gas embolism
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2021 ◽  
Vol 11 (1) ◽  
Author(s):  
D. Franchini ◽  
C. Valastro ◽  
S. Ciccarelli ◽  
P. Trerotoli ◽  
S. Paci ◽  
...  

AbstractSea turtles that are entrapped in static and towed nets may develop gas embolism which can lead to severe organ injury and death. Trawling characteristics, physical and physiologic factors associated with gas-embolism and predictors of mortality were analysed from 482 bycaught loggerheads. We found 204 turtles affected by gas-embolism and significant positive correlations between the presence of gas-embolism and duration, depth, ascent rate of trawl, turtle size and temperature, and between mortality and ascent time, neurological deficits, significant acidosis and involvement of > 12 cardiovascular sites and the left atrium and sinus venosus-right atrium. About 90% turtles with GE alive upon arrival at Sea Turtle Clinic recovered from the disease without any supportive drug therapy. Results of this study may be useful in clinical evaluation, prognostication, and management for turtles affected by gas-embolism, but bycatch reduction must become a priority for major international organizations. According to the results of the present study the measures to be considered to reduce the catches or mortality of sea turtles for trawling are to be found in the modification of fishing nets or fishing operations and in greater awareness and education of fishermen.


Trials ◽  
2021 ◽  
Vol 22 (1) ◽  
Author(s):  
Danfeng Jin ◽  
Mingyue Liu ◽  
Jian Huang ◽  
Yongfeng Xu ◽  
Luping Liu ◽  
...  

Abstract Background Gas embolism induced by CO2 pneumoperitoneum is commonly identified as a risk factor for morbidity, especially cardiopulmonary morbidity, after laparoscopic liver resection (LLR) in adults. Increasing pneumoperitoneum pressure (PP) contributes to gas accumulation following laparoscopy. However, few studies have examined the effects of PP in the context of LLR. In LLR, the PP-central venous pressure (CVP) gradient is increased due to hepatic vein rupture, hepatic sinusoid exposure, and low CVP management, which together increase the risk of CO2 embolization. The aim of this study is to primarily determine the role of low PP (10 mmHg) on the incidence of severe gas embolism. Methods Adult participants (n = 140) undergoing elective LLR will be allocated to either a standard (15 mmHg) or low (10 mmHg) PP group. Anesthesia management, postoperative care, and other processes will be performed similarly in both groups. The occurrence of severe gas embolism, which is defined as gas embolism ≥ grade 3 according to the Schmandra microbubble method, will be detected by transesophageal echocardiography (TEE) and recorded as the primary outcome. The subjects will be followed up until discharge and followed up by telephone 1 and 3 months after surgery. Postoperative outcomes, such as the Post-Operative Quality of Recovery Scale, pain severity, and adverse events, will be assessed. Serum cardiac markers and inflammatory factors will also be assessed during the study period. The correlation between intraoperative inferior vena cava-collapsibility index (IVC-CI) under TEE and central venous pressure (CVP) will also be explored. Discussion This study is the first prospective randomized clinical trial to determine the effect of low versus standard PP on gas embolism using TEE during elective LLR. These findings will provide scientific and clinical evidence of the role of PP. Trial status Protocol version: version 1 of 21-08-2020 Trial registration ChiCTR2000036396 (http://www.chictr.org.cn). Registered on 22 August 2020.


2021 ◽  
pp. 1051-1098
Author(s):  
Andrew Kane ◽  
Richard Armstrong ◽  
Jerry P Nolan ◽  
Jasmeet Soar ◽  
Sorcha Evans ◽  
...  

This chapter discusses anaesthetic emergencies. It begins with a description of adult basic life support (BLS) and advanced life support (ALS). It goes on to describe post resuscitation care; severe bradycardia; tachycardia; severe hypo- or hypertension; severe hypoxia; laryngospasm; air/ gas embolism; gastric aspiration; severe bronchospasm; pulmonary oedema; anaphylaxis; latex allergy; intra-arterial injection; incomplete reversal of neuromuscular blockade; local anaesthetic toxicity; failed intubation; the can’t-intubate-can’t-oxygenate (CICO) scenario and malignant hyperthermia (MH).


2021 ◽  
Vol 27 (5) ◽  
pp. 362-365
Author(s):  
Jeffrey CW Chau ◽  
Joe KS Leung ◽  
WW Yan

2021 ◽  
Vol 51 (3) ◽  
pp. 303-305
Author(s):  
Lionel Bapteste ◽  
◽  
Zeinab Kamar ◽  
Anthony Mazaud ◽  
Baptiste Balança ◽  
...  

Only a few clinical cases of cerebral arterial gas embolism during spinal surgery are published. It seems important not to overlook this diagnosis in order to initiate rapid appropriate treatment. This was a suspected case of paradoxical gas embolism revealed postoperatively by neurological deficits and whose recovery was noted during hyperbaric oxygen treatment. Unfortunately, no complementary examination showed gas embolism and only the context, the clinical picture and the case evolution evoke this diagnosis. The diagnostic difficulty in the immediate postoperative period is highlighted.


2021 ◽  
Vol 12 ◽  
Author(s):  
Kiyotaka Kohshi ◽  
Petar J. Denoble ◽  
Hideki Tamaki ◽  
Yoshitaka Morimatsu ◽  
Tatsuya Ishitake ◽  
...  

Nitrogen (N2) accumulation in the blood and tissues can occur due to breath-hold (BH) diving. Post-dive venous gas emboli have been documented in commercial BH divers (Ama) after repetitive dives with short surface intervals. Hence, BH diving can theoretically cause decompression illness (DCI). “Taravana,” the diving syndrome described in Polynesian pearl divers by Cross in the 1960s, is likely DCI. It manifests mainly with cerebral involvements, especially stroke-like brain attacks with the spinal cord spared. Neuroradiological studies on Ama divers showed symptomatic and asymptomatic ischemic lesions in the cerebral cortex, subcortex, basal ganglia, brainstem, and cerebellum. These lesions localized in the external watershed areas and deep perforating arteries are compatible with cerebral arterial gas embolism. The underlying mechanisms remain to be elucidated. We consider that the most plausible mechanisms are arterialized venous gas bubbles passing through the lungs, bubbles mixed with thrombi occlude cerebral arteries and then expand from N2 influx from the occluded arteries and the brain. The first aid normobaric oxygen appears beneficial. DCI prevention strategy includes avoiding long-lasting repetitive dives for more than several hours, prolonging the surface intervals. This article provides an overview of clinical manifestations of DCI following repetitive BH dives and discusses possible mechanisms based on clinical and neuroimaging studies.


2021 ◽  
Vol 12 ◽  
Author(s):  
Nathan J. Robinson ◽  
Daniel García-Párraga ◽  
Brian A. Stacy ◽  
Alexander M. Costidis ◽  
Gabriela S. Blanco ◽  
...  

Sea turtles, like other air-breathing diving vertebrates, commonly experience significant gas embolism (GE) when incidentally caught at depth in fishing gear and brought to the surface. To better understand why sea turtles develop GE, we built a mathematical model to estimate partial pressures of N2 (PN2), O2 (PO2), and CO2 (PCO2) in the major body-compartments of diving loggerheads (Caretta caretta), leatherbacks (Dermochelys coriacea), and green turtles (Chelonia mydas). This model was adapted from a published model for estimating gas dynamics in marine mammals and penguins. To parameterize the sea turtle model, we used values gleaned from previously published literature and 22 necropsies. Next, we applied this model to data collected from free-roaming individuals of the three study species. Finally, we varied body-condition and cardiac output within the model to see how these factors affected the risk of GE. Our model suggests that cardiac output likely plays a significant role in the modulation of GE, especially in the deeper diving leatherback turtles. This baseline model also indicates that even during routine diving behavior, sea turtles are at high risk of GE. This likely means that turtles have additional behavioral, anatomical, and/or physiologic adaptions that serve to reduce the probability of GE but were not incorporated in this model. Identifying these adaptations and incorporating them into future iterations of this model will further reveal the factors driving GE in sea turtles.


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