Summary: | Background
The unpredictability of the nature of the next call is a basic feature of Emergency Services; the call could vary from a trauma victim, to a hypothermic patient or a prehospital birth. All patients (other than those who are pyrexic) have in common the need for a warm environment to prevent deterioration in their condition. Multiple observation studies found that patients suffering from various levels of trauma, arrived in the Emergency Department with hypothermia. Hypothermia, a core temperature <35°C, affects multiple organ systems, and is associated with poor outcomes including death. Also, cold has been reported as negatively impacting the comfort of an ill or injured patient. It is currently assumed that the ambulance patient compartment’s heater (Air Top Evo 40, Webasto™, Gilching, Germany), produces enough heat to offer thermal comfort and to help prevent further decrease of body temperature in the hypothermic patient. However, what is not clear is for how long and to what ambient temperature the ambulance’s patient compartment needs to be heated, to provide the ambulance’s furniture with sufficient stored energy to maintain the patient at an appropriate temperature for the duration of their transport to hospital. We consider how current practices and behaviours may need to be adapted to improve patient comfort and outcomes.
Objectives
This study is to determine the feasibility of measuring and monitoring temperatures in a new generation Emergency Ambulance. The overarching objective, is to optimise patient comfort, outcome and prevention of hypothermia.
Methods
Using thermocouples, a data logger and a thermal camera to record temperatures at strategic locations in the patient compartment, we recorded the variation of temperature in a typical new generation Emergency Ambulance compliant with the CEN - EN 1789:2007 standard. Thermal imaging and temperature logging studies were conducted on in May/July 2018. Temperature was logged for 24 hours. The locations examined were the stretcher mattress surface, low and high blanket storage lockers and the outdoor ambient air. The vehicle was located outdoor, facing west-north-west.
Anticipated outcome
This study will provide us with data that can be used to improve patients’ thermal comfort through behaviour and practice change.
Results
The thermal camera images show a significant variation of surface temperature throughout the patient compartment. Preliminary temperature logging experiments show a measurable difference in temperatures at the areas of interest relative to the outside temperature over 24 hours. Some variations in rates of cooling and warming in each area have been observed during the cool – heat period; the stretcher mattress is the slowest to rewarm.
Conclusion
The proposed method of measuring temperature variation in targeted locations in the patient compartment of a new generation ambulance proves efficient and could be used in further studies.
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