Trauma Clinical Trial
Official title:
Effect of Pre-hospital Blood Transfusion on Early Outcomes in Trauma Patients Transported by Physician-staffed HEMS (Helicopter Emergency Medical Service)
Trauma is a leading cause of death among people younger than 44 years. Five million people worldwide die from trauma annually. Uncontrolled haemorrhage causing traumatic-haemorrhagic shock (THS) is the leading cause of potentially preventable deaths from severe trauma. Uncorrected hypervolaemia and prolonged shock cause severe tissue hypoperfusion, vital organ ischemia and subsequently acidosis. In up to one third of trauma patients, laboratory findings suggest traumatic induced coagulopathy, which is further triggered by loss or dilution of coagulation factors. These patients have a significantly increased morbidity and mortality compared to patients with similar injury patterns without coagulopathy. Minimizing the time to surgical control of haemorrhage is key in order to improve outcome. However, immediate and goal directed volume and coagulation resuscitation including use of blood transfusion is crucial to enable survival until definitive hospital care. The primary objective of this study will be to evaluate feasibility of prehospital administration of 1 unit of human plasma and 1 unit of red blood cells, and explore association of early prehospital transfusion with early outcomes in patients presenting with THS, severe bleeding or peri-arrest state who are matching indication criteria and are transported by Helicopter Emergency Medical Service. Results of clinical examinations and laboratory variables in a group of patients receiving prehospital transfusion will be compared to matched population of patients treated before blood has been available on board. Secondary aim of the study is to detect any potential logistical and/or organisational adverse effects, incl. cost-effectiveness, in a regional trauma system with prehospital times (time of injury to trauma centre) ranging from 45 to 75 minutes.
Background and rationale of the project Trauma is a leading cause of death among people
younger than 44 years. Uncontrolled haemorrhage causing traumatic-haemorrhagic shock (THS) is
the leading cause of potentially preventable deaths from severe trauma. Uncorrected
hypervolaemia and prolonged shock cause severe tissue hypoperfusion, vital organ ischemia and
subsequently acidosis. Shock, acidosis and hypothermia are recognized drivers of
anti-coagulant and fibrinolytic pathways. In up to one third of trauma patients, laboratory
findings suggest traumatic induced coagulopathy, which is further triggered by loss or
dilution of coagulation factors. These patients have a significantly increased morbidity and
mortality compared to patients with similar injury patterns without coagulopathy. Minimizing
the time to surgical control of haemorrhage is key in order to improve outcome. However,
immediate and goal directed volume and coagulation resuscitation including use of blood
product transfusion is crucial to enable survival until definitive hospital care.
Role of HEMS in a trauma system. Helicopter Emergency Medical Services (HEMS) can rapidly
deliver advanced medical care and speed up patient transport to designated trauma centres. In
the Czech Republic, HEMS covers 76.5% of the area and 99.4% of the population of the Czech
Republic within 20 minutes since the emergency call is received via Emergency Medical
Dispatch Centre (EMDC). HEMS Hradec Kralove is one of the well-recognized systems in the
country. Its catchment area is 1.1 million inhabitants living in the Hradec Kralove and
Pardubice regions. Trauma patients include 100-120 multiple trauma injuries and 50-60
isolated traumatic brain injuries (TBI) annually. In 2017, there were 95.9% primary flights
(to the scene of accident), of which 81.9% take-offs were decided by EMDC dispatchers
immediately after receiving an emergency call. Management of patients in THS requires early
identification of the bleeding source, use of effective techniques to stop compressible
haemorrhage, support of clot formation and minimisation of on-going blood loss in
non-compressible haemorrhage, judicious fluid resuscitation with monitoring of effect, and a
pre-alert system for damage control resuscitation or surgery at the receiving hospital. HEMS
teams must be skilled to recognise and treat massive bleeding and acute traumatic
coagulopathy in the pre-hospital environment.
Diagnostics of THS. Haemorrhage leads to a fall in systemic filling pressure and venous
return. The resulting decrease in cardiac minute volume, and therefore in oxygen and nutrient
supply, sets off an endogenous stress response aiming to maintain perfusion pressure. Thus,
blood pressure and heart rate must be interpreted with caution, and cardiac output might have
dropped to some 60% until blood pressure will start to decrease. Although a systolic blood
pressure <90 mmHg is the typically considered as the leading symptom of hypovolemic shock,
clinical assessment of trauma patients comprises on-going and repeated evaluation of the
mental status, capillary filling time, clinical appearance, changes in heart rate, and
mechanism of injury. Current literature suggests that the combined evaluation of heart rate,
SABP, Glasgow Coma Scale (GCS) and the ability to maintain a patent airway increases the
predictability for advanced in-hospital interventions up to four times. This is of particular
importance for an in-hospital blood transfusion request policy. Suitable triggers for
preparation for massive transfusion are suspicion or evidence of active haemorrhage, incl.
trauma triage criteria, systolic arterial blood pressure (SABP) < 90 mmHg, failure to respond
to a fluid bolus, heart rate > 120/min, and penetrating injuries. Accordingly, physical
examination on scene should focus on injury patterns known to cause haemorrhage such as
penetrating trauma, pelvic or femoral fractures and blunt abdominal trauma.
Prehospital treatment of THS. The up-to-date concept of initial trauma care is called damage
control resuscitation, which comprises hypotensive resuscitation, haemostatic resuscitation
and damage control surgery. Control of haemorrhage is crucial in order to interrupt the
vicious circle of blood loss, hypervolaemia, hypoperfusion, acidosis and coagulopathy,
finally resulting in therapy refractory shock and death. Basic techniques like direct
compression, pressure dressings, tourniquets, traction devices and pelvic splints are used
routinely in obvious or suspicious bleeding. In life threatening haemorrhagic shock, fluid
resuscitation is still the main stem therapy. The primary and ultimate goal of pre-hospital
fluid resuscitation is to prevent hypovolemic cardiac arrest and to minimize organ damage
caused by prolonged or uncorrected hypotension causing organ ischemia. For this reason
permissive hypotension should only be applied in the first hour after the insult. There are
extensive side effects of fluid resuscitation in uncontrolled bleeding patients.
Inappropriate or over-infusion has been shown to harm and to worsen outcome. Hypotensive
resuscitation is a temporary strategy for management of patients with uncontrolled blood loss
until the source of bleeding is controlled. Fluid resuscitation should be spared or postponed
in patients with uncontrolled haemorrhage, normal mental status and SABP > 90 mmHg. Fluids
should be titrated in uncontrolled bleeding patients without head trauma to a target SABP
around 90 mmHg. However, it is noteworthy that the concept of hypotensive resuscitation must
be tailored and adjusted to the patients need. In patients with severe traumatic brain injury
higher SABP must be achieved with higher amounts of fluids and very seldom use of vasopressor
drugs when necessary. There is an on-going debate which fluids and what amounts should be
considered optimal for haemorrhagic shock management. Colloids did not show to improve
outcome when compared with crystalloids. The same is true for hyperosmolar solutions.
Compared to the United Kingdom, Scandinavia and other highly developed countries, there are
no prehospital blood products currently available in Central, Southern and Eastern Europe,
partially because of high logistic and material demands, risk of wasting, high expenses, and
unproven benefit of prehospital use of red blood cells without plasma.
Co-operation between HEMS and a trauma centre. The regional trauma system in the Hradec
Kralove Region has been gradually developed during last couple of years. One of its main
advantages is excellent long-term co-operation between EMDC, HEMS, and receiving trauma
centre, incl. quality management. There are different triage tools used to help to outline
patient routes to trauma centres. These latter can include immediate need for blood or life
saving surgery. In Hradec Kralove, it was for the first time in the Czech Republic, when a
new concept of trauma triage was implemented and improved on-scene triage. The triage
criteria were adopted from the American College of Surgeons (ACS) and include: mechanism of
injury (e.g. fall from height > 6 m, person trapped in a vehicle), anatomical and
physiological criteria, and selected special considerations (e.g. age, comorbidities). Its
specificity is 8-10% and sensitivity 95-97%. The same triage system was later implemented
into all other prehospital systems, integrated into the nation-wide recommendations of the
Ministry of Health (Trauma Care in the Czech Republic) and Guidelines of the Czech Society
for Emergency and Disaster Medicine ČLS JEP. Use of pre-hospital triage can predict risk of
THS and need for specialized trauma care.
Prehospital blood transfusion. Haemostatic resuscitation is the very early use of blood
products as primary resuscitation fluid to prevent exsanguination by trauma-induced
coagulopathy. The recommended ratio of packed red cells, fresh frozen plasma and platelets is
1:1:1. In a few locations around the world, physician led HEMS teams provide advanced medical
interventions such as thoracotomy, resuscitative endovascular balloon occlusion of aorta
(REBOA), and blood product (BP) transfusion which traditionally occurred in the highly
specialized hospital centres. Administration of BPs in a helicopter has been studied in
specific cohorts including either longer transport times to definitive treatment facility,
high prevalence of penetrating thorax and epigastrium injuries, or war injuries with
restricted medical care. The potential role of packed red blood cells is yet to be
identified, although many HEMS systems already demonstrated feasibility. Recent systematic
review searching bibliographic databases to July 2015 did not identify any prospective
comparative or randomized studies on prehopsital use of BPs. A single study showed improved
survival in the first 24 hours, but vast majority of studies provided very low quality of
evidence. None of these studies was performed on a cohort of patients similar to the
population treated in our setting: blunt injuries and short prehospital times. Transfusion
reactions were rare, suggesting the short-term safety of prehospital BP administration equal
to those occurring at emergency departments. Current practice at the HEMS Hradec Kralove is
to prealert the admitting facility and request blood products from the scene. These are
available after helicopter arrival at hospital. It was calculated that availability of BPs on
board would result in earlier BP transfusion for at least 20-30 minutes compared to current
situation.
Hypothesis. Given evidence in support of massive transfusion protocol in hospitals, the
investigators hypothesize that early prehospital BP transfusion will be associated with lower
risk of THS and coagulopathy on admission to the trauma centre, and during 24 hours after
admission. Lower requirements for BP transfusion during 24 hours after admission, improved
24-hour mortality, and outcome on discharge from hospital are also expected.
Statistical analysis. Conditional logistic regression and mixed-effects linear regression
will be used to determine the association of early administration of BP transfusion with
outcome variables. Patients receiving BP transfusion are supposed to be more severely injured
with a higher risk of mortality. Because of this, we cannot compare their outcome data to
those of patients without prehospital BP transfusions, but with a retrospective cohort of
patients who had received massive transfusion protocol already requested by HEMS from the
scene during the period of previous 12/24 months before implementation of BP transfusion into
HEMS. To prevent selection bias, the propensity score model will be developed to predict the
likelihood of receiving BP transfusion based on several prehospital variables to allow
appropriate matching of treated and control patients based on this probability of receiving
BP transfusion. Covariates in the propensity score model will include age, SABP, heart rate,
crystalloid volume before HEMS arrival (if given by a ground ambulance team), crystalloid
volume during HEMS transport, type of injury (blunt vs. penetrating), prehospital time and
distance to hospital. Covariates for 24-hour survival will include at least sex, Injury
Severity Score (ISS), SABP, heart rate and Glasgow Coma Score (GCS) at admission, INR,
rotational thromboelastometry (ROTEM) parameters (e.g. clotting time, alfa-angle), intensive
care unit admission, days of mechanical ventilation, and need for surgery. Similar covariates
will be used for THS and trauma induced coagulopathy indicators. Subgroup analysis will be
performed for patients with traumatic cardiac arrest.
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