Cerebrospinal fluid markers of central nervous system injury in decompression illness - a case-controlled pilot study.

INTRODUCTION: Decompression sickness (DCS) may cause a wide variety of symptoms, including central nervous system (CNS) manifestations. The main objective of this study was to examine whether DCS is associated with neuronal injury, and whether DCS could result in altered amyloid metabolism. METHODS: Seven, male divers with DCS and seven age-matched controls were included in the study. All the divers were treated by recompression but the controls did not receive hyperbaric oxygen. Cerebrospinal fluid (CSF) samples were collected 7-10 days after the diving injury and at three months follow-up. CSF biomarkers of neuronal injury, astroglial Injury/activation, and a range of markers of amyloid ß (Aß) metabolism, as well as two proinflammatory interleukins, were analysed using immunochemical methods. RESULTS: There were no significant differences in the best-established CSF markers of neuronal injury, total tau (T-tau) and neurofilament light, between DCS patients and controls or between the two sampling time points. Also, there were no significant changes in the astroglial or amyloid (Aß)-related markers between DCS patients and controls. However, the only diver with CNS symptoms had the highest levels of CSF T-tau, Aß38, Aß40 and Aß42. CONCLUSION: The results of our study speak against subclinical CNS injury or induction of inflammation or amyloid build-up in the brain among the six DCS patients without neurological symptoms. Further research, including on divers with CNS DCS, is justified.

Case report on a diver with type II decompression sickness and viral meningitis.

A 33-yr-old man came to the emergency department with the chief complaint of a severe headache and decreased sensation in his right hand following a deep dive on scuba. Physical examination before recompression treatment was remarkable only for hypesthesia on the right hand. We diagnosed type II decompression sickness and the patient underwent standard recompression therapy. The patient experienced near-complete resolution of his symptoms, his only residual complaint being that of neck pain with head movement. To investigate other causes of headache, a computed tomography of the head was performed which was normal, and a lumbar puncture was performed which was consistent with viral meningitis. This is the first reported case of recompression treatment on a patient with viral meningitis and decompression sickness.

Mechanisms underlying spinal cord damage in decompression sickness.

Decompression sickness, which damaged the spinal cord, was produced in anesthetized dogs using a compression chamber. Cerebrospinal fluid pressure and several intravascular and intracardiac pressures were monitored during the course of the simulated dives. Manometric responses to forcible lung inflation and abdominal compression were measured both predive and postdive after signs of spinal cord damage were evident. Cinevenography of the epidural vertebral venous system was performed both predive and postdive. Histopathologic studies of the brains and cords of both predive and postdive. Histopathologic studies of the brains and cords of paretic animals were carried out. The results indicate that the epidural vertebral venous system becomes obstructed during spinal cord damaging decompression sickness and strongly suggests that spinal cord infarction in decompression sickness is caused by obstruction of cord venous drainage at the level of the epidural vertebral venous system.