Pesticide exposure and lung cancer risk: A case-control study in Nakhon Sawan, Thailand

Introduction

Lung cancer is a common and deadly type of cancer. In 2018, there were 2.1 million people around the world diagnosed with lung cancer, and 1.8 million died of the disease¹. In 2018, Thailand had 170,495 incidences, and 114,199 deaths from lung cancer². Besides genetic factors³, a major risk factor of lung cancer is cigarette smoking^4,5. However, lung cancer was also related to other risk factors, including asbestos, crystalline silica, radon, polycyclic aromatic hydrocarbons, diesel engine exhaust particles, chromium, and nickel^6,7. Previous studies have also linked cooking fumes to lung cancer⁸.

Results from recent studies suggested pesticide exposure as a potential risk factor of lung cancer⁹. The association between pesticides and lung cancer were presented around 50 years ago among grape farmers¹⁰. A large study in the United States found that lung cancer cases increase with the number of years working as a licensed pesticide applicator¹¹. Another study in USA reported an increased risk of lung cancer among acetochlor herbicide users (RR = 1.74, 95% CI 1.07-2.84)¹². In Pakistan, a study also found a strong association between pesticide exposure and lung cancer (OR = 5.1, 95% CI 3.1-8.3)¹³.

Some studies also linked individual pesticides to lung cancer. In the USA, a study evaluated 50 pesticides and found that seven—dicamba, metolaclor, pendimethalin, carbofuran, chlorpyrifos, diazinon, and dieldrin—to be positively associated with lung cancer¹⁴. Another study also showed a significantly increased risk of lung cancer among applicators who had been exposed to dieldrin¹⁵. Jones et al.¹⁶ reported an increased lung cancer incidence among male pesticide applicators with the highest exposure category of diazinon (OR = 1.6, 95% CI 1.11-2.31). Other individual pesticides that had been associated with lung cancer were chlopyrifos¹⁷, diazinon¹⁸, and pendimenthalin¹⁹.

Currently, there is limited evidence on the association between pesticide exposure and lung cancer and more studies are needed to confirm the association and identify more individual pesticides. According to our knowledge, the association between lung cancer and pesticides has never been studied before among Thai people. The objective of this study was to investigate the associations between pesticide exposure and lung cancer using a case-control design. The results can be used in the prevention of lung cancer, and to support global literature on the subject.

Methods

Results

Discussion

The study results showed a positive association between lung cancer and the historical use of herbicides and insecticides (Table 3). The associations were in dose-response pattern and the risk of lung cancer increase with both number of years and day using the chemicals. The study also found three insecticides (dieldrin, chlorpyrifos, and carbofuran) and two herbicides (glyphosate, and paraquat) to be statistically associated with lung cancer. These results were consistent with literature indicating the potential carcinogenicity of pesticides²⁹. In an experimental study, exposure to pesticides caused the production of reactive oxygen species (ROS), an oxygen-containing species containing an unpaired electron, such as superoxide, hydrogen peroxide, and hydroxyl radical, which are highly unstable and may cause DNA damage, protein damage, mutagenicity, necrosis, and apoptosis³⁰. Pesticides may also increase the risk of cancer via other mechanisms including genotoxicity, tumour promotion, epigenetic effects, hormonal action and immunotoxicity³¹. In epidemiological study, evidence linked pesticide exposure to lung cancer are increasing, and the issue will be further discussed in the following section.

In this study, dieldrin was found to strongly associate with lung cancer and the association was in a dose-response relationship. The finding was consistent with literature. Dieldrin is an extremely persistent organic pollutant linked to many health problems, e.g., Parkinson's disease, breast cancer, affecting the immunity system, the reproductive, and nervous systems³². In the USA, the Agricultural Health Study (AHS) found seven pesticides including dicamba, metolaclor, pendimethalin, carbofuran, chlorpyrifos, diazinon, and dieldrin to be positively associated with lung cancer¹⁴. Further studies found dieldrin exposure to relate to the highest tertile of days use (RR = 5.30; 95% CI 1.50–18.60)¹⁵. After fifteen years of follow-up, the latest AHS by Bonner et al.³³ found dieldrin to associate with lung cancer (OR=1.93; 95% CI: 0.70, 5.30). In Thailand, 688 tons of dieldrin was used in 1981–1990, before it was banned on May 16, 1990.

It was found that historical use of chlorpyrifos was dose-response association with lung cancer. Those who use the pesticide had 3.29 times (1.93-5.61) higher risk of lung cancer as compare to the control group. This finding was in agreement with previous studies. A study among pest control workers in Florida, USA found a long-term exposure to organophosphate and carbamate insecticides over ten years to increase mortality risk of lung cancer¹¹. In the Agricultural Health Study, a dose response relationship was found between lung cancer and chlorpyrifos¹⁷ and diazinon¹⁸. In later studies of the AHS cohort identified chlorpyrifos as another potential risk factor¹⁷. However, the last updated results from the AHS did not support the association³³. At this time, chlorpyrifos was still not banned by Thai government. On the other hand, chlorpyrifos was the primary insecticide imported to Thailand (1,193,302 kilograms in 2013)³⁴.

This study also found a significant association between carbofuran and lung cancer (OR=2.10, 95% CI 1.28-3.42). Although previous studies did not find the association, there is some evidence suggested the potential effects of the chemical. Carbofuran (2,3-dihydro-2,2-dimethylbenzofuran-7-yl methylcarbamate) is one of the most toxic broad-spectrum carbamate insecticides. In laboratory studies, although evidence on carcinogenicity is inconclusive, carbofuran has been demonstrated to have mutagenic properties; and there are studies that have linked it to other types of cancer, e.g., lymphoma in mice³. Evidence from previous epidemiology studies were rather contradictory. In the Agricultural Health Study, the first report by Bonner et al. in 2005 found a rather strong association when lung cancer risk was compared to those in the lowest exposure category^14,35. However, this association was reported to be absent in a later study in 2017 by the same author³³. For other types of cancer, carbofuran has been identified as a potential cause of non-Hodgkin’s Lymphoma (NHL)³⁶. A survey In Thailand (2012) found carbofuran to be the most commonly used pesticides in rice fields³⁷.

Although, a rough estimation of the use of glyphosate and paraquat were not significantly associated with lung cancer, more detailed exposure data showed that people in the higher category of cumulative exposure day, especially those in a high quartile of exposure days had an elevated risk of lung cancer (Table 3). Paraquat (dipyridylium), also known as Gramoxone, is a non-selective herbicide commonly used worldwide^33,38. Although, the mechanism of toxicity has not been clearly defined, research found that paraquat can cause damage to the lungs, kidneys, and the liver³⁹. At the cellular level, paraquat can produce reactive oxygen species (ROS), the superoxide free radical, which can initiate or promote carcinogenesis⁴⁰. In a case study, pulmonary fibrosis was found in the patient with paraquat poisoning⁴¹. In Thailand, paraquat was banned in May 2020.

Glyphosate [N-(phosphonomethyl) glycine, also known as Roundup] is another broad-spectrum herbicide that has been used widely in Thailand and other countries^33,38. In the past decade, cancer potency of glyphosate received much attention and several comprehensive literature reviews are available^42,43. In 2015, WHO revised carcinogenicity of glyphosate and classified it as “probable carcinogen”⁴³. Laboratory studies found glyphosate to increase incidence of tumour, chromosomal damage, and oxidative stress⁴³. Currently, evidence from epidemiological studies were limited. Although it was previously reported to relate to non-Hodgkin lymphoma, glyphosate did not relate to cancer at any sites in the large perspective Agricultural Health Study^33,44,45.

The potential limitations of this type of study were the recall bias where cases and controls can recall past exposure differently. Cases tend to memorize exposure better, particularly when they know or are aware of what caused their illness⁴⁶. However, with limited available information on the issues in Thailand, we did not expect participants to be aware of pesticides as causal factor for lung cancer. It was very likely that the study could have exposure misclassification due to the participants not being able to recall or name the pesticides they used in the past. In addition, data on pesticide exposure were obtained solely from the interview questionnaire without any exposure measurement. However, this information bias usually occurs evenly across a case and control group, and only has a negative effect on the association⁴⁷. Selection bias might also occur when using non-random sampling or when the study sample did not represent the study population. However, in this study, data from all the lung cancer patients except those who were severely ill, were collected to minimize the bias. The study faces potential selection bias in the control group due to non-random selection. Nevertheless, considering the efforts made to minimize this issue through the study's design, which involved using neighborhood controls and incorporating two controls per case, the problem should not significantly impact the study results.

This study constitutes a rare case-control investigation of lung cancer in a developing country such as Thailand. The findings contribute significantly to the literature, particularly given that the majority of publications on this topic originate from developed Western countries. The association of pesticides with lung cancer is a critical concern due to the widespread use of these chemicals, posing a substantial risk of exposure to a large population.

Conclusion

This study found the occurrence of lung cancer to be associated with the historical use of pesticides. The results confirmed the association between dieldrin and chlorpyrifos and lung cancer and suggested the potential effects of carbofuran, glyphosate, and paraquat. More studies are still required to confirm the results and to identify more individual pesticides that could cause lung cancer, as well as other types of cancer. These issues should receive more attention since these chemicals have been used widely.