The study was performed with the approval of the Institutional Review Board of the Experimental Teaching Demonstration Center, Central Laboratory, College of Public Health of North China University of Science and Technology (Tangshan, China). Informed written consent was collected from each eligible worker and the entire study was performed based on the Declaration of Helsinki (16).

A total of 376 male workers specialized in mining operations, who did not change occupation since they began coal mining operations, were selected from a coal mine in Tangshan as the observation group. These male subjects were aged between 21 and 59 years, with a mean age of 40.67±11.17 years, body weight of 47–86 kg, mean body weight of 66.47±11.37 kg, mean height of 170.8±6.24 cm and mean working duration of 22.53±9.56 years. Workers were considered to be dust-exposed and were included into the study if they met the following criteria: i) Exposure to dust for >1 year; ii) exposure time in the specific coal mine accounted for >50% of their total exposure time; iii) health examination results within the past 2 years were available; and iv) the history of changes in work were clear and complete, or could be completed through archives.

In addition, 179 healthy male workers in the instrument and meter plant and electrical power plant, which were in the same area as the coal mine, were selected as the control group of non-dust exposure workers. Control subjects were aged between 20 and 58 years, with a mean age of 38.99±11.62 years, body weight of 46–87 kg, mean body weight of 66.65±11.81 kg, and mean height of 169.3±5.32 cm. There was no statistically significant difference in the age, gender, body weight and height between the two groups (P>0.05). The selected subjects were free of active tuberculosis, short-term (within 2 weeks) bronchial-pulmonary infection history, bronchial asthma, and heart, liver, kidney, immune system or endocrine system diseases. Furthermore, the subjects had not received treatments affecting the immune and endocrine functions. A professional physician performed unified health inspection using a unified health examination form, which was completed individually for each participant. The main information collected included the following: Name, gender, age, height, body weight, temperature, pressure, smoking status, type of dust exposed to, dust work history, work environment, protection measures and past medical history.

The determination and analysis of PFT results were performed by respiration physicians using Beijing AS.507 type spirometer (Beijing Kangxin Tongchuang Science and Technology Co. Ltd., Beijing, China). Prior to the examination, the subjects were instructed to rest for 5–10 min and to breath calmly 4–5 times before each test. The subjects inhaled deeply, aligning the inlet of the equipment with the oral cavity, and subsequently exhaled deeply as fast as possible. The pulmonary function measurement parameters included FVC, FEV1 and FEV1/FVC. The optimum results obtained from three or more measurements in each subject were selected as the final results of the pulmonary function.

Smoking was evaluated based on the smoking index, which was calculated by the number of cigarettes smoked per day per smoking year. Subjects with a smoking index ≥20 were classified as smokers, while subjects with an index <20 were classified as non-smokers.

Abnormal pulmonary functions were evaluated according to the relative values of FVC and FEV1, with the exception of FEV1/FVC. The relative value was calculated as follows: (Actual measured value / theoretical value) × 100%. The theoretical value was obtained using a PFT instrument and a computational formula (17) based on the age, gender, height, weight, temperature, pressure and other factors, while the relative value eliminated the influence of the aforementioned factors. Generally, an index with a theoretical value of ≥80% was considered as normal, according to the techniques and methods of compiled normal values of pulmonary function reported nationwide (18).

Dust-exposure time was also evaluated. The dust-exposed working duration was considered to be 1 year in subjects exposed to coal dust for 1 full year, without changes in work history. Subjects were divided into the following four groups, according to the dust-exposure working duration: <10 years, 10–20 years, 20–30 years and >30 years.

According to the detection data of dust-exposure levels reported between 1970 and 2013 by the Safety and Environmental Protection Department of the coal mine (total dust concentration is mainly measured by the filter membrane method) (19), the work history of subjects was carefully investigated, including details on the work hours or the length of time working in the mine in their career, and any changes in the type of work. The CTE of each coal-mine worker was calculated as follows: CTE = ∑(Ci × Ti), where Ci is the dust concentration the worker was exposed to at a certain period of time, and Ti is the working year during which the worker was exposed to this concentration. CTE is expressed in terms of mg/m³.years.

The cumulative abnormal rate of pulmonary function was calculated as follows: Cumulative abnormal rate = 1 − cumulative normal rate; cumulative normal rate = (1 − abnormal rate) × (1 − higher abnormal rate); abnormal rate = morbidity [number of subjects at the beginning of the period – (number of subjects at the end of the period / 2)]. Number of subjects at the beginning of the period refers to all the individuals with a certain initial CTE, while the number at the end of the period refers to all the individuals with a certain CTE at the end.

The calculation formula according to quantitative results of sample size was as follows: n = [2σ²/(µ₂−µ₁)²] × f⁺(α, β), and this formula was used to calculate whether the research object met the required sample size. µ₁ and µ₂ refer to the mean values in non-dust exposed and dust-exposed workers, respectively. σ refers to standard deviation, f(α,β) refers to the function. α refers to the probability of the first type of error and β is the probability of second type of error. Considering the relative value of FEV1 as an example, if α=0.05, β=0.10 and f⁺(α, β)=10.5, and the results of the present study were µ₁=87.46, µ₂=79.07 and σ=14.63, then the obtained sample size would be 63.85. Therefore, a sample size of 64 cases is required in this test, while the actual sample size of the control group was 179 cases, and the sample size of the dust-exposed worker group was 376 cases; thus, the sample sizes included in the present study satisfy the required number.

In the current study, the associated information was collected and a database was established. SPSS version 16.0 software (SPSS, Inc., Chicago, IL, USA) was used for data analysis and processing. Measurement data are presented as the mean ± standard deviation, and were analyzed using t test and F test. Enumeration data are presented as %, and were analyzed using χ² test. Correlations were analyzed by Pearson's correlation. A P-value of <0.05 was considered to indicate a statistically significant difference.

The distribution of smoking status in the observational and control groups is displayed in Fig. 1. In the observational group, 200/376 subjects (53.19%) were smokers, which was higher compared with the number of smokers in the control group (72/179 subjects; 40.22%), with a significant difference observed (χ²=8.16; P=0.004).

As shown in Fig. 2, the cumulative abnormal rate of pulmonary function within smokers in the observational group (102/200; 51.00%) was evidently higher compared with that of smokers in the control group, with a statistically significant difference identified (χ²=12.98; P=0.003). However, in the non-smoking subgroup, the cumulative abnormal rate of pulmonary function in the control group was 44.86% (48/107), while the rate was 55.68% (98/176) in the observational group, with no significant difference observed (χ²=3.121; P=0.077).

In the smoking and non-smoking subgroups, FVC and FEV1 in the observational group were markedly lower compared with those in the control group (both P<0.05). In addition, FEV1/FVC in the observational group was weakly lower compared with that in the control group; however, no significant difference was detected (P>0.05; Table I).

As shown in Table II, in the smoking subgroup, FVC and FEV1 in the group with a working duration of >30 years were evidently lower compared with the values in the <10-year, 10–20-year and 20–30-year working duration group (all P<0.05). Comparison of FEV1/FVC in different working duration groups showed no significant difference (P=0.169). However, in the non-smoking subgroup, the comparison of FVC, FEV1 and FEV1/FVC in different working duration groups also showed no significant difference (all P>0.05).

Table III demonstrates the correlation of smoking with pulmonary function in the observational group. The results indicated that FVC, FEV1 and FEV1/FVC in the smoking subgroup were negatively correlated with the time length of dust exposure (all P<0.05). By contrast, FVC, FEV1 and FEV1/FVC in the non-smoking subgroup of coal-mine workers were not found to be correlated with dust-exposure working duration (all P>0.05).

The cumulative abnormal rate of pulmonary function in the smoking subgroup increased from 0.54% (100 mg/m³.years group) to 77.78% (1,700 mg/m³.years group) as shown in Table IV and Fig. 3. Similarly, the cumulative abnormal rate in the non-smoking subgroup increased from 0.58% (100 mg/m³·years group) to 75.76% (1,700 mg/m³·years group; Table V and Fig. 3).

CTE was positively correlated with cumulative abnormal rate of pulmonary function in both the smoking and non-smoking subgroups (smoking subgroup: r=0.884, P<0.001; non-smoking subgroup: r=0.901, P<0.001). As shown in Table VI, FEV1 was negatively correlated with CTE in the smoking subgroup (r=−0.184, P=0.009); however, FVC and FEV1/FVC showed no correlation with CTE (both P>0.05). In the non-smoking subgroup, FVC, FEV1 and FEV1/FVC had no significant association with CTE (all P>0.05; Table VI).