Active clinical trials for "Decompression Sickness"

The impact of oxygen therapy in many pathologies has been subject of recent work, arguing both favourable and harmful effects. Consequently, one can wonder about the influence of hyperoxic gas mixture during diving on the genesis of decompression sickness, but also about the systematic application of normobaric and hyperbaric oxygen in case of proven decompression sickness. In mammals, normoxic concentrations have been redefined at 20-100 mbars at the extracellular level and below 10 mbars in the mitochondria. Under hyperbaric conditions, most of the oxygen being dissolved in blood plasma, a state of hyperoxia is established which escapes the usual delivery and regulation system represented by red blood cells. The results of our team's previous work suggest a specific effect of diving on the levels of circulating mitochondrial DNA (mtDNA), suggesting cellular destruction linked to hyperoxia/hyperbaria. In fact, our studies, carried out on both animals and human divers, have shown that diving accident leads to an increase in mtDNA levels and an immune reaction through the mobilisation of leukocytes. The main objective of this study is to compare the influence of oxygen partial pressure levels on the evolution of clinical and biological variables during hyperbaric oxygen therapy sessions in healthy versus injured divers.

Research hypothesis There is a correlation between the quantity of fluid markers of CNS injury in blood and DCS. There is a correlation between quantity and kind of fluid markers of CNS injury in blood and both diving profile and severity of DCS. There is a correlation between the quantity of inflammatory markers in blood an DCS. Objectives: Assess whether individuals suffering decompression sickness exhibit fluid markers of central nervous system injury. Evaluate the correlation between quantity and kind of fluid marker of CNS injury and clinical signs of neurological impairment. Evaluate the correlation between quantity and kind of fluid marker of CNS injury and clinical outcome after 3-6 months. Assess whether individuals suffering decompression sickness exhibit inflammatory markers in blood.

Video intubating stylet can be safely and effectively used for nasotracheal intubation, but the optimal bending angle is still unknown. In this study, the optimal bending angle will be determined by comparing the intubation time and success rate of nasotracheal intubation with video intubating stylet at two different bending angles.

The purpose of this study is to comparing the effects of different double-lumen endotracheal tube's bending type in tracheal intubation.

For tracheal intubation with a lightwand, adequate bending angle was not exactly investigated. The purpose of the study is compare three bending angles of lightwands for safe and efficient tracheal intubation.

Primary objective: - Assessment of venous gas emboli load post diving when breathing normobaric oxygen compared to air. Secondary objective: Assessment of fluid markers of central nervous system injury in blood post diving Assessment of fluid markers of inflammation and endothelial dysfunction in blood post diving Tertiary objective: - Assessment of DCS frequency

Carbon plates inserted in competitive running shoes have been increasingly used in the past 2-3 years and several investigations have shown that these plates increase the longitudinal bending stiffness (LBS) of the shoe. It leads to a redistribution of muscle work and to a modification of the force generation conditions, which may reduce the energy cost of running (Cr) and improve performance.

The aims of this proposal are to test current USN procedures for adjusting decompression procedures during air diving at 8,000 and 10,000 ft altitude and to provide a decompression algorithm for no-stop dives to 100 feet of sea water (fsw) at 10,000 and 12,000 ft altitude using enriched O2 (PO2=1.3 ATM). Additionally, the experiments will determine whether a period of hyperbaric hyperoxia, such as would be experienced during a dive at altitude, reverses altitude acclimatization, resulting in a return of acute mountain sickness (AMS) symptoms.

SCUBA diving frequently involves repetitive exposures over multiple days. The goal of this study was to see how exercise impacts microparticles (MPs), endothelial function, and venous gas emboli (VGE) over a series of dives. 16 divers in 2 groups each completed 6 dives. One group completed 3 control dives followed by 5 days rest then 3 dives preceded by exercise. The other group completed the opposite protocol. Flow-mediated dilation (FMD) data and blood for MP analysis was collected before and after each dive. VGE were monitored via transthoracic echocardiography 30, 60, and 90 min after surfacing. Exercise before diving consisted of 60 min running outdoors including 8x4 min intervals at 90% VO2max effort.

Decompression sickness syndrome (DCS) is caused by microbubbles forming in blood vessels or tissues during a reduction in environmental pressure (decompression). Bubbles have mechanical, embolic and biochemical effects with manifestations ranging from none to fatal. By reducing bubble volume and hastening inert gas elimination, recompression therapy with hyperbaric treatment remains the main therapy for DCS. The most common hyperbaric protocol used, is based on US Navy Treatment table 6, started as early as possible after surfacing. The outcome of hyperbaric therapy varies with reported complete resolution in 13%-63% of the patients suffering from severe DCS, and in 73%-100% of the patients with mild-moderate DCS. The significance of time to recompression is controversial. It has been suggested that early hyperbaric treatment improves the outcome by decreasing bubble size and avoiding further tissue injury. However, in recent studies time to recompression had very little effect on clinical recovery. Moreover, the time beyond which hyperbaric treatment isn't effective has not been determined yet. The aim of this study was to evaluate the clinical outcome of delayed hyperbaric treatment to divers who referred to tertiary care hospital hyperbaric unit, more than 48 hours after surfacing. The clinical outcome of the delayed hyperbaric treatments was compared to early treatments given at the same hyperbaric unit.