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3 results

  • Chapter 8 - Anaesthetic Equipment: The Machine, Breathing Systems and Ventilators

  • from Section 1 - Nuts and Bolts
  • William Fawcett, Royal Surrey County Hospital, Guildford and University of Surrey, Olivia Dow, Guy's and St Thomas' NHS Foundation Trust, London, Judith Dinsmore, St George's Hospital, London
  • Book:
    Robinson and Hall's How to Survive in Anaesthesia
    Published online:
    09 June 2025
    Print publication:
    26 June 2025, pp 42-54

  • Summary

    The anaesthetic machine is designed to enable oxygenation, safe delivery of both gases and volatile anaesthetic agents and appropriate ventilation. Modern machines are complex pieces of equipment dependent on electronic hardware and software. Many incorporate electronic monitoring systems for both the patient and the gas delivery. Breathing systems and ventilators may be included to form a ‘workstation’. Familiarity with the anaesthetic machine is fundamental for safe practice. It must be checked before every operating list.

    Gas supply is usually via pipelines drawn from a central supply or from cylinders. Pressure and flow of gases to the patient are regulated by valves and flowmeters. The concentration of volatile agents is controlled by individual vaporisers. Anaesthetic gas scavenging systems are designed to safely remove anaesthetic waste.

    Anaesthetic breathing systems or circuits consist of several components: fresh gas, inspiratory and expiratory limbs, a pressure limiting valve and a reservoir bag. They may also have a carbon dioxide absorber and unidirectional valves. They are classified as either circle systems or semi-closed rebreathing systems. Ventilators can be considered as constant or non-constant generators of pressure or flow. Both are described in detail.

  • 25 - Carbon dioxide production, metabolism, and anesthesia

  • from 1 - Ventilation
  • Edited by J. S. Gravenstein, University of Florida, Michael B. Jaffe, Nikolaus Gravenstein, University of Florida, David A. Paulus, University of Florida
  • Book:
    Capnography
    Published online:
    05 August 2011
    Print publication:
    17 March 2011, pp 239-249

  • Summary

    This chapter reviews the current status of combining the new evolving technologies of CO2 monitoring and non-invasive positive pressure ventilation (NPPV). It explores the advantages as well as the challenges that prompt further research. The non-invasive character of both NPPV and capnography make the combination attractive for the clinical management of acute and chronic respiratory failure. Several different types of patient interfaces are available for the delivery of non-invasive ventilation, including full face masks, complete face masks, nasal masks, sealed helmets, nasal pillows, mouthpieces and custom-fabricated masks. Sidestream gas measurement offers a number of sampling locations, including: inside the mask, at the mask outlet, or with the nasal cannula at or near the patient's nostrils. It is plausible that the synergies between NPPV and time/volumetric capnography will help the clinician to more rapidly identify therapeutic pressure levels that optimize CO2 elimination and patient work of breathing-key objectives for non-invasive ventilation.