Hostname: page-component-586b7cd67f-rcrh6 Total loading time: 0 Render date: 2024-11-28T00:17:03.712Z Has data issue: false hasContentIssue false

Cryoprecipitate transfusion in bleeding patients

Published online by Cambridge University Press:  21 October 2020

Barto Nascimento
Affiliation:
Department of Surgery, Sunnybrook Health Sciences Centre, University of Toronto, Toronto, ON
Jerrold H. Levy
Affiliation:
Departments of Anesthesiology, Critical Care, and Surgery, Duke University School of Medicine, Durham, North Carolina
Homer Tien
Affiliation:
Department of Surgery, Sunnybrook Health Sciences Centre, University of Toronto, Toronto, ON
Luis Teodoro Da Luz*
Affiliation:
Department of Surgery, Sunnybrook Health Sciences Centre, University of Toronto, Toronto, ON
*
Correspondence to: Dr. Luis Teodoro da Luz, Department of Surgery, University of Toronto, Sunnybrook Health Sciences Centre, 2075 Bayview Avenue, Room H1 15, Toronto, ON, Canada, M4N 3M5; Email: [email protected]

Abstract

Objectives

The management of acquired coagulopathy in multiple clinical settings frequently involves fibrinogen supplementation. Cryoprecipitate, a multidonor product, is widely used for the treatment of acquired hypofibrinogenemia following massive bleeding, but it has been associated with adverse events. We aimed to review the latest evidence on cryoprecipitate for treatment of bleeding.

Methods

We conducted a narrative review of current literature on cryoprecipitate therapy, describing its history, formulations and preparation, and recommended dosing. We also reviewed guideline recommendations on the use of cryoprecipitate in bleeding situations and recent studies on its efficacy and safety.

Results

Cryoprecipitate has a relatively high fibrinogen content; however, as it is produced by pooling fresh frozen donor plasma, the fibrinogen content per unit can vary considerably. Current guidelines suggest that cryoprecipitate use should be limited to treating hypofibrinogenemia in patients with clinical bleeding. Until recently, cryoprecipitate was deemed unsuitable for pathogen reduction, and potential safety concerns and lack of standardized fibrinogen content have led to some professional bodies recommending that cryoprecipitate is only indicated for the treatment of bleeding and hypofibrinogenemia in perioperative settings where fibrinogen concentrate is not available. While cryoprecipitate is effective in increasing plasma fibrinogen levels, data on its clinical efficacy are limited.

Conclusions

There is a lack of robust evidence to support the use of cryoprecipitate in bleeding patients, with few prospective, randomized clinical trials performed to date. Clinical trials in bleeding settings are needed to investigate the safety and efficacy of cryoprecipitate and to determine its optimal use and administration.

Résumé

Résumé Objectif

La prise en charge des coagulopathies acquises dans différents contextes cliniques nécessite souvent un apport supplémentaire de fibrinogène. Les cryoprécipités, produits à base de sang de plusieurs donneurs, sont utilisés très souvent dans le traitement de l'hypofibrinogénémie acquise par suite d'une hémorragie massive, mais leur administration est associée à des effets indésirables. L’étude visait donc à examiner les données les plus récentes sur le traitement des hémorragies par les cryoprécipités.

Méthode

Il s'agit d'un examen descriptif de la documentation actuelle sur le traitement par les cryoprécipités, qui fait état de l'historique, de la préparation du produit ainsi que des doses recommandées. L’équipe a aussi passé en revue les recommandations contenues dans les lignes directrices sur l'utilisation des cryoprécipités dans les cas d'hémorragie, ainsi que les études récentes sur leur efficacité et leur innocuité.

Résultats

Les cryoprécipités ont une teneur relativement élevée en fibrinogène, mais celle-ci peut varier considérablement d'un sac à l'autre, car le produit est obtenu par la mise en commun de plasma frais congelé provenant de plusieurs donneurs. D'après les lignes directrices actuelles, les cryoprécipités ne devraient être utilisés que dans le traitement de l'hypofibrinogénémie chez les patients en état d'hémorragie clinique. Jusqu’à tout récemment, on considérait que les cryoprécipités ne se prêtaient pas à la réduction des micro-organismes pathogènes; de plus, des préoccupations relatives à l'innocuité et l'absence de normalisation de la teneur en fibrinogène ont incité certaines organisations professionnelles à recommander que les cryoprécipités ne soient indiqués que dans le traitement des hémorragies et de l'hypofibrinogénémie en contexte périopératoire, en cas de manque de concentrés de fibrinogène. Si les cryoprécipités sont efficaces dans l'augmentation des taux de fibrinogène plasmatique, les données sur leur efficacité clinique, elles, sont peu nombreuses.

Conclusion

L’équipe n'a pu que constater le manque de données probantes robustes sur l'utilisation des cryoprécipités dans les cas d'hémorragie, et le peu d'essais cliniques prospectifs, à répartition aléatoire, réalisés jusqu’à maintenant. Pourtant, des essais cliniques s'imposent en contexte d'hémorragie afin que soient déterminées l'innocuité et l'efficacité des cryoprécipités ainsi que leur utilisation optimale.

Type
ORNGE Supplement
Copyright
Copyright © Canadian Association of Emergency Physicians 2020

CLINICIAN'S CAPSULE

What is known about the topic?

Cryoprecipitate is frequently administered for the treatment of hypofibrinogenemia induced by massive hemorrhage.

What did this study ask?

The latest evidence on cryoprecipitate therapy for hypofibrinogenemia following major surgery, postpartum hemorrhage or trauma was reviewed.

What did this study find?

Cryoprecipitate administration has demonstrated efficacy in raising plasma fibrinogen levels, although further large-scale clinical trials in bleeding settings are required.

Why does this study matter to clinicians?

This review supports the current guidelines regarding cryoprecipitate and demonstrates the utility of cryoprecipitate administration for treating acquired hypofibrinogenemia.

INTRODUCTION

Acquired coagulopathy can occur in multiple clinical settings, including cardiac surgery, liver transplantation, trauma, and obstetrics. In the trauma setting, uncontrolled hemorrhage is responsible for approximately 40% of early deaths.Reference Sauaia, Moore and Moore1 Fibrinogen is the first coagulation factor to fall to critical levels during hemorrhage,Reference Hiippala2 and evidence suggests that fibrinogen supplementation in the bleeding patient can restore hemostasis.Reference Levy, Szlam, Tanaka and Sniecienski3 Three therapeutic options are available for fibrinogen supplementation: donor plasma, fibrinogen concentrate, and cryoprecipitate.

Fresh frozen plasma (plasma frozen within 8 hours after collection) is widely used and recommended in the European Trauma Guidelines for initial administration to patients with massive bleeding.Reference Rossaint, Bouillon and Cerny4 However, it has a lower fibrinogen content than cryoprecipitate or fibrinogen concentrate,Reference Levy, Szlam, Tanaka and Sniecienski3 and is associated with several risks and adverse events, including allergic and anaphylactic reactions, multiorgan failure, acute respiratory distress syndrome, transfusion-related acute lung injury, and potential transmission of infections.Reference Johnson, Moore and Kashuk5Reference Watson, Sperry and Rosengart8 Fresh frozen plasma is typically stored at −30°C and must be thawed before use, meaning that it may not be immediately available.Reference Rossaint, Bouillon and Cerny4,Reference Stanworth9 Two recent randomized controlled trials on 1:1 ratios of plasma to red blood cells (RBCs) failed to demonstrate survival benefits of higher volume plasma transfusionReference Nascimento, Callum and Tien10,Reference Holcomb, Tilley and Baraniuk11 ; however, one of these studies was a feasibility trial, and was not powered for clinical endpoints.Reference Nascimento, Callum and Tien10

Of the three available therapeutic options, fibrinogen concentrate has the highest fibrinogen content (~2000 mg/dL), can be stored at room temperature and can be reconstituted within 15 minutes. It is also possible to infuse 1 g in under 20 seconds in an emergency situation.Reference Levy, Szlam, Tanaka and Sniecienski3,Reference Solomon, Hagl and Rahe-Meyer12 Studies investigating the safety and efficacy of fibrinogen concentrate have been conducted in major surgery (including cardiovascular, abdominal, and orthopedic spine), trauma, and postpartum hemorrhage settings.Reference Rahe-Meyer, Solomon and Hanke13Reference Ahmed, Harrity and Johnson17 A recent Cochrane review assessed available evidence and identified six randomized controlled trials investigating the use of fibrinogen concentrate in bleeding patients.Reference Wikkelsø, Lunde and Johansen18 The authors concluded that evidence supporting the use of fibrinogen concentrate is weak, and that its use should be limited to a controlled clinical setting or trial until further data are available. However, no alternative to fibrinogen concentrate for use in bleeding patients was recommended, and it should be noted that fibrinogen concentrate has become standard-of-care in some countries,Reference Kozek-Langenecker, Fries, Spahn and Zacharowski19 and is recommended in the European Trauma Guidelines for the continued management of significant bleeding accompanied by hypofibrinogenemia.Reference Rossaint, Bouillon and Cerny4

The third option, cryoprecipitate, contains around 32% of the fibrinogen from plasma.Reference Napier, Bass and Pengilley20 However, owing to the small plasma volume used for cryoprecipitate resuspension, it has a higher fibrinogen concentration than fresh frozen plasma.Reference Rossaint, Bouillon and Cerny4,Reference Nascimento, Goodnough and Levy21 Cryoprecipitate was previously used as a treatment for hemophilia A before factor concentrates were available; however, its main use today is to replenish fibrinogen in acquired bleeding and coagulopathy.Reference Levy, Szlam, Tanaka and Sniecienski3,Reference Nascimento, Goodnough and Levy21 Due to its relatively high fibrinogen content (~300–3,000 mg/dL), cryoprecipitate has been used to replenish fibrinogen levels in various clinical settings, including trauma,Reference Rourke, Curry and Khan22 gastrointestinal hemorrhage,Reference McQuilten, Bailey and Cameron23 cardiac surgery,Reference Lee, Lee and Kim24 vascular surgery,Reference McQuilten, Bailey and Cameron23 and liver transplantation.Reference Liu, Fan and Wang25 However, its use has been associated with several adverse events, including infectious disease transmission, transfusion-related acute lung injury, and transfusion-associated circulatory overload.Reference Nascimento, Goodnough and Levy21,Reference Chapman, Stainsby and Jones26

The routine and widespread use of cryoprecipitate as an alternative therapeutic option for fibrinogen supplementation occurs irrespective of the known adverse events associated with its transfusion. Here, we review the evidence supporting its use as a therapeutic agent to treat acquired bleeding.

The development of cryoprecipitate

In the 1940s, concentrated antihemophilic factor, created by means of the fractionation of plasma with ethanol, was developed by Edwin J. Cohn and used for treatment of hemophilia.Reference Cohn, Strong and Hughes27,Reference McMillan, Diamond and Surgenor28 Cryoprecipitate arrived in the 1960s, when investigations to create an improved, concentrated form of factor VIII (FVIII) revealed that thawing frozen plasma slowly at 1–10°C provided a product rich in FVIII, FXIII, and fibrinogen.Reference Nascimento, Goodnough and Levy21,Reference Kasper29

Preparation and components of cryoprecipitate

Cryoprecipitate is prepared from fresh frozen plasma.Reference Eder and Sebok30 One unit of fresh frozen plasma from a single donor is thawed at 1–6°C and centrifuged to remove the supernatant. The remaining insoluble precipitate is resuspended in a small amount of plasma and refrozen at −18°C to form a single unit of cryoprecipitate.Reference Nascimento, Goodnough and Levy21 Typically, five single units from multiple donors are pooled into one bag before use.Reference Nascimento, Goodnough and Levy21 Cryoprecipitate may be prepooled, with pooling of units occurring at the central blood bank before freezing.Reference Nascimento, Goodnough and Levy21 Alternatively, units may be pooled by licensed centers upon thawing, either by the blood bank or at the patient's bedside, potentially leading to delayed treatment that may be unacceptable in an emergency setting.Reference Callum, Karkouti and Lin31 The best method of pooling (laboratory v. bedside) remains to be determined, and the reliability of the pooling process regarding the content of each pool and ensuring the full dose is administered have not been established.Reference Nascimento, Goodnough and Levy21,Reference Callum, Karkouti and Lin31

In accordance with AABB (American Association of Blood Banks) guidance, cryoprecipitate should be thawed in a protective plastic overwrap in a water bath at 30–37°C.32 Once thawed, cryoprecipitate can be stored between 20 and 24°C, but must be administered within 6 hours (or within 4 hours if pooled after thawing).32 Although fibrinogen levels and von Willebrand factor (vWF) activity do not appear to be significantly affected by extended storage of thawed cryoprecipitate (up to 120 hours at ambient temperature), the levels of FVIII activity were significantly decreased.Reference Lokhandwala, O'Neal and Patel33,Reference Soundar, Reyes, Korte and Bracey34 Moreover, although some studies have not identified any bacterial contamination following extended storage, a recent report showed that, while bacterial growth was not observed in spiked, thawed cryoprecipitate samples after 4 hours, considerable proliferation was seen after 24 hours.Reference Lokhandwala, O'Neal and Patel33Reference Ramirez-Arcos, Jenkins and Sheffield35

Fibrinogen content per cryoprecipitate unit has been shown to vary, ranging from 183 to 611 mg/unit, potentially due to between-donor variability, and preparation and storage methods at different institutions.Reference Lee, Lee and Kim24 Cryoprecipitate also contains several other clotting factors, including FXIII (20–30% of levels found in plasma), FVIII, vWF (40–70%), fibronectin (20–25%), as well as albumin (5–8%), immunoglobulins G (5–8%), and M (1–2%), and platelet microparticles.Reference Callum, Karkouti and Lin31

Cryoprecipitate dosing

As cryoprecipitate contains variable amounts of fibrinogen, dosing may provide variable amounts of fibrinogen repletion. The European Trauma Guidelines recommend an initial cryoprecipitate dose of 50 mg/kg (15–20 units for a 70 kg individual) in patients with significant bleeding following major traumaReference Rossaint, Bouillon and Cerny4; the AABB recommends 1 unit per 7–10 kg bodyweight to raise plasma fibrinogen by 50–75 mg/dL in patients with fibrinogen deficiency-associated bleeding32; and the Australian National Blood Authority suggests a dose of 3–4 g in patients with critical bleeding.36 The British Committee for Standards in Haematology (BCSH) suggests using 10 units with the aim of raising plasma fibrinogen by 100 mg/dL for management of disseminated intravascular coagulation.Reference Levi, Toh, Thachil and Watson37 A common adult dose is a pool of 10 single-unit bags or two pools of 5 units each, i.e., 10 units of cryoprecipitate.Reference Stanworth9,Reference Pantanowitz, Kruskall and Uhl38

Appropriate use of cryoprecipitate

Current guidelines for appropriate use of cryoprecipitate generally agree that it should be limited to hypofibrinogenemia treatment in clinical bleeding events; however, specific recommendations vary between guidelines. The European Trauma Guidelines recommend fibrinogen supplementation if plasma fibrinogen concentrations fall below 150–200 mg/dL, and suggest that cryoprecipitate may be used for treatment of bleeding accompanied by thromboelastometric signs of a functional fibrinogen deficit or a plasma fibrinogen level below the specified threshold.Reference Rossaint, Bouillon and Cerny4

The Association of Anaesthetists of Great Britain and Ireland and the European Society of Anaesthesiology recommend cryoprecipitate for fibrinogen replacement in massive hemorrhage only in the absence of fibrinogen concentrate.Reference Thomas and Wee39,Reference Kozek-Langenecker, Afshari and Albaladejo40 Similarly, the Australian National Blood Authority guidelines indicate that cryoprecipitate may be used in critical bleeding requiring massive transfusion, if fibrinogen levels are not maintained above 100 mg/dL by fresh frozen plasma.36 However, these guidelines also indicate that early cryoprecipitate administration may be warranted in major obstetric hemorrhage.36

The BCSH guidelines for use of fresh frozen plasma, cryoprecipitate, and cryosupernatant note that cryoprecipitate is commonly used to enhance fibrinogen levels in dysfibrinogenemia and acquired hypofibrinogenemia in massive transfusion and disseminated intravascular coagulation, where plasma fibrinogen is below 100 mg/dL.Reference O'Shaughnessy, Atterbury and Bolton Maggs6 The related BCSH guidelines on management of massive blood loss recommend that cryoprecipitate should be given if fibrinogen cannot be maintained above this 100 mg/dL threshold using fresh frozen plasma, further noting that cryoprecipitate is rarely needed except in disseminated intravascular coagulation.Reference Stainsby, MacLennan, Thomas, Isaac and Hamilton41 Considering the treatment of disseminated intravascular coagulation, the BCSH recommend that severe hypofibrinogenemia (plasma fibrinogen below 100 mg/dL) that persists despite fresh frozen plasma replacement may be treated with fibrinogen concentrate or cryoprecipitate.Reference Levi, Toh, Thachil and Watson37

In the United States, the AABB, American Red Cross, America's Blood Centers, and Armed Services Blood Program advise that cryoprecipitate is indicated for the control of bleeding associated with fibrinogen deficiency, FVIII, or FXIII deficiency only if recombinant or virus-inactivated FVIII or FXIII are unavailable, and for the control of uremic bleeding if all other modalities have failed.32 The American Society of Anesthesiologists Practice Guidelines for Perioperative Blood Transfusion and Adjuvant Therapies note that cryoprecipitate is rarely required for fibrinogen levels above 150 mg/dL, but is indicated when fibrinogen levels are below 80–100 mg/dL and accompanied by excessive microvascular bleeding, or in a massively transfused patient with excessive microvascular bleeding in whom fibrinogen levels cannot be rapidly assessed.42 Several of these guidelines are currently undergoing revision.

Efficacy of cryoprecipitate

Impact on fibrinogen and clotting factors

Galas et al. evaluated the hemostatic effects of fibrinogen concentrate compared with cryoprecipitate in 63 children following cardiac surgery with cardiopulmonary bypass. Compared with baseline values, patients in the fibrinogen group exhibited higher levels of FVII and FIX 1 hour after treatment, whereas patients from the cryoprecipitate group exhibited higher levels of FII, FVII, FIX, and FX.Reference Galas, de Almeida and Fukushima43 At this time point, patients in the cryoprecipitate group had higher levels of FII, FVII, and FX compared with patients in the fibrinogen group (no between-group difference was observed at baseline). This is perhaps due to a multitude of variable factors that exist in cryoprecipitate during isolation. Treatment with both fibrinogen concentrate and cryoprecipitate increased FIBTEM maximum clot firmness (MCF). Posttreatment plasma fibrinogen concentration increased and was similar in both groups at all time points.Reference Galas, de Almeida and Fukushima43

Curry et al. assessed the feasibility of administering cryoprecipitate within 90 minutes of hospital admission in 43 adult trauma patients.Reference Curry, Rourke and Davenport44 Patients received either the standard major hemorrhage therapy or the standard hemorrhage therapy plus two early pools of cryoprecipitate (five single units per pool, in a volume of 150–200 mL with a mean fibrinogen content of 2 g per pool). The primary outcome was the feasibility of early cryoprecipitate administration. Mean plasma fibrinogen concentration was the same in both treatment arms at admission; during active hemorrhage, fibrinogen concentration was higher in the cryoprecipitate arm compared with the standard therapy arm following the infusion of 4, 8, and 12 units of RBCs.Reference Curry, Rourke and Davenport44 Fibrinogen concentration increased in both groups after 24 hours and up to 72 hours, but was not significantly different between the treatment arms.

A trend toward lower fibrinogen concentration was observed from day 7 to study end (day 28) in the cryoprecipitate arm. ROTEM FIBTEM CA5 (clot amplitude at 5 minutes) and MCF values followed the same pattern as fibrinogen concentration at 24 and 72 hours. ROTEM EXTEM values rose significantly in both groups at 24 hours and 72 hours, with a larger increase seen in the cryoprecipitate arm. As this study assessed the feasibility of administering cryoprecipitate within 90 minutes of hospital admission, these results should be treated with caution as the study was not powered for evaluating these clinical outcomes.Reference Curry, Rourke and Davenport44

An increase in, or maintenance of, plasma fibrinogen levels following cryoprecipitate administration has been observed in both prospective and retrospective studies,Reference Rourke, Curry and Khan22,Reference Lee, Lee and Kim24,Reference Nascimento, Rizoli and Rubenfeld45,Reference Tinegate, Allard and Grant-Casey46 although two studies noted that fibrinogen concentrate dosage had a stronger correlation with plasma fibrinogen levels than cryoprecipitate.Reference Ahmed, Harrity and Johnson17,Reference Theodoulou, Berryman, Nathwani and Scully47

Impact on bleeding

In the randomized study conducted by Galas et al., there was no significant difference between fibrinogen concentrate and cryoprecipitate groups in the primary outcome of postoperative blood loss during 48 hours after surgery (320 v. 410 mL, respectively; p = 0.672).Reference Galas, de Almeida and Fukushima43 The posttreatment incidence of allogeneic blood transfusion was also similar between fibrinogen and cryoprecipitate groups (RBCs, 83.3% v. 97.0%, p = 0.094; platelets, 0% v. 9.1%, p = 0.240; FFP, 10.0% v. 24.2%, p = 0.137; cryoprecipitate, 43.3% v. 42.4%, p = 0.942).Reference Galas, de Almeida and Fukushima43 No deaths occurred during the study (up to postoperative day 7 or hospital discharge) in either treatment arm.

By comparison, Curry et al. found a nonsignificant difference in all-cause 28-day mortality between treatment groups: 10.0% (2/20 patients) in the cryoprecipitate arm and 28.6% (6/21 patients) in the standard therapy arm (p = 0.14).Reference Curry, Rourke and Davenport44 Causes of death in the cryoprecipitate arm were severe head injury (n = 1) and sepsis (n = 1), while in the standard therapy arm they were uncontrolled hemorrhage (n = 1), severe head injuries (n = 4), and hypoxic ischemic encephalopathy (n = 1). The patient who died from uncontrolled hemorrhage received tranexamic acid, but no cryoprecipitate. Transfusion requirements were not significantly different between cryoprecipitate and standard therapy treatment arms at 6 hours, 24 hours, or 28 days, except for the number of cryoprecipitate pools at 6 hours, which was significantly greater in the cryoprecipitate group (median 2 [interquartile range 2–4] v. 2 [0–2] pools; p = 0.03).Reference Curry, Rourke and Davenport44 Again, this study was not powered for evaluation of clinical outcomes, so results should be interpreted cautiously.

Among women with major obstetric hemorrhage, cryoprecipitate administration was associated with a greater, but nonsignificant, increase in blood loss (5.2 v. 3.3 L; p = 0.10), red cell concentrate (7.2 v. 5.9 units; p = 0.40), and FFP (4.1 v. 3.2 units; p = 0.36) transfusions, compared with FCH.Reference Ahmed, Harrity and Johnson17

A retrospective observational study compared tranexamic acid, cryoprecipitate, tranexamic acid plus cryoprecipitate, and no tranexamic acid or cryoprecipitate in 1332 patients in a wartime injury setting. An independent beneficial effect on mortality associated with cryoprecipitate administration (odds ratio, 0.61; p = 0.02) additional to that of tranexamic acid was observed.Reference Morrison, Ross, Dubose, Jansen, Midwinter and Rasmussen48 Similarly, early cryoprecipitate administration in trauma patients was associated with improved survival in a UK-based, prospective cohort study; risk of death during the first 28 days decreased with increasing cryoprecipitate dose (conditional on initial 12-hour survival).Reference Rourke, Curry and Khan22 However, Watson et al. and Holcomb et al. have observed no significant effect of cryoprecipitate on mortality rates in trauma patients.Reference Watson, Sperry and Rosengart8,Reference Holcomb, Fox and Zhang49

Risks of cryoprecipitate use

Although the adverse-event rate with cryoprecipitate is difficult to quantify precisely, one hemovigilance study of adverse transfusion events reported a rate of 6.57 events per 10,000 units administered.Reference Robillard, Nawej and Jochem50 This is considerably lower than rates reported for all other blood components evaluated, including for fresh frozen plasma (28.84 events per 10,000 units).Reference Robillard, Nawej and Jochem50 In a UK retrospective observational study of 89 patients between October 2010 and September 2011, there were no reports of acute adverse transfusion reactions following cryoprecipitate infusion,Reference Idris, Hadjinicolaou, Sweeney, Winthrop, Balendran and Besser51 and the Serious Hazards of Transfusion report published in 2011 reported only one serious acute transfusion reaction (urticaria and a sudden drop in cardiac output) in the United Kingdom.Reference Bolton-Maggs52 Furthermore, the specific risk of transfusion-related acute lung injury has been estimated at 1 in 317,000 units of cryoprecipitate administered, compared with 1 in 81,000 units for fresh frozen plasma/cryosupernatant.Reference Chapman, Stainsby and Jones26

In a small, randomized controlled pilot study in children after cardiac surgery, Galas et al. found no significant differences between fibrinogen concentrate and cryoprecipitate arms in percentage of patients experiencing clinical complications (acute myocardial infarction, stroke, acute kidney injury requiring dialysis, septic shock, reoperation, peripheral artery occlusion, deep venous thrombosis) up to 7 days after surgery or hospital discharge.Reference Galas, de Almeida and Fukushima43 No adverse events were observed in either group. In a randomized, controlled feasibility trial in adult trauma patients, Curry et al. observed no increase in thrombotic events in the cryoprecipitate arm, and no acute or nonacute transfusion reactions were attributed to cryoprecipitate.Reference Curry, Rourke and Davenport44 Seven serious adverse events were recorded in the cryoprecipitate arm (three incidents of sepsis, one multiorgan failure, and three events classified as “other”), v. 11 events in the standard therapy arm. No severe bleeding events were described in the Galas et al. and Curry et al. studies.Reference Galas, de Almeida and Fukushima43,Reference Curry, Rourke and Davenport44

In a large, prospective cohort study of patients with blunt trauma (N = 1,175), cryoprecipitate administration was independently associated with a 4.4% lower risk of developing multiorgan failure (hazard ratio, 0.956; p = 0.01 [95% confidence interval, 0.923–0.989]) per unit transfused.Reference Watson, Sperry and Rosengart8 In contrast, fresh frozen plasma was associated with a 2.1% increased risk of multiorgan failure for each transfused unit. In addition, no significant dose–response relationship was observed for cryoprecipitate transfusion and the increased risk of multiorgan failure or acute respiratory distress syndrome.Reference Watson, Sperry and Rosengart8

Intraoperative cryoprecipitate transfusion was independently associated with biliary complications following liver transplantation (relative risk, 3.46; p < 0.001) in a retrospective analysis.Reference Liu, Fan and Wang25 Randomized controlled studies are needed to determine the safety and role of cryoprecipitate in liver transplantation.

Until recently, cryoprecipitate has been considered unsuitable for pathogen reduction, so there is a small risk of viral transmission associated with this product. Cryoprecipitate can be produced from plasma subjected to viral reduction or inactivation (e.g., by means of methylene blue treatment); however, this can reduce fibrinogen content by up to 40%.Reference Cardigan, Philpot, Cookson and Luddington53 As 1 unit of cryoprecipitate is produced from 1 unit of fresh frozen plasma, the risk of adverse events per unit is assumed to be similar for both products. However, as cryoprecipitate is usually administered as a pooled dose of approximately 10 units from multiple donors, the risk of viral transmission per dose is actually higher compared with fresh frozen plasma.Reference Callum, Karkouti and Lin31 In 2017, the manufacture of a pathogen-reduced cryoprecipitate was announced; this product should reduce the risks of viral transmission previously associated with cryoprecipitate.54

Galas et al. observed no significant difference between fibrinogen concentrate and cryoprecipitate groups regarding the median length of mechanical ventilation, length of intensive care unit (ICU) stay and vasopressor requirement.Reference Galas, de Almeida and Fukushima43 Curry et al. noted that patients in the standard therapy arm remained in the ICU for 7 days longer on average, but no difference was observed in total hospital stay between the treatment arms.Reference Curry, Rourke and Davenport44

CONCLUSION

Despite its widespread use, there is limited evidence supporting use of cryoprecipitate in bleeding patients. Perhaps unsurprisingly, several recent publications have highlighted the lack of robust evidence to support the use of cryoprecipitate.Reference Nascimento, Goodnough and Levy21,Reference McQuilten, Crighton and Engelbrecht55Reference Jensen, Stensballe and Afshari57 This highlights a clear need for large-scale clinical trials, in bleeding settings, to investigate the safety and efficacy of cryoprecipitate, and assess whether its ongoing use in bleeding patients is justified. CRYOSTAT-2, which builds on the study by Curry et al., is currently investigating the effect on 28-day mortality of early administration (within 90 minutes) of high-dose cryoprecipitate in trauma patients in the hospital setting,58 while the FIBRES study is investigating administration of fibrinogen concentrate v. cryoprecipitate in patients with cardiac surgery-induced hypofibrinogenemia.Reference Karkouti, Callum and Rao59 Furthermore, a phase 2 randomized control trial comparing fibrinogen concentrate with cryoprecipitate in traumatic hemorrhage has recently completed and results are awaited with interest.Reference Winearls, Wullschleger and Wake60,61

Acknowledgments

Medical writing and editorial assistance with manuscript preparation was provided by Philip Chapman of Fishawack Communications Ltd., funded by CSL Behring.

Competing interests

B.N. has received speaker's honoraria and research grant from CSL Behring. L.T.D.L. has no conflict of interest to declare. J.H.L. serves on steering committees for Boehringer Ingelheim, CSL Behring, Grifols, Instrumentation Laboratories, Octapharma, and Merck.

References

REFERENCES

1.Sauaia, A, Moore, FA, Moore, EE, et al. Epidemiology of trauma deaths: a reassessment. J Trauma 1995;38(2):185–93.Google ScholarPubMed
2.Hiippala, S. Replacement of massive blood loss. Vox Sang 1998;74(Suppl 2):399407.Google ScholarPubMed
3.Levy, JH, Szlam, F, Tanaka, KA, Sniecienski, RM. Fibrinogen and hemostasis: a primary hemostatic target for the management of acquired bleeding. Anesth Analg 2012;114(2):261–74.Google ScholarPubMed
4.Rossaint, R, Bouillon, B, Cerny, V, et al. The European guideline on management of major bleeding and coagulopathy following trauma: fourth edition. Crit Care 2016;20:100.Google ScholarPubMed
5.Johnson, JL, Moore, EE, Kashuk, JL, et al. Effect of blood products transfusion on the development of postinjury multiple organ failure. Arch Surg 2010;145(10):973–7.Google ScholarPubMed
6.O'Shaughnessy, DF, Atterbury, C, Bolton Maggs, P, et al. Guidelines for the use of fresh-frozen plasma, cryoprecipitate and cryosupernatant. Br J Haematol 2004;126(1):1128.Google ScholarPubMed
7.Sarani, B, Dunkman, WJ, Dean, L, Sonnad, S, Rohrbach, JI, Gracias, VH. Transfusion of fresh frozen plasma in critically ill surgical patients is associated with an increased risk of infection. Crit Care Med 2008;36(4):1114–8.Google ScholarPubMed
8.Watson, GA, Sperry, JL, Rosengart, MR, et al. Fresh frozen plasma is independently associated with a higher risk of multiple organ failure and acute respiratory distress syndrome. J Trauma 2009;67(2):221–7; discussion 228–30.Google ScholarPubMed
9.Stanworth, SJ. The evidence-based use of FFP and cryoprecipitate for abnormalities of coagulation tests and clinical coagulopathy. Hematology Am Soc Hematol Educ Program 2007:179–86.Google ScholarPubMed
10.Nascimento, B, Callum, J, Tien, H, et al. Effect of a fixed-ratio (1:1:1) transfusion protocol versus laboratory-results-guided transfusion in patients with severe trauma: a randomized feasibility trial. CMAJ 2013;185(12):E5839.Google ScholarPubMed
11.Holcomb, JB, Tilley, BC, Baraniuk, S, et al. Transfusion of plasma, platelets, and red blood cells in a 1:1:1 vs a 1:1:2 ratio and mortality in patients with severe trauma: the PROPPR randomized clinical trial. JAMA 2015;313(5):471–82.Google Scholar
12.Solomon, C, Hagl, C, Rahe-Meyer, N. Time course of haemostatic effects of fibrinogen concentrate administration in aortic surgery. Br J Anaesth 2013;110(6):947–56.Google ScholarPubMed
13.Rahe-Meyer, N, Solomon, C, Hanke, A, et al. Effects of fibrinogen concentrate as first-line therapy during major aortic replacement surgery: a randomized, placebo-controlled trial. Anesthesiology 2013;118(1):4050.Google ScholarPubMed
14.Innerhofer, P, Fries, D, Mittermayr, M, et al. Reversal of trauma-induced coagulopathy using first-line coagulation factor concentrates or fresh frozen plasma (RETIC): a single-centre, parallel-group, open-label, randomised trial. Lancet Haematol 2017;4(6):e25871.CrossRefGoogle ScholarPubMed
15.Solomon, C, Pichlmaier, U, Schoechl, H, et al. Recovery of fibrinogen after administration of fibrinogen concentrate to patients with severe bleeding after cardiopulmonary bypass surgery. Br J Anaesth 2010;104(5):555–62.Google ScholarPubMed
16.Lance, MD, Ninivaggi, M, Schols, SE, et al. Perioperative dilutional coagulopathy treated with fresh frozen plasma and fibrinogen concentrate: a prospective randomized intervention trial. Vox Sang 2012;103(1):2534.Google ScholarPubMed
17.Ahmed, S, Harrity, C, Johnson, S, et al. The efficacy of fibrinogen concentrate compared with cryoprecipitate in major obstetric haemorrhage--an observational study. Transfus Med 2012;22(5):344–9.Google Scholar
18.Wikkelsø, A, Lunde, J, Johansen, M, et al. Fibrinogen concentrate in bleeding patients. Cochrane Database Syst Rev 2013;8:CD008864.Google Scholar
19.Kozek-Langenecker, S, Fries, D, Spahn, DR, Zacharowski, K. III.: Fibrinogen concentrate: clinical reality and cautious Cochrane recommendation. Br J Anaesth 2014;112(5):784–7.Google ScholarPubMed
20.Napier, JA, Bass, H, Pengilley, R. Technical method. Fresh frozen cryosupernatant in place of fresh frozen plasma for broad spectrum coagulation factor replacement. J Clin Pathol 1985;38(4):475–7.Google ScholarPubMed
21.Nascimento, B, Goodnough, LT, Levy, JH. Cryoprecipitate therapy. Br J Anaesth 2014;113(6):922–34.CrossRefGoogle ScholarPubMed
22.Rourke, C, Curry, N, Khan, S, et al. Fibrinogen levels during trauma hemorrhage, response to replacement therapy, and association with patient outcomes. J Thromb Haemost 2012;10(7):1342–51.Google ScholarPubMed
23.McQuilten, ZK, Bailey, M, Cameron, PA, et al. Fibrinogen concentration and use of fibrinogen supplementation with cryoprecipitate in patients with critical bleeding receiving massive transfusion: a bi-national cohort study. Br J Haematol 2017;179(1):131–41.Google ScholarPubMed
24.Lee, SH, Lee, SM, Kim, CS, et al. Fibrinogen recovery and changes in fibrin-based clot firmness after cryoprecipitate administration in patients undergoing aortic surgery involving deep hypothermic circulatory arrest. Transfusion 2014;54(5):1379–87.Google ScholarPubMed
25.Liu, S, Fan, J, Wang, X, et al. Intraoperative cryoprecipitate transfusion and its association with the incidence of biliary complications after liver transplantation--a retrospective cohort study. PLoS One 2013;8(5):e60727.Google ScholarPubMed
26.Chapman, CE, Stainsby, D, Jones, H, et al. Ten years of hemovigilance reports of transfusion-related acute lung injury in the United Kingdom and the impact of preferential use of male donor plasma. Transfusion 2009;49(3):440–52.CrossRefGoogle ScholarPubMed
27.Cohn, EJ, Strong, LE, Hughes, WL, et al. Preparation and properties of serum and plasma proteins; a system for the separation into fractions of the protein and lipoprotein components of biological tissues and fluids. J Am Chem Soc 1946;68:459–75.Google ScholarPubMed
28.McMillan, CW, Diamond, LK, Surgenor, DM. Treatment of classic hemophilia: the use of fibrinogen rich in factor VIII for hemorrhage and for surgery. N Engl J Med 1961;265:277–83 concl.CrossRefGoogle Scholar
29.Kasper, CK. Judith Graham Pool and the discovery of cryoprecipitate. Haemophilia 2012;18(6):833–5.CrossRefGoogle Scholar
30.Eder, AF, Sebok, MA. Plasma components: FFP, FP24, and thawed plasma. Immunohematology 2007;23(4):150–7.Google ScholarPubMed
31.Callum, JL, Karkouti, K, Lin, Y. Cryoprecipitate: the current state of knowledge. Transfus Med Rev 2009;23(3):177–88.Google ScholarPubMed
32.AABB, ARC, ABC, ASBP. Circular of information: for the use of human blood and blood components 2017. Available at: http://www.aabb.org/tm/coi/Documents/coi1017.pdf (accessed January 19, 2020).Google Scholar
33.Lokhandwala, PM, O'Neal, A, Patel, EU, et al. Hemostatic profile and safety of pooled cryoprecipitate up to 120 hours after thawing. Transfusion 2018;58:1126–31.CrossRefGoogle ScholarPubMed
34.Soundar, EP, Reyes, M, Korte, L, Bracey, A. Characteristics of thawed pooled cryoprecipitate stored at refrigerated temperature for 24 hours. Blood Transfus 2018;16:443–6.Google ScholarPubMed
35.Ramirez-Arcos, S, Jenkins, C, Sheffield, WP. Bacteria can proliferate in thawed cryoprecipitate stored at room temperature for longer than 4 h. Vox Sang 2017;112(5):477–9.Google ScholarPubMed
36.National Blood Authority, Australia. Patient blood management guidelines: module 1 critical bleeding/massive transfusion. 2011. Available at: https://www.blood.gov.au/pbm-module-1 (accessed January 19, 2020).Google Scholar
37.Levi, M, Toh, CH, Thachil, J, Watson, HG. Guidelines for the diagnosis and management of disseminated intravascular coagulation. British Committee for Standards in Haematology. Br J Haematol 2009;145(1):2433.Google ScholarPubMed
38.Pantanowitz, L, Kruskall, MS, Uhl, L. Cryoprecipitate. Patterns of use. Am J Clin Pathol 2003;119(6):874–81.Google ScholarPubMed
39.Association of Anaesthetists of Great Britain and Ireland, Thomas, D, Wee, M, et al. Blood transfusion and the anaesthetist: management of massive haemorrhage. Anaesthesia 2010;65(11):1153–61.Google ScholarPubMed
40.Kozek-Langenecker, SA, Afshari, A, Albaladejo, P, et al. Management of severe perioperative bleeding: guidelines from the European Society of Anaesthesiology. Eur J Anaesthesiol 2013;30(6):270382.Google ScholarPubMed
41.British Committee for Standards in Haematology, Stainsby, D, MacLennan, S, Thomas, D, Isaac, J, Hamilton, PJ. Guidelines on the management of massive blood loss. Br J Haematol 2006;135(5):634–41.Google ScholarPubMed
42.American Society of Anesthesiologists Task Force on Perioperative Blood Transfusion and Adjuvant Therapies. Practice guidelines for perioperative blood transfusion and adjuvant therapies: an updated report by the American Society of Anesthesiologists Task Force on Perioperative Blood Transfusion and Adjuvant Therapies. Anesthesiology 2006;105(1):198208.CrossRefGoogle Scholar
43.Galas, FR, de Almeida, JP, Fukushima, JT, et al. Hemostatic effects of fibrinogen concentrate compared with cryoprecipitate in children after cardiac surgery: a randomized pilot trial. J Thorac Cardiovasc Surg 2014;148(4):1647–55.Google ScholarPubMed
44.Curry, N, Rourke, C, Davenport, R, et al. Early cryoprecipitate for major haemorrhage in trauma: a randomised controlled feasibility trial. Br J Anaesth 2015;115(1):7683.CrossRefGoogle ScholarPubMed
45.Nascimento, B, Rizoli, S, Rubenfeld, G, et al. Cryoprecipitate transfusion: assessing appropriateness and dosing in trauma. Transfus Med 2011;21(6):394401.Google ScholarPubMed
46.Tinegate, H, Allard, S, Grant-Casey, J, et al. Cryoprecipitate for transfusion: which patients receive it and why? A study of patterns of use across three regions in England. Transfus Med 2012;22(5):356–61.CrossRefGoogle Scholar
47.Theodoulou, A, Berryman, J, Nathwani, A, Scully, M. Comparison of cryoprecipitate with fibrinogen concentrate for acquired hypofibrinogenaemia. Transfus Apher Sci 2012;46(2):159–62.Google ScholarPubMed
48.Morrison, JJ, Ross, JD, Dubose, JJ, Jansen, JO, Midwinter, MJ, Rasmussen, TE. Association of cryoprecipitate and tranexamic acid with improved survival following wartime injury: findings from the MATTERs II Study. JAMA Surg 2013;148(3):218–25.Google ScholarPubMed
49.Holcomb, JB, Fox, EE, Zhang, X, et al. Cryoprecipitate use in the PROMMTT study. J Trauma Acute Care Surg 2013;75(1 Suppl 1):S31–9.CrossRefGoogle ScholarPubMed
50.Robillard, P, Nawej, KI, Jochem, K. The Quebec hemovigilance system: description and results from the first two years. Transfus Apher Sci 2004;31(2):111–22.CrossRefGoogle ScholarPubMed
51.Idris, SF, Hadjinicolaou, AV, Sweeney, M, Winthrop, C, Balendran, G, Besser, M. The efficacy and safety of cryoprecipitate in the treatment of acquired hypofibrinogenaemia. Br J Haematol 2014;166(3):458–61.Google ScholarPubMed
52.Bolton-Maggs, P (Ed.) and Cohen H on behalf of the Serious Hazards of Transfusion (SHOT) Steering Group. The 2011 Annual SHOT Report. 2012.Google Scholar
53.Cardigan, R, Philpot, K, Cookson, P, Luddington, R. Thrombin generation and clot formation in methylene blue-treated plasma and cryoprecipitate. Transfusion 2009;49(4):696703.CrossRefGoogle ScholarPubMed
54.Cerus Corporation. Cerus announces collaboration with central California blood center to manufacture pathogen-reduced cryoprecipitate 2017. Available at: http://www.cerus.com/Investors/Press-Releases/Press-Release-Details/2017/Cerus-Announces-Collaboration-with-Central-California-Blood-Center-to-Manufacture-Pathogen-Reduced-Cryoprecipitate/default.aspx (accessed January 19, 2020).Google Scholar
55.McQuilten, ZK, Crighton, G, Engelbrecht, S, et al. Transfusion interventions in critical bleeding requiring massive transfusion: a systematic review. Transfus Med Rev 2015;29(2):127–37.Google ScholarPubMed
56.Shah, A, Stanworth, SJ, McKechnie, S. Evidence and triggers for the transfusion of blood and blood products. Anaesthesia 2015;70(Suppl 1):10–9, e3–5.Google ScholarPubMed
57.Jensen, NH, Stensballe, J, Afshari, A. Comparing efficacy and safety of fibrinogen concentrate to cryoprecipitate in bleeding patients: a systematic review. Acta Anaesthesiol Scand 2016;60:1033–42.Google ScholarPubMed
58.Cryostat-2 protocol 2018. Available at: http://cryostat2.co.uk/downloads/trial-protocol.pdf (accessed January 19, 2020).Google Scholar
59.Karkouti, K, Callum, J, Rao, V, et al. Protocol for a phase III, non-inferiority, randomised comparison of a new fibrinogen concentrate versus cryoprecipitate for treating acquired hypofibrinogenaemia in bleeding cardiac surgical patients: the FIBRES trial. BMJ Open 2018;8(4):e020741.Google ScholarPubMed
60.Winearls, J, Wullschleger, M, Wake, E, et al. Fibrinogen Early In Severe Trauma studY (FEISTY): study protocol for a randomised controlled trial. Trials 2017;18(1):241.Google ScholarPubMed