麻醉及其对环境的影响:尽量减少接触麻醉气体和减少废物的方法。

IF 3 Q2 MEDICINE, RESEARCH & EXPERIMENTAL Medical Gas Research Pub Date : 2025-03-01 Epub Date: 2024-06-26 DOI:10.4103/mgr.MEDGASRES-D-23-00059
Khalid Samad, Muhammad Saad Yousuf, Hameed Ullah, Syed Shabbir Ahmed, Khalid Maudood Siddiqui, Asad Latif
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引用次数: 0

摘要

在当今的现代医疗保健时代,医疗实践与环境责任之间的交集已引起人们的极大关注。其中一个重点领域就是在各种外科手术中发挥关键作用的麻醉实践。一氧化二氮和挥发性卤化醚(地氟烷、异氟烷、七氟烷)等麻醉剂属于医疗气体,它们是导致全球变暖的强温室气体。在医疗过程中,这些麻醉剂大多被释放到大气中,从而加剧了它们对环境的影响。此外,麻醉给药系统传统上使用高流量气体,不仅消耗过多,而且温室气体排放也对环境造成了相当大的影响。然而,低流量麻醉(LFA)的出现为实现减排和节约成本提供了一个前景广阔的解决方案,从而使医疗保健实践与可持续发展目标保持一致。与传统的高流量方法相比,低流量麻醉涉及以较低的流速向患者施用麻醉气体。这种做法需要精确的气体输送,通常需要采用先进的监测和控制系统。通过优化气体流量以满足患者的需求,LFA 最大限度地减少了浪费和向环境中的过量气体释放,从而抑制了与医疗保健操作相关的碳足迹。减少挥发性麻醉剂的输送为麻醉提供者降低成本和减少环境污染提供了安全有效的策略。目前支持 LFA 的文献代表了一个成本控制领域和一个减少麻醉对环境影响的机会。本文将介绍 LFA 的概念、低流量和最小流量之间的区别以及 LFA 的潜在优势,例如与患者安全、环境和经济相关的优势。
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Anesthesia and its environmental impact: approaches to minimize exposure to anesthetic gases and reduce waste.

In today's era of modern healthcare, the intersection between medical practices and environmental responsibility has gained significant attention. One such area of focus is the practice of anesthesia, which plays a crucial role in various surgical procedures. Anesthetics such as nitrous oxide and volatile halogenated ethers (desflurane, isoflurane, sevoflurane) are examples of medical gases that are strong greenhouse gases that contribute to global warming. During medical procedures, most of these anesthetic agents are released into the atmosphere, which exacerbates their influence on the environment. Also anesthesia delivery systems have traditionally utilized high flow rates of gases, leading to not only excessive consumption but also a considerable environmental impact in terms of greenhouse gas emissions. However, the emergence of low-flow anesthesia (LFA) presents a promising solution for achieving emission reduction and cost savings, thereby aligning healthcare practices with sustainability goals. Understanding LFA involves the administration of anesthetic gases to patients at reduced flow rates compared to conventional high-flow methods. This practice requires precision in gas delivery, often incorporating advanced monitoring and control systems. By optimizing gas flow to match the patient's requirements, LFA minimizes wastage and excessive gas release into the environment, subsequently curbing the carbon footprint associated with healthcare operations. Decreasing volatile anesthetic delivery provides safe and effective strategies for anesthesia providers to decrease costs and reduce environmental pollution. Current literature support in favor of LFA represents an area of cost containment and an opportunity to lessen the environmental impact of anesthesia. This article will cover the concept of LFA, the distinctions between low flow and minimal flow, and the potential advantages of LFA, such as those related to patient safety, the environment, and the economy.

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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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