麻醉工作站冷凝器组件严重泄漏。

IF 3 Q2 MEDICINE, RESEARCH & EXPERIMENTAL
Amit Rai, Krithika Ramamoorthy, Sachin Kulkarni, Sameer Taneja
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We reported a case of gas leak from an unconventional site in the Datex Ohmeda Aespire View (GE Healthcare Pvt. Ltd. (India), Bangalore, India) workstation after anesthesia machine checks. As a routine, the complete pre-use anesthesia machine check was performed through the electronic self-check. A complete pre-use check of the machine included cylinders, pipelines, low-pressure system, vaporizers, breathing circuits, monitors and integrated ventilator. The circle system was also checked for any leaks and the ventilator systems were checked by setting the oxygen flow meter at minimum flows. However, after preliminary checks, soda lime in the carbon dioxide (CO2) absorber canister was changed. The canister was then reattached firmly. The water trap was also drained at this time. The patient was induced with propofol but bag mask ventilation was not adequate. There was a chest rise along with an end tidal CO2 trace but the reservoir bag was not filled adequately at a usual flow of 5 L/min. An oropharyngeal airway was inserted, and the flow increased to 10 L/min and the bag was filled better. The trachea was intubated with an 8.5 mm internal diameter cuffed endotracheal polyvinyl chloride tube using succinylcholine. However, the bag still required higher flows to fill up and when turned to the ventilation mode, the bellows required more than 8 L/min to fill up. We checked all the connections in the external circuit but found no loose connections or leaks. However, there was a large audible leak heard from the soda lime canister assembly. The CO2 absorber canister was removed and put back again to ensure that it is secured appropriately and locked. However, the audible leak still persisted. We decided to go ahead with the surgery as it was an emergency and ventilate the patient manually using Bains circuit. After the surgery got over, a detailed inspection of the CO2 canister assembly was done, and the leak seemed to originate from the EZchange and condenser part of the machine (Figure 1). Further evaluation revealed no issue in the EZchange part. The drain button of the condenser, however, was stuck in a semiopen position due to a soda lime granule trapped under the flap valve, leading to the leakage of gases through the condenser via the water drain (Figure 2). Once the granule was cleaned out from underneath the flap valve, the drain button was restored to the original position and the audible leak was eliminated, as was evident upon rechecking the machine. The EZchange and condenser option are included in the Advanced Breathing System of the Datex Ohmeda Aespire View workstation. The EZchange option allows the user to change a canister during a case without introducing a large leak and the condenser (Figure 1). The condenser helps to remove moisture from the freshly scrubbed gas that comes out of the canister before going to the inspiratory flow sensors. This moisture is then drained out at the bottom of the condenser through the water drain. A similar experience was reported by Kummar et al.4 using the Aisys Carestation in 2009. A possible explanation in their case was that a high content of dust in the absorbent material was carried by the flowing gas that may have carried that dust through the breathing system, leading to deposits caking in the condenser reservoir. The reusable canister design incorporates two separate mechanisms to prevent the migration of absorber material into the circuit. There is a metal grate designed to contain particles of more than 1 mm and a foam filter designed to trap dust particles. These mechanisms were found to be intact in our case.4 It is very difficult to explain the presence of absorbent granule in the lower part of the condenser assembly, thereby causing a circuit leak in our case. There was a high content of dust in the absorbent material used. But how it could reach the condenser assembly is difficult to explain. Modern-day workstations have evolved and become complex Figure 1: Canister on the machine with EZchange option. 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The circle system was also checked for any leaks and the ventilator systems were checked by setting the oxygen flow meter at minimum flows. However, after preliminary checks, soda lime in the carbon dioxide (CO2) absorber canister was changed. The canister was then reattached firmly. The water trap was also drained at this time. The patient was induced with propofol but bag mask ventilation was not adequate. There was a chest rise along with an end tidal CO2 trace but the reservoir bag was not filled adequately at a usual flow of 5 L/min. An oropharyngeal airway was inserted, and the flow increased to 10 L/min and the bag was filled better. The trachea was intubated with an 8.5 mm internal diameter cuffed endotracheal polyvinyl chloride tube using succinylcholine. However, the bag still required higher flows to fill up and when turned to the ventilation mode, the bellows required more than 8 L/min to fill up. We checked all the connections in the external circuit but found no loose connections or leaks. However, there was a large audible leak heard from the soda lime canister assembly. The CO2 absorber canister was removed and put back again to ensure that it is secured appropriately and locked. However, the audible leak still persisted. We decided to go ahead with the surgery as it was an emergency and ventilate the patient manually using Bains circuit. After the surgery got over, a detailed inspection of the CO2 canister assembly was done, and the leak seemed to originate from the EZchange and condenser part of the machine (Figure 1). Further evaluation revealed no issue in the EZchange part. The drain button of the condenser, however, was stuck in a semiopen position due to a soda lime granule trapped under the flap valve, leading to the leakage of gases through the condenser via the water drain (Figure 2). 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A major leak from the condenser assembly of the anesthesia workstation.

A major leak from the condenser assembly of the anesthesia workstation.

A major leak from the condenser assembly of the anesthesia workstation.
Dear Editor, From a simple pneumatic device of the early 20th century, the anesthesia machine has evolved to incorporate various mechanical, electrical and electronic components to be more appropriately called anesthesia workstation.1 Despite advanced technology, a remote but life-threatening possibility of intraoperative machine malfunction exists. The leakage in the anesthesia circuit may result in hypoventilation, hypoxia, awareness, pollution of operating room and ventilatory failure even leading to death.2 Various causes of leaks in the breathing system have been reported in the literature that includes failure of an adjustable pressure limiting valve to close, mis-installation of a canister,3 weak connections in between different parts of the breathing circuit. We reported a case of gas leak from an unconventional site in the Datex Ohmeda Aespire View (GE Healthcare Pvt. Ltd. (India), Bangalore, India) workstation after anesthesia machine checks. As a routine, the complete pre-use anesthesia machine check was performed through the electronic self-check. A complete pre-use check of the machine included cylinders, pipelines, low-pressure system, vaporizers, breathing circuits, monitors and integrated ventilator. The circle system was also checked for any leaks and the ventilator systems were checked by setting the oxygen flow meter at minimum flows. However, after preliminary checks, soda lime in the carbon dioxide (CO2) absorber canister was changed. The canister was then reattached firmly. The water trap was also drained at this time. The patient was induced with propofol but bag mask ventilation was not adequate. There was a chest rise along with an end tidal CO2 trace but the reservoir bag was not filled adequately at a usual flow of 5 L/min. An oropharyngeal airway was inserted, and the flow increased to 10 L/min and the bag was filled better. The trachea was intubated with an 8.5 mm internal diameter cuffed endotracheal polyvinyl chloride tube using succinylcholine. However, the bag still required higher flows to fill up and when turned to the ventilation mode, the bellows required more than 8 L/min to fill up. We checked all the connections in the external circuit but found no loose connections or leaks. However, there was a large audible leak heard from the soda lime canister assembly. The CO2 absorber canister was removed and put back again to ensure that it is secured appropriately and locked. However, the audible leak still persisted. We decided to go ahead with the surgery as it was an emergency and ventilate the patient manually using Bains circuit. After the surgery got over, a detailed inspection of the CO2 canister assembly was done, and the leak seemed to originate from the EZchange and condenser part of the machine (Figure 1). Further evaluation revealed no issue in the EZchange part. The drain button of the condenser, however, was stuck in a semiopen position due to a soda lime granule trapped under the flap valve, leading to the leakage of gases through the condenser via the water drain (Figure 2). Once the granule was cleaned out from underneath the flap valve, the drain button was restored to the original position and the audible leak was eliminated, as was evident upon rechecking the machine. The EZchange and condenser option are included in the Advanced Breathing System of the Datex Ohmeda Aespire View workstation. The EZchange option allows the user to change a canister during a case without introducing a large leak and the condenser (Figure 1). The condenser helps to remove moisture from the freshly scrubbed gas that comes out of the canister before going to the inspiratory flow sensors. This moisture is then drained out at the bottom of the condenser through the water drain. A similar experience was reported by Kummar et al.4 using the Aisys Carestation in 2009. A possible explanation in their case was that a high content of dust in the absorbent material was carried by the flowing gas that may have carried that dust through the breathing system, leading to deposits caking in the condenser reservoir. The reusable canister design incorporates two separate mechanisms to prevent the migration of absorber material into the circuit. There is a metal grate designed to contain particles of more than 1 mm and a foam filter designed to trap dust particles. These mechanisms were found to be intact in our case.4 It is very difficult to explain the presence of absorbent granule in the lower part of the condenser assembly, thereby causing a circuit leak in our case. There was a high content of dust in the absorbent material used. But how it could reach the condenser assembly is difficult to explain. Modern-day workstations have evolved and become complex Figure 1: Canister on the machine with EZchange option. Note: 1: EZchange Canister manifold; 2: condenser; 3: drain button.
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来源期刊
Medical Gas Research
Medical Gas Research MEDICINE, RESEARCH & EXPERIMENTAL-
CiteScore
5.10
自引率
13.80%
发文量
35
期刊介绍: Medical Gas Research is an open access journal which publishes basic, translational, and clinical research focusing on the neurobiology as well as multidisciplinary aspects of medical gas research and their applications to related disorders. The journal covers all areas of medical gas research, but also has several special sections. Authors can submit directly to these sections, whose peer-review process is overseen by our distinguished Section Editors: Inert gases - Edited by Xuejun Sun and Mark Coburn, Gasotransmitters - Edited by Atsunori Nakao and John Calvert, Oxygen and diving medicine - Edited by Daniel Rossignol and Ke Jian Liu, Anesthetic gases - Edited by Richard Applegate and Zhongcong Xie, Medical gas in other fields of biology - Edited by John Zhang. Medical gas is a large family including oxygen, hydrogen, carbon monoxide, carbon dioxide, nitrogen, xenon, hydrogen sulfide, nitrous oxide, carbon disulfide, argon, helium and other noble gases. These medical gases are used in multiple fields of clinical practice and basic science research including anesthesiology, hyperbaric oxygen medicine, diving medicine, internal medicine, emergency medicine, surgery, and many basic sciences disciplines such as physiology, pharmacology, biochemistry, microbiology and neurosciences. Due to the unique nature of medical gas practice, Medical Gas Research will serve as an information platform for educational and technological advances in the field of medical gas.
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