Difference between revisions of "Guidelines for safe sputum collection"

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==Introduction==
 
==Introduction==
Sputum specimen examination is the main diagnostic procedure for pulmonary Tuberculosis <ref>Hansen, D. J., 1993. The Work Environment: Healthcare, Laboratories and Biosafety, Volume 2. Lewis publishers: USA.</ref>; however, the medical procedure (patient coughing) that is used for sputum collection increases the potential for transmission of M. Tuberculosis significantly <ref>Centers for Disease Control and Prevention. Guidelines for Preventing the Transmission of Mycobacterium tuberculosis in Health-Care Settings, 2005. MMWR 2005;54(No. RR-17).</ref>; therefore, there is need to administer sputum collection safely in healthcare facilities [3]. The CSIR’s Infrastructure Innovation research group has conducted many TB risk assessments in South African public healthcare facilities for over 10 years. A common finding was that engineering controls for sputum collection were not always adequate, maintained or monitored. Sputum was observed to be collected from toilets, consulting rooms and counselling rooms which implies increased risk of TB transmission.  
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Sputum specimen examination is the main diagnostic procedure for pulmonary Tuberculosis <ref>Hansen, D. J., 1993. The Work Environment: Healthcare, Laboratories and Biosafety, Volume 2. Lewis publishers: USA.</ref>; however, the medical procedure (patient coughing) that is used for sputum collection increases the potential for transmission of M. Tuberculosis significantly <ref>Centers for Disease Control and Prevention. Guidelines for Preventing the Transmission of Mycobacterium tuberculosis in Health-Care Settings, 2005. MMWR 2005;54(No. RR-17).</ref>; therefore, there is need to administer sputum collection safely in healthcare facilities <ref>Infrastructure Unit Support Systems (IUSS), 2014. IUSS HEALTH FACILITY GUIDES: TB Services. South Africa. National Department of Health.</ref>. The CSIR’s Infrastructure Innovation research group has conducted many TB risk assessments in South African public healthcare facilities for over 10 years. A common finding was that engineering controls for sputum collection were not always adequate, maintained or monitored. Sputum was observed to be collected from toilets, consulting rooms and counselling rooms which implies increased risk of TB transmission.  
 
This guideline provide guidance on conducting sputum collection safely for suspected or known infectious TB patients. Although there is a three level hierarchy of control measures; administrative controls, engineering controls and personal respiratory protection to prevent transmission of TB, this guideline is limited to engineering control measures for sputum collection.
 
This guideline provide guidance on conducting sputum collection safely for suspected or known infectious TB patients. Although there is a three level hierarchy of control measures; administrative controls, engineering controls and personal respiratory protection to prevent transmission of TB, this guideline is limited to engineering control measures for sputum collection.
  
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===Local exhaust ventilation devices===
 
===Local exhaust ventilation devices===
Local exhaust ventilation devices capture of airborne contaminants at or near the source before they are dispersed into the work space [4,5]. The basic components of an LEV device are hood, ductwork, air cleaner and fan [5]. Burgess, et al., [4] identifies two major categories of LEV devices; enclosures and exterior. The major difference between these two is that for enclosures, contaminants are released from inside the device whereas for exterior contaminants are released outside the device. A sputum booth is considered as an example of an enclosure LEV device. Illustrations of an enclosure and exterior LEV devices are shown in Figures 1 and 2 respectively. Figure 1 shows a CSIR designed sputum booth. Technical specifications for the booth that can be used for procurement are included in Appendix A.
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Local exhaust ventilation devices capture of airborne contaminants at or near the source before they are dispersed into the work space <ref>Burgess, W.A., Ellenbecker, M.J., and Treitman, R.D. 2004. Ventilation for control of the work environment. Second edition. New Jersey USA. John Wiley & Sons</ref><ref>Heinsohn, P. 1996. Tuberculosis resources guide CEC Report CR 106146. Carlifonia. USA. Heinsohn Consulting services.</ref>. The basic components of an LEV device are hood, ductwork, air cleaner and fan [5]. Burgess, et al., [4] identifies two major categories of LEV devices; enclosures and exterior. The major difference between these two is that for enclosures, contaminants are released from inside the device whereas for exterior contaminants are released outside the device. A sputum booth is considered as an example of an enclosure LEV device. Illustrations of an enclosure and exterior LEV devices are shown in Figures 1 and 2 respectively. Figure 1 shows a CSIR designed sputum booth. Technical specifications for the booth that can be used for procurement are included in Appendix A.
 
[[File:Mechanical sputum booth.jpg|none|thumb|Mechanical sputum booth]]Table 1 gives a comparison between enclosure and exterior LEV devices.<br />
 
[[File:Mechanical sputum booth.jpg|none|thumb|Mechanical sputum booth]]Table 1 gives a comparison between enclosure and exterior LEV devices.<br />
  

Revision as of 18:09, 18 June 2020

Introduction

Sputum specimen examination is the main diagnostic procedure for pulmonary Tuberculosis [1]; however, the medical procedure (patient coughing) that is used for sputum collection increases the potential for transmission of M. Tuberculosis significantly [2]; therefore, there is need to administer sputum collection safely in healthcare facilities [3]. The CSIR’s Infrastructure Innovation research group has conducted many TB risk assessments in South African public healthcare facilities for over 10 years. A common finding was that engineering controls for sputum collection were not always adequate, maintained or monitored. Sputum was observed to be collected from toilets, consulting rooms and counselling rooms which implies increased risk of TB transmission. This guideline provide guidance on conducting sputum collection safely for suspected or known infectious TB patients. Although there is a three level hierarchy of control measures; administrative controls, engineering controls and personal respiratory protection to prevent transmission of TB, this guideline is limited to engineering control measures for sputum collection.

Engineering control measures for sputum collection

There are two main types of engineering methodologies that can be utilized for sputum collection; local exhaust ventilation devices and sputum induction rooms.

Local exhaust ventilation devices

Local exhaust ventilation devices capture of airborne contaminants at or near the source before they are dispersed into the work space [4][5]. The basic components of an LEV device are hood, ductwork, air cleaner and fan [5]. Burgess, et al., [4] identifies two major categories of LEV devices; enclosures and exterior. The major difference between these two is that for enclosures, contaminants are released from inside the device whereas for exterior contaminants are released outside the device. A sputum booth is considered as an example of an enclosure LEV device. Illustrations of an enclosure and exterior LEV devices are shown in Figures 1 and 2 respectively. Figure 1 shows a CSIR designed sputum booth. Technical specifications for the booth that can be used for procurement are included in Appendix A.

Mechanical sputum booth

Table 1 gives a comparison between enclosure and exterior LEV devices.

Table 1. Comparison between enclosure and exterior LEV devices

Local Exhaust Ventilation device Advantages Disadvantages
Enclosure

Contaminants are released from inside the LEV device. Example is a booth as illustrated in Figure 1.

  • Complete physical separation between patient and staff which ensures negligible exposure to contaminants hence providing the greatest protection when compared to exterior [4].
  • Conserves energy when compared to the external LEV since it requires least amount of airflow to ensure adequate control [4].
  • An exhaust airflow is chosen sufficient to create a negative air pressure inside the LEV; this ensures that contaminated air will not escape from the device [4].
  • Contaminants are quickly captured due to high air change rates. Therefore shorter contaminants clearance times when compared to sputum rooms.
  • Devices with HEPA-filtered exhaust can be used in any room regardless of room ventilation system
  • Can be moved to accommodate room function changes.
  • Cost is higher than external LEV device approximately R125 000.
  • Requires routine maintenance such as changing the HEPA filter and pre-filter.
  • Booths are not as portable as external LEV device.
Exterior

Contaminants are released from outside the LEV device. Example is illustrated in Figure 2.

  • Cost is relatively low compared to complete enclosures.
  • Portable, small enough to be used at patient’s bedside.
  • Exterior LEV devices are susceptible to cross-drafts which may completely disrupt their performance by disrupting the airflow patterns between the point of contaminant release and the exhaust [4].
  • Since the contaminants are released into the air surrounding an exterior LEV device and then captured, it is possible for a healthcare worker to be in the path between the contaminant source and the device, and be exposed to the contaminants before they are captured [4].
  • Does not provide complete physical separation between patient and staff.
  • Requires more supervision of patient to ensure proper placement than complete enclosures
  • Open windows or doors, or people moving in the area can create drafts, which disrupt the capture of airborne particles.


References

  1. Hansen, D. J., 1993. The Work Environment: Healthcare, Laboratories and Biosafety, Volume 2. Lewis publishers: USA.
  2. Centers for Disease Control and Prevention. Guidelines for Preventing the Transmission of Mycobacterium tuberculosis in Health-Care Settings, 2005. MMWR 2005;54(No. RR-17).
  3. Infrastructure Unit Support Systems (IUSS), 2014. IUSS HEALTH FACILITY GUIDES: TB Services. South Africa. National Department of Health.
  4. Burgess, W.A., Ellenbecker, M.J., and Treitman, R.D. 2004. Ventilation for control of the work environment. Second edition. New Jersey USA. John Wiley & Sons
  5. Heinsohn, P. 1996. Tuberculosis resources guide CEC Report CR 106146. Carlifonia. USA. Heinsohn Consulting services.