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Spirometry Handbook
 
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Spirometry
Introduction
Measurement of Ventilatory Function
Measurement Devices
The Technique
Predicted Normal Values
Interpretation of Ventilatory Function Tests
Infection Control Measures
Summary
Appendix A
Appendix B
Bibliography
Acknowledgements
Copyright & Disclaimer
Content updated March 2008
Page updated 28 Mar 2008

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ForwardBackAppendix A - Calibration Checks

From a practical point of view it is necessary to perform calibration checks on spirometers: a calibration syringe is generally needed. The frequency of performing checks will vary with the clinical setting and the type of instrument being used, and the need to adjust the calibration will depend on whether it is outside control limits. Flow-type spirometers generally require daily calibration checks. An important determinant is the stability of the calibration over time and this can only be established with hindsight, having performed many calibration checks on the instrument. All spirometers must be recalibrated after cleaning or disinfection, or if an unusual or unexpected result indicates a problem.

Typically, spirometers should be accurate (volume to within ± 0.05 L or ±3%, whichever is greater; flow to within ±0.2 L/sec or ±5%, whichever is greater) and calibrated periodically with an accurate (certified) 3 L syringe. When a spirometer is moved into a cooler or hotter environment, it is important to allow time for it to reach the new temperature and to measure it, otherwise the BTPS correction factor will be incorrect. Similarly, the calibration syringe needs to be at the same temperature as the spirometer and for this reason it is usually stored near the spirometer. In order to detect changes in overall spirometer performance, the ventilatory function of one or more subjects with stable respiratory function should be measured and recorded regularly as part of an ongoing quality control programme.

Records of calibration checks, quality control and service history should be kept with the equipment. In the surgery, testing yourself (if you have stable function) on your spirometer every week or two is a practical way of ensuring quality control. A variation of >5% in FEV1 or FVC should alert you to a problem and the need to have your instrument properly checked and serviced.

Flow measurement devices (e.g. pneumotachographs, turbinometers) should be checked regularly for linearity over the physiological range of flows (0-14 L per second). A good test of linearity is to deliver a given volume (e.g. with a 3 L syringe) at a wide variety of flows, ensuring that the volume recorded by the instrument is close to 3.00 L over the whole range of flows. When 3 L is passed into the spirometer it should record a volume to within ±3.5%; that is, a spirometer is accurate if the recorded volume is between 2.895 L and 3.105 L.

Peak flow meters can generally be expected to wear out after about 12 to 24 months of heavy use, although there is little published data to support this, whereas a volume-displacement spirometer will usually last years if properly maintained and serviced.