Making thawed universal donor plasma available rapidly for massively bleeding trauma patients: experience from the Pragmatic, Randomized Optimal Platelets and Plasma Ratios (PROPPR) trial

Novak, Deborah J.; Bai, Yu; Cooke, Rhonda; Marques, Marisa B.; Fontaine, Magali J.; Gottschall, Jerome L.; Carey, Patricia M.; Scanlan, Richard M.; Fiebig, Eberhard; Shulman, Ira A.; Nelson, Janice M.; Flax, Sherri; Duncan, Veda; Daniel-Johnson, Jennifer A.; Callum, Jeannie; Holcomb, John B.; Fox, Erin E.; Baraniuk, Sarah; Tilley, Barbara C.; Schreiber, Martin A.; Inaba, Kenji; Rizoli, Sandro; Podbielski, Jeanette; Cotton, Bryan A.; Hess, John R.

doi:10.1111/trf.13098

Cited by 74 publications

(63 citation statements)

References 19 publications

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“…Prior to starting the study, and as part of site training and verification, each site was evaluated for the ability of its blood bank to randomize, prepare, and deliver the first MTP cooler to the bedside within ten minutes, as well as to prepare and deliver subsequent coolers on-demand. 11 As such, time of arrival, time to MTP activation and time to arrival of initial and each subsequent cooler were collected as time points of interest. The content of each MTP cooler was identical between centers, varying only by randomization group ( i.e.…”

Section: Methodsmentioning

confidence: 99%

Every minute counts

Meyer

Vincent

Fox

et al. 2017

Journal of Trauma and Acute Care Surgery

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228

126

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BACKGROUND ACS-TQIP Best Practices recommends initial massive transfusion (MT) cooler delivery within 15 minutes of protocol activation, with a goal of 10 minutes. The current study sought to examine the impact of timing of first cooler delivery on patient outcomes. METHODS Patients predicted to receive MT at 12 level-1 trauma centers were randomized to two separate transfusion ratios as described in the PROPPR trial. ABC score or clinician gestalt prediction of MT was used to randomize patients and call for initial study cooler. In this planned sub-analysis, the time to MT protocol activation and time to delivery of the initial cooler were evaluated. The impact of these times on mortality and time to hemostasis were examined using both Wilcoxon rank sum and linear and logistic regression. RESULTS Among 680 patients, the median time from patient arrival to MT protocol activation was 9 minutes with a median time from MT activation call to delivery of first cooler of 8 minutes. An increase in both time to MT activation and time to arrival of first cooler were associated with prolonged time to achieving hemostasis (coef 1.09, p=0.001 and coef. 1.16, p < 0.001, respectively). Increased time to MT activation and time to arrival of first cooler were associated with increased mortality (OR 1.02, p=0.009 and OR 1.02, p = 0.012, respectively). Controlling for injury severity, physiology, resuscitation intensity, and treatment arm (1:1:1 vs. 1:1:2), increased time to arrival of first cooler was associated with an increased mortality at 24-hours (OR 1.05, p = 0.035) and 30-days (OR 1.05, p = 0.016). CONCLUSIONS Delays in MT protocol activation and delays in initial cooler arrival were associated with prolonged time to achieve hemostasis and an increase in mortality. Independent of products ratios, every minute from time of MT protocol activation to time of initial cooler arrival increases odds of mortality by 5%. LEVEL OF EVIDENCE Level II, Prognostic

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Section: Methodsmentioning

confidence: 99%

Every minute counts

Meyer

Vincent

Fox

et al. 2017

Journal of Trauma and Acute Care Surgery

Self Cite

228

126

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“…A number of studies have reported that in patients receiving higher ratios there is an increase in the amount of plasma transfused and an increased incidence of transfusion-related adverse events without a survival benefit, however, these concerns were not confirmed in the PROPPR trial (49) (50) (51). Time to delivery of product replacement in PROPPR was rapidly achieved without significant wastage but this is dependent on having thawed product available 24 hours a day in either the trauma unit or blood bank (52). The impressive delivery of blood component therapy as described in the PROPPR trial may be difficult to translate into routine clinical practise (53).…”

Section: Major Haemorrhage Protocols (Mhp)mentioning

confidence: 99%

Fibrinogen in traumatic haemorrhage: A narrative review

Winearls

Campbell

Hurn

et al. 2017

Injury

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Abstract:Haemorrhage in the setting of severe trauma is associated with significant morbidity and mortality. There is increasing awareness of the important role fibrinogen plays in traumatic haemorrhage. Fibrinogen levels fall precipitously in severe trauma and the resultant hypofibrinogenaemia is associated with poor outcomes. Hence, it has been postulated that early fibrinogen replacement in severe traumatic haemorrhage may improve outcomes, although, to date there is a paucity of high quality evidence to support this hypothesis. In addition there is controversy regarding the optimal method for fibrinogen supplementation. We review the current evidence regarding the role of fibrinogen in trauma, the rationale behind fibrinogen supplementation and discuss current research.

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“…The transition of large trauma centers to thawed plasma has led to a near 50% decrease in time to plasma transfusion 23,24 resulting in an independent predictor of decreased mortality. 23 The trade-off with the increasing use of thawed plasma is the 2.2% wastage rate, most of which is limited AB donor plasma.…”

Section: Discussionmentioning

confidence: 99%

14-Day thawed plasma retains clot enhancing properties and inhibits tPA-induced fibrinolysis

Huebner¹,

Moore

Moore³

et al. 2017

Journal of Surgical Research

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Background Plasma-first resuscitation attenuates trauma-induced-coagulopathy (TIC), however, the logistics of plasma-first resuscitation require thawed plasma (TP) be readily available due to the obligatory thawing time of FFP. The current standard is storage of TP for up to 5 days at 4°C, based on factor levels at outdate, for use in patients at risk for TIC, but there remains a 2.2% outdated wastage rate. However, the multitude of plasma proteins in attenuating TIC remain unknown. We hypothesize that TP retains the ability to enhance clotting and reduce tPA-induced fibrinolysis at 14 days storage. Methods FFP was thawed and stored at 4°C at the following intervals: 14, 10, 7, 5, 3, and 1-day prior to the experiment. Healthy volunteers underwent blood draws followed by 50% dilution with above TP stored intervals as well as FFP, normal saline (NS), albumin, and whole blood (WB) control. Samples underwent tPA-modified (75ng/ml) thrombelastography (TEG) with analysis of R-time, angle, maximum amplitude (MA), and LY30. Results TEG properties did not change significantly over the thawed storage. 14-day TP retained the ability to inhibit tPA-induced hyperfibrinolysis (median LY30% 9.6%) similar to FFP (5.6%), WB (14.6%) and superior to albumin (59.3%) and NS (58.1%). 14-day TP also retained faster clot formation (median angle, 66.2°) and superior clot strength (MA, 61.5mm) to albumin (34.8°, 21.6mm) and NS (41.6°, 32.2mm). Conclusion TP plasma stored for 14 days retains clot enhancing ability and resistance to clot degradation similar to FFP. A clinical trial is needed to validate these in vitro results.

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Making thawed universal donor plasma available rapidly for massively bleeding trauma patients: experience from the Pragmatic, Randomized Optimal Platelets and Plasma Ratios (PROPPR) trial

Cited by 74 publications

References 19 publications

Every minute counts

Every minute counts

Fibrinogen in traumatic haemorrhage: A narrative review

14-Day thawed plasma retains clot enhancing properties and inhibits tPA-induced fibrinolysis

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