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Combined effect of silica dust exposure and cigarette smoking on total and cause-specific mortality in iron miners: a cohort study

Abstract

Background

Both cigarette smoking and long-term exposure to crystalline silica dust were reported to be associated with increased mortality. However, the combined effect of both factors has not been well evaluated.

Methods

We investigated a retro-prospective cohort of 7,665 workers from one Chinese iron mine with a median follow-up of 42.8 years. Cumulative silica exposure was estimated for each worker by linking work histories with a job-exposure matrix. Cigarette smoking information was collected through face-to-face questionnaires. Hazard ratios (HRs) for total and cause-specific mortality due to silica exposure and smoking were estimated using Cox proportional hazards models.

Results

A total of 2,814 deaths occurred during 315,772.9 person-years of follow-up. Significantly elevated mortality from all causes, cardiovascular disease, non-malignant respiratory disease and lung cancer was observed among silica-exposed workers, while elevated mortality from non-malignant respiratory disease and lung cancer was observed among smokers. Combined exposure to silica dust and cigarette smoking elevated the proportion of mortality and accounted for 21.2, 76.0, 35.7 and 81.4% of all causes, non-malignant respiratory disease, cardiovascular disease, and lung cancer, respectively. Significant additive joint effects of silica exposure and cigarette smoking on mortality from lung cancer (HR 1.893, 95% CI 0.628 to 3.441) and pneumoconiosis (6.457, 0.725 to 39.114), together with a significant multiplicative joint effect from all causes (1.002, 1.000 to 1.004) were observed.

Conclusions

The present findings indicated that silica exposure in combination with cigarette smoking accounted for a fraction of extra deaths in our cohort. Our research showed the urgent need for smoking cessation and silica control among iron miners.

Peer Review reports

Background

Crystalline silica is one of the most abundant minerals in the earth’s crust and a basic component of sand, soil and granite. Environmental exposure to crystalline silica can occur not only in various natural phenomena such as volcanic explosion and sandstorms but also in agricultural areas and a series of industries, such as metal mining, pottery process, quarrying, construction, and clay manufacturing. Volcanoes and sands are major sources of silica. It has been reported that approximately 9% of the world’s population lives within 100 km of active volcanoes [1], and more than 30% of the population has been exposed to sandstorms. In industrial areas, more than 30 million workers have been exposed to silica worldwide [2, 3]. The adverse health effects of silica exposure are an increasing public health concern in recent years [4, 5]. Long-term exposure to silica dust has been confirmed to be associated with elevated mortality from silicosis, chronic obstructive pulmonary disease (COPD) [6, 7] and other airway diseases, while recent research has further revealed its association with elevated mortality from pulmonary tuberculosis [8, 9], lung cancer [10,11,12] and cardiovascular disease [3, 13].

Cigarette smoking is a common health problem in the world. According to the World Health Organization, China has approximately 320 million smokers, representing one third of the world’s total smokers [14]. Accumulating evidence has suggested that cigarette smoking is associated with increased mortality risks from all causes, malignant neoplasm (especially lung cancer) [15], digestive system tumours [16], ischaemic heart disease [17], and stroke [18]. Published investigations have also reported that the rate of smoking among manual workers was relatively high [19]. In our previous study [20], approximately 64% workers in metal mines and pottery factories had a history of smoking cigarettes. Based on these facts, consequences due to silica exposure in combination with cigarette smoking need to be explored in detail. However, the joint effect of silica exposure and cigarette smoking on mortality from all causes and specific diseases, especially cardiovascular disease and non-malignant respiratory disease, has not been well evaluated.

Therefore, we presented a retro-prospective cohort study of 7,665 participants from one Chinese iron mine from January 1, 1960 to December 31, 2012. For each participant, cumulative crystalline silica exposure was calculated by linking work histories with a job-exposure matrix since 1950. Cigarette smoking information was collected through questionnaires from self-report and next-of-kin (or colleagues). The objectives of this study were to assess the health effects of silica exposure and cigarette smoking on total and cause-specific mortality and to evaluate the joint effects of silica exposure and cigarette smoking on total and cause-specific mortality.

Methods

Study population

This retro-prospective cohort included 7,665 participants who were registered in one iron mine company located in central China and worked for at least 1 year between January 1, 1960 and December 31, 1974. This cohort is one part of the Chinese silica cohort that has been described previously [3, 21]. All participants were followed up until they died, were lost to follow-up, or survived to the end of 2012. Data on personal information and work history were retrospectively collected in 1986, and job information, vital status, cause of death and new diagnosis of pneumoconiosis were prospectively updated yearly until 2012 by industrial hygienists.

Cause of death

Vital status was traced by local physicians during the follow-up. The cause of death for the deceased was collected from medical records in the hospital (84.45%), employment registers, accident records or death certificates in the company (15.34%), or oral reports from relatives (0.21%). The 10th version of the International Classification of Diseases (ICD-10) was used to code and classified the causes of death into different disease systems.

Silica exposure data

Monthly measurement of dust concentration in workplaces with silica exposure was required by the Chinese government enforcement system in the early 1950s. A dust monitoring scheme including total dust concentration and crystalline silica content has been conducted by professional staff in iron mines since 1950. Respirable silica concentration in workplaces was then converted from total dust concentration and silica percent in dust particles through a field study [22, 23]. Then, a job-exposure matrix (JEM) with job- and calendar year-specific silica concentrations was established [3]. The work history for each participant including job titles and work start and end dates was taken from company occupational records. Cumulative respirable silica dust exposure (CDE) for each participant (mg/m3-years) was calculated as Eq. (1):

$$ CDE={\sum}_{i=1}^n\left({C}_i\times {T}_i\right) $$
(1)

where n is the total number of job titles, C is the 8-h-weighted mean respirable silica concentration for the ith job title, and T is the duration of working years for the ith job title.

Smoking information

Detailed smoking data for all participants were first collected in 1986 and updated in 1995, 2004, and 2012. Cigarette smoking is defined as having at least 1 cigarette per day for at least 6 months. Smoking information from 728 of the participants (9.5%) was provided by their relatives because they either died or withdrew before 1986. Smoking amount was calculated by multiplying packs per day by years of smoking. To examine the reliability of the data, 385 randomly selected subjects were re-investigated in 2004. Agreement on smoking status (never or ever) between next-of-kin and colleagues of decedents was 89.1%, and agreement on smoking status between self-report and next-of-kin (or colleagues) for living subjects was 93.6% [20].

Statistical analysis

Based on the distribution of CDE in the entire cohort, we equally divided participants into unexposed, and low, medium, and high silica exposure groups. Cox proportional hazards regression models were used for estimating hazard ratios (HRs) and 95% confidence intervals (CIs) for total and cause-specific mortality in different silica exposure levels when compared with the unexposed group. Additionally, by fitting the models with CDE as a continuous variable instead of a categorical one, we determined the correlation between HRs and per one mg/m3-y increase in CDE. The other covariates were adjusted, including gender, year at hire (five categories, 1955 or earlier, 1956–1960, 1961–1965, 1966–1970, and 1971 or later), age at hire (continuous) and smoking intensity (pack-years, continuous).

The participants who smoked were divided into two groups by median pack-years. We also introduced pack-year as a continuous variable to determine the correlation between HRs and per unit increase in pack-years. The other confounding factors, such as gender, year at hire (five categories, 1955 or earlier, 1956–1960, 1961–1965, 1966–1970, and 1971 or later), age at hire (continuous) and silica exposure (continuous), were adjusted.

The population attributable risks (PARs) were calculated as Eq. (2):

$$ PAR=\left[P\times \left( RR-1\right)\right]/\left[P\times \left( RR-1\right)+1\right] $$
(2)

where P is the percentage of exposure among the study population, and RR is the relative risk estimated from HR.

To assess the additive joint effects, the relative excess risks due to interaction (RERIs) needed to be evaluated. A linear relative rate model [24] was thus implemented, with the relative risks (RRs) of dichotomized silica exposure and smoking intensity at different levels calculated as Eq. (3):

$$ RR=\left(e\hat{\mkern6mu} {\beta}_0\right)\ast \left[1+{\beta}_1A+{\beta}_2B+{\beta}_3\left(A\ast B\right)\right] $$
(3)

where β1 and β2 is the excess relative risk per unit of exposure to A and B, respectively, and β3 is the departure from additivity of the exposure effects on an relative risk scale. Therefore, β3 is taken as estimator of RERI.

To assess the multiplicative joint effects, we constructed the Cox regression models by including continuous metrics for both smoking intensity and silica exposure as well as a product term for the interaction of them and determined the HRs. A p-value smaller than 0.05 was considered statistically significant. All p-values were 2-sided. We conducted all data analyses using SAS, version 9.3 software (SAS Inc. Cary, North Carolina).

Results

A total of 7,665 participants (6,542 male, 85.4%) with median follow-up of 42.8 years were included into analyses. The average participant age upon entry to the cohort was 24.8 years. At the end of follow-up, only 38 (0.5%) participants were still employed, while 6,519 (85.0%) participants had retired or died, and 1,108 (14.5%) had left for other companies. Among those who left for other companies, 270 individuals were lost to follow-up, and their person-years were thus truncated at time of loss.

Table 1 shows characteristics of the cohort according to different silica exposure levels. A total of 3,658 (47.7%) participants were exposed to silica dust during their working period, and 96.2% of silica-exposed workers were male. The number of smokers (current and former) among all participants and silica-exposed workers were 5,070 (66.1%) and 2,732 (74.7%), respectively. The percentage of smokers was 76.9% for male workers and 3.3% for female workers. During the follow-up, 2,814 deaths were identified during 315,772.9 person-years of follow-up. Mortality was 891.2 per 100,000 person-years for all participants. The mortality was 1042.0 per 100,000 person-years and 751.6 per 100,000 person-years among silica-exposed and non-silica-exposed workers, respectively. Among the deaths, 1,581 (56.2%) were silica-exposed workers, and 1,917 (68.1%) were smokers.

Table 1 Basic characteristics of participants (n = 7,665) by silica exposure level, 1960–2012

Annual respirable silica concentrations for different job titles classified by major activity groups from 1950 to 2012 are listed in Fig. 1. The mean respirable silica concentrations ranged from 0.03 mg/m3 to 0.07 mg/m3 before 1978. After taking protection measures, silica concentration fell to between 0.01 mg/m3 and 0.02 mg/m3 from 1978 to 2010 and gradually decreased to below 0.01 mg/m3 in 2012. The silica concentration for the underground mining group was higher than 0.09 mg/m3 in the early 1950s and then decreased stably. The silica concentration for the ore separation process group was approximately 0.05 mg/m3 before 1969 and became higher than 0.07 mg/m3 between 1970 and 1974 due to adoption of mechanical crushing, and then the concentration decreased to lower than 0.02 mg/m3 after 1975 due to ventilation and wet work.

Fig. 1
figure 1

Annual respirable silica concentration for different job titles, classified by major activity groups, 1950–2012. Horizontal axis represents the year of industrial production and vertical axis represents respirable silica concentration. Solid line represents annual average respirable silica concentration among all the silica-exposed job titles and the other three types of dotted lines represent annual average respirable silica concentration among the specific major activity groups, that is underground mining, open-pit mining and ore separation process group

Table 2 shows the number of deaths and HRs for total and cause-specific mortality due to silica exposure. Malignant neoplasm was the leading cause of death in the iron mine. The second to fourth causes of death in this cohort were cerebrovascular disease, cardiovascular disease, and non-malignant respiratory disease, respectively. Compared with the unexposed group, significantly higher mortality was found in silica-exposed workers from all causes (HR 1.303, 95% CI 1.206 to 1.408), malignant neoplasm (1.357, 1.173 to 1.570), cardiovascular disease (1.446, 1.169 to 1.789) and non-malignant respiratory disease (3.166, 2.440 to 4.107). A positive exposure-response relationship was found between (both categorical and continuous) CDE and mortality from all causes, non-malignant respiratory disease (including pneumoconiosis), cardiovascular disease (including pulmonary heart disease), certain infectious and parasitic diseases (including respiratory tuberculosis), and lung cancer. Each 1 mg/m3-y increase in CDE was associated with an 11.7, 41.4, 21.3 and 19.0% increase in mortality risk from all causes, non-malignant respiratory disease, cardiovascular disease, and lung cancer, respectively. In addition, a positive exposure-response relationship existed between categorical CDE and mortality from ischaemic heart disease, and the HRs were 1.190, 1.538 and 1.781 (monotonically increased) for low, medium and high levels of CDE (P-value for linear trend: < 0.001), respectively, although the relationship between continuous CDE and mortality was not statistically clear (HR 1.134, 0.990 to 1.298).

Table 2 HRs for total and cause-specific mortality associated with silica exposure in the cohort (n = 7,665), 1960–2012

Table 3 shows the death number of ever and never smokers and HRs for total and cause-specific mortality due to cigarette smoking. As seen, malignant neoplasm had the largest proportion of ever smokers (77.95%). When compared with the never smokers, significantly increased mortality risks were found from all causes (HR 1.102, 95% CI 1.008 to 1.205), non-malignant respiratory disease (1.612, 1.229 to 2.115), pulmonary heart disease (2.067, 1.112 to 3.843), malignant neoplasm (1.694, 1.404 to 2.045) and lung cancer (4.347, 2.820 to 6.700) among the smokers, while the increment was not significant from ischaemic heart disease (1.126, 0.823 to 1.539). A statistically significant exposure-response relationship was found between smoking amount (both categorical and continuous) and mortality from malignant neoplasm (including lung cancer) and non-malignant respiratory disease (including chronic lower respiratory disease). Each 1 pack-year increase in smoking was associated with a 0.7, 1.0, 0.7 and 2.3% increase in the mortality risk from non-malignant respiratory disease, chronic lower respiratory disease, malignant neoplasm and lung cancer, respectively. Furthermore, we found a positive exposure-response relationship between categorical smoking and mortality from pneumoconiosis with a linear p-trend of 0.005, despite of the fact that the HR for each 1 pack-year increase in smoking did not reach statistical significance (HR 1.008, 0.999 to 1.017).

Table 3 HRs for total and cause-specific mortality associated with cigarette smoking in the cohort (n = 7,665), 1960–2012

After adjustment for potential confounders and smoking, we found that silica exposure accounted for 12.6, 50.8, 17.5 and 24.2% of mortality from all deaths, non-malignant respiratory disease, cardiovascular disease, and lung cancer, respectively. Likewise, after adjustment for potential confounders and silica exposure, cigarette smoking accounted for 6.3, 28.8, 12.6 and 68.9% of mortality from all deaths, non-malignant respiratory disease, cardiovascular disease, and lung cancer, respectively. Eventually, combined exposure to silica dust and cigarette smoking accounted for 21.2, 76.0, 35.7 and 81.4% of mortality from all deaths, non-malignant respiratory disease, cardiovascular disease, and lung cancer, respectively.

When compared with non-silica-exposed and non-smoking workers, we found significantly elevated mortality risks from all causes (HR 1.344, 95% CI 1.189 to 1.520), non-malignant respiratory disease (5.052, 3.144 to 8.116), cardiovascular disease (1.709, 1.214 to 2.405) and lung cancer (6.586, 3.616 to 11.992) among silica-exposed and smoking workers. The joint effects of silica exposure and cigarette smoking on total and cause-specific mortality are shown in Table 4. From combined effects analysis, the relative excess risks due to interaction (RERIs) of smoking and silica exposure were 1.893 (95% CI 0.628 to 3.441) for lung cancer and 6.457 (0.725 to 39.114) for pneumoconiosis, indicating that joint effects were significant and more than additive. The additive joint effects could be further observed without significance for all causes, malignant neoplasm, and non-malignant respiratory disease. A multiplicative interaction between silica exposure and smoking was only significant for all causes (1.002, 1.000 to 1.004).

Table 4 Estimated HRs for mortality, associated with combined exposure to silica and smoking (n = 7,665), 1960–2012

Discussion

In our cohort study of 7,665 workers from one Chinese iron mine, we not only confirmed an exposure-response relationship between long-term exposure to cumulative crystalline silica dust and mortality risk from all causes, non-malignant respiratory disease, cardiovascular disease and lung cancer but also found significant exposure-response relationships between lifelong cigarette smoking and mortality from non-malignant respiratory disease and lung cancer. Furthermore, we observed significant additive joint effects of silica exposure and cigarette smoking on mortality from lung cancer and pneumoconiosis, together with a significant multiplicative joint effect from all causes.

A significant positive exposure-response relationship was found between CDE and mortality from all causes, non-malignant respiratory disease, respiratory tuberculosis, and cardiovascular disease among 74,040 Chinese workers in our previous analysis [3]. In the present study, we extended 10 years of follow-up for all participants from one iron mine of the above cohort. At the end of follow-up, only 0.5% participants of this cohort were still working. In other words, we completed the entire follow-up of lifetime occupational exposure to silica dust for more than 99% participants and could therefore provide reliable evaluations about adverse health effects from silica exposure. Our cohort reconfirmed an obvious exposure-response relationship between silica exposure and mortality from all causes, non-malignant respiratory disease, cardiovascular disease, and lung cancer.

Consistent with our study, research at an iron ore mine in Cumbria showed significantly elevated standardized mortality ratios (SMRs) from all causes (1.27), neoplasm (1.18), ischaemic heart disease (1.18), and respiratory disease (1.73) [25]. Another iron ore mine cohort study in Sweden with 5 years of follow-up reported significantly elevated mortality risks from all causes (SMR 1.05, 95% CI 1.02 to 1.09), lung cancer (1.73, 1.52 to 1.97), respiratory disease (1.14, 1.00 to 1.28), and myocardial infarction (1.12, 1.07 to 1.18) [26]. However, a retrospective research from a Minnesota haematite cohort did not find any excess death rates from all causes or respiratory disease, which might be due to insufficient control for smoking or potential interference from other unknown types of productive dusts [27].

As a serious public health concern, smoking contributes to increased mortality from cardiovascular disease, respiratory disease and malignant neoplasm. Our study strongly demonstrated the exposure-response relationship between smoking amount and mortality from non-malignant respiratory disease and lung cancer, two main causes of death occupying the top rank in much of the current smoking research worldwide. The World Health Organization estimated that approximately 100 million people died of smoking across the twentieth century [28]. In addition, according to the Surgeon General’s Report in 2014 [29], smoking causes one of every three deaths from cardiovascular disease. In our study, an increase in mortality from cardiovascular disease (including ischaemic and pulmonary heart disease) was also observed among smokers when compared with non-smokers.

A large amount of research has testified to the influence of smoking on mortality. According to 50 years of observational research on British male doctors, the excess mortality associated with cigarette smoking was elevated for men born before 1900 (SMR = 1.16) and peaked for men born in the 1920s (SMR = 2.83). The probabilities of dying in middle age were 42 and 24% among smokers and non-smokers (a 2-fold mortality ratio) for those born in the 1910s, and 43% vs 15% (a 3-fold mortality ratio) for those born in the 1920s, respectively [30]. A cohort study in New Zealand also reported that the relative effect of smoking on mortality differed over time [31]. Additionally, a pooled study provided 2-fold and 1.3-fold excess mortality for current and former smokers compared with those who never smoked, and the excess mortality decreased with time since cessation of smoking [32].

Smoking acts as an essential inducing factor for lung cancer and non-malignant respiratory disease on its own, just as our research suggested. In addition, smoking, especially cigarette smoking, modifies the relationship between silica exposure and mortality from lung cancer and non-malignant respiratory disease. Because of the inherent toxicity and carcinogenicity of cigarettes [33], the adverse health effects due to combined exposure to silica dust and cigarette smoking are strengthened to some extent. In our previous research with 34,018 workers over 44 years of follow-up [20], a joint effect of occupational silica exposure and cigarette smoking on mortality from lung cancer was discovered to be greater than additive models (RERI 0.98, 0.23 to 1.74) and very close to multiplicative models (interaction term 1.27, 0.75 to 2.15). Similar results were also reported from a pooled analysis in Canada, which discovered that joint effects of silica exposure and smoking were between additive and multiplicative models, perhaps closer to the latter [34]. Our present study provided obvious results again for lung cancer, confirming a joint effect far beyond additive models (RERI 1.893, 0.628 to 3.441) and approaching multiplicative models (interaction term 0.999, 0.993 to 1.005). The significant additive joint effect of silica and cigarettes for lung cancer can be explained by the synergy of cigarette-induced genetic and cellular toxicity [33] and the silica-induced pulmonary inflammation and fibrosis [35].

Further, our research evaluated potential joint effects of silica exposure and smoking on mortality from other diseases. Significant additive interactions were observed on the mortality from lung cancer and pneumoconiosis, and a significant multiplicative interaction was found on the mortality from all causes. The analysis of population attributable risks (PARs) provided similar results, where combined exposure to silica dust and cigarette smoking accounted for elevated proportions of mortality from all causes, non-malignant respiratory disease, cardiovascular disease, and lung cancer compared with exposure to silica dust or cigarette smoking alone. Published literature has also suggested that persistent inflammation induced by silica dust may be related to health damage not only from lungs [36] but also from kidney, heart and liver [5]. On the other hand, cigarette smoking may exacerbate persistent toxicity and inflammation induced by silica exposure.

This study has several advantages. First, the cohort is large with a long period of follow-up and a low rate of withdrawal. Second, detailed data on dust concentration from the workplace and personal work history were acquired to estimate cumulative respirable silica exposure for each participant. Moreover, we have collected detailed and accurate smoking data for each participant.

One limitation of this study is that the silica concentration before 1950 was estimated using the concentration in 1950, which might lead to underestimated exposure for workers who started working before 1950 (140 workers). However, the results did not change after excluding the participants who started work before 1950. Another limitation is that cigarette smoking data for the deceased derived from their colleagues or next-of-kin, and recall bias might exist as a consequence. Lastly, the healthy worker survivor effect might underestimate risk of mortality from total and specific causes. Nevertheless, the results did not change substantially when we put the duration of employment into the regression models to re-analyse mortality risks with regard to silica, smoking and their combined effects.

Conclusions

In this cohort study of an iron mine, we confirmed adverse health effects of long-term crystalline silica exposure and life-long cigarette smoking. The joint effects of silica exposure and cigarette smoking were found on mortality from lung cancer and all causes, which indicate that silica in combination with cigarette smoking accounts for a fraction of extra deaths. Therefore, more effective measures should be taken towards silica control and smoking cessation among iron mine workers.

Abbreviations

CDE:

Cumulative respirable silica dust exposure

CI:

Confidence interval

COPD:

Chronic obstructive pulmonary disease

HR:

Hazard ratio

ICD-10:

The 10th version of the international classification of diseases

JEM:

Job-exposure matrix

PAR:

Population attributable risk

RERI:

Relative excess risk due to interaction

SMR:

Standardized mortality ratio

References

  1. Small C, Naumann T. The global distribution of human population and recent volcanism. Global Environmental Change Part B: Environmental Hazards. 2001;3:93–109.

    Article  Google Scholar 

  2. Leung CC, Yu ITS, Chen W. Silicosis. Lancet. 2012;379:2008–18.

    Article  CAS  Google Scholar 

  3. Chen W, Liu Y, Wang H, Hnizdo E, Sun Y. Su L, et al. long-term exposure to silica dust and risk of total and cause-specific mortality in Chinese workers: a cohort study. PLoS Med. 2012;9:e1001206.

    Article  CAS  Google Scholar 

  4. Liu Y, Rong Y, Steenland K, Christiani DC, Huang X, Wu T, et al. Long-term exposure to crystalline silica and risk of heart disease mortality. Epidemiology. 2014;25:689–96.

    Article  CAS  Google Scholar 

  5. Guo J, Shi T, Cui X, Rong Y, Zhou T, Zhang Z, et al. Effects of silica exposure on the cardiac and renal inflammatory and fibrotic response and the antagonistic role of interleukin-1 beta in C57BL/6 mice. Arch Toxicol. 2016;90:247–58.

    Article  CAS  Google Scholar 

  6. Hnizdo E. Loss of lung function associated with exposure to silica dust and with smoking and its relation to disability and mortality in south African gold miners. Occup Environ Med. 1992;49:472–9.

    Article  CAS  Google Scholar 

  7. Hnizdo E, Vallyathan V. Chronic obstructive pulmonary disease due to occupational exposure to silica dust: a review of epidemiological and pathological evidence. Occup Environ Med. 2003;60:237–43.

    Article  CAS  Google Scholar 

  8. Ehrlich R, Churchyard G, Pemba L, Dekker K, Vermeis M, White N, et al. Tuberculosis and silica exposure in south African gold miners. Occup Environ Med. 2006;63:187–92.

    Article  Google Scholar 

  9. Hnizdo E, Murray J. Risk of pulmonary tuberculosis relative to silicosis and exposure to silica dust in south African gold miners. Occup Environ Med. 1998;55:496–502.

    Article  CAS  Google Scholar 

  10. Steenland K, Sanderson W. Lung cancer among industrial sand workers exposed to crystalline silica. Am J Epidemiol. 2001;153:695–703.

    Article  CAS  Google Scholar 

  11. Pelucchi C, Pira E, Piolatto G, Coggiola M, Carta P, La Vecchia C. Occupational silica exposure and lung cancer risk: a review of epidemiological studies 1996–2005. Ann Oncol. 2006;17:1039–50.

    Article  CAS  Google Scholar 

  12. Lacasse Y, Martin S, Gagné D, Lakhal L. Dose–response meta-analysis of silica and lung cancer. Cancer Causes Control. 2009;20:925–33.

    Article  Google Scholar 

  13. Weiner J, Barlow L, Sjögren B. Ischemic heart disease mortality among miners and other potentially silica-exposed workers. Am J Ind Med. 2007;50:403–8.

    Article  Google Scholar 

  14. Zhang H, Cai B. The impact of tobacco on lung health in China. Respirology. 2003;8:17–21.

    Article  Google Scholar 

  15. Peto R, Darby S, Deo H, Silcocks P, Whitley E, Doll R. Smoking, smoking cessation, and lung cancer in the UK since 1950: combination of national statistics with two case-control studies. BMJ. 2000;321:323–9.

    Article  CAS  Google Scholar 

  16. Giovannucci E. An updated review of the epidemiological evidence that cigarette smoking increases risk of colorectal cancer. Cancer Epidemiology and Prevention. Biomarkers. 2001;10:725–31.

    CAS  Google Scholar 

  17. Huxley RR, Woodward M. Cigarette smoking as a risk factor for coronary heart disease in women compared with men: a systematic review and meta-analysis of prospective cohort studies. Lancet. 2011;378:1297–305.

    Article  Google Scholar 

  18. Ueshima H, Choudhury SR, Okayama A, Hayakawa T, Kita Y, Kadowaki T, et al. Cigarette smoking as a risk factor for stroke death in Japan. Stroke. 2004;35:1836–41.

    Article  CAS  Google Scholar 

  19. Laaksonen M, Rahkonen O, Karvonen S, Lahelma E. Socioeconomic status and smoking. Eur. J Pub Health. 2005;15:262–9.

    Article  Google Scholar 

  20. Liu Y, Steenland K, Rong Y, Hnizdo E, Huang X, Zhang H, et al. Exposure-response analysis and risk assessment for lung cancer in relationship to silica exposure: a 44-year cohort study of 34,018 workers. Am J Epidemiol. 2013;178:1424–33.

    Article  Google Scholar 

  21. Chen J, McLaughlin JK, Zhang J-Y, Stone B, Luo J, Chen R-a, et al. Mortality among dust-exposed Chinese mine and pottery workers. J Occup Environ Med. 1992;34:311–6.

    Article  CAS  Google Scholar 

  22. Dosemeci M, Chen JQ, Hearl F, Chen RG, McCawley M, Wu Z, et al. Estimating historical exposure to silica among mine and pottery workers in the People's Republic of China. Am J Ind Med. 1993;24:55–66.

    Article  CAS  Google Scholar 

  23. Zhuang Z, Hearl F, Odencrantz J, Chen W, Chen B, Chen J, et al. Estimating historical respirable crystalline silica exposures for Chinese pottery workers and iron/copper, tin, and tungsten miners. Ann Occup Hyg. 2001;45:631–42.

    Article  CAS  Google Scholar 

  24. Richardson DB, Kaufman JS. Estimation of the relative excess risk due to interaction and associated confidence bounds. Am J Epidemiol. 2009;169:756–60.

    Article  Google Scholar 

  25. Kinlen L, Willows A. Decline in the lung cancer hazard: a prospective study of the mortality of iron ore miners in Cumbria. Br J Ind Med. 1988;45:219–24.

    CAS  Google Scholar 

  26. Björ B, Burström L, Jonsson H, Nathanaelsson L, Damber L, Nilsson T. Fifty-year follow-up of mortality among a cohort of iron-ore miners in Sweden, with specific reference to myocardial infarction mortality. Occup Environ Med. 2009;66:264–8.

    Article  Google Scholar 

  27. Lawler AB, Mandel JS, Schuman LM, Lubin JH. A retrospective cohort mortality study of iron ore (hematite) miners in Minnesota. J Occup Environ Med. 1985;27:507–17.

    CAS  Google Scholar 

  28. Organization WH, Control RIT. WHO report on the global tobacco epidemic, 2008: the MPOWER package: World Health Organization; 2008.

  29. Alberg AJ, Shopland DR, Cummings KM. The 2014 surgeon General's report: commemorating the 50th anniversary of the 1964 report of the advisory committee to the US surgeon general and updating the evidence on the health consequences of cigarette smoking. Am J Epidemiol. 2014;179:403–12.

    Article  Google Scholar 

  30. Doll R, Peto R, Boreham J, Sutherland I. Mortality in relation to smoking: 50 years' observations on male British doctors. BMJ. 2004;328:1519.

    Article  Google Scholar 

  31. Hunt D, Blakely T, Woodward A, Wilson N. The smoking–mortality association varies over time and by ethnicity in New Zealand. Int J Epidemiol. 2005;34:1020–8.

    Article  Google Scholar 

  32. Müezzinler A, Mons U, Gellert C, Schöttker B, Jansen E, Kee F, et al. Smoking and all-cause mortality in older adults: results from the CHANCES consortium. Am J Prev Med. 2015;49:e53–63.

    Article  Google Scholar 

  33. Adams JD, O'Mara-Adams KJ, Hoffmann D. Toxic and carcinogenic agents in undiluted mainstream smoke and sidestream smoke of different types of cigarettes. Carcinogenesis. 1987;8:729–31.

    Article  CAS  Google Scholar 

  34. Vida S, Pintos J, Parent M-É, Lavoué J, Siemiatycki J. Occupational exposure to silica and lung cancer: pooled analysis of two case-control studies in Montreal, Canada. Cancer Epidemiol Biomark Prev. 2010;19:1602–11.

    Article  CAS  Google Scholar 

  35. Suzuki N, Ohta K, Horiuchi T, Takizawa H, Ueda T, Kuwabara M, et al. T lymphocytes and silica-induced pulmonary inflammation and fibrosis in mice. Thorax. 1996;51:1036–42.

    Article  CAS  Google Scholar 

  36. Guo J, Gu N, Chen J, Shi T, Zhou Y, Rong Y, et al. Neutralization of interleukin-1 beta attenuates silica-induced lung inflammation and fibrosis in C57BL/6 mice. Arch Toxicol. 2013;87:1963–73.

    Article  CAS  Google Scholar 

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Acknowledgements

We thank all the participants for their help.

Funding

This study was supported by the Fundamental Research Funds for the Central Universities, HUST 2016JCTD116. The funder did not participate in the research design, data collection, data analysis, and manuscript writing.

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Authors and Affiliations

Authors

Contributions

HL, MZ, YZ, SW and WC contributed to study concept and design. HL, YL, TS, SW and WC contributed to data collection and interpretation. HL, YL, MZ and WC contributed substantially to the statistical analysis. All the authors have approved the manuscript and agree with submission to Occupational and Environmental Medicine.

Corresponding author

Correspondence to Weihong Chen.

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Ethics approval and consent to participate

All participants in this study gave the written informed consents for participation. The methods were carried out in accordance with the relevant guidelines. This study protocol was approved by the Ethics and Human Subject Committee of Tongji Medical College, Huazhong University of Science and Technology, P. R. China.

Competing interests

The authors declare that they have no competing interests.

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Lai, H., Liu, Y., Zhou, M. et al. Combined effect of silica dust exposure and cigarette smoking on total and cause-specific mortality in iron miners: a cohort study. Environ Health 17, 46 (2018). https://doi.org/10.1186/s12940-018-0391-0

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