Your search keyword '"Markus F Stevens"' showing total 2 results

1. Detection of cerebral arterial gas embolism using regional cerebral oxygen saturation, quantitative electroencephalography, and brain oxygen tension in the swine

Author

Markus F. Stevens, J. Kager, R. A. van Hulst, T.M. van Gulik, Robert P. Weenink, Markus W. Hollmann, Amsterdam Cardiovascular Sciences, Amsterdam institute for Infection and Immunity, Anesthesiology, Other Research, Amsterdam Gastroenterology Endocrinology Metabolism, Surgery, and 02 Surgical specialisms

Subjects

Intracranial Pressure, Swine, Microdialysis, Statistics as Topic, Cerebral oxygen saturation, Air embolism, Brain ischemia, Outcome Assessment, Health Care, medicine, Animals, Embolism, Air, Oxygen saturation (medicine), Intracranial pressure, Chemistry, Intracranial Embolism, General Neuroscience, Brain, Electroencephalography, Quantitative electroencephalography, medicine.disease, Oxygen tension, Disease Models, Animal, Area Under Curve, Cerebrovascular Circulation, Anesthesia, Female, Blood Gas Analysis, Biomedical engineering

Abstract

Background Cerebral air emboli occur as a complication of invasive medical procedures. The sensitivity of cerebral monitoring methods for the detection of air emboli is not known. This study investigates the utility of electroencephalography and non-invasively measured cerebral oxygen saturation in the detection of intracerebrovascular air. New method In 12 pigs oxygen saturation was continuously measured using transcranial near-infrared spectroscopy and oxygen tension was continuously measured using intraparenchymal probes. Additionally, quantitative electroencephalography and microdialysis were performed. Doses of 0.2, 0.4, 0.8, and 1.6 ml of air were injected into the cerebral arterial vasculature through a catheter. Results Oxygen saturation and electroencephalography both reacted almost instantaneously on the air emboli, but were less sensitive than the intraparenchymal oxygen tension. There was reasonable correlation (ρ ranging from 0.417 to 0.898) between oxygen saturation, oxygen tension, electroencephalography and microdialysis values. Comparison with existing methods Our study is the first to demonstrate the effects of cerebral air emboli using multimodal monitoring, specifically on oxygen saturation as measured using near-infrared spectroscopy. Conclusions Our results show that non-invasively measured oxygen saturation and quantitative electroencephalography can detect the local effects of air emboli on cerebral oxygenation, but with reduced sensitivity as compared to intraparenchymal oxygen tension. Prospective human studies using multimodal monitoring incorporating electroencephalography and oxygen saturation should be performed.

Published

2014

2. Cerebral arterial gas embolism in swine. Comparison of two sites for air injection

Author

Elham Ghazi-Hosseini, Robert P. Weenink, Markus F. Stevens, Krijn P. van Lienden, Markus W. Hollmann, Robert A. van Hulst, Thomas M. van Gulik, Other departments, ACS - Amsterdam Cardiovascular Sciences, AII - Amsterdam institute for Infection and Immunity, Anesthesiology, Other Research, Radiology and Nuclear Medicine, AGEM - Amsterdam Gastroenterology Endocrinology Metabolism, and Surgery

Subjects

Time Factors, Intracranial Pressure, Swine, Neuroscience(all), Statistics as Topic, External carotid artery, Air embolism, Brain ischemia, medicine.artery, medicine, Animals, Embolism, Air, Lactic Acid, Intracranial pressure, business.industry, Air, General Neuroscience, Ascending pharyngeal artery, Brain, medicine.disease, Animal models, Oxygen tension, Disease Models, Animal, Metabolism, medicine.anatomical_structure, Embolism, Anesthesia, Cerebral Arterial Diseases, business, Artery

Abstract

Cerebral arterial gas embolism is a risk in diving and occurs as a complication in surgery and interventional radiology. Swine models for cerebral arterial gas embolism have been used in the past. However, injection of air into the main artery feeding the pig brain - the ascending pharyngeal artery - might be complicated by the presence of the carotid rete, an arteriolar network at the base of the brain. On the other hand, anastomoses between external and internal carotid territories are present in the pig. In order to determine the most appropriate vessel for air injection, we performed experiments in which air was injected into either the ascending pharyngeal artery or the external carotid artery. We injected 0.25 ml/kg of room air selectively into the ascending pharyngeal artery or the external carotid artery of 35-40 kg Landrace pigs (n = 8). We assessed the effect on cerebral metabolism by measuring intracranial pressure, brain oxygen tension and brain glucose and lactate concentrations using cerebral microdialysis. Intracranial pressure and brain oxygen tension changed significantly in both groups, but did not differ between groups. Brain lactate increased significantly more in pigs in which air was injected into the ascending pharyngeal artery. Intracranial pressure, brain oxygen tension and brain lactate correlated after injection of air into the ascending pharyngeal artery, but not after injection into the external carotid artery. Our model is suitable for investigation of cerebral arterial gas embolism. The ascending pharyngeal artery is the most appropriate vessel for air injection. (C) 2010 Elsevier B.V. All rights reserved

Published

2011