Division of Field Studies and Engineering, National Institute for Occupational Safety and Health (NIOSH), Cincinnati, OH, USA.
School of Medicine, Institute of Public Health and Clinical Nutrition, University of Eastern Finland, Kuopio, Finland.
Cochrane Database Syst Rev. 2024 May 17;5(5):CD015066. doi: 10.1002/14651858.CD015066.pub2.
Global Burden of Disease studies identify hearing loss as the third leading cause of years lived with a disability. Their estimates point to large societal and individual costs from unaddressed hearing difficulties. Workplace noise is an important modifiable risk factor; if addressed, it could significantly reduce the global burden of disease. In practice, providing hearing protection devices (HPDs) is the most common intervention to reduce noise exposure at work. However, lack of fit of HPDs, especially earplugs, can greatly limit their effectiveness. This may be the case for 40% of users. Testing the fit and providing instructions to improve noise attenuation might be effective. In the past two decades, hearing protection fit-test systems have been developed and evaluated in the field. They are called field attenuation estimation systems. They measure the noise attenuation obtained by individual workers using HPDs. If there is a lack of fit, instruction for better fit is provided, and may lead to better noise attenuation obtained by HPDs.
To assess: (1) the effects of field attenuation estimation systems and associated training on the noise attenuation obtained by HPDs compared to no instruction or to less instruction in workers exposed to noise; and (2) whether these interventions promote adherence to HPD use.
We used CENTRAL, MEDLINE, five other databases, and two trial registers, together with reference checking, citation searching, and contact with study authors to identify studies. We imposed no language or date restrictions. The latest search date was February 2024.
We included randomised controlled trials (RCTs), cluster-RCTs, controlled before-after studies (CBAs), and interrupted time-series studies (ITSs) exploring HPD fit testing in workers exposed to noise levels of more than 80 A-weighted decibels (or dBA) who use hearing protection devices. The unit 'dBA' reports on the use of a frequency-weighting filter to adjust sound measurement results to better reflect how human ears process sound. The outcome noise attenuation had to be measured either as a personal attenuation rating (PAR), PAR pass rate, or both. PAR pass rate is the percentage of workers who passed a pre-established level of sufficient attenuation from their HPDs, identified on the basis of their individual noise exposure.
Two review authors independently assessed study eligibility, risk of bias, and extracted data. We categorised interventions as fit testing of HPDs with instructions at different levels (no instructions, simple instructions, and extensive instructions).
We included three RCTs (756 participants). We did not find any studies that examined whether fit testing and training contributed to hearing protector use, nor any studies that examined whether age, gender, or HPD experience influenced attenuation. We would have included any adverse effects if mentioned by the trial authors, but none reported them. None of the included studies blinded participants; two studies blinded those who delivered the intervention. Effects of fit testing of HPDs with instructions (simple or extensive) versus fit testing of HPDs without instructions Testing the fit of foam and premoulded earplugs accompanied by simple instructions probably does not improve their noise attenuation in the short term after the test (1-month follow-up: mean difference (MD) 1.62 decibels (dB), 95% confidence interval (CI) -0.93 to 4.17; 1 study, 209 participants; 4-month follow-up: MD 0.40 dB, 95% CI -2.28 to 3.08; 1 study, 197 participants; both moderate-certainty evidence). The intervention probably does not improve noise attenuation in the long term (MD 0.15 dB, 95% CI -3.44 to 3.74; 1 study, 103 participants; moderate-certainty evidence). Fit testing of premoulded earplugs with extensive instructions on the fit of the earplugs may improve their noise attenuation at the immediate retest when compared to fit testing without instructions (MD 8.34 dB, 95% CI 7.32 to 9.36; 1 study, 100 participants; low-certainty evidence). Effects of fit testing of HPDs with extensive instructions versus fit testing of HPDs with simple instructions Fit testing of foam earplugs with extensive instructions probably improves their attenuation (MD 8.62 dB, 95% CI 6.31 to 10.93; 1 study, 321 participants; moderate-certainty evidence) and also the pass rate of sufficient attenuation (risk ratio (RR) 1.75, 95% CI 1.44 to 2.11; 1 study, 321 participants; moderate-certainty evidence) when compared to fit testing with simple instructions immediately after the test. This is significant because every 3 dB decrease in noise exposure level halves the sound energy entering the ear. No RCTs reported on the long-term effectiveness of the HPD fit testing with extensive instructions.
AUTHORS' CONCLUSIONS: HPD fit testing accompanied by simple instructions probably does not improve noise attenuation from foam and premoulded earplugs. Testing the fit of foam and premoulded earplugs with extensive instructions probably improves attenuation and PAR pass rate immediately after the test. The effects of fit testing associated with training to improve attenuation may vary with types of HPDs and training methods. Better-designed trials with larger sample sizes are required to increase the certainty of the evidence.
全球疾病负担研究将听力损失确定为导致残疾生活年数的第三大主要原因。这些研究表明,由于未解决的听力困难,会给社会和个人带来巨大的成本。工作场所噪音是一个重要的可改变的风险因素;如果加以解决,它可以显著降低全球疾病负担。在实践中,提供听力保护装置(HPD)是减少工作场所噪声暴露的最常见干预措施。然而,HPD 特别是耳塞的适配不当,可能会极大地限制其效果。这种情况可能会发生在 40%的使用者身上。测试适配并提供改善噪声衰减的说明可能是有效的。在过去的二十年中,已经开发和评估了听力保护适配测试系统,它们被称为现场衰减估计系统。它们测量使用 HPD 的个体工人获得的噪声衰减。如果适配不当,会提供更好适配的说明,并可能导致使用 HPD 获得更好的噪声衰减。
评估:(1)现场衰减估计系统及其相关培训对暴露于噪声中的工人使用 HPD 获得的噪声衰减的影响,与无指导或指导较少相比;(2)这些干预措施是否促进了 HPD 使用的依从性。
我们使用了 CENTRAL、MEDLINE、其他五个数据库以及两个试验登记处,并结合参考文献检查、引文搜索以及与研究作者的联系,以确定研究。我们没有对语言或日期进行限制。最新的搜索日期是 2024 年 2 月。
我们纳入了随机对照试验(RCT)、群组随机对照试验(cluster-RCT)、对照前后研究(CBCA)和中断时间序列研究(ITS),这些研究探索了暴露于噪声水平超过 80 分贝(或 dBA)的工人中 HPD 适配测试,他们使用听力保护装置。单位 'dBA' 报告了使用频率加权滤波器来调整声音测量结果,以更好地反映人耳对声音的处理方式。结果噪声衰减必须通过个人衰减率(PAR)、PAR 通过率或两者来衡量。PAR 通过率是指通过其个体噪声暴露确定的足够衰减的 HPD 通过率,是指通过其个体噪声暴露确定的足够衰减的 HPD 通过率。
两名综述作者独立评估了研究的合格性、偏倚风险,并提取了数据。我们将干预措施分为不同水平的 HPD 适配测试和说明(无说明、简单说明和详细说明)。
我们纳入了三项 RCT(756 名参与者)。我们没有发现任何研究表明适配测试和培训有助于听力保护器的使用,也没有任何研究表明年龄、性别或 HPD 经验会影响衰减。如果试验作者提到了任何不良影响,我们本应包括在内,但没有。没有纳入的研究对参与者进行了盲法;两项研究对实施干预的人员进行了盲法。有说明的 HPD 适配测试与无说明的 HPD 适配测试的效果 用简单说明测试泡沫和预成型耳塞的适配情况,可能会在测试后的短期(1 个月随访:平均差异(MD)1.62 分贝(dB),95%置信区间(CI)-0.93 至 4.17;1 项研究,209 名参与者;4 个月随访:MD 0.40 dB,95% CI -2.28 至 3.08;1 项研究,197 名参与者;均为中度确定性证据)内不会改善其噪声衰减。该干预措施可能不会在长期(MD 0.15 dB,95% CI -3.44 至 3.74;1 项研究,103 名参与者;中度确定性证据)内改善噪声衰减。用详细说明耳塞适配的预成型耳塞进行 HPD 适配测试,与无说明的适配测试相比,在立即重新测试时可能会提高其噪声衰减(MD 8.34 dB,95% CI 7.32 至 9.36;1 项研究,100 名参与者;低确定性证据)。有详细说明的 HPD 适配测试与有简单说明的 HPD 适配测试的效果 用详细说明的方法测试泡沫耳塞,可能会提高其衰减(MD 8.62 dB,95% CI 6.31 至 10.93;1 项研究,321 名参与者;中度确定性证据)和通过足够衰减的通过率(风险比(RR)1.75,95% CI 1.44 至 2.11;1 项研究,321 名参与者;中度确定性证据),与立即测试后的简单说明相比。这是重要的,因为噪声暴露水平每降低 3 分贝,声音能量进入耳朵的一半。没有 RCT 报告 HPD 适配测试与详细说明的长期效果。
用简单说明测试泡沫耳塞和预成型耳塞可能不会改善噪声衰减。用详细说明测试泡沫耳塞和预成型耳塞可能会立即提高衰减和 PAR 通过率。与培训相关的改善衰减的适配测试效果可能因 HPD 类型和培训方法而异。需要设计更好的、更大样本量的试验来提高证据的确定性。
