A、C计权峰度调整噪声等效声级在评估职业性听力损失中的作用

刘海英; 武林杰; 李扬; 李金哲; 辛佳芮; 邹华; 邱伟; 沈彤; 张美辨

doi:10.11836/JEOM24548

A、C计权峰度调整噪声等效声级在评估职业性听力损失中的作用

Roles of A- and C-weighted kurtosis adjustment for equivalent sound level in evaluating occupational hearing loss

摘要

摘要:
背景已有研究证明了时域峰度（无频率计权，即Z计权峰度）可评估噪声性听力损失（NIHL），但既往研究甚少考虑到频率计权（A、C计权）峰度对NIHL的作用。
目的研究A、C计权峰度调整噪声等效声级（L'_{EX,8 h}）对评估职业性听力损失的有效性。
方法采用横断面调查方法，选择7个行业973名接噪工人作为研究对象，观察所有工人的噪声接触情况，包括A、C、Z计权峰度（K_A、K_C、K_Z）及其调整噪声等效声级（L'_{EX,8 h}-K_A、L'_{EX,8 h}-K_C和L'_{EX,8 h}-K_Z）的暴露分布情况。通过计算三种L'_{EX,8 h}与NIHL的相关性以及对比噪声性永久性听阈位移（NIPTS）的ISO 1999-2013《声学噪声性听力损失的评估》（简称ISO 1999预测模型）预测低估值改善情况，分析A、C计权峰度对NIHL评估的有效性。
结果 K_A、K_C、K_Z的中位数分别为68.33、28.22和19.82。二元logistic回归结果显示L'_{EX,8 h}-K_A、L'_{EX,8 h}-K_C和L'_{EX,8 h}-K_Z均为NIHL的危险因素（OR>1，P<0.001）。受试者工作特征曲线结果显示：当结局变量为噪声性听力障碍（NIHI）时，L'_{EX,8 h}-K_A、L'_{EX,8 h}-K_C、L'_{EX,8 h}-K_Z对应的曲线下面积分别为0.625、0.628和0.625；当结局变量为高频噪声性听力损失（HFNIHL）时，L'_{EX,8 h}-K_A、L'_{EX,8 h}-K_C、L'_{EX,8 h}-K_Z对应的曲线下面积分别为0.624、0.623和0.622（P<0.05）。L'_{EX,8 h}对NIPTS₁₂₃₄预测低估改善值的顺序为：L'_{EX,8 h}-K_A（4.68 dB HL）>L'_{EX,8 h}-K_C（4.38 dB HL）>L'_{EX,8 h}-K_Z（4.28 dB HL）（P<0.001）；L'_{EX,8 h}-K对NIPTS₃₄₆预测低估改善值的顺序为L'_{EX,8 h}-K_A（7.20 dB HL）>L'_{EX,8 h}-K_C（6.83 dB HL）>L'_{EX,8 h}-K_Z（6.71 dB HL）（P<0.001）。
结论 A、C计权的峰度对等效声级L_{EX,8 h}进行调整后可有效提高ISO 1999预测模型对NIPTS预测的准确程度。相对于C计权，A计权的频域峰度对ISO 1999预测模型低估NIPTS的改善效果更佳。

Abstract:
Background Temporal kurtosis (without frequency weighting, i.e., Z-weighted kurtosis) can evaluate noise-induced hearing loss (NIHL). However, few studies have considered the function of frequency weighting (A- or C-weighted) kurtosis on NIHL.
Objective To study the significance of A- and C-weighted kurtosis adjustment for equivalent sound level (L'_{EX,8 h}) in evaluating occupational hearing loss.
Methods A cross-sectional survey was used to select 973 noise-exposed workers in seven industries as the subjects. The noise exposure of all workers was assessed by distributions of A-, C-, and Z-weighted kurtosis (e.g., K_A, K_C, and K_Z) and respective adjusted equivalent sound level (e.g., L'_{EX,8 h}-K_A, L'_{EX,8 h}-K_C, and L'_{EX,8 h}-K_Z). The significance of A- and C-weighted kurtosis in evaluating NIHL was evaluated by correlations between three types of L'_{EX,8 h} and NIHL, and improvement of noise-induced permanent threshold shift (NIPTS) underestimation predicted by the ISO prediction model (Acoustics—Estimation of noise-induced hearing loss, ISO 1999-2013).
Results The median K_A, K_C, and K_Z were 68.33, 28.22, and 19.82, respectively. The binary logistic regression showed that L_{EX, 8 h}-K_A, L_{EX, 8 h}-K_C, and L'_{EX, 8 h}-K_Z were risk factors for NIHL (OR>1, P<0.001). The receiver operating characteristic (ROC) curve showed that when the outcome variable was noise-induced hearing impairment (NIHI), the areas under the curves corresponding to L'_{EX,8 h}-K_A, L'_{EX,8 h}-K_C, and L'_{EX,8 h}-K_Z were 0.625, 0.628, and 0.625, respectively. When the outcome variable was high-frequency noise-induced hearing loss (HFNIHL), the areas under the curves corresponding to L'_{EX,8 h}-K_A, L'_{EX, 8 h}-K_C, and L'_{EX,8 h}-K_Z were 0.624, 0.623, and 0.622, respectively (P<0.05). The order of underestimation improvement values predicted by L'_{EX,8 h} for NIPTS₁₂₃₄ was: L'_{EX,8 h}-K_A(4.68 dB HL)>L'_{EX,8 h}-K_C(4.38 dB HL)>L'_{EX,8 h}-K_Z(4.28 dB HL) (P<0.001). The order of underestimation improvement values predicted by L'_{EX,8 h}-K for NIPTS₃₄₆ was: L'_{EX,8 h}-K_A (7.20 dB HL)>L'_{EX,8 h}-K_C (6.83 dB HL)>L'_{EX,8 h}-K_Z (6.71 dB HL) (P<0.001).
Conclusion The adjustment of A- and C-weighted kurtosis to equivalent sound level L_{EX,8 h} can effectively improve the accuracy of the ISO 1999 prediction model in NIPTS prediction, and compared with the C-weighted, the A-weighted kurtosis can improve the result of the ISO 1999 prediction model in terms of underestimating NIPTS.

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