ABSTRACT
Pulmonary barotrauma is a kind of disease caused by the injury of lung tissue or blood vessel when the gas pressure of lung is too high or too lower than the external pressure of the body, which causes the air to enter the blood vessel and adjacent tissue. It could be happened in the escape of the divers with the light diving equipment or the sailors from submarine. Generally, the decompression chamber was used to treating the disease, and the minimum air pressure of 0.5 MPa recompression therapeutic schedule was used to selecting. In November 2019, a patient with pulmonary barotrauma combined with cerebral arterial gas embolism caused by improper underwater escape with light diving equipment was admitted to the General Hospital of Eastern War Zone. He was treated with 0.12 MPa oxygen inhalation recompression scheme in the oxygen chamber pressurized with air. 7 days later, the patient recovered and discharged.
Subject(s)
Humans , Male , Barotrauma/complications , Decompression Sickness/complications , Diving/adverse effects , Embolism, Air/etiology , Lung InjuryABSTRACT
RESUMEN Paciente masculino de 23 años de edad, buzo aficionado, que ingresó en el Hospital Militar "Dr. Joaquín Castillo Duany", con historia de haber realizado inmersiones profundas, dos días consecutivos, con escape a superficie sin realizar las paradas de descompresión establecidas, a la salida de la segunda inmersión. Comenzó a presentar de forma brusca calambres, pérdida total de la fuerza muscular en miembros inferiores y disminución de la fuerza muscular en miembros superiores, así como falta de aire, opresión torácica, relajación de esfínter anal y vesical e intranquilidad. Se diagnosticó enfermedad descompresiva grave o tipo II y barotrauma pulmonar. Fue reportado grave e ingresado en sala de terapia intensiva. Se realizó tratamiento recompresivo de urgencia. La evolución clínica resultó favorable sin peligro para la vida; aunque con secuelas neurológicas invalidantes(AU)
ABSTRACT We present a 23-year-old male patient, amateur diver, who came to Dr. Joaquín Castillo Duany Militar Hospital complaining of sudden cramps, total loss of muscle strength in lower limbs, decreased muscle strength in upper limbs, shortness of breath, chest tightness, anal and bladder sphincter relaxation and restlessness. He had done deep-sea dives in two consecutive days, with escape to the surface but not performing required decompression stops at the exit of the second dive. His diagnosis was severe decompression sickness or type II and pulmonary barotrauma. He is reported as severe and admitted to the intensive care unit. Urgent recompression treatment was performed. The clinical evolution was favorable without danger to life although with disabling neurological sequelae(AU)
Subject(s)
Humans , Male , Adult , Barotrauma/complications , Lower Extremity , Decompression Sickness , Intensive Care Units , Decompression , Muscle StrengthABSTRACT
Objective To investigate the clinical treatment and outcomes of severe community-acquired pneumonia (CAP) complicated with mediastinal emphysema after renal transplantation. Methods Clinical data of9 patients with severe CAP complicated with mediastinal emphysema after renal transplantation were retrospectively analyzed. The acute physiology and chronic health evaluationⅡ(APACHEⅡ) and oxygenation index were recorded when the patients were admitted to the intensive care unit (ICU). The complications of mediastinal emphysema and corresponding treatment were observed. The treatment course during the ICU, mortality rate in ICU, ICU stay time and hospital stay time were recorded. All patients underwent pathogenic examinations. Results The APACHEⅡ score of9 patients with severe CAP complicated with mediastinal emphysema after renal transplantation was 14 (8-21) scores and the oxygenation index was 150 (133-189) mmHg. Among 9 patients, 3 cases were infected by bacteria alone, 3 cases were infected by bacterial infection combined with viral infection, 1 case was infected by mycobacterium tuberculosis complicated with other bacterial infection and 1 case was viral infection. No pathogenic evidence was detected in the remaining 1 patient. Mediastinal emphysema complicated with subcutaneous emphysema occurred in 7 cases and pneumothorax occurred in 6 cases. Treatment methods included anti-infection, modified immunosuppressive program, mediastinal drainage, thoracic closed drainage, subcutaneous incision and extracorporeal membrane oxygenation (ECMO) treatment. Six patients received invasive mechanical ventilation (IMV), 2 received non-invasive positive pressure ventilation (NIV) and 1 received high-flow nasal oxygen cannula (HFNC). Among 9 patients, the mortality rate in ICU was 6/9, the remaining 3 patients were recovered and discharged, the ICU stay time was 26 (17-40) d, and the total hospital stay time was 27-61 d. Conclusions Mediastinal emphysema is a serious complication of patients presenting with severe CAP after renal transplantation with a high mortality rate. For these patients, imaging evaluation, timely drainage and full sedation should be strengthened, and ECMO treatment should be delivered when necessary.
ABSTRACT
Recreational diving is an exciting and adventurous sport, but is also potentially hazardous. Despite its inherent hazards, an increasing number of people enjoy SCUBA (self-contained underwater breathing apparatus) diving; the number of diving-related accidents is therefore also likely to increase. Divers might face physical or psychological stresses from the unfamiliar or hostile underwater environment, which can lead to fatal accidents. To investigate deaths related to SCUBA diving, a forensic pathologist should understand the types and mechanisms of injuries and illnesses unique to SCUBA diving. Postmortem examination of diving fatalities is therefore a formidable task for most forensic pathologists because cases are sparse and the process requires an understanding of diving physiology, diving equipment, and the underwater environment. The primary aim of autopsies in SCUBA diving fatalities is to detect evidence of pulmonary barotrauma, intravascular gas, or pre-existing illnesses. Standard autopsy protocol for SCUBA diving-related deaths should include methods to detect intravascular gas and gas accumulation in the tissue or body cavity through plain radiographs or Computerized Tomography (CT) scans. Analysis of the gas components is also helpful for determining the origin of the gas. Here, the author proposes a practical method for performing an autopsy on a person who died while SCUBA diving.