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Aviation medicine aspects of Aero Medical Evacuation Dr. A. Khamaki Flight Surgeon The first Aero Medical Evacuation During the siege of Paris in 1870 a total of 160 patients were removed by means of an observational balloon HISTORY The history of aero medical transportation is almost as long as the history of powered flight itself. The earliest recorded evacuation of wounded casualties by aircraft took place during the first world war (1915) when 12 Serbian patients were carried in French aircraft. The second world war heralded rapid advancement and created military casualty evacuation organizations .In the later years of conflict more tan 90% of allied casualties were evacuated by air from all theatres. The potential value of Helicopters in reducing the mortality rates of battlefield casualties demonstrated in Korean and Vietnam conflict. Aero medical transport is a rapidly developing health care concept which can decrease disability and save lives Golden time The time saving factor of Aero medical transport is often the crucial element in a patient's progress and recovery. Aero Medical Evacuation (AME) Many studies have shown that the main cause of preventable death prior to the hospitalization was loss of air way. AME can assist in early resuscitation by: Rapidly getting the patient to medical help Rapidly getting good care to patient Trained personnel should be transported to the patient, then the patient can be stabilized and transported back to the hospital. Specific considerations There are some specific aspects of transferring patients by air due to the effects of altitude and physical characteristics and limitation of the aircraft environment as well as psychological effects of flight. Problems of altitude A decrease in air density A fall in air pressure Low temperature Flight stressors Hypoxia Hyperventilation Barotraumas Low temperature Low humidity G-forces Vibration Noise Fatigue Motion sickness Jet lag D.V.T Hypoxic hypoxia Hypoxic hypoxia occurs when there is a lack of available oxygen in the atmosphere The most lethal factor of all physiological causes of accidents is Hypoxic hypoxia. Cabin mild hypoxia Although mild hypoxia, experienced in a modern airliner is not noticed by the healthy passengers, the sudden exposure to mild hypoxia may be the final step over the threshold into the significant tissue hypoxia. Conditions susceptible to Hypoxia Cardiovascular disease Respiratory disease Blood disorders Neurological disorders Cardiovascular disease Congestive heart failure Recent myocardial infarction Unstable angina Significant cardiac arrhythmia Respiratory disease Chronic bronchitis Emphysema Bronchioectasis Blood disorders Severe anemia Hemoglobinopathies Neurological disorders CVA Arteriosclerosis Epilepsy Cerebral tumors Head injuries Oxygen therapy The problems of hypoxia may be largely overcome by the use of supplementary oxygen in flight. Passengers’ own oxygen cylinders are generally unacceptable as they may not comply with safety regulations. Barotraumas Pressure changes in gas containing cavities Body gas-filled cavities Semi closed cavities: Lungs Middle ear Para nasal sinuses Closed cavities: Gastro-intestinal tract Teeth Conditions susceptible to Barotraumas Otic & sinus barotraumas Gastro-intestinal disorders Recent GI surgery Recent intestinal hemorrhage Recent laparoscopy Colostomies Paralytic ileuses/bowel obstruction Pneumothorax Head injuries Skull fractures Closed gun-shot wounds craniotomy Penetrating eye injuries Plaster of Paris Vibration Vibration can cause a deterioration in the condition of patients with head or spinal injuries. Fractures may be more painful due to movement. Motion sickness Motion sickness is a physiological response to discordant sensory information. It is characterized primarily by nausea, vomiting, pallor and cold sweating. Preventive procedures: Prophylactic anti emetics Placing the patient over the centre of gravity of aircraft Using nasogastric tube DVT (Orthostasis) Prolonged immobilization predispose the patient to deep vein thrombosis. Prophylaxis with calf movement, TED stockings or subcutaneous heparin should be instituted. Low humidity Many aircraft cabins have very low humidity (often less than 15% relative humidity). Care must be taken for: Eye and mouth Hydration Heat conservation Noise Although there is no good evidence that noise directly compromises any patient’s condition, but hearing protection is necessary. Spinal injuries Fixed traction The Soehngen vacuum mattress A full length sheepskin Core body temperature monitoring 6-12 L of oxygen by nasal tongs Betamethasone 4mg. 6hourly Head injuries Ventilator settings before transport Intubations of the patient Passing a nasogastric tube Determining presence of air in the head Monitoring of BP and PR A good IV line A urinary catheter Monitoring of core body temperature Orthopedic injuries Blood loss »» »» IV fluid administration Fractures »» »» Immobilization with splints or vacuum mattress Pain »» »» Administration of small doses of intravenous narcotics Serious burns Protection of the air way and ventilation Assessment of the degree of thermal damage Appropriate intravenous fluid administration Pain relief by suitable intravenous infusion Care of the burnt area Eye injuries The eye is sensitive to hypoxia An eye with a perforating injury is at risk of extruding the contents if there is a drop in pressure Precaution procedures for transport of Psychiatric patient Well restrained before flight Trained medical escort Sedation Prevention of barotraumas, DVT & nerve palsy. Contraindications to air travel Infectious disease Late pregnancy The moribund Offensive conditions General principles of AME Stabilize before take-off Don’t be rushed by any one Anticipate and prevent: Complications Movement induced changes Position changes التماس دعا
