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Gas Embolism (gas + embolism)

Distribution by Scientific Domains
Medical Sciences100%

Selected Abstracts

CT31 HYPERBARIC OXYGEN IN POST-CARDIAC SURGERY STROKE PATIENTS , THE CHRISTCHURCH EXPERIENCE

ANZ JOURNAL OF SURGERY, Issue 2007
A. J. Gibson
Introduction Post-operative strokes occur in a small percentage of adult cardiac surgical patients and have devastating consequences for these patients. There is evidence to suggest that Cerebral Arterial Gas Embolism (CAGE) is an important aetiological factor in most of these cases. Hyperbaric Oxygen therapy (HBOT) is the administration of 100% oxygen at greater than atmospheric pressure. It is accepted as the definitive treatment for CAGE related to SCUBA diving accidents. The similarities between this and the pathophysiology of post cardiac-surgical strokes due to iatrogenic CAGE suggest that beneficial effects from HBOT may accrue to these patients. Purpose The purpose of this study is to review the experience of treating post cardiac-surgical stroke patients in our local hyperbaric oxygen facility, including their presentation, delay before treatment and outcomes. The current evidence base is reviewed. Method A retrospective case series analysis was conducted. Results Over a 10 year period, patients with post cardiac-surgical strokes and who presented within the first 48 hours were referred for HBOT, of whom 12 were treated. The neurological outcomes were excellent in all but one case who died. A review of the literature provides a rational basis for the potential benefits of HBOT in this scenario, but at present there is only limited clinical data to support its use. Conclusion The postulated mechanisms for the development of post cardiac-surgical strokes provide a sound theoretical basis for the suggestion that the use of HBOT is associated with improved outcomes. However there is no prospective data to support such a claim. Such a trial would be problematic and until more evidence is available, HBOT should be considered on a case by case basis. [source]

Gas embolism: pathophysiology and treatment

CLINICAL PHYSIOLOGY AND FUNCTIONAL IMAGING, Issue 5 2003
Robert A. van Hulst
Summary Based on a literature search, an overview is presented of the pathophysiology of venous and arterial gas embolism in the experimental and clinical environment, as well as the relevance and aims of diagnostics and treatment of gas embolism. The review starts with a few historical observations and then addresses venous air embolism by discussing pulmonary vascular filtration, entrapment, and the clinical occurrence of venous air emboli. The section on arterial gas embolism deals with the main mechanisms involved, coronary and cerebral air embolism (CAE), and the effects of bubbles on the blood,brain barrier. The diagnosis of CAE uses various techniques including ultrasound, perioperative monitoring, computed tomography, brain magnetic resonance imaging and other modalities. The section on therapy starts by addressing the primary treatment goals and the roles of adequate oxygenation and ventilation. Then the rationale for hyperbaric oxygen as a therapy for CAE based on its physiological mode of action is discussed, as well as some aspects of adjuvant drug therapy. A few animal studies are presented, which emphasize the importance of the timing of therapy, and the outcome of patients with air embolism (including clinical patients, divers and submariners) is described. [source]

INLINE RADIOFREQUENCY ABLATION-ASSISTED LAPAROSCOPIC LIVER RESECTION: FIRST EXPERIMENT WITH STAPLING DEVICE

ANZ JOURNAL OF SURGERY, Issue 6 2007
Peng Yao
Background: In liver surgery, the increase in advancement of laparoscopic equipment has allowed the feasibility and safety of complex laparoscopic liver resection. However, blood loss and the potential risk of gas embolism seem to be the main obstacles. In this study, we successfully used the InLine radiofrquency ablation (RFA) device to carry out laparoscopic hand-assisted liver resection in pigs. Methods: Under general anaesthesia with tracheal intubation, pigs underwent InLine RFA-assisted laparoscopic liver resection. After installation of Hand Port and trocars, the InLine RFA device was introduced through Hand Port system and inserted into the premarked resection line. Then the generator was turned on and the power was applied according to the power setting. The resection was finally carried out using diathermy or stapler. For the control group, resection was simply carried out by diathermy or stapler. Results: Eight Landrace pigs underwent 23 liver resections. Blood loss was reduced significantly in the InLine group (P < 0.001) when compared with control group in both surgical methods (diathermy and stapler). Conclusion: In this study, we successfully carried out InLine RFA-assisted laparoscopic liver resection in both stapled and diathermy group. We showed that there was a highly significant difference between InLine and other liver resection techniques laparoscopically. [source]

Increased Cerebral Blood Flow And Cardiac Output Following Cerebral Arterial Air Embolism In Sheep

CLINICAL AND EXPERIMENTAL PHARMACOLOGY AND PHYSIOLOGY, Issue 11 2001
David J Williams
SUMMARY 1. The effects of cerebral arterial gas embolism on cerebral blood flow and systemic cardiovascular parameters were assessed in anaesthetized sheep. 2. Six sheep received a 2.5 mL injection of air simultaneously into each common carotid artery over 5 s. Mean arterial blood pressure, heart rate, end-tidal carbon dioxide and an ultrasonic Doppler index of cerebral blood flow were monitored continuously. Cardiac output was determined by periodic thermodilution. 3. Intracarotid injection of air produced an immediate drop in mean cerebral blood flow. This drop was transient and mean cerebral blood flow subsequently increased to 151% before declining slowly to baseline. Coincident with the increased cerebral blood flow was a sustained increase in mean cardiac output to 161% of baseline. Mean arterial blood pressure, heart rate and end-tidal carbon dioxide were not significantly altered by the intracarotid injection of air. 4. The increased cardiac output is a pathological response to impact of arterial air bubbles on the brain, possibly the brainstem. The increased cerebral blood flow is probably the result of the increased cardiac output and dilation of cerebral resistance vessels caused by the passage of air bubbles. [source]

Gas embolism: pathophysiology and treatment

CLINICAL PHYSIOLOGY AND FUNCTIONAL IMAGING, Issue 5 2003
Robert A. van Hulst
Summary Based on a literature search, an overview is presented of the pathophysiology of venous and arterial gas embolism in the experimental and clinical environment, as well as the relevance and aims of diagnostics and treatment of gas embolism. The review starts with a few historical observations and then addresses venous air embolism by discussing pulmonary vascular filtration, entrapment, and the clinical occurrence of venous air emboli. The section on arterial gas embolism deals with the main mechanisms involved, coronary and cerebral air embolism (CAE), and the effects of bubbles on the blood,brain barrier. The diagnosis of CAE uses various techniques including ultrasound, perioperative monitoring, computed tomography, brain magnetic resonance imaging and other modalities. The section on therapy starts by addressing the primary treatment goals and the roles of adequate oxygenation and ventilation. Then the rationale for hyperbaric oxygen as a therapy for CAE based on its physiological mode of action is discussed, as well as some aspects of adjuvant drug therapy. A few animal studies are presented, which emphasize the importance of the timing of therapy, and the outcome of patients with air embolism (including clinical patients, divers and submariners) is described. [source]