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Sharp safety in healthcare settings

Authors: Dr J. Ford (R&D Officer, SMTL) & Mr P. Phillips (Director, SMTL)

Summary

This paper is a general introduction to the issue of sharp safety in health care settings.

Occupational sharps injuries are a common occurrence and the emerging risk of blood borne viruses has increased awareness and concern in health care settings. This has led to the production of safety-engineered devices, designed to protect the user from injury after use. This paper summarises some of the issues surrounding sharps safety and is the first in a series of related articles to be published on the web site.

Introduction

Health care workers (HCWs) have always been at risk from exposure to blood-borne pathogens, but in the 1980s, the emergence of AIDS made HCWs focus on their practices, and evaluate methods for reducing this risk.

In the UK, it is estimated that approximately 100,000 needlestick injuries occur per year (Unison 2000). Transmission most commonly occurs after percutaneous exposure to a patient's blood by a 'sharps' or 'needlestick' injury. The estimated risk of transmission following such an injury has been shown to be as follows (Brewer, 2001):

Estimated risk of transmission

following injury

Type of infection

1 in 3

Hepatitis B virus (HBV)

1 in 30

Hepatitis C virus (HCV)

1 in 300

Human Immunodeficiency virus (HIV)

From 1997 to 2007, the Health Protection Agency received reports of 5 HIV and 14 HCV seroconversions from health care centres throughout the UK (HPA 2008).

Prevalence of sharps injuries

Data collected from 6 Welsh NHS trusts (2003, unpublished) shows very similar trends to UK injury data collected via the EPINet system (Watterson, 2004). The main results are summarised as follows:

Desirable properties of safer devices

Safety engineered devices are designed to protect the user from sharps injuries following use. These include devices with shields or sheaths which are placed over the needle following use or retractable needle systems where the needle retracts into the body of the device. Devices are either 'active' (i.e. require user action to engage safety feature) or passive (i.e. require no additional action to make the device 'safe').

The FDA identified key factors in the design of sharps safety instruments, which are as follows:

(Taken from section 5, FDA 2005)

Factors to consider when using safety-engineered devices include the following:

Legislation

An EU directive (2010/32/EU) was passed in May 2010 aimed at preventing occupational sharps injuries. It includes measures that have to be taken in order to protect workers. These include 'on the basis of the results of the risk assessment, providing medical devices incorporating safety-engineered protection mechanisms' (Clause 6 of Directive). Healthcare organisations are to implement the requirements of the Directive by May 2013.  At the date of writing (Aug 2012), the Health & Safety Executive (H&SE) are consulting on proposed UK regulations to implement the Council Directive. The consultation period ends on 8th Nov 2012.

Are safety devices always better?

There is evidence suggesting that sharps safety devices can lower rates of sharps injuries, and this is thought to be enhanced by sharp safety training and education (Health and Safety Executive, 2012). However, other evidence shows that safer devices do not always prevent sharps injuries, and there are reports that some 'safer' devices have actually caused needlestick injuries while in use (Letter from US General accounting office 2000, Paterson and Elder 2005).

In some cases, users may not realise that a device requires activation to be made safe, whilst others may not bother to carry out the additional 'activation' step. Other studies which inspected sharps disposal boxes during clinical evaluations revealed that high numbers of devices had not been activated - percentages of non-activated devices ranged from 2-44% (PHL 1997, Mendleson et al., 2003 and Mulherin et al., 1996 ). Only a few published studies have investigated user acceptability and this is thought to be an important aspect of introducing sharp safety devices (Health and Safety Executive, 2012).

Conclusion

Tackling sharp safety in the workplace requires a holistic approach. This should include raising awareness, providing training and carrying out risk assessments as well as evaluating 'safety-engineered' devices prior to possible introduction.

NOTE: Other sharps safety articles will be available on Medidex soon.

Bibliography

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