Risk analysis of noise-induced hearing loss of workers in the automobile manufacturing industries based on back-propagation neural network model: a cross-sectional study in Han Chinese population

Yanmei Ruan; Guanhao Huang; Jinwei Zhang; Shiqi Mai; Chunrong Gu; Xing Rong; Lili Huang; Wenfeng Zeng; Zhi Wang

doi:10.1136/bmjopen-2023-079955

Risk analysis of noise-induced hearing loss of workers in the automobile manufacturing industries based on back-propagation neural network model: a cross-sectional study in Han Chinese population

BMJ Open. 2024 May 17;14(5):e079955. doi: 10.1136/bmjopen-2023-079955.

Authors

Yanmei Ruan¹, Guanhao Huang², Jinwei Zhang¹, Shiqi Mai¹, Chunrong Gu³, Xing Rong¹, Lili Huang¹, Wenfeng Zeng¹, Zhi Wang^{4

5}

Affiliations

¹ Key Laboratory of Occupational Environment and Health, Guangzhou Twelfth People's Hospital, Guangzhou, China.
² Department of Health care, BaiYun Women and Children's Hospital and Health Institute, Guangzhou, China.
³ Department of anesthesia, People's Liberation Army Southern Theater Air Force Hospital, Guangzhou, China.
⁴ Key Laboratory of Occupational Environment and Health, Guangzhou Twelfth People's Hospital, Guangzhou, China zhi_wang@outlook.com.
⁵ The Institute of Occupational and Environmental Health, Guangzhou Medical University, Guangzhou, China.

Abstract

Objectives: This study aims to predict the risk of noise-induced hearing loss (NIHL) through a back-propagation neural network (BPNN) model. It provides an early, simple and accurate prediction method for NIHL.

Design: Population based, a cross sectional study.

Setting: Han, China.

Participants: This study selected 3266 Han male workers from three automobile manufacturing industries.

Primary outcome measures: Information including personal life habits, occupational health test information and occupational exposure history were collected and predictive factors of NIHL were screened from these workers. BPNN and logistic regression models were constructed using these predictors.

Results: The input variables of BPNN model were 20, 16 and 21 important factors screened by univariate, stepwise and lasso-logistic regression. When the BPNN model was applied to the test set, it was found to have a sensitivity (TPR) of 83.33%, a specificity (TNR) of 85.92%, an accuracy (ACC) of 85.51%, a positive predictive value (PPV) of 52.85%, a negative predictive value of 96.46% and area under the receiver operating curve (AUC) is: 0.926 (95% CI: 0.891 to 0.961), which demonstrated the better overall properties than univariate-logistic regression modelling (AUC: 0.715) (95% CI: 0.652 to 0.777). The BPNN model has better predictive performance against NIHL than the stepwise-logistic and lasso-logistic regression model in terms of TPR, TNR, ACC, PPV and NPV (p<0.05); the area under the receiver operating characteristics curve of NIHL is also higher than that of the stepwise and lasso-logistic regression model (p<0.05). It was a relatively important factor in NIHL to find cumulative noise exposure, auditory system symptoms, age, listening to music or watching video with headphones, exposure to high temperature and noise exposure time in the trained BPNN model.

Conclusions: The BPNN model was a valuable tool in dealing with the occupational risk prediction problem of NIHL. It can be used to predict the risk of an individual NIHL.

Keywords: occupational & industrial medicine; public health; risk factors; risk management.

MeSH terms

Adult
Automobiles*
China / epidemiology
Cross-Sectional Studies
East Asian People
Hearing Loss, Noise-Induced* / diagnosis
Hearing Loss, Noise-Induced* / epidemiology
Hearing Loss, Noise-Induced* / etiology
Humans
Logistic Models
Male
Manufacturing Industry*
Middle Aged
Neural Networks, Computer*
Noise, Occupational / adverse effects
Occupational Diseases* / epidemiology
Occupational Diseases* / etiology
Occupational Exposure* / adverse effects
ROC Curve
Risk Assessment / methods
Risk Factors