Pneumoperitoneum usually indicates rupture of a hollow viscus and considered a surgical emergency. But air may also enter the peritoneum from the lung or the genital organs in female without visceral perforation. While scuba diving, the rapid ascent is usually controlled by placing in a decompression chamber and the excess gas volume is exhaled. Failure to allow this excess gas to escape will result in overdistension of air passage, which may rupture resulting in pulmonary interstitial emphysema or, if air enters the circulation, air embolus can occur. Pneumo-peritoneum is a rare complication of diving accidents. While the majority of cases are not related to an intraabdominal catastrophy, more than 20% have been the result of gastric rupture. We report a 42-yr-old male patient with massive pneumoperitoneum after scuba diving, who presented himself with dyspnea and abdominal distension. Knowledge of this rare condition and its benign course may allow the emergency physician and surgeon to order appropriate studies to help avoid unnecessary surgical treatment. It is important to determine promptly whether the air emanated from a ruptured viscus or was introduced from an extraperitoneal source. Free air in the abdomen does not always indicate a ruptured intra-abdominal viscus.
Adult ; Diving/adverse effects* ; Female ; Human ; Male ; Pneumoperitoneum/diagnosis* ; Pneumoperitoneum/etiology* ; Radiography, Abdominal ; Radiography, Thoracic

OBJECTIVETo analyze and summarize the characteristics and treatment of acute spinal cord decompression sickness. To explore the factors that influence the treatment effect.

METHODS77 cases of acute spinal cord decompression sickness patients should be divided into 4 groups according to the pressurized treatment and drug treatment options. They were group I, group II, group III and group IV. At the same time they were get hyperbaric oxygen therapy and other treatment. The evaluation index, were Frankel function classification and paraplegia index. There were 17 factors that affected the treatment effect.

RESULTSThe rate of early cure was 57.14% (44/77). The rate of late cure was 74.03% (57/77). Their difference was statistically significant (P<0.05). In 3 months and 1 year the cure rate of group IV and group B were the highest. But there was no difference between them(P>0.05). They were higher than group ii and group I (P<0.05). The Frankel function classification in 3months and 1 year in each group was higher than before treatment (P<0.05). The paraplegia index in 3 months and 1 year in each group was lower than before treatment (P<0.05). In 3 months and 1 year the Frankel function classification was increased gradually and the paraplegia index was decreased gradually in group I , group II, group III (P<0.05). In group IV and group III the Frankel function and the paraplegia index had not significant difference (P>0.05). Among the 17 factors that affect the treatment effect there are 9 factors that affect the proportion of the large.

CONCLUSIONSThe first choice of treatment method for the patients with acute spinal cord decompression sickness would be group III. Drug therapy was also imporpant. At the same time the hyperbaric oxygen therapy and other treatments were taken. Although the cure rate was not high in this article. But most of the cure is within 3 months. Within 1 year.the cure rate still could be improved. 9 factors that affect the efficacy of acute spinal cord decompression sickness was more noteworthy.

Decompression Sickness ; therapy ; Diving ; adverse effects ; Humans ; Hyperbaric Oxygenation ; Paraplegia ; physiopathology ; therapy ; Spinal Cord ; physiopathology

OBJECTIVETo clinically characterize the divers who suffer from decompression sickness in group after diving, optimize therapeutic treatment settings for grouped patients where the conventional individualized treatment cannot be implemented.

METHODSClinical parameters of patients such as age, professional seniority in dive, labor intensity, diving depth and their symptoms were statistically categorized to identify the factors that correlate with treatment efficacy and recurrence rate. In accordance with the symptoms and the reactions to pressure, 4 treatment programs were applied: Program A, Program B, Program C, Program D.

RESULTS(1) age, professional seniority, diving depth, length of service, dive frequency were positively correlated with the treatment efficacy (P<0.05, P<0.01), and these parameters together with pain intensity were also positively correlated with recurrence risk (P<0.05, P<0.01), while long latency time of the disease often related with poor therapeutic outcome and high recurrence rate (P<0.01), (2) pain intensity were positively affected by age, diving depth and dive frequency (P<0.05, P<0.01), whereas negatively affected by disease latency time (P<0.01), (3) Four elements in this clinic project, selection of treatment program, length of service, diving depth and disease latency time of patient, were responsible for (or: could account for) 48.0% change of treatment efficacy, (4) Among Programs using different therapeutic pressure, Program D, C and B had better outcomes than Program A (P<0.01, P<0.05). Also, less patients in Program D, C and B suffered from recurrence with relative to Program A (P<0.01, P<0.05), (5) Between Programs adopting same hyperbaric pressure and treatment duration time, Program D was more efficient and fewer recurrent cases were found in it if compared to Program B (P<0.05), (6) In programs with same pressure and duration time settings, Program D was remarkably superior to program C in regard of its treatment efficacy.

CONCLUSIONSIn condition with only limited clinic supplies, Program D could be the first choice to provide the hyperbaric oxygen as an ideal group treatment, and it is not very necessary for the clinician to provide individualized therapy. An appropriate extension of stay in hyperbaric chamber may apply to some patients but depending on the clinical symptoms, however, no longer time than 120 min is recommended.

Acute Disease ; Adult ; Decompression Sickness ; etiology ; therapy ; Diving ; adverse effects ; Humans ; Treatment Outcome

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.
Barotrauma/complications* ; Decompression Sickness/complications* ; Diving/adverse effects* ; Embolism, Air/etiology* ; Humans ; Lung Injury ; Male

Acetates ; pharmacology ; Animals ; Disease Models, Animal ; Diving ; adverse effects ; Ear Canal ; injuries ; Nitrogen ; Oxygen ; Protective Agents ; pharmacology ; Rabbits

OBJECTIVETo investigate whether a simulated He-O2 saturation dive to 65 msw would affect oxidative balance in humans.

METHODSSeven divers participated in a simulated saturation dive to 0.75 MPa (65 msw). 24-h urine samples were collected twice before, twice during, and twice after the dive, then were analyzed for contents of superoxide dismutase (SOD), malondialdehyde (MDA), total amino acid (T-AA) and total anti-oxidant capacity (T-AOC). Meanwhile, total urine volume and body weight were measured.

RESULTSThe content of T-AA was higher. (P < 0.05) than the base value in final decompression, but reverse to normal at one week after decompression. There were no changes in contents of SOD, MDA and T-AOC during and after the dive compared with their basic value. Total urine volume was lower (P < 0.05, vs basic value) at first day in chamber, then returned to normal. Body weight gradually increased after compression till the end of decompression (higher than basic value, P < 0.05).

CONCLUSIONThese data indicate that simulated saturation dive to 65 msw may not induce obvious oxidative damage, but it is necessary to monitor 24-h urine volume and oxidative sress by time in order to prevent from tissue injury.

Adult ; Amino Acids ; urine ; Decompression ; Diving ; physiology ; Helium ; chemistry ; Humans ; Male ; Malondialdehyde ; urine ; Oxidative Stress ; physiology ; Oxygen ; adverse effects ; chemistry

AIMTo investigate the preventive effects of Panax notoginseng saponins (PNS) and Ginkgo biloba extracts (GbE) on acute oxygen toxicity and the possible mechanisms.

METHODSMice were injected intraperitoneally with PNS and GbE for 5 days, then were exposed to 500 kPa hyperbaric oxygen (HBO) for 60 min, the convulsion latency, times and interval were observed. Moreover, reactive oxygen (RO) unit, MDA, NO, GSH levels and GSH-Px, CAT, MAO activities of mice brain were determined after they were exposed to HBO for 15 min.

RESULTSPNS and GbE could markedly prolong the convulsion latency and interval, reduce convulsion times, decrease contents of MDA and NO in mice brain, keep RO unit, GSH and GSH-Px at higher levels, but had no effects on CAT and MAO activities.

CONCLUSIONPNS and GbE could effectively prevent acute oxygen toxicity, which were related to their antioxidant activities.

Animals ; Antioxidants ; pharmacology ; Diving ; adverse effects ; Ginkgo biloba ; Hyperbaric Oxygenation ; adverse effects ; Male ; Mice ; Oxygen ; poisoning ; Panax notoginseng ; Phytotherapy ; Plant Extracts ; pharmacology ; Saponins ; pharmacology

This study aimed to establish an animal model of decompression-induced lung injury (DILI) secondary to repetitive diving in mice and explore the role of macrophages in DILI and the protective effects of high-concentration hydrogen (HCH) on DILI. Mice were divided into three groups: control group, DILI group, and HCH group. Mice were exposed to hyperbaric air at 600 kPa for 60 min once daily for consecutive 3 d and then experienced decompression. In HCH group, mice were administered with HCH (66.7% hydrogen and 33.3% oxygen) for 60 min after each hyperbaric exposure. Pulmonary function tests were done 6 h after decompression; the blood was harvested for cell counting; the lung tissues were harvested for the detection of inflammatory cytokines, hematoxylin and eosin (HE) staining, and immunohistochemistry; western blotting and polymerase chain reaction (PCR) were done for the detection of markers for M1 and M2 macrophages. Our results showed that bubbles formed after decompression and repeated hyperbaric exposures significantly reduced the total lung volume and functional residual volume. Moreover, repetitive diving dramatically increased proinflammatory factors and increased the markers of both M1 and M2 macrophages. HCH inhalation improved lung function to a certain extent, and significantly reduced the pro-inflammatory factors. These effects were related to the reduction of M1 macrophages as well as the increase in M2 macrophages. This study indicates that repetitive diving damages lung function and activates lung macrophages, resulting in lung inflammation. HCH inhalation after each diving may be a promising strategy for the prevention of DILI.
Animals ; Cell Polarity ; Diving/adverse effects* ; Lung/physiology* ; Lung Injury/etiology* ; Macrophages/physiology* ; Male ; Mice ; Mice, Inbred BALB C ; Pulmonary Edema/etiology*