns and blisters (Figures 1 and 2). In light of these adverse events, the physicians have questioned whether RICE ought to be part of their standard perioperative recommendations. These physicians are not alone in their uncertainty. Interestingly, even Mirkin,31 who coined the RICE mnemonic, now believes that consistent icing post-injury actually inhibits the body’s natural inflammatory healing response, delaying rather than speeding recovery, and suggests that icing ought to be used for pain control only.

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DISCUSSION

Though there is ample literature supporting the common belief that cryotherapy minimizes inflammation at the cellular level, whether or not it results in meaningful improvements in post-surgical orthopedic outcomes remains unclear. Table 1 reflects a dearth of evidence to support the widespread current practice of cold therapy following orthopedic procedures, but few studies could demonstrate a significant difference in the analgesic use, VAS score, or ROM between cryotherapy and control groups. It is worth noting that these studies used different cryotherapy systems. Though in theory the continuous flow cryotherapy systems are similarly designed, there are potential differences among them that have not been controlled for in this analysis. All studies had <90 participants and focused on a single joint or procedure, making it difficult to draw large scale conclusions about the utility of cold therapy in the postoperative orthopedic population at large. Furthermore, researchers measured endpoints at a range of time intervals that were inconsistent across studies. In some cases, the significance of the impact of cryotherapy on recovery within a single study differed based on the time point at which researchers measured outcomes.12-14 This raises the question as to whether cryotherapy has no benefits, or whether they are simply time-dependent. Future studies should seek to ascertain whether there is a postoperative time window in which cryotherapy could potentially expedite the recovery process.

Similarly, Table 2 shows a lack of consensus regarding the effect of advanced cryotherapy when compared to traditional ice application on pain, analgesic use, and joint mobility after surgery. However, all but 1 of these studies focused on knee procedures. Therefore, our findings may not be applicable to orthopedic surgeries on other joints. Nevertheless, the use of advanced cryotherapy in postoperative orthopedic care may wane if researchers continue to show that it is no more beneficial than its far less expensive counterpart of ice and an ace bandage.

The case studies discussed in this review serve as cautionary tales of the dangers of cryotherapy when used improperly. Though frostbite and subsequent tissue necrosis seem most common, physicians should be made aware that compartment syndrome and perniosis are also possible consequences. Orthopedic patients perhaps have an increased risk of developing these side effects due to the nature of their injuries and the large cutaneous surface area to which cryotherapy is applied. These outcomes could seemingly be avoided with improved educational initiatives targeted at both healthcare personnel and patients. Orthopedic surgeons might consider adding a short, instructive video focusing on proper usage as well as signs of adverse events to their discharge protocol to limit occurrences of these pitfalls associated with cryotherapy.

CONCLUSION

There is inadequate literature to support the of use postoperative cryotherapy of any kind in the field of orthopedics at this time. More robust, standardized studies, and a formidable economic analysis of advanced cold therapy systems are necessary before physicians prescribing cryotherapy can be confident that they are augmenting patient recovery. Nevertheless, as new developments in medicinal cryotherapy occur, it may be possible for the orthopedic community to wield its salutatory effects to limit complications and improve post-surgical outcomes.

References

1. Freiman N, Bouganim N. History of cryotherapy. Dermatol Online J. 2005;11(2):9.

2. Spencer JH, inventor; Nortech Lab Inc, assignee. Device for use as a hot and cold compress. US patent US3780537A. December 25, 1973.

3. Stålman A, Berglund L, Dungnerc E, Arner P, Felländer-Tsai L. Temperature-sensitive release of prostaglandin E₂ and diminished energy requirements in synovial tissue with postoperative cryotherapy: a prospective randomized study after knee arthroscopy. J Bone Joint Surg Am. 2011;93(21):1961-1968. doi:10.2106/JBJS.J.01790.

4. Kawabata A. Prostaglandin E2 and pain--an update. Biol Pharm Bull. 2011;34(8):1170-1173. doi:10.1248/bpb.34.1170.

5. Schaser KD, Stover JF, Melcher I, et al. Local cooling restores microcirculatory hemodynamics after closed soft-tissue trauma in rats. J Trauma. 2006;61(3):642-649. doi:10.1097/01.ta.0000174922.08781.2f.

6. Ruffilli A, Buda R, Castagnini F, et al. Temperature-controlled continuous cold flow device versus traditional icing regimen following anterior cruciate ligament reconstruction: a prospective randomized comparative trial. Arch Orthop Trauma Surg. 2015;135(10):1405-1410. doi:10.1007/s00402-015-2273-z.

7. Kuyucu E, Bülbül M, Kara A, Koçyiğit F, Erdil M. Is cold therapy really efficient after knee arthroplasty? Ann Med Surg. 2015;4(4):475-478. doi:10.1016/j.amsu.2015.10.019.

8. Martin SS, Spindler KP, Tarter JW, Detwiler K, Petersen HA. Cryotherapy: an effective modality for decreasing intraarticular temperature after knee arthroscopy. Am J Sports Med. 2001;29(3):288-291. doi:10.1177/03635465010290030501.

9. Yu SY, Chen S, Yan HD, Fan CY. Effect of cryotherapy after elbow arthrolysis: A prospective, single-blinded, randomized controlled study. Arch Phys Med Rehabil. 2015;96(1):1-6. doi:10.1016/j.apmr.2014.08.011.

10. Dambros C, Martimbianco ALC, Polachini LO, Lahoz GL, Chamlian TR, Cohen M. Effectiveness of cryotherapy after anterior cruciate ligament reconstruction. Acta Ortop Bras. 2012;20(5):285-290. doi:10.1590/S1413-78522012000500008.

11. Leegwater NC, Nolte PA, de Korte N, et al. The efficacy of continuous-flow cryo and cyclic compression therapy after hip fracture surgery on postoperative pain: design of a prospective, open-label, parallel, multicenter, randomized controlled, clinical trial. BMC Musculoskelet Disord. 2016;17(1):153. doi:10.1186/s12891-016-1000-4.

12. Kullenberg B, Ylipää S, Söderlund K, Resch S. Postoperative cryotherapy after total knee arthroplasty: a prospective study of 86 patients. J Arthroplasty. 2006;21(8):1175-1179. doi:10.1016/j.arth.2006.02.159.

13. Morsi E. Continuous-flow cold therapy after total knee arthroplasty. J Arthroplasty. 2002;17(6):718-722. doi:10.1054/arth.2002.33562.

14. Singh H, Osbahr DC, Holovacs TF, Cawley PW, Speer KP. The efficacy of continuous cryotherapy on the postoperative shoulder: A prospective, randomized investigation. J Shoulder Elb Surg. 2001;10(6):522-525. doi:10.1067/mse.2001.118415.

15. Saito N, Horiuchi H, Kobayashi S, Nawata M, Takaoka K. Continuous local cooling for pain relief following total hip arthroplasty. J Arthroplasty. 2004;19(3):334-337. doi:10.1016/j.arth.2003.10.011.

16. Gibbons C, Solan M, Ricketts D, Patterson M. Cryotherapy compared with Robert Jones bandage after total knee replacement: A prospective randomized trial. Int Orthop. 2001;25(4):250-252. doi:10.1007/s002640100227.

17. Kraeutler MJ, Reynolds KA, Long C, McCarty EC. Compressive cryotherapy versus ice-a prospective, randomized study on postoperative pain in patients undergoing arthroscopic rotator cuff repair or subacromial decompression. J Shoulder Elb Surg. 2015;24(6):854-859. doi:10.1016/j.jse.2015.02.004.

18. Thienpont E. Does Advanced Cryotherapy Reduce Pain and Narcotic Consumption After Knee Arthroplasty? Clin Orthop Relat Res. 2014;472(11):3417-3423. doi:10.1007/s11999-014-3810-8.

19. Woolf SK, Barfield WR, Merrill KD, McBryde AM Jr. Comparison of a continuous temperature-controlled cryotherapy device to a simple icing regimen following outpatient knee arthroscopy. J Knee Surg. 2008;21(1):15-19.

20. Su EP, Perna M, Boettner F, et al. A prospective, multi-center, randomised trial to evaluate the efficacy of a cryopneumatic device on total knee arthroplasty recovery. J Bone Joint Surg Br. 2012;94(11 Suppl A):153-156. doi:10.1302/0301-620X.94B11.30832.

21. Barber F. A comparison of crushed ice and continuous flow cold therapy. Am J Knee Surg. 2000;13(2):97-101.

22. Demoulin C, Brouwers M, Darot S, Gillet P, Crielaard JM, Vanderthommen M. Comparison of gaseous cryotherapy with more traditional forms of cryotherapy following total knee arthroplasty. Ann Phys Rehabil Med. 2012;55(4):229-240. doi:10.1016/j.rehab.2012.03.004.

23. Mumith A, Pavlou P, Barrett M, Thurston B, Garrett S. Enhancing postoperative rehabilitation following knee arthroplasty using a new cryotherapy product: a prospective study. Geriatr Orthop Surg Rehabil. 2015;6(4):316-321. doi:10.1177/2151458515609722.

24. Dickinson RN, Kuhn JE, Bergner JL, Rizzone KH. A systematic review of cost-effective treatment of postoperative rotator cuff repairs. J Shoulder Elb Surg. 2017;26(5):915-922. doi:10.1016/j.jse.2017.02.009.

25. Brown WC, Hahn DB. Frostbite of the Feet After Cryotherapy: A Report of Two Cases. J Foot Ankle Surg. 2009;48(5):577-580. doi:10.1053/j.jfas.2009.06.003.

26. Dundon JM, Rymer MC, Johnson RM. Total patellar skin loss from cryotherapy after total knee arthroplasty. J Arthroplasty. 2013;28(2):376.e5-e7. doi:10.1016/j.arth.2012.05.024.

27. Khajavi K, Pavelko T, Mishra A. Compartment syndrome arising from use of an electronic cooling pad. Am J Sports Med. 2004;32(6):1538-1541. doi:10.1177/0363546503262191.

28. King J, Plotner A, Adams B. Perniosis induced by a cold therapy system. Arch Dermatol. 2012;148(9):1101-1102.

29. Lee CK, Pardun J, Buntic R, Kiehn M, Brooks D, Buncke HJ. Severe frostbite of the knees after cryotherapy. Orthopedics. 2007;30(1):63-64.

30. McGuire DA, Hendricks SD. Incidences of frostbite in arthroscopic knee surgery postoperative cryotherapy rehabilitation. Arthroscopy. 2006;22(10):1141.e1-e6. doi:10.1016/j.arthro.2005.06.027.

31. Mirkin G. Why Ice Delays Recovery. http://www.drmirkin.com/fitness/why-ice-delays-recovery.html. Published September 16, 2015. Accessed July 17, 2017.

References

1. Freiman N, Bouganim N. History of cryotherapy. Dermatol Online J. 2005;11(2):9.

2. Spencer JH, inventor; Nortech Lab Inc, assignee. Device for use as a hot and cold compress. US patent US3780537A. December 25, 1973.

3. Stålman A, Berglund L, Dungnerc E, Arner P, Felländer-Tsai L. Temperature-sensitive release of prostaglandin E₂ and diminished energy requirements in synovial tissue with postoperative cryotherapy: a prospective randomized study after knee arthroscopy. J Bone Joint Surg Am. 2011;93(21):1961-1968. doi:10.2106/JBJS.J.01790.

4. Kawabata A. Prostaglandin E2 and pain--an update. Biol Pharm Bull. 2011;34(8):1170-1173. doi:10.1248/bpb.34.1170.

5. Schaser KD, Stover JF, Melcher I, et al. Local cooling restores microcirculatory hemodynamics after closed soft-tissue trauma in rats. J Trauma. 2006;61(3):642-649. doi:10.1097/01.ta.0000174922.08781.2f.

6. Ruffilli A, Buda R, Castagnini F, et al. Temperature-controlled continuous cold flow device versus traditional icing regimen following anterior cruciate ligament reconstruction: a prospective randomized comparative trial. Arch Orthop Trauma Surg. 2015;135(10):1405-1410. doi:10.1007/s00402-015-2273-z.

7. Kuyucu E, Bülbül M, Kara A, Koçyiğit F, Erdil M. Is cold therapy really efficient after knee arthroplasty? Ann Med Surg. 2015;4(4):475-478. doi:10.1016/j.amsu.2015.10.019.

8. Martin SS, Spindler KP, Tarter JW, Detwiler K, Petersen HA. Cryotherapy: an effective modality for decreasing intraarticular temperature after knee arthroscopy. Am J Sports Med. 2001;29(3):288-291. doi:10.1177/03635465010290030501.

9. Yu SY, Chen S, Yan HD, Fan CY. Effect of cryotherapy after elbow arthrolysis: A prospective, single-blinded, randomized controlled study. Arch Phys Med Rehabil. 2015;96(1):1-6. doi:10.1016/j.apmr.2014.08.011.

10. Dambros C, Martimbianco ALC, Polachini LO, Lahoz GL, Chamlian TR, Cohen M. Effectiveness of cryotherapy after anterior cruciate ligament reconstruction. Acta Ortop Bras. 2012;20(5):285-290. doi:10.1590/S1413-78522012000500008.

11. Leegwater NC, Nolte PA, de Korte N, et al. The efficacy of continuous-flow cryo and cyclic compression therapy after hip fracture surgery on postoperative pain: design of a prospective, open-label, parallel, multicenter, randomized controlled, clinical trial. BMC Musculoskelet Disord. 2016;17(1):153. doi:10.1186/s12891-016-1000-4.

12. Kullenberg B, Ylipää S, Söderlund K, Resch S. Postoperative cryotherapy after total knee arthroplasty: a prospective study of 86 patients. J Arthroplasty. 2006;21(8):1175-1179. doi:10.1016/j.arth.2006.02.159.

13. Morsi E. Continuous-flow cold therapy after total knee arthroplasty. J Arthroplasty. 2002;17(6):718-722. doi:10.1054/arth.2002.33562.

14. Singh H, Osbahr DC, Holovacs TF, Cawley PW, Speer KP. The efficacy of continuous cryotherapy on the postoperative shoulder: A prospective, randomized investigation. J Shoulder Elb Surg. 2001;10(6):522-525. doi:10.1067/mse.2001.118415.

15. Saito N, Horiuchi H, Kobayashi S, Nawata M, Takaoka K. Continuous local cooling for pain relief following total hip arthroplasty. J Arthroplasty. 2004;19(3):334-337. doi:10.1016/j.arth.2003.10.011.

16. Gibbons C, Solan M, Ricketts D, Patterson M. Cryotherapy compared with Robert Jones bandage after total knee replacement: A prospective randomized trial. Int Orthop. 2001;25(4):250-252. doi:10.1007/s002640100227.

17. Kraeutler MJ, Reynolds KA, Long C, McCarty EC. Compressive cryotherapy versus ice-a prospective, randomized study on postoperative pain in patients undergoing arthroscopic rotator cuff repair or subacromial decompression. J Shoulder Elb Surg. 2015;24(6):854-859. doi:10.1016/j.jse.2015.02.004.

18. Thienpont E. Does Advanced Cryotherapy Reduce Pain and Narcotic Consumption After Knee Arthroplasty? Clin Orthop Relat Res. 2014;472(11):3417-3423. doi:10.1007/s11999-014-3810-8.

19. Woolf SK, Barfield WR, Merrill KD, McBryde AM Jr. Comparison of a continuous temperature-controlled cryotherapy device to a simple icing regimen following outpatient knee arthroscopy. J Knee Surg. 2008;21(1):15-19.

20. Su EP, Perna M, Boettner F, et al. A prospective, multi-center, randomised trial to evaluate the efficacy of a cryopneumatic device on total knee arthroplasty recovery. J Bone Joint Surg Br. 2012;94(11 Suppl A):153-156. doi:10.1302/0301-620X.94B11.30832.

21. Barber F. A comparison of crushed ice and continuous flow cold therapy. Am J Knee Surg. 2000;13(2):97-101.

22. Demoulin C, Brouwers M, Darot S, Gillet P, Crielaard JM, Vanderthommen M. Comparison of gaseous cryotherapy with more traditional forms of cryotherapy following total knee arthroplasty. Ann Phys Rehabil Med. 2012;55(4):229-240. doi:10.1016/j.rehab.2012.03.004.

23. Mumith A, Pavlou P, Barrett M, Thurston B, Garrett S. Enhancing postoperative rehabilitation following knee arthroplasty using a new cryotherapy product: a prospective study. Geriatr Orthop Surg Rehabil. 2015;6(4):316-321. doi:10.1177/2151458515609722.

24. Dickinson RN, Kuhn JE, Bergner JL, Rizzone KH. A systematic review of cost-effective treatment of postoperative rotator cuff repairs. J Shoulder Elb Surg. 2017;26(5):915-922. doi:10.1016/j.jse.2017.02.009.

25. Brown WC, Hahn DB. Frostbite of the Feet After Cryotherapy: A Report of Two Cases. J Foot Ankle Surg. 2009;48(5):577-580. doi:10.1053/j.jfas.2009.06.003.

26. Dundon JM, Rymer MC, Johnson RM. Total patellar skin loss from cryotherapy after total knee arthroplasty. J Arthroplasty. 2013;28(2):376.e5-e7. doi:10.1016/j.arth.2012.05.024.

27. Khajavi K, Pavelko T, Mishra A. Compartment syndrome arising from use of an electronic cooling pad. Am J Sports Med. 2004;32(6):1538-1541. doi:10.1177/0363546503262191.

28. King J, Plotner A, Adams B. Perniosis induced by a cold therapy system. Arch Dermatol. 2012;148(9):1101-1102.

29. Lee CK, Pardun J, Buntic R, Kiehn M, Brooks D, Buncke HJ. Severe frostbite of the knees after cryotherapy. Orthopedics. 2007;30(1):63-64.

30. McGuire DA, Hendricks SD. Incidences of frostbite in arthroscopic knee surgery postoperative cryotherapy rehabilitation. Arthroscopy. 2006;22(10):1141.e1-e6. doi:10.1016/j.arthro.2005.06.027.

31. Mirkin G. Why Ice Delays Recovery. http://www.drmirkin.com/fitness/why-ice-delays-recovery.html. Published September 16, 2015. Accessed July 17, 2017.

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TAKE-HOME POINTS

  • Cryotherapy is often used in postoperative orthopedic care but there is limited literature demonstrating its efficacy.
  • Postoperative cryotherapy has been used to reduce visual analog scale pain scores, analgesic consumption, and to increase range of motion.
  • There is no consensus on the advantages of postoperative cryotherapy vs traditional ice application.
  • Adverse outcomes from postoperative cryotherapy use include frostbite/skin loss, compartment syndrome, and perniosis.
  • Future studies, including a formidable economic analysis of advanced cold therapy systems are necessary before physicians prescribing cryotherapy can be confident that they are augmenting patient recovery.
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Implementing Patient-Reported Outcome Measures in Your Practice: Pearls and Pitfalls

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Take-Home Points

  • Systematic use of PROMs allows physicians to review data on pain, physical function, and psychological status to aid in clinical decision-making and best practices.
  • PROMs should include both general outcome measures (VAS, SF-36, or EQ-5D) and reliable, valid, and responsive disease specific measures.
  • PROM questionnaires should collect pertinent information while limiting the length to maximize patient compliance and reliability.
  • PROMIS has been developed to standardize questionnaires, but generality for specific orthopedic procedures may result in less effective measures.
  • PROMs can also be used for predictive modeling, which has the potential to help develop more cost-effective care and predict expected outcomes and recovery trajectories for individual patients.

Owing to their unique ability to recognize patients as stakeholders in their own healthcare, patient-reported outcome measures (PROMs) are becoming increasingly popular in the assessment of medical and surgical outcomes.1 PROMs are an outcome measures subset in which patients complete questionnaires about their perceptions of their overall health status and specific health limitations. By systematically using PROMs before and after a clearly defined episode of care, clinicians can collect data on perceived pain level, physical function, and psychological status and use the data to validate use of surgical procedures and shape clinical decisions about best practices.2-4 Although mortality and morbidity rates and other traditional measures are valuable in assessing outcomes, they do not represent or communicate the larger impact of an episode of care. As many orthopedic procedures are elective, and some are low-risk, the evaluation of changes in quality of life and self-reported functional improvement is an important addition to morbidity and mortality rates in capturing the true impact of a surgical procedure and recovery. The patient’s preoperative and postoperative perspectives on his or her health status have become important as well; our healthcare system has been placing more emphasis on patient-centered quality care.2,5

Although PROMs have many benefits, implementation in an orthopedic surgery practice has its challenges. With so many PROMs available, selecting those that fit the patient population for a specialized orthopedic surgery practice can be difficult. In addition, although PROM data are essential for research and for measuring individual or institutional recovery trajectories for surgical procedures, in a busy practice getting patients to provide these data can be difficult.

PROMs are heavily used for outcomes assessment in the orthopedics literature, but there are few resources for orthopedic surgeons who want to implement PROMs in their practices. In this article, we review the literature on the challenges of effectively implementing PROMs in an orthopedic surgery practice.

PROM Selection Considerations

PROMs can be categorized as either generic or disease-specific,4 but together they are used to adequately capture the impact, both broad and local, of an orthopedic condition.

Generic Outcome Measures

Generic outcome measures apply to a range of subspecialties or anatomical regions, allowing for evaluation of a patient’s overall health or quality of life. The most widely accepted measure of pain is the visual analog scale (VAS). The VAS for pain quantifies the level of pain a patient experiences at a given time on a graphic sliding scale from 0 (no pain) to 10 (worst possible pain). The VAS is used in clinical evaluation of pain and in reported outcomes literature.6,7

Many generic PROMs assess mental health status in addition to physical limitations. Poor preoperative mental health status has been recognized as a predictor of worse outcomes across a variety of orthopedic procedures.8,9 Therefore, to assess the overall influence of an orthopedic condition, it is important to include at least 1 generic PROM that assesses mental health status before and after an episode of care. Generic PROMs commonly used in orthopedic surgery include the 36-Item Short Form Health Survey (SF-36), the shorter SF-12, the Veterans RAND 12-Item Health Survey (VR-12), the World Health Organization Disability Assessment Schedule (WHODAS), the European Quality of Life-5 Dimensions (EQ-5D) index, and the 10-item Patient-Reported Outcomes Measurement Information System Global Health (PROMIS-10) scale.10-14

Some generic outcome measures (eg, the EQ-5D index) offer the “utility” calculation, which represents a preference for a patient’s desired health status. Such utilities allow for a measurement of quality of life, represented by quality-adjusted life years (QALY), which is a standardized measure of disease burden. Calculated QALY from measures such as the EQ-5D can be used in cost-effectiveness analyses of surgical interventions and have been used to validate use of procedures, particularly in arthroplasty.15-17

Disease-Specific Outcome Measures

Likewise, there is a range of disease-specific PROMs validated for use in orthopedic surgery, and providers select PROMs that fit their scope of practice. In anatomical regions such as the knee, hip, and shoulder, disease-specific outcome measures vary significantly by subspecialty and patient population. When selecting disease-specific PROMs, providers must consider tools such as reliability, validity, responsiveness, and available population norms. One study used Evaluating Measures of Patient-Reported Outcomes (EMPRO) to assess the quality of a PROM in shoulders and concluded that the American Shoulder and Elbow Surgeons (ASES) index, the Simple Shoulder Test (SST), and the Oxford Shoulder Score (OSS) were all supported for use in practice.18 It is important to note that reliability, validity, and responsiveness of a PROM may vary with the diagnosis or the patient population studied. For example, the SST was found to be responsive in assessing rotator cuff injury but not as useful in assessing shoulder instability or arthritis.19 Variable responsiveness highlights the need for a diagnosis-based level of PROM customization. For example, patients who undergo a surgical intervention for shoulder instability are given a customized survey, which includes PROMs specific to their condition, such as the Western Ontario Shoulder Instability (WOSI) index.20 For patients with knee instability, similar considerations apply; specific measures such as the Lysholm score and the Tenger Activity Scale capture the impact of injury in physically demanding activities.21 When selecting disease-specific PROMs, providers should consult articles like those by Davidson and Keating22 and Bent and colleagues,23 who present provider-friendly tools that can be used to examine the effectiveness of a PROM, and provide additional background information on selecting disease-specific PROMs. For hip and knee arthroplasty subspecialties, the International Society of Arthroplasty Registries (ISAR) created a working group that determines best practices for PROM collection and identifies PROMs most commonly reported in arthroplasty.24

Questionnaire Length Considerations

When PROMs are used in a practice, a balance must be struck between gathering enough information to determine functionality and limiting the patient burden of questionnaire length. A decision to use several PROMs all at once, at a single data collection point, can lengthen the questionnaire significantly. One study found that, with use of longer questionnaires, patients may lose interest, resulting in decreased reliability and compliance.25 For example, providers who use the long (42-item) Knee Injury and Osteoarthritis Outcome Score (KOOS) questionnaire to assess knee function are often limited in what other PROMs they may administer at the same time. Efforts to shorten this questionnaire while still capturing necessary information led to the development of the 7-item KOOS Jr, which was validated for use in knee arthroplasty and had its 7 items drawn from the original 42.26 Similarly, the 40-item Hip Disability and Osteoarthritis Outcome Score (HOOS) questionnaire was shortened to the 6-item HOOS Jr, which was validated for use in hip arthroplasty,27 and the generic SF-36 was shortened to the SF-12.11 Providers trying to build an outcomes database while minimizing patient burden should consider using the shorter versions of these questionnaires but should also consider their validity, as KOOS Jr and HOOS Jr have been validated for use only in knee and hip arthroplasty and not in other knee and hip conditions.

PROM Data Collection Considerations

Comprehensive collection of longitudinal PROM data poses many challenges for providers and patients. For providers, the greatest challenges are infrastructure, technology, and the personnel needed to administer and store paper or electronic surveys. For patients, the most common survey completion barriers are questionnaire length, confusing or irrelevant content, and, in the case of some older adults, inability to complete surveys electronically.25

Identifying a nonresponsive or noncompliant patient population is an important issue in collecting PROM data for research or other purposes. A study of factors associated with higher nonresponse rates in elective surgery patients (N = 135,474) found that noncompliance was higher for males, patients under age 55 years, nonwhites, patients in the lowest socioeconomic quintile, patients living alone, patients needing assistance in completing questionnaires, and patients who previously underwent surgery for their condition.28 In a systematic review of methods that increased the response rates of postal and electronic surveys, Edwards and colleagues29 found significantly higher odds of response for patients who were prenotified of the survey, given shorter questionnaires, or given a deadline for survey completion. Of note, response rates were lower when the word survey was used in the subject line of an email. 

PROM distribution has evolved with the rise of technological advances that allow for electronic survey distribution and data capture. Several studies have found that electronically administered PROMs have high response rates.3,30,31 In a study of patients who underwent total hip arthroplasty, Rolfson and colleagues32 found that response rates were significantly higher for those who were surveyed on paper than for those surveyed over the internet. A randomized controlled study found that, compared with paper surveys, digital tablet surveys effectively and reliably collected PROM data; in addition, digital tablets provided instant data storage, and improved survey completion by requiring that all questions be answered before the survey could be submitted.33 However, age, race/ethnicity, and income disparities in technology use must be considered when administering internet-based follow-up surveys and analyzing data collected with web-based methods.34 A study of total joint arthroplasty candidates found that several groups were less likely to complete electronic PROM questionnaires: patients over age 75 years, Hispanic or black patients, patients with Medicare or Medicaid, patients who previously underwent orthopedic surgery, patients undergoing revision total joint arthroplasty, patients with other comorbidities, and patients whose primary language was not English.35 Providers interested in implementing PROMs must consider their patient population when selecting a method for survey distribution and follow-up. A study found that a majority of PROMs were written at a level many patients may not have understood, because of their literacy level or age; this lack of understanding created a barrier to compliance in many patient populations.36

PROM Limitations and PROMIS Use

Use of PROMs has its limitations. The large variety of PROMs available for use in orthopedic surgery has led to several standardization initiatives. The National Institutes of Health funded the development of PROMIS, a person-centered measures database that evaluates and monitors the physical, social, and emotional health of adults and children.37 The goal of PROMIS is to develop a standardized method of selecting PROMs, so that all medical disciplines and subspecialties can choose an applicable set of questions from the PROMIS question bank and use it in practice. Orthopedic surgery can use questions pertaining to physical functioning of the lower and upper extremities as well as quality of life and mental health. PROMIS physical function questions have been validated for use in several areas of orthopedic surgery.38-40 A disadvantage of PROMIS is the overgenerality of its questions, which may not be as effective in capturing the implications of specific diagnoses. For example, it is difficult to use generalized questions to determine the implications of a diagnosis such as shoulder instability, which may affect only higher functioning activities or sports. More research on best PROM selection practices is needed in order to either standardize PROMs or move toward use of a single database such as PROMIS.

Future Directions in PROM Applications

PROMs are being used for research and patient engagement, but there are many other applications on the horizon. As already mentioned, predictive modeling is of particular interest. The existence of vast collaborative PROM databases that capture a diverse patient population introduces the possibility of creating models capable of predicting a patient outcome and enhancing shared decision-making.3 Predicting good or excellent patient outcomes for specific patient populations may allow elimination of certain postoperative visits, thereby creating more cost-effective care and reducing the burden of unnecessary clinic visits for both patients and physicians.

As with other healthcare areas, PROM data collection technology is rapidly advancing. Not only has electronic technology almost entirely replaced paper-and-pencil collection methods, but a new method of outcome data collection has been developed: computerized adaptive testing (CAT). CAT uses item-response theory to minimize the number of questions patients must answer in order for validated and reliable outcome scores to be calculated. According to multiple studies, CAT used across several questionnaires has reliably assessed PROMs while minimizing floor and ceiling effects, eliminating irrelevant questions, and shortening survey completion time.41-43

Besides becoming more patient-friendly and accessible across multiple interfaces (mobile devices and computers), PROMs are also beginning to be integrated into the electronic medical record, allowing easier access to information during chart reviews. Use of statistical and predictive modeling, as described by Chang,3 could give PROMs a role in clinical decision-making. Informing patients of their expected outcome and recovery trajectory—based on demographics, comorbidities, preoperative functional status, and other factors—could influence their decision to undergo surgical intervention. As Halawi and colleagues44 pointed out, it is important to discuss patient expectations before surgery, as unrealistic ones can negatively affect outcomes and lead to dissatisfaction. With clinicians having ready access to statistics and models in patient charts, we may see a transformation in clinical practices and surgical decision-making.

Conclusion

PROMs offer many ways to improve research and clinical care in orthopedic surgery. However, implementing PROMs in practice is not without challenges. Interested orthopedic surgeons should select the PROMs that are most appropriate—reliable, validated, and responsive to their patient population. Electronic distribution of PROM questionnaires is effective and allows data to be stored on entry, but orthopedic surgeons must consider their patient population to ensure accurate data capture and compliance in longitudinal surveys. Proper implementation of PROMs in a practice can allow clinicians to formulate expectations for postoperative recovery and set reasonable postoperative goals while engaging patients in improving quality of care.

References

1. Howie L, Hirsch B, Locklear T, Abernethy AP. Assessing the value of patient-generated data to comparative effectiveness research. Health Aff (Millwood). 2014;33(7):1220-1228.

2. Haywood KL. Patient-reported outcome I: measuring what matters in musculoskeletal care. Musculoskeletal Care. 2006;4(4):187-203.

3. Chang CH. Patient-reported outcomes measurement and management with innovative methodologies and technologies. Qual Life Res. 2007;16(suppl 1):157-166.

4. Black N. Patient reported outcome measures could help transform healthcare. BMJ. 2013;346:f167.

5. Porter ME. A strategy for health care reform—toward a value-based system. N Engl J Med. 2009;361(2):109-112.

6. Scott J, Huskisson EC. Graphic representation of pain. Pain. 1976;2(2):175-184.

7. de Nies F, Fidler MW. Visual analog scale for the assessment of total hip arthroplasty. J Arthroplasty. 1997;12(4):416-419.

8. Ayers DC, Franklin PD, Ring DC. The role of emotional health in functional outcomes after orthopaedic surgery: extending the biopsychosocial model to orthopaedics: AOA critical issues. J Bone Joint Surg Am. 2013;95(21):e165.

9. Edwards RR, Haythornthwaite JA, Smith MT, Klick B, Katz JN. Catastrophizing and depressive symptoms as prospective predictors of outcomes following total knee replacement. Pain Res Manag. 2009;14(4):307-311.

10. Patel AA, Donegan D, Albert T. The 36-Item Short Form. J Am Acad Orthop Surg. 2007;15(2):126-134.

11. Ware J Jr, Kosinski M, Keller SD. A 12-Item Short-Form Health Survey: construction of scales and preliminary tests of reliability and validity. Med Care. 1996;34(3):220-233.

12. About the VR-36, VR-12 and VR-6D. Boston University School of Public Health website. http://www.bu.edu/sph/research/research-landing-page/vr-36-vr-12-and-vr-6d/. Accessed October 4, 2017.

13. Jansson KA, Granath F. Health-related quality of life (EQ-5D) before and after orthopedic surgery. Acta Orthop. 2011;82(1):82-89.

14. Oak SR, Strnad GJ, Bena J, et al. Responsiveness comparison of the EQ-5D, PROMIS Global Health, and VR-12 questionnaires in knee arthroscopy. Orthop J Sports Med. 2016;4(12):2325967116674714.

15. Lavernia CJ, Iacobelli DA, Brooks L, Villa JM. The cost-utility of total hip arthroplasty: earlier intervention, improved economics. J Arthroplasty. 2015;30(6):945-949.

16. Mather RC 3rd, Watters TS, Orlando LA, Bolognesi MP, Moorman CT 3rd. Cost effectiveness analysis of hemiarthroplasty and total shoulder arthroplasty. J Shoulder Elbow Surg. 2010;19(3):325-334.

17. Brauer CA, Rosen AB, Olchanski NV, Neumann PJ. Cost-utility analyses in orthopaedic surgery. J Bone Joint Surg Am. 2005;87(6):1253-1259.

18. Schmidt S, Ferrer M, González M, et al; EMPRO Group. Evaluation of shoulder-specific patient-reported outcome measures: a systematic and standardized comparison of available evidence. J Shoulder Elbow Surg. 2014;23(3):434-444.

19. Godfrey J, Hamman R, Lowenstein S, Briggs K, Kocher M. Reliability, validity, and responsiveness of the Simple Shoulder Test: psychometric properties by age and injury type. J Shoulder Elbow Surg. 2007;16(3):260-267.

20. Kirkley A, Griffin S, McLintock H, Ng L. The development and evaluation of a disease-specific quality of life measurement tool for shoulder instability. The Western Ontario Shoulder Instability Index (WOSI). Am J Sports Med. 1998;26(6):764-772.

21. Briggs KK, Lysholm J, Tegner Y, Rodkey WG, Kocher MS, Steadman JR. The reliability, validity, and responsiveness of the Lysholm score and Tegner Activity Scale for anterior cruciate ligament injuries of the knee: 25 years later. Am J Sports Med. 2009;37(5):890-897.

22. Davidson M, Keating J. Patient-reported outcome measures (PROMs): how should I interpret reports of measurement properties? A practical guide for clinicians and researchers who are not biostatisticians. Br J Sports Med. 2014;48(9):792-796.

23. Bent NP, Wright CC, Rushton AB, Batt ME. Selecting outcome measures in sports medicine: a guide for practitioners using the example of anterior cruciate ligament rehabilitation. Br J Sports Med. 2009;43(13):1006-1012.

24. Rolfson O, Eresian Chenok K, Bohm E, et al; Patient-Reported Outcome Measures Working Group of the International Society of Arthroplasty Registries. Patient-reported outcome measures in arthroplasty registries. Acta Orthop. 2016;87(suppl 1):3-8.

25. Franklin PD, Lewallen D, Bozic K, Hallstrom B, Jiranek W, Ayers DC. Implementation of patient-reported outcome measures in U.S. total joint replacement registries: rationale, status, and plans. J Bone Joint Surg Am. 2014;96(suppl 1):104-109.

26. Lyman S, Lee YY, Franklin PD, Li W, Cross MB, Padgett DE. Validation of the KOOS, JR: a short-form knee arthroplasty outcomes survey. Clin Orthop Relat Res. 2016;474(6):1461-1471.

27. Lyman S, Lee YY, Franklin PD, Li W, Mayman DJ, Padgett DE. Validation of the HOOS, JR: a short-form hip replacement survey. Clin Orthop Relat Res. 2016;474(6):1472-1482.

28. Hutchings A, Neuburger J, Grosse Frie K, Black N, van der Meulen J. Factors associated with non-response in routine use of patient reported outcome measures after elective surgery in England. Health Qual Life Outcomes. 2012;10:34.

29. Edwards PJ, Roberts I, Clarke MJ, et al. Methods to increase response to postal and electronic questionnaires. Cochrane Database Syst Rev. 2009;(3):MR000008.

30. Gakhar H, McConnell B, Apostolopoulos AP, Lewis P. A pilot study investigating the use of at-home, web-based questionnaires compiling patient-reported outcome measures following total hip and knee replacement surgeries. J Long Term Eff Med Implants. 2013;23(1):39-43.

31. Bojcic JL, Sue VM, Huon TS, Maletis GB, Inacio MC. Comparison of paper and electronic surveys for measuring patient-reported outcomes after anterior cruciate ligament reconstruction. Perm J. 2014;18(3):22-26.

32. Rolfson O, Salomonsson R, Dahlberg LE, Garellick G. Internet-based follow-up questionnaire for measuring patient-reported outcome after total hip replacement surgery—reliability and response rate. Value Health. 2011;14(2):316-321.

33. Shah KN, Hofmann MR, Schwarzkopf R, et al. Patient-reported outcome measures: how do digital tablets stack up to paper forms? A randomized, controlled study. Am J Orthop. 2016;45(7):E451-E457.

34. Kaiser Family Foundation. The Digital Divide and Access to Health Information Online. http://kff.org/disparities-policy/poll-finding/the-digital-divide-and-access-to-health/. Published April 1, 2011. Accessed October 4, 2017.

35. Schamber EM, Takemoto SK, Chenok KE, Bozic KJ. Barriers to completion of patient reported outcome measures. J Arthroplasty. 2013;28(9):1449-1453.

36. El-Daly I, Ibraheim H, Rajakulendran K, Culpan P, Bates P. Are patient-reported outcome measures in orthopaedics easily read by patients? Clin Orthop Relat Res. 2016;474(1):246-255.

37. Intro to PROMIS. 2016. Health Measures website. http://www.healthmeasures.net/explore-measurement-systems/promis/intro-to-promis. Accessed October 4, 2017.

38. Hung M, Baumhauer JF, Latt LD, Saltzman CL, SooHoo NF, Hunt KJ; National Orthopaedic Foot & Ankle Outcomes Research Network. Validation of PROMIS ® Physical Function computerized adaptive tests for orthopaedic foot and ankle outcome research. Clin Orthop Relat Res. 2013;471(11):3466-3474.

39. Hung M, Clegg DO, Greene T, Saltzman CL. Evaluation of the PROMIS Physical Function item bank in orthopaedic patients. J Orthop Res. 2011;29(6):947-953.

40. Tyser AR, Beckmann J, Franklin JD, et al. Evaluation of the PROMIS Physical Function computer adaptive test in the upper extremity. J Hand Surg Am. 2014;39(10):2047-2051.e4.

41. Hung M, Stuart AR, Higgins TF, Saltzman CL, Kubiak EN. Computerized adaptive testing using the PROMIS Physical Function item bank reduces test burden with less ceiling effects compared with the Short Musculoskeletal Function Assessment in orthopaedic trauma patients. J Orthop Trauma. 2014;28(8):439-443.

42. Hung M, Clegg DO, Greene T, Weir C, Saltzman CL. A lower extremity physical function computerized adaptive testing instrument for orthopaedic patients. Foot Ankle Int. 2012;33(4):326-335.

43. Döring AC, Nota SP, Hageman MG, Ring DC. Measurement of upper extremity disability using the Patient-Reported Outcomes Measurement Information System. J Hand Surg Am. 2014;39(6):1160-1165.

44. Halawi MJ, Greene K, Barsoum WK. Optimizing outcomes of total joint arthroplasty under the comprehensive care for joint replacement model. Am J Orthop. 2016;45(3):E112-E113.

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Take-Home Points

  • Systematic use of PROMs allows physicians to review data on pain, physical function, and psychological status to aid in clinical decision-making and best practices.
  • PROMs should include both general outcome measures (VAS, SF-36, or EQ-5D) and reliable, valid, and responsive disease specific measures.
  • PROM questionnaires should collect pertinent information while limiting the length to maximize patient compliance and reliability.
  • PROMIS has been developed to standardize questionnaires, but generality for specific orthopedic procedures may result in less effective measures.
  • PROMs can also be used for predictive modeling, which has the potential to help develop more cost-effective care and predict expected outcomes and recovery trajectories for individual patients.

Owing to their unique ability to recognize patients as stakeholders in their own healthcare, patient-reported outcome measures (PROMs) are becoming increasingly popular in the assessment of medical and surgical outcomes.1 PROMs are an outcome measures subset in which patients complete questionnaires about their perceptions of their overall health status and specific health limitations. By systematically using PROMs before and after a clearly defined episode of care, clinicians can collect data on perceived pain level, physical function, and psychological status and use the data to validate use of surgical procedures and shape clinical decisions about best practices.2-4 Although mortality and morbidity rates and other traditional measures are valuable in assessing outcomes, they do not represent or communicate the larger impact of an episode of care. As many orthopedic procedures are elective, and some are low-risk, the evaluation of changes in quality of life and self-reported functional improvement is an important addition to morbidity and mortality rates in capturing the true impact of a surgical procedure and recovery. The patient’s preoperative and postoperative perspectives on his or her health status have become important as well; our healthcare system has been placing more emphasis on patient-centered quality care.2,5

Although PROMs have many benefits, implementation in an orthopedic surgery practice has its challenges. With so many PROMs available, selecting those that fit the patient population for a specialized orthopedic surgery practice can be difficult. In addition, although PROM data are essential for research and for measuring individual or institutional recovery trajectories for surgical procedures, in a busy practice getting patients to provide these data can be difficult.

PROMs are heavily used for outcomes assessment in the orthopedics literature, but there are few resources for orthopedic surgeons who want to implement PROMs in their practices. In this article, we review the literature on the challenges of effectively implementing PROMs in an orthopedic surgery practice.

PROM Selection Considerations

PROMs can be categorized as either generic or disease-specific,4 but together they are used to adequately capture the impact, both broad and local, of an orthopedic condition.

Generic Outcome Measures

Generic outcome measures apply to a range of subspecialties or anatomical regions, allowing for evaluation of a patient’s overall health or quality of life. The most widely accepted measure of pain is the visual analog scale (VAS). The VAS for pain quantifies the level of pain a patient experiences at a given time on a graphic sliding scale from 0 (no pain) to 10 (worst possible pain). The VAS is used in clinical evaluation of pain and in reported outcomes literature.6,7

Many generic PROMs assess mental health status in addition to physical limitations. Poor preoperative mental health status has been recognized as a predictor of worse outcomes across a variety of orthopedic procedures.8,9 Therefore, to assess the overall influence of an orthopedic condition, it is important to include at least 1 generic PROM that assesses mental health status before and after an episode of care. Generic PROMs commonly used in orthopedic surgery include the 36-Item Short Form Health Survey (SF-36), the shorter SF-12, the Veterans RAND 12-Item Health Survey (VR-12), the World Health Organization Disability Assessment Schedule (WHODAS), the European Quality of Life-5 Dimensions (EQ-5D) index, and the 10-item Patient-Reported Outcomes Measurement Information System Global Health (PROMIS-10) scale.10-14

Some generic outcome measures (eg, the EQ-5D index) offer the “utility” calculation, which represents a preference for a patient’s desired health status. Such utilities allow for a measurement of quality of life, represented by quality-adjusted life years (QALY), which is a standardized measure of disease burden. Calculated QALY from measures such as the EQ-5D can be used in cost-effectiveness analyses of surgical interventions and have been used to validate use of procedures, particularly in arthroplasty.15-17

Disease-Specific Outcome Measures

Likewise, there is a range of disease-specific PROMs validated for use in orthopedic surgery, and providers select PROMs that fit their scope of practice. In anatomical regions such as the knee, hip, and shoulder, disease-specific outcome measures vary significantly by subspecialty and patient population. When selecting disease-specific PROMs, providers must consider tools such as reliability, validity, responsiveness, and available population norms. One study used Evaluating Measures of Patient-Reported Outcomes (EMPRO) to assess the quality of a PROM in shoulders and concluded that the American Shoulder and Elbow Surgeons (ASES) index, the Simple Shoulder Test (SST), and the Oxford Shoulder Score (OSS) were all supported for use in practice.18 It is important to note that reliability, validity, and responsiveness of a PROM may vary with the diagnosis or the patient population studied. For example, the SST was found to be responsive in assessing rotator cuff injury but not as useful in assessing shoulder instability or arthritis.19 Variable responsiveness highlights the need for a diagnosis-based level of PROM customization. For example, patients who undergo a surgical intervention for shoulder instability are given a customized survey, which includes PROMs specific to their condition, such as the Western Ontario Shoulder Instability (WOSI) index.20 For patients with knee instability, similar considerations apply; specific measures such as the Lysholm score and the Tenger Activity Scale capture the impact of injury in physically demanding activities.21 When selecting disease-specific PROMs, providers should consult articles like those by Davidson and Keating22 and Bent and colleagues,23 who present provider-friendly tools that can be used to examine the effectiveness of a PROM, and provide additional background information on selecting disease-specific PROMs. For hip and knee arthroplasty subspecialties, the International Society of Arthroplasty Registries (ISAR) created a working group that determines best practices for PROM collection and identifies PROMs most commonly reported in arthroplasty.24

Questionnaire Length Considerations

When PROMs are used in a practice, a balance must be struck between gathering enough information to determine functionality and limiting the patient burden of questionnaire length. A decision to use several PROMs all at once, at a single data collection point, can lengthen the questionnaire significantly. One study found that, with use of longer questionnaires, patients may lose interest, resulting in decreased reliability and compliance.25 For example, providers who use the long (42-item) Knee Injury and Osteoarthritis Outcome Score (KOOS) questionnaire to assess knee function are often limited in what other PROMs they may administer at the same time. Efforts to shorten this questionnaire while still capturing necessary information led to the development of the 7-item KOOS Jr, which was validated for use in knee arthroplasty and had its 7 items drawn from the original 42.26 Similarly, the 40-item Hip Disability and Osteoarthritis Outcome Score (HOOS) questionnaire was shortened to the 6-item HOOS Jr, which was validated for use in hip arthroplasty,27 and the generic SF-36 was shortened to the SF-12.11 Providers trying to build an outcomes database while minimizing patient burden should consider using the shorter versions of these questionnaires but should also consider their validity, as KOOS Jr and HOOS Jr have been validated for use only in knee and hip arthroplasty and not in other knee and hip conditions.

PROM Data Collection Considerations

Comprehensive collection of longitudinal PROM data poses many challenges for providers and patients. For providers, the greatest challenges are infrastructure, technology, and the personnel needed to administer and store paper or electronic surveys. For patients, the most common survey completion barriers are questionnaire length, confusing or irrelevant content, and, in the case of some older adults, inability to complete surveys electronically.25

Identifying a nonresponsive or noncompliant patient population is an important issue in collecting PROM data for research or other purposes. A study of factors associated with higher nonresponse rates in elective surgery patients (N = 135,474) found that noncompliance was higher for males, patients under age 55 years, nonwhites, patients in the lowest socioeconomic quintile, patients living alone, patients needing assistance in completing questionnaires, and patients who previously underwent surgery for their condition.28 In a systematic review of methods that increased the response rates of postal and electronic surveys, Edwards and colleagues29 found significantly higher odds of response for patients who were prenotified of the survey, given shorter questionnaires, or given a deadline for survey completion. Of note, response rates were lower when the word survey was used in the subject line of an email. 

PROM distribution has evolved with the rise of technological advances that allow for electronic survey distribution and data capture. Several studies have found that electronically administered PROMs have high response rates.3,30,31 In a study of patients who underwent total hip arthroplasty, Rolfson and colleagues32 found that response rates were significantly higher for those who were surveyed on paper than for those surveyed over the internet. A randomized controlled study found that, compared with paper surveys, digital tablet surveys effectively and reliably collected PROM data; in addition, digital tablets provided instant data storage, and improved survey completion by requiring that all questions be answered before the survey could be submitted.33 However, age, race/ethnicity, and income disparities in technology use must be considered when administering internet-based follow-up surveys and analyzing data collected with web-based methods.34 A study of total joint arthroplasty candidates found that several groups were less likely to complete electronic PROM questionnaires: patients over age 75 years, Hispanic or black patients, patients with Medicare or Medicaid, patients who previously underwent orthopedic surgery, patients undergoing revision total joint arthroplasty, patients with other comorbidities, and patients whose primary language was not English.35 Providers interested in implementing PROMs must consider their patient population when selecting a method for survey distribution and follow-up. A study found that a majority of PROMs were written at a level many patients may not have understood, because of their literacy level or age; this lack of understanding created a barrier to compliance in many patient populations.36

PROM Limitations and PROMIS Use

Use of PROMs has its limitations. The large variety of PROMs available for use in orthopedic surgery has led to several standardization initiatives. The National Institutes of Health funded the development of PROMIS, a person-centered measures database that evaluates and monitors the physical, social, and emotional health of adults and children.37 The goal of PROMIS is to develop a standardized method of selecting PROMs, so that all medical disciplines and subspecialties can choose an applicable set of questions from the PROMIS question bank and use it in practice. Orthopedic surgery can use questions pertaining to physical functioning of the lower and upper extremities as well as quality of life and mental health. PROMIS physical function questions have been validated for use in several areas of orthopedic surgery.38-40 A disadvantage of PROMIS is the overgenerality of its questions, which may not be as effective in capturing the implications of specific diagnoses. For example, it is difficult to use generalized questions to determine the implications of a diagnosis such as shoulder instability, which may affect only higher functioning activities or sports. More research on best PROM selection practices is needed in order to either standardize PROMs or move toward use of a single database such as PROMIS.

Future Directions in PROM Applications

PROMs are being used for research and patient engagement, but there are many other applications on the horizon. As already mentioned, predictive modeling is of particular interest. The existence of vast collaborative PROM databases that capture a diverse patient population introduces the possibility of creating models capable of predicting a patient outcome and enhancing shared decision-making.3 Predicting good or excellent patient outcomes for specific patient populations may allow elimination of certain postoperative visits, thereby creating more cost-effective care and reducing the burden of unnecessary clinic visits for both patients and physicians.

As with other healthcare areas, PROM data collection technology is rapidly advancing. Not only has electronic technology almost entirely replaced paper-and-pencil collection methods, but a new method of outcome data collection has been developed: computerized adaptive testing (CAT). CAT uses item-response theory to minimize the number of questions patients must answer in order for validated and reliable outcome scores to be calculated. According to multiple studies, CAT used across several questionnaires has reliably assessed PROMs while minimizing floor and ceiling effects, eliminating irrelevant questions, and shortening survey completion time.41-43

Besides becoming more patient-friendly and accessible across multiple interfaces (mobile devices and computers), PROMs are also beginning to be integrated into the electronic medical record, allowing easier access to information during chart reviews. Use of statistical and predictive modeling, as described by Chang,3 could give PROMs a role in clinical decision-making. Informing patients of their expected outcome and recovery trajectory—based on demographics, comorbidities, preoperative functional status, and other factors—could influence their decision to undergo surgical intervention. As Halawi and colleagues44 pointed out, it is important to discuss patient expectations before surgery, as unrealistic ones can negatively affect outcomes and lead to dissatisfaction. With clinicians having ready access to statistics and models in patient charts, we may see a transformation in clinical practices and surgical decision-making.

Conclusion

PROMs offer many ways to improve research and clinical care in orthopedic surgery. However, implementing PROMs in practice is not without challenges. Interested orthopedic surgeons should select the PROMs that are most appropriate—reliable, validated, and responsive to their patient population. Electronic distribution of PROM questionnaires is effective and allows data to be stored on entry, but orthopedic surgeons must consider their patient population to ensure accurate data capture and compliance in longitudinal surveys. Proper implementation of PROMs in a practice can allow clinicians to formulate expectations for postoperative recovery and set reasonable postoperative goals while engaging patients in improving quality of care.

Take-Home Points

  • Systematic use of PROMs allows physicians to review data on pain, physical function, and psychological status to aid in clinical decision-making and best practices.
  • PROMs should include both general outcome measures (VAS, SF-36, or EQ-5D) and reliable, valid, and responsive disease specific measures.
  • PROM questionnaires should collect pertinent information while limiting the length to maximize patient compliance and reliability.
  • PROMIS has been developed to standardize questionnaires, but generality for specific orthopedic procedures may result in less effective measures.
  • PROMs can also be used for predictive modeling, which has the potential to help develop more cost-effective care and predict expected outcomes and recovery trajectories for individual patients.

Owing to their unique ability to recognize patients as stakeholders in their own healthcare, patient-reported outcome measures (PROMs) are becoming increasingly popular in the assessment of medical and surgical outcomes.1 PROMs are an outcome measures subset in which patients complete questionnaires about their perceptions of their overall health status and specific health limitations. By systematically using PROMs before and after a clearly defined episode of care, clinicians can collect data on perceived pain level, physical function, and psychological status and use the data to validate use of surgical procedures and shape clinical decisions about best practices.2-4 Although mortality and morbidity rates and other traditional measures are valuable in assessing outcomes, they do not represent or communicate the larger impact of an episode of care. As many orthopedic procedures are elective, and some are low-risk, the evaluation of changes in quality of life and self-reported functional improvement is an important addition to morbidity and mortality rates in capturing the true impact of a surgical procedure and recovery. The patient’s preoperative and postoperative perspectives on his or her health status have become important as well; our healthcare system has been placing more emphasis on patient-centered quality care.2,5

Although PROMs have many benefits, implementation in an orthopedic surgery practice has its challenges. With so many PROMs available, selecting those that fit the patient population for a specialized orthopedic surgery practice can be difficult. In addition, although PROM data are essential for research and for measuring individual or institutional recovery trajectories for surgical procedures, in a busy practice getting patients to provide these data can be difficult.

PROMs are heavily used for outcomes assessment in the orthopedics literature, but there are few resources for orthopedic surgeons who want to implement PROMs in their practices. In this article, we review the literature on the challenges of effectively implementing PROMs in an orthopedic surgery practice.

PROM Selection Considerations

PROMs can be categorized as either generic or disease-specific,4 but together they are used to adequately capture the impact, both broad and local, of an orthopedic condition.

Generic Outcome Measures

Generic outcome measures apply to a range of subspecialties or anatomical regions, allowing for evaluation of a patient’s overall health or quality of life. The most widely accepted measure of pain is the visual analog scale (VAS). The VAS for pain quantifies the level of pain a patient experiences at a given time on a graphic sliding scale from 0 (no pain) to 10 (worst possible pain). The VAS is used in clinical evaluation of pain and in reported outcomes literature.6,7

Many generic PROMs assess mental health status in addition to physical limitations. Poor preoperative mental health status has been recognized as a predictor of worse outcomes across a variety of orthopedic procedures.8,9 Therefore, to assess the overall influence of an orthopedic condition, it is important to include at least 1 generic PROM that assesses mental health status before and after an episode of care. Generic PROMs commonly used in orthopedic surgery include the 36-Item Short Form Health Survey (SF-36), the shorter SF-12, the Veterans RAND 12-Item Health Survey (VR-12), the World Health Organization Disability Assessment Schedule (WHODAS), the European Quality of Life-5 Dimensions (EQ-5D) index, and the 10-item Patient-Reported Outcomes Measurement Information System Global Health (PROMIS-10) scale.10-14

Some generic outcome measures (eg, the EQ-5D index) offer the “utility” calculation, which represents a preference for a patient’s desired health status. Such utilities allow for a measurement of quality of life, represented by quality-adjusted life years (QALY), which is a standardized measure of disease burden. Calculated QALY from measures such as the EQ-5D can be used in cost-effectiveness analyses of surgical interventions and have been used to validate use of procedures, particularly in arthroplasty.15-17

Disease-Specific Outcome Measures

Likewise, there is a range of disease-specific PROMs validated for use in orthopedic surgery, and providers select PROMs that fit their scope of practice. In anatomical regions such as the knee, hip, and shoulder, disease-specific outcome measures vary significantly by subspecialty and patient population. When selecting disease-specific PROMs, providers must consider tools such as reliability, validity, responsiveness, and available population norms. One study used Evaluating Measures of Patient-Reported Outcomes (EMPRO) to assess the quality of a PROM in shoulders and concluded that the American Shoulder and Elbow Surgeons (ASES) index, the Simple Shoulder Test (SST), and the Oxford Shoulder Score (OSS) were all supported for use in practice.18 It is important to note that reliability, validity, and responsiveness of a PROM may vary with the diagnosis or the patient population studied. For example, the SST was found to be responsive in assessing rotator cuff injury but not as useful in assessing shoulder instability or arthritis.19 Variable responsiveness highlights the need for a diagnosis-based level of PROM customization. For example, patients who undergo a surgical intervention for shoulder instability are given a customized survey, which includes PROMs specific to their condition, such as the Western Ontario Shoulder Instability (WOSI) index.20 For patients with knee instability, similar considerations apply; specific measures such as the Lysholm score and the Tenger Activity Scale capture the impact of injury in physically demanding activities.21 When selecting disease-specific PROMs, providers should consult articles like those by Davidson and Keating22 and Bent and colleagues,23 who present provider-friendly tools that can be used to examine the effectiveness of a PROM, and provide additional background information on selecting disease-specific PROMs. For hip and knee arthroplasty subspecialties, the International Society of Arthroplasty Registries (ISAR) created a working group that determines best practices for PROM collection and identifies PROMs most commonly reported in arthroplasty.24

Questionnaire Length Considerations

When PROMs are used in a practice, a balance must be struck between gathering enough information to determine functionality and limiting the patient burden of questionnaire length. A decision to use several PROMs all at once, at a single data collection point, can lengthen the questionnaire significantly. One study found that, with use of longer questionnaires, patients may lose interest, resulting in decreased reliability and compliance.25 For example, providers who use the long (42-item) Knee Injury and Osteoarthritis Outcome Score (KOOS) questionnaire to assess knee function are often limited in what other PROMs they may administer at the same time. Efforts to shorten this questionnaire while still capturing necessary information led to the development of the 7-item KOOS Jr, which was validated for use in knee arthroplasty and had its 7 items drawn from the original 42.26 Similarly, the 40-item Hip Disability and Osteoarthritis Outcome Score (HOOS) questionnaire was shortened to the 6-item HOOS Jr, which was validated for use in hip arthroplasty,27 and the generic SF-36 was shortened to the SF-12.11 Providers trying to build an outcomes database while minimizing patient burden should consider using the shorter versions of these questionnaires but should also consider their validity, as KOOS Jr and HOOS Jr have been validated for use only in knee and hip arthroplasty and not in other knee and hip conditions.

PROM Data Collection Considerations

Comprehensive collection of longitudinal PROM data poses many challenges for providers and patients. For providers, the greatest challenges are infrastructure, technology, and the personnel needed to administer and store paper or electronic surveys. For patients, the most common survey completion barriers are questionnaire length, confusing or irrelevant content, and, in the case of some older adults, inability to complete surveys electronically.25

Identifying a nonresponsive or noncompliant patient population is an important issue in collecting PROM data for research or other purposes. A study of factors associated with higher nonresponse rates in elective surgery patients (N = 135,474) found that noncompliance was higher for males, patients under age 55 years, nonwhites, patients in the lowest socioeconomic quintile, patients living alone, patients needing assistance in completing questionnaires, and patients who previously underwent surgery for their condition.28 In a systematic review of methods that increased the response rates of postal and electronic surveys, Edwards and colleagues29 found significantly higher odds of response for patients who were prenotified of the survey, given shorter questionnaires, or given a deadline for survey completion. Of note, response rates were lower when the word survey was used in the subject line of an email. 

PROM distribution has evolved with the rise of technological advances that allow for electronic survey distribution and data capture. Several studies have found that electronically administered PROMs have high response rates.3,30,31 In a study of patients who underwent total hip arthroplasty, Rolfson and colleagues32 found that response rates were significantly higher for those who were surveyed on paper than for those surveyed over the internet. A randomized controlled study found that, compared with paper surveys, digital tablet surveys effectively and reliably collected PROM data; in addition, digital tablets provided instant data storage, and improved survey completion by requiring that all questions be answered before the survey could be submitted.33 However, age, race/ethnicity, and income disparities in technology use must be considered when administering internet-based follow-up surveys and analyzing data collected with web-based methods.34 A study of total joint arthroplasty candidates found that several groups were less likely to complete electronic PROM questionnaires: patients over age 75 years, Hispanic or black patients, patients with Medicare or Medicaid, patients who previously underwent orthopedic surgery, patients undergoing revision total joint arthroplasty, patients with other comorbidities, and patients whose primary language was not English.35 Providers interested in implementing PROMs must consider their patient population when selecting a method for survey distribution and follow-up. A study found that a majority of PROMs were written at a level many patients may not have understood, because of their literacy level or age; this lack of understanding created a barrier to compliance in many patient populations.36

PROM Limitations and PROMIS Use

Use of PROMs has its limitations. The large variety of PROMs available for use in orthopedic surgery has led to several standardization initiatives. The National Institutes of Health funded the development of PROMIS, a person-centered measures database that evaluates and monitors the physical, social, and emotional health of adults and children.37 The goal of PROMIS is to develop a standardized method of selecting PROMs, so that all medical disciplines and subspecialties can choose an applicable set of questions from the PROMIS question bank and use it in practice. Orthopedic surgery can use questions pertaining to physical functioning of the lower and upper extremities as well as quality of life and mental health. PROMIS physical function questions have been validated for use in several areas of orthopedic surgery.38-40 A disadvantage of PROMIS is the overgenerality of its questions, which may not be as effective in capturing the implications of specific diagnoses. For example, it is difficult to use generalized questions to determine the implications of a diagnosis such as shoulder instability, which may affect only higher functioning activities or sports. More research on best PROM selection practices is needed in order to either standardize PROMs or move toward use of a single database such as PROMIS.

Future Directions in PROM Applications

PROMs are being used for research and patient engagement, but there are many other applications on the horizon. As already mentioned, predictive modeling is of particular interest. The existence of vast collaborative PROM databases that capture a diverse patient population introduces the possibility of creating models capable of predicting a patient outcome and enhancing shared decision-making.3 Predicting good or excellent patient outcomes for specific patient populations may allow elimination of certain postoperative visits, thereby creating more cost-effective care and reducing the burden of unnecessary clinic visits for both patients and physicians.

As with other healthcare areas, PROM data collection technology is rapidly advancing. Not only has electronic technology almost entirely replaced paper-and-pencil collection methods, but a new method of outcome data collection has been developed: computerized adaptive testing (CAT). CAT uses item-response theory to minimize the number of questions patients must answer in order for validated and reliable outcome scores to be calculated. According to multiple studies, CAT used across several questionnaires has reliably assessed PROMs while minimizing floor and ceiling effects, eliminating irrelevant questions, and shortening survey completion time.41-43

Besides becoming more patient-friendly and accessible across multiple interfaces (mobile devices and computers), PROMs are also beginning to be integrated into the electronic medical record, allowing easier access to information during chart reviews. Use of statistical and predictive modeling, as described by Chang,3 could give PROMs a role in clinical decision-making. Informing patients of their expected outcome and recovery trajectory—based on demographics, comorbidities, preoperative functional status, and other factors—could influence their decision to undergo surgical intervention. As Halawi and colleagues44 pointed out, it is important to discuss patient expectations before surgery, as unrealistic ones can negatively affect outcomes and lead to dissatisfaction. With clinicians having ready access to statistics and models in patient charts, we may see a transformation in clinical practices and surgical decision-making.

Conclusion

PROMs offer many ways to improve research and clinical care in orthopedic surgery. However, implementing PROMs in practice is not without challenges. Interested orthopedic surgeons should select the PROMs that are most appropriate—reliable, validated, and responsive to their patient population. Electronic distribution of PROM questionnaires is effective and allows data to be stored on entry, but orthopedic surgeons must consider their patient population to ensure accurate data capture and compliance in longitudinal surveys. Proper implementation of PROMs in a practice can allow clinicians to formulate expectations for postoperative recovery and set reasonable postoperative goals while engaging patients in improving quality of care.

References

1. Howie L, Hirsch B, Locklear T, Abernethy AP. Assessing the value of patient-generated data to comparative effectiveness research. Health Aff (Millwood). 2014;33(7):1220-1228.

2. Haywood KL. Patient-reported outcome I: measuring what matters in musculoskeletal care. Musculoskeletal Care. 2006;4(4):187-203.

3. Chang CH. Patient-reported outcomes measurement and management with innovative methodologies and technologies. Qual Life Res. 2007;16(suppl 1):157-166.

4. Black N. Patient reported outcome measures could help transform healthcare. BMJ. 2013;346:f167.

5. Porter ME. A strategy for health care reform—toward a value-based system. N Engl J Med. 2009;361(2):109-112.

6. Scott J, Huskisson EC. Graphic representation of pain. Pain. 1976;2(2):175-184.

7. de Nies F, Fidler MW. Visual analog scale for the assessment of total hip arthroplasty. J Arthroplasty. 1997;12(4):416-419.

8. Ayers DC, Franklin PD, Ring DC. The role of emotional health in functional outcomes after orthopaedic surgery: extending the biopsychosocial model to orthopaedics: AOA critical issues. J Bone Joint Surg Am. 2013;95(21):e165.

9. Edwards RR, Haythornthwaite JA, Smith MT, Klick B, Katz JN. Catastrophizing and depressive symptoms as prospective predictors of outcomes following total knee replacement. Pain Res Manag. 2009;14(4):307-311.

10. Patel AA, Donegan D, Albert T. The 36-Item Short Form. J Am Acad Orthop Surg. 2007;15(2):126-134.

11. Ware J Jr, Kosinski M, Keller SD. A 12-Item Short-Form Health Survey: construction of scales and preliminary tests of reliability and validity. Med Care. 1996;34(3):220-233.

12. About the VR-36, VR-12 and VR-6D. Boston University School of Public Health website. http://www.bu.edu/sph/research/research-landing-page/vr-36-vr-12-and-vr-6d/. Accessed October 4, 2017.

13. Jansson KA, Granath F. Health-related quality of life (EQ-5D) before and after orthopedic surgery. Acta Orthop. 2011;82(1):82-89.

14. Oak SR, Strnad GJ, Bena J, et al. Responsiveness comparison of the EQ-5D, PROMIS Global Health, and VR-12 questionnaires in knee arthroscopy. Orthop J Sports Med. 2016;4(12):2325967116674714.

15. Lavernia CJ, Iacobelli DA, Brooks L, Villa JM. The cost-utility of total hip arthroplasty: earlier intervention, improved economics. J Arthroplasty. 2015;30(6):945-949.

16. Mather RC 3rd, Watters TS, Orlando LA, Bolognesi MP, Moorman CT 3rd. Cost effectiveness analysis of hemiarthroplasty and total shoulder arthroplasty. J Shoulder Elbow Surg. 2010;19(3):325-334.

17. Brauer CA, Rosen AB, Olchanski NV, Neumann PJ. Cost-utility analyses in orthopaedic surgery. J Bone Joint Surg Am. 2005;87(6):1253-1259.

18. Schmidt S, Ferrer M, González M, et al; EMPRO Group. Evaluation of shoulder-specific patient-reported outcome measures: a systematic and standardized comparison of available evidence. J Shoulder Elbow Surg. 2014;23(3):434-444.

19. Godfrey J, Hamman R, Lowenstein S, Briggs K, Kocher M. Reliability, validity, and responsiveness of the Simple Shoulder Test: psychometric properties by age and injury type. J Shoulder Elbow Surg. 2007;16(3):260-267.

20. Kirkley A, Griffin S, McLintock H, Ng L. The development and evaluation of a disease-specific quality of life measurement tool for shoulder instability. The Western Ontario Shoulder Instability Index (WOSI). Am J Sports Med. 1998;26(6):764-772.

21. Briggs KK, Lysholm J, Tegner Y, Rodkey WG, Kocher MS, Steadman JR. The reliability, validity, and responsiveness of the Lysholm score and Tegner Activity Scale for anterior cruciate ligament injuries of the knee: 25 years later. Am J Sports Med. 2009;37(5):890-897.

22. Davidson M, Keating J. Patient-reported outcome measures (PROMs): how should I interpret reports of measurement properties? A practical guide for clinicians and researchers who are not biostatisticians. Br J Sports Med. 2014;48(9):792-796.

23. Bent NP, Wright CC, Rushton AB, Batt ME. Selecting outcome measures in sports medicine: a guide for practitioners using the example of anterior cruciate ligament rehabilitation. Br J Sports Med. 2009;43(13):1006-1012.

24. Rolfson O, Eresian Chenok K, Bohm E, et al; Patient-Reported Outcome Measures Working Group of the International Society of Arthroplasty Registries. Patient-reported outcome measures in arthroplasty registries. Acta Orthop. 2016;87(suppl 1):3-8.

25. Franklin PD, Lewallen D, Bozic K, Hallstrom B, Jiranek W, Ayers DC. Implementation of patient-reported outcome measures in U.S. total joint replacement registries: rationale, status, and plans. J Bone Joint Surg Am. 2014;96(suppl 1):104-109.

26. Lyman S, Lee YY, Franklin PD, Li W, Cross MB, Padgett DE. Validation of the KOOS, JR: a short-form knee arthroplasty outcomes survey. Clin Orthop Relat Res. 2016;474(6):1461-1471.

27. Lyman S, Lee YY, Franklin PD, Li W, Mayman DJ, Padgett DE. Validation of the HOOS, JR: a short-form hip replacement survey. Clin Orthop Relat Res. 2016;474(6):1472-1482.

28. Hutchings A, Neuburger J, Grosse Frie K, Black N, van der Meulen J. Factors associated with non-response in routine use of patient reported outcome measures after elective surgery in England. Health Qual Life Outcomes. 2012;10:34.

29. Edwards PJ, Roberts I, Clarke MJ, et al. Methods to increase response to postal and electronic questionnaires. Cochrane Database Syst Rev. 2009;(3):MR000008.

30. Gakhar H, McConnell B, Apostolopoulos AP, Lewis P. A pilot study investigating the use of at-home, web-based questionnaires compiling patient-reported outcome measures following total hip and knee replacement surgeries. J Long Term Eff Med Implants. 2013;23(1):39-43.

31. Bojcic JL, Sue VM, Huon TS, Maletis GB, Inacio MC. Comparison of paper and electronic surveys for measuring patient-reported outcomes after anterior cruciate ligament reconstruction. Perm J. 2014;18(3):22-26.

32. Rolfson O, Salomonsson R, Dahlberg LE, Garellick G. Internet-based follow-up questionnaire for measuring patient-reported outcome after total hip replacement surgery—reliability and response rate. Value Health. 2011;14(2):316-321.

33. Shah KN, Hofmann MR, Schwarzkopf R, et al. Patient-reported outcome measures: how do digital tablets stack up to paper forms? A randomized, controlled study. Am J Orthop. 2016;45(7):E451-E457.

34. Kaiser Family Foundation. The Digital Divide and Access to Health Information Online. http://kff.org/disparities-policy/poll-finding/the-digital-divide-and-access-to-health/. Published April 1, 2011. Accessed October 4, 2017.

35. Schamber EM, Takemoto SK, Chenok KE, Bozic KJ. Barriers to completion of patient reported outcome measures. J Arthroplasty. 2013;28(9):1449-1453.

36. El-Daly I, Ibraheim H, Rajakulendran K, Culpan P, Bates P. Are patient-reported outcome measures in orthopaedics easily read by patients? Clin Orthop Relat Res. 2016;474(1):246-255.

37. Intro to PROMIS. 2016. Health Measures website. http://www.healthmeasures.net/explore-measurement-systems/promis/intro-to-promis. Accessed October 4, 2017.

38. Hung M, Baumhauer JF, Latt LD, Saltzman CL, SooHoo NF, Hunt KJ; National Orthopaedic Foot & Ankle Outcomes Research Network. Validation of PROMIS ® Physical Function computerized adaptive tests for orthopaedic foot and ankle outcome research. Clin Orthop Relat Res. 2013;471(11):3466-3474.

39. Hung M, Clegg DO, Greene T, Saltzman CL. Evaluation of the PROMIS Physical Function item bank in orthopaedic patients. J Orthop Res. 2011;29(6):947-953.

40. Tyser AR, Beckmann J, Franklin JD, et al. Evaluation of the PROMIS Physical Function computer adaptive test in the upper extremity. J Hand Surg Am. 2014;39(10):2047-2051.e4.

41. Hung M, Stuart AR, Higgins TF, Saltzman CL, Kubiak EN. Computerized adaptive testing using the PROMIS Physical Function item bank reduces test burden with less ceiling effects compared with the Short Musculoskeletal Function Assessment in orthopaedic trauma patients. J Orthop Trauma. 2014;28(8):439-443.

42. Hung M, Clegg DO, Greene T, Weir C, Saltzman CL. A lower extremity physical function computerized adaptive testing instrument for orthopaedic patients. Foot Ankle Int. 2012;33(4):326-335.

43. Döring AC, Nota SP, Hageman MG, Ring DC. Measurement of upper extremity disability using the Patient-Reported Outcomes Measurement Information System. J Hand Surg Am. 2014;39(6):1160-1165.

44. Halawi MJ, Greene K, Barsoum WK. Optimizing outcomes of total joint arthroplasty under the comprehensive care for joint replacement model. Am J Orthop. 2016;45(3):E112-E113.

References

1. Howie L, Hirsch B, Locklear T, Abernethy AP. Assessing the value of patient-generated data to comparative effectiveness research. Health Aff (Millwood). 2014;33(7):1220-1228.

2. Haywood KL. Patient-reported outcome I: measuring what matters in musculoskeletal care. Musculoskeletal Care. 2006;4(4):187-203.

3. Chang CH. Patient-reported outcomes measurement and management with innovative methodologies and technologies. Qual Life Res. 2007;16(suppl 1):157-166.

4. Black N. Patient reported outcome measures could help transform healthcare. BMJ. 2013;346:f167.

5. Porter ME. A strategy for health care reform—toward a value-based system. N Engl J Med. 2009;361(2):109-112.

6. Scott J, Huskisson EC. Graphic representation of pain. Pain. 1976;2(2):175-184.

7. de Nies F, Fidler MW. Visual analog scale for the assessment of total hip arthroplasty. J Arthroplasty. 1997;12(4):416-419.

8. Ayers DC, Franklin PD, Ring DC. The role of emotional health in functional outcomes after orthopaedic surgery: extending the biopsychosocial model to orthopaedics: AOA critical issues. J Bone Joint Surg Am. 2013;95(21):e165.

9. Edwards RR, Haythornthwaite JA, Smith MT, Klick B, Katz JN. Catastrophizing and depressive symptoms as prospective predictors of outcomes following total knee replacement. Pain Res Manag. 2009;14(4):307-311.

10. Patel AA, Donegan D, Albert T. The 36-Item Short Form. J Am Acad Orthop Surg. 2007;15(2):126-134.

11. Ware J Jr, Kosinski M, Keller SD. A 12-Item Short-Form Health Survey: construction of scales and preliminary tests of reliability and validity. Med Care. 1996;34(3):220-233.

12. About the VR-36, VR-12 and VR-6D. Boston University School of Public Health website. http://www.bu.edu/sph/research/research-landing-page/vr-36-vr-12-and-vr-6d/. Accessed October 4, 2017.

13. Jansson KA, Granath F. Health-related quality of life (EQ-5D) before and after orthopedic surgery. Acta Orthop. 2011;82(1):82-89.

14. Oak SR, Strnad GJ, Bena J, et al. Responsiveness comparison of the EQ-5D, PROMIS Global Health, and VR-12 questionnaires in knee arthroscopy. Orthop J Sports Med. 2016;4(12):2325967116674714.

15. Lavernia CJ, Iacobelli DA, Brooks L, Villa JM. The cost-utility of total hip arthroplasty: earlier intervention, improved economics. J Arthroplasty. 2015;30(6):945-949.

16. Mather RC 3rd, Watters TS, Orlando LA, Bolognesi MP, Moorman CT 3rd. Cost effectiveness analysis of hemiarthroplasty and total shoulder arthroplasty. J Shoulder Elbow Surg. 2010;19(3):325-334.

17. Brauer CA, Rosen AB, Olchanski NV, Neumann PJ. Cost-utility analyses in orthopaedic surgery. J Bone Joint Surg Am. 2005;87(6):1253-1259.

18. Schmidt S, Ferrer M, González M, et al; EMPRO Group. Evaluation of shoulder-specific patient-reported outcome measures: a systematic and standardized comparison of available evidence. J Shoulder Elbow Surg. 2014;23(3):434-444.

19. Godfrey J, Hamman R, Lowenstein S, Briggs K, Kocher M. Reliability, validity, and responsiveness of the Simple Shoulder Test: psychometric properties by age and injury type. J Shoulder Elbow Surg. 2007;16(3):260-267.

20. Kirkley A, Griffin S, McLintock H, Ng L. The development and evaluation of a disease-specific quality of life measurement tool for shoulder instability. The Western Ontario Shoulder Instability Index (WOSI). Am J Sports Med. 1998;26(6):764-772.

21. Briggs KK, Lysholm J, Tegner Y, Rodkey WG, Kocher MS, Steadman JR. The reliability, validity, and responsiveness of the Lysholm score and Tegner Activity Scale for anterior cruciate ligament injuries of the knee: 25 years later. Am J Sports Med. 2009;37(5):890-897.

22. Davidson M, Keating J. Patient-reported outcome measures (PROMs): how should I interpret reports of measurement properties? A practical guide for clinicians and researchers who are not biostatisticians. Br J Sports Med. 2014;48(9):792-796.

23. Bent NP, Wright CC, Rushton AB, Batt ME. Selecting outcome measures in sports medicine: a guide for practitioners using the example of anterior cruciate ligament rehabilitation. Br J Sports Med. 2009;43(13):1006-1012.

24. Rolfson O, Eresian Chenok K, Bohm E, et al; Patient-Reported Outcome Measures Working Group of the International Society of Arthroplasty Registries. Patient-reported outcome measures in arthroplasty registries. Acta Orthop. 2016;87(suppl 1):3-8.

25. Franklin PD, Lewallen D, Bozic K, Hallstrom B, Jiranek W, Ayers DC. Implementation of patient-reported outcome measures in U.S. total joint replacement registries: rationale, status, and plans. J Bone Joint Surg Am. 2014;96(suppl 1):104-109.

26. Lyman S, Lee YY, Franklin PD, Li W, Cross MB, Padgett DE. Validation of the KOOS, JR: a short-form knee arthroplasty outcomes survey. Clin Orthop Relat Res. 2016;474(6):1461-1471.

27. Lyman S, Lee YY, Franklin PD, Li W, Mayman DJ, Padgett DE. Validation of the HOOS, JR: a short-form hip replacement survey. Clin Orthop Relat Res. 2016;474(6):1472-1482.

28. Hutchings A, Neuburger J, Grosse Frie K, Black N, van der Meulen J. Factors associated with non-response in routine use of patient reported outcome measures after elective surgery in England. Health Qual Life Outcomes. 2012;10:34.

29. Edwards PJ, Roberts I, Clarke MJ, et al. Methods to increase response to postal and electronic questionnaires. Cochrane Database Syst Rev. 2009;(3):MR000008.

30. Gakhar H, McConnell B, Apostolopoulos AP, Lewis P. A pilot study investigating the use of at-home, web-based questionnaires compiling patient-reported outcome measures following total hip and knee replacement surgeries. J Long Term Eff Med Implants. 2013;23(1):39-43.

31. Bojcic JL, Sue VM, Huon TS, Maletis GB, Inacio MC. Comparison of paper and electronic surveys for measuring patient-reported outcomes after anterior cruciate ligament reconstruction. Perm J. 2014;18(3):22-26.

32. Rolfson O, Salomonsson R, Dahlberg LE, Garellick G. Internet-based follow-up questionnaire for measuring patient-reported outcome after total hip replacement surgery—reliability and response rate. Value Health. 2011;14(2):316-321.

33. Shah KN, Hofmann MR, Schwarzkopf R, et al. Patient-reported outcome measures: how do digital tablets stack up to paper forms? A randomized, controlled study. Am J Orthop. 2016;45(7):E451-E457.

34. Kaiser Family Foundation. The Digital Divide and Access to Health Information Online. http://kff.org/disparities-policy/poll-finding/the-digital-divide-and-access-to-health/. Published April 1, 2011. Accessed October 4, 2017.

35. Schamber EM, Takemoto SK, Chenok KE, Bozic KJ. Barriers to completion of patient reported outcome measures. J Arthroplasty. 2013;28(9):1449-1453.

36. El-Daly I, Ibraheim H, Rajakulendran K, Culpan P, Bates P. Are patient-reported outcome measures in orthopaedics easily read by patients? Clin Orthop Relat Res. 2016;474(1):246-255.

37. Intro to PROMIS. 2016. Health Measures website. http://www.healthmeasures.net/explore-measurement-systems/promis/intro-to-promis. Accessed October 4, 2017.

38. Hung M, Baumhauer JF, Latt LD, Saltzman CL, SooHoo NF, Hunt KJ; National Orthopaedic Foot & Ankle Outcomes Research Network. Validation of PROMIS ® Physical Function computerized adaptive tests for orthopaedic foot and ankle outcome research. Clin Orthop Relat Res. 2013;471(11):3466-3474.

39. Hung M, Clegg DO, Greene T, Saltzman CL. Evaluation of the PROMIS Physical Function item bank in orthopaedic patients. J Orthop Res. 2011;29(6):947-953.

40. Tyser AR, Beckmann J, Franklin JD, et al. Evaluation of the PROMIS Physical Function computer adaptive test in the upper extremity. J Hand Surg Am. 2014;39(10):2047-2051.e4.

41. Hung M, Stuart AR, Higgins TF, Saltzman CL, Kubiak EN. Computerized adaptive testing using the PROMIS Physical Function item bank reduces test burden with less ceiling effects compared with the Short Musculoskeletal Function Assessment in orthopaedic trauma patients. J Orthop Trauma. 2014;28(8):439-443.

42. Hung M, Clegg DO, Greene T, Weir C, Saltzman CL. A lower extremity physical function computerized adaptive testing instrument for orthopaedic patients. Foot Ankle Int. 2012;33(4):326-335.

43. Döring AC, Nota SP, Hageman MG, Ring DC. Measurement of upper extremity disability using the Patient-Reported Outcomes Measurement Information System. J Hand Surg Am. 2014;39(6):1160-1165.

44. Halawi MJ, Greene K, Barsoum WK. Optimizing outcomes of total joint arthroplasty under the comprehensive care for joint replacement model. Am J Orthop. 2016;45(3):E112-E113.

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The American Journal of Orthopedics - 46(6)
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The American Journal of Orthopedics - 46(6)
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