Give prehospital blood & save a life?
Date First Published:
October 26, 2015
Last Updated:
February 10, 2017
Report by:
Dr Nicholas Scott, ST6 Emergency Medicine (University Hospitals of Leicester NHS trust)
Search checked by:
Sarah Sutton, University Hospitals of Leicester NHS trust
Three-Part Question:
In [prehospital patients with traumatic haemorrhage] is [a blood transfusion superior to care without transfusion] at [reducing mortality]?
Clinical Scenario:
A 30-year-old male involved in a high-speed motorcycle accident is attended to by a prehospital critical care team. On scene the patient is moribund and in a shocked state. As the reversible causes of shock are addressed you wonder if resuscitation with blood products rather than crystalloid would improve the patient's chances of survival. Major haemorrhage protocols are used in hospital and intuition would suggest potential benefit if these protocols were administered at the point of injury, in order to reduce the later incidence of coagulopathy.
Search Strategy:
A literature search of EMBASE, MEDLINE and CINAHL was conducted via NHS Evidence. UK Blood Services Transfusion Evidence Library, Google Scholar were also searched.
Medline and CINAHL: [(prehospital*.ti.ab OR pre-hospital*.ti.ab OR “HEMS.”ti.ab OR helicopter* adj2 emergenc*.ti.ab OR “air medic*”.ti.ab OR “emergency medic* service*.”ti.ab OR ground adj4 medic*) AND (exp WOUNDS AND INJURIES/OR h?emorrhag*.ti.ab OR trauma*.ti.ab) AND (exp BLOOD TRANSFUSION/OR “red blood cell*."ti.ab OR plasma adj2* transfuse*.ti.ab OR fresh frozen plasma.”ti.ab)] [LIMIT to English and Human].
EMBASE (date of searching 2 March): [(prehospital*.ti.ab OR pre-hospital*.ti.ab OR “HEMS.”ti.ab OR helicopter* adj2 emergenc*.ti.ab OR “air medic*”.ti.ab OR “emergency medic* service*.”ti.ab OR ground adj4 medic*) AND (exp INJURY/OR h?emorrhag*.ti.ab OR trauma*.ti.ab) AND (exp BLOOD TRANSFUSION/OR “red blood cell*."ti.ab OR plasma adj2* transfuse*.ti.ab OR fresh frozen plasma.”ti.ab)] [LIMIT to English and Human].
EMBASE; 265 papers, MEDLINE; 104 papers, CINAHL; 57 papers, UK Blood Services Transfusion Evidence Library; 121 papers, Google Scholar; 50 papers.
The Cochrane Library Issue 3 of 12 March 2016
MeSH descriptor: [Blood Transfusion] explode all trees AND prehospital ti, ab.kw=4 results
Medline and CINAHL: [(prehospital*.ti.ab OR pre-hospital*.ti.ab OR “HEMS.”ti.ab OR helicopter* adj2 emergenc*.ti.ab OR “air medic*”.ti.ab OR “emergency medic* service*.”ti.ab OR ground adj4 medic*) AND (exp WOUNDS AND INJURIES/OR h?emorrhag*.ti.ab OR trauma*.ti.ab) AND (exp BLOOD TRANSFUSION/OR “red blood cell*."ti.ab OR plasma adj2* transfuse*.ti.ab OR fresh frozen plasma.”ti.ab)] [LIMIT to English and Human].
EMBASE (date of searching 2 March): [(prehospital*.ti.ab OR pre-hospital*.ti.ab OR “HEMS.”ti.ab OR helicopter* adj2 emergenc*.ti.ab OR “air medic*”.ti.ab OR “emergency medic* service*.”ti.ab OR ground adj4 medic*) AND (exp INJURY/OR h?emorrhag*.ti.ab OR trauma*.ti.ab) AND (exp BLOOD TRANSFUSION/OR “red blood cell*."ti.ab OR plasma adj2* transfuse*.ti.ab OR fresh frozen plasma.”ti.ab)] [LIMIT to English and Human].
EMBASE; 265 papers, MEDLINE; 104 papers, CINAHL; 57 papers, UK Blood Services Transfusion Evidence Library; 121 papers, Google Scholar; 50 papers.
The Cochrane Library Issue 3 of 12 March 2016
MeSH descriptor: [Blood Transfusion] explode all trees AND prehospital ti, ab.kw=4 results
Outcome:
After review of title and abstract 11 papers were found and reviewed in full. Seven were excluded after full text review due to the following: three poor quality, two wrong comparison group, one descriptive study and one unpublished study
Relevant Paper(s):
| Study Title | Patient Group | Study type (level of evidence) | Outcomes | Key results | Study Weaknesses |
|---|---|---|---|---|---|
| Prehospital blood transfusion in the en route management of severe combat trauma: a matched cohort study. O'Reilly DJ, Morrison JJ, Jansen JO et al. 2014 UK | 1592 casualties over a 6-year period. Introduction of prehospital blood transfusion (PHBTX) by MERT-E in 2008 created two cohorts ie, a pre-PHBTX and post-PHBTX era. 97 patients were matched. 26.9% received a PHBTX of PRBC and FFP. | Retrospective matched cohort study | mortality (no PHBTX vs PHBTX) | 19.6% vs 8.2% (p < 0.001) | Losses to follow-up. Multiple potential confounders were identified: recipients of a PHBTX received more prehospital interventions (eg, chest decompression, advanced airway intervention, tranexamic acid, larger total blood infusions, improved ratios of PRBC: FFP and shorter prehospital times). No statistical analysis was used to control for these confounders. |
| Prehospital Transfusion of Plasma and Red Blood Cells in Trauma Patients. Holcomb JB, Donathan DP, Cotton BA, et al . 2015 USA | 885 prehospital trauma patients transported by two different HEMS (LF and OA) operations. Comparison was made between cohorts of 716 patients with LF with available blood products and 169 patients with OA resuscitated with crystalloid only. 19% of the LF received a PHBTX of PRBC and FFP. |
Retrospective cohort study | mortality at 6-hours amongst those with critical ED disposition (admitted directly to the ICU, IR, OR or morgue) | OR 0.23 (95% CI 0.0062-0.890 P = 0.033) | Differences in critical care capabilities between the HEMS were not discussed in detail. Ground platforms are excluded from analysis due to ‘gross inequities’ and represent selection bias. No matching of patients was attempted in this study. LF shared its governance with the major trauma centre, possibly representing a conflict of interests. No breakdown in injury type. Marked differences in transport times. |
| mortality at 24-hours | OR 0.57 (p = 0.117) | ||||
| mortality 30-days | OR 0.71 (P = 0.441) | ||||
| Pre-trauma center red blood cell transfusion is associated with improved early outcomes in air medical trauma patients. Brown JB, Sperry JL, Fombona A, et al. 2015 USA | 8616 prehospital trauma patients transport by air to a level 1 trauma centre. Matched cohort of 213 was created. 2.9% received a PHBTX of PRBC. | Retrospective matched cohort study |
survival at 24-hours | AOR 6.32 (95% CI 1.88-21.14 p <0.01) | Single-centre study using a single HEMS operation. Potential for selection bias. Missing data. Initial large crystalloid infusions. Survival bias. PRBC transfusion only. |
| survival in-hospital | AOR 4.32 (95% CI 0.76-24.72 p= 0.10) | ||||
| Pretrauma center red blood cell transfusion is associated with reduced mortality and coagulopathy in severely injured patients with blunt trauma. Brown JB, Cohen MJ, Minei JP, et al . 2015 USA | 1415 civilian patients with blunt trauma transferred to a trauma centre. A matched cohort of 113 was created. 3.5% received a PHBTX of PRBC±plasma. |
Retrospective cohort study | mortality at 24-hours | AOR 0.02 (95% CI 0.01-0.69; P=0.04) | Small numbers of transfusions. 2 h cut-off creating selection bias. Missing data. No description of the capabilities of the prehospital provider. No data regarding type of transfusions or ratios of blood products. Survival bias. Blunt trauma only. |
| mortality at 30-days | AOR 0.12 (95% CI 0.03-0.61; P=0.01) |
Author Commentary:
All of the studies included are of a retrospective observational design and are therefore subject to selection bias and confounding. In addition, several are distinct ‘before and after’ comparisons, a methodology which has numerous flaws and limited ability to assess causation (Goodacre et al 2015). The dependence on evidence from observational studies is common in the setting of prehospital trauma care; the number of high-quality randomised control trials is small and design is challenging across regions with variable geography, medical response times, patient demographics and levels of medical response. In conclusion, all of the four papers suggest an early survival benefit (6–24 h), however there is limited evidence of a sustained reduction in mortality. These data are also level 4 evidence only and conclusions should therefore be regarded as hypothesis generating. The feasibility of delivering prehospital blood has been demonstrated in multiple cohort studies (Rehn et al 2015). It is the effectiveness, cost, resource implications and risk/benefit profile that remain in question. Several future studies are planned that may help address these questions (Reynolds et al 2015, Dretzke et al 2014, RePHIL).
Bottom Line:
There is a potential clinical benefit in prehospital blood transfusion. However, this has not been confirmed with high-level evidence and potential harms/costs remain unquantified. Further high-quality randomised control trials are needed, with stratified design accounting for injury type, scene times and prehospital response.
Level of Evidence:
Level 3: Small numbers of small studies or great heterogeneity or very different population
References:
- O'Reilly DJ, Morrison JJ, Jansen JO et al.. Prehospital blood transfusion in the en route management of severe combat trauma: a matched cohort study.
- Holcomb JB, Donathan DP, Cotton BA, et al . . Prehospital Transfusion of Plasma and Red Blood Cells in Trauma Patients.
- Brown JB, Sperry JL, Fombona A, et al.. Pre-trauma center red blood cell transfusion is associated with improved early outcomes in air medical trauma patients.
- Brown JB, Cohen MJ, Minei JP, et al . . Pretrauma center red blood cell transfusion is associated with reduced mortality and coagulopathy in severely injured patients with blunt trauma.
- Goodacre S.. Uncontrolled before-after studies; discouraged by Cochrane and the EMJ.
- Rehn M, Weaver A, Eshelby S, et al .. London's air ambulance: 3 year experience with pre-hospital transfusion.
- Reynolds PS, Michael MJ, Cochran ED, et al .. Prehospital use of plasma in traumatic hemorrhage (The PUPTH Trial): study protocol for a randomised controlled trial.
- Dretzke J, Smith IM, James RH, et al . . Protocol for a systematic review of the clinical effectiveness of pre-hospital blood components compared to other resuscitative fluids in patients with major traumatic haemorrhage.
- The RePHIL trial.. http://www.transfusionguidelines.org.uk/…/rtc-eeng_2014_11_E_major.pdf