ONLINE ONLY - REVIEW ARTICLE
|Year : 2021 | Volume
| Issue : 2 | Page : 371
Association between Smokeless Tobacco and risk of malignant and premalignant conditions of oral cavity: A systematic review of Indian literature
Shivesh Acharya1, Shruti Singh1, Sarabjot Kaur Bhatia2
1 Department of Dentistry, All India Institute of Medical Sciences, Raebareli, Uttar Pradesh, India
2 Oral Health Sciences Centre, PGIMER, Chandigarh, India
|Date of Submission||23-May-2020|
|Date of Decision||18-May-2021|
|Date of Acceptance||02-Jun-2021|
|Date of Web Publication||31-Aug-2021|
Department of Dentistry, All India Institute of Medical Sciences, Munshiganj, Raebareli - 229 405, Uttar Pradesh
Source of Support: None, Conflict of Interest: None
| Abstract|| |
Causative linkages of tobacco use with oral potentially malignant disorders and cancers of oral cavity have been studied. Oral squamous cell carcinoma is one of the most common cancers in India. The International Agency for Research on Cancer (IARC) monograph found a significant association between smokeless tobacco (SLT) use and oral cancer. However, only a few limited studies have been represented on the IARC monograph. Published meta-analyses have provided pooled risk estimates for oral cancers caused by tobacco, both on global and regional levels. This systematic review was aimed at summarizing all the available studies exclusively in India by collecting data from PubMed and Medline. Emphasis was laid on cohort and case–control studies, and a few cross-sectional studies for premalignant lesions were also discussed. A significant association was noticed on SLT and premalignant and malignant oral cavity lesions.
Keywords: Case–control, cohort, oral cancer, oral premalignant lesion, smokeless tobacco
|How to cite this article:|
Acharya S, Singh S, Bhatia SK. Association between Smokeless Tobacco and risk of malignant and premalignant conditions of oral cavity: A systematic review of Indian literature. J Oral Maxillofac Pathol 2021;25:371
|How to cite this URL:|
Acharya S, Singh S, Bhatia SK. Association between Smokeless Tobacco and risk of malignant and premalignant conditions of oral cavity: A systematic review of Indian literature. J Oral Maxillofac Pathol [serial online] 2021 [cited 2021 Dec 2];25:371. Available from: https://www.jomfp.in/text.asp?2021/25/2/371/325258
| Introduction|| |
Epidemiological studies in India have shown that up to 80% of oral cancer patients are tobacco users.
They are consumed either has smoking forms: beedi, cigarette, cigar, dhumti, gudakhu, hookah and hookli and chewable forms or smokeless tobacco (SLT): paan, khaini, snuff, zarda, mawa, etc.
SLT is a major public health problem in the Indian subcontinent, and India is considered the global capital of SLT use.
Unlike other countries where cigarettes and waterpipe smoking are the major form of tobacco used, in India, only less than one-fifth (19%) of tobacco consumed is in the form of cigarettes.
As per the Global Adult Tobacco Survey (2010), more than one-third (35%) of adults in India are tobacco users. Of them, 21% are addicted only to SLT products whereas 9% are addicted to smoking alone. The rest 5% are addicted to both forms, i.e., smoking as well as SLT.,
As per the World Health Organization report, the most significant risk factor for cancer is tobacco use, which alone is responsible for 22% of cancer deaths worldwide. According to the International Agency for Research on Cancer (IARC) monograph of 2007 on SLT, among the different subsites of the head-and-neck region, tobacco chewing is associated with only cancer of the oral cavity. The majority of the studies were from Europe and North American countries. Countable studies from India were discussed in the monograph due to limited data from the Indian subcontinent.,
Research studies conducted over the years have shown linkage of SLT use with oral potentially malignant disorders (PMDs) and cancers of oral cavity.
According to the population-based cancer registry published by the Indian Council of Medical Research, in India, oral cavity and pharynx cancers account for about 12%–32% of all cancers in males and about 3.5%–10% of all cancers in females.,
Oral cancer is by far the most common cancer in India; laryngeal cancers are common in the Western world and nasopharyngeal cancers in the Chinese and southeast population. The difference of incidence and site-wise distribution of head-and-neck cancer between India and most parts of the world is believed to be due to the difference in tobacco consumption pattern, i.e., smoking and SLT use. According to a recently published study from India, the mortality rate in tobacco chewers has increased by five times due to oral cancer in comparison to the nonchewers.
SLT products are known to contain more than thirty carcinogens. The basic ingredients of SLT include sun-cured unprocessed or processed tobacco of Nicotiana tabacum and Nicotiana rustica species. Tobacco-specific N-nitrosamines (TSNAs) – N-nitrosonornicotine, 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone and N-nitrosamino acids – are quantitatively the most prevalent strong carcinogens in SLT along with heavy metals such as nickel, cadmium, chromium and copper., They are formed by nitrosation of tobacco alkaloids. Hence, nitrate and nitrite levels in SLT determine the extent of carcinogenicity, toxicity and health risk associated with the product as their levels vary widely among the SLT products. This hinders the comparability of results of various studies evaluating the health effects of SLT use.,
The carcinogens cause the formation of DNA adducts and subsequent mutations in K-ras, p53 and other genes, leading to uncontrolled cell growth. Other changes, including chronic local inflammation, oxidative stress and formation of reactive oxygen species, may also contribute to tumor promotion. Mechanisms such as activation of Akt and protein kinase A lead to reduced apoptosis and increased angiogenesis and cellular transformation. Apart from TSNAs, other compounds present in SLT products such as polycyclic aromatic hydrocarbons and areca nut may also contribute to causation of cancer in SLT users. SLT-related carcinogenesis can also be caused by epigenetic mechanism, like promoter methylation of tumor suppressor genes leading to unregulated proliferation.
The review aims to discuss the harmful effects of SLT leading to premalignant lesions and oral cancer throwing an insight on the premalignant lesions. The review includes a short briefing on SLT products along with analysis of various study results carried on the Indian population on establishing correlation between usage and malignant, premalignant lesions and oral cancers.
We have reviewed all articles, which have investigated for association of oral cancer and premalignant lesions with usages of chewable form of tobacco with or without areca nut.
| Methodolgy|| |
A systematic literature search was conducted in PubMed and Google Scholar databases for articles using combination of keywords smoking, tobacco chewing and oral cancer, premalignant lesion, leukoplakia, erythroplakia, oral submucous fibrosis and oral squamous cell carcinoma from 1980 to 2020. The primary focus was on cohort and case–control studies published exclusively in India. To rule out any bias, we have reviewed all articles, which have searched for association of oral cancer and premalignant lesions with usages of chewable form of tobacco with or without areca nut. In tables, as applicable, the form of tobacco usage has been mentioned.
| Results and Discussion|| |
Oral cancer is one of the most common forms of cancer in India. Most oral cancers are preceded by premalignant lesion such as leukoplakia, erythroplakia, oral submucous fibrosis (OSMF) and verrucous carcinoma which when neglected lead to Oral Squamous cell carcinoma. Microscopically, they are detected as oral epithelial dysplasia whose malignant transformation rate is as high as 36%. It is well known that oral cancer is preceded by visible oral precursors. The most commonly seen PMDs are leukoplakia, erythroplakia, oral submucous fibrosis (OSMF), palatal lesions in reverse smokers and oral lichen planus. The prevalence of OSMF ranged from 0.4% to 1.2%, and the malignant transformation rate varies from 7.6% to 40%. The prevalence of leukoplakia varied from 0.2% to 4.9%. The malignant transformation of leukoplakia ranges from 3.6% to 17.5%. Erythroplakia is rare and has an incidence of 0.02%–0.83%. Villa et al. reported the global mean prevalence of oral erythroplakia to be 0.11% and malignant transformation rate of 14.3%–66.7%. Oral premalignant lesions (OPMLs) are relatively common, occurring in about 2.5% of the general population and are an important target for cancer prevention. Tobacco is the major risk factor in oral cancer. In India, chewing tobacco in a mixture form along with areca nut and other ingredients such as betel leaf, slaked lime and catechu is a very common practice. Areca nut is derived from a oriental palm Areca catechu. Arecoline, the major alkaloid in areca nut, has been found to stimulate collagen synthesis in fibroblasts; the presence of copper upregulates lysyl oxidase, leading to excessive cross-linking and accumulation of collagen in patients with oral submucous fibrosis (OSF). Slaked lime is composed of calcium hydroxide that boosts the pH of a product and results in increased availability of free nicotine, the form that is most easily absorbed in oral mucosa. Catechu contains tannins which serve as flavoring agents. The use of unprocessed tobacco, the cheapest form, varies in different parts of India. It is sold in different forms and with different names. The various forms are chewed, sucked or used as dentifrice. Commonly used SLT products with local names and their ingredients used across the country are enlisted in [Table 1].
|Table 1: Local smokeless tobacco products with ingredients used across the country|
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In an evaluation of epidemiological studies on the carcinogenic risk to humans of tobacco habits other than smoking, the IARC Working Group concluded that there was sufficient evidence that the habits of chewing betel quid containing tobacco and tobacco mixed with lime were carcinogenic to humans. We hereby report various studies in the country revealing strong association between oral cancer, premalignant lesions and chewing tobacco from 1980 to 2019.
Limited cohort studies are available in India, and Karunagappally cohort is the first study established in 1990 at a rural coastal area in Kollam district of Kerala covering 93% of population. The baseline data were collected between 1990 and 1997. The study analyzed cancer incidence in the period of 1990–2005. A total of 79,593 eligible women aged 30–84 years were taken as a subject, and 102 female cases of oral cancer were identified by the end of 2005. After excluding women without habit history, a total of 92 oral cancer cases were diagnosed. The study found tobacco chewing as a significant risk factor for oral cancer among females strongly related to daily frequency of tobacco chewing was increased 9.2-fold among women chewing tobacco ten times or more a day though age did not pose any risk [Table 2].
A similar analysis was performed on males. The risk of having cancer of mouth and gum was very high (relative risk [RR]: 4.7) among the current tobacco chewers, whereas the risk of having tongue cancer was only slightly higher (RR: 1.1). Alcohol was not found to be a significant risk factor for oral cancer, whereas bidi smoking was a significant risk factor only for those who did not chew tobacco [Table 3].
As per study conducted by Pednekar et al. in Mumbai, the incidence of oral cancer in bidi smokers (hazard ratio [HR] =3.55; 95% confidence interval [CI]: 2.40–5.24) was 42% higher than in cigarette smokers (HR = 2.50; 95% CI: 1.65–3.78). SLT use was associated with cancers of the lip and oral cavity [Table 2].
All the case control studies available in India reveal a strong association between tobacco chewing and oral cancer. And majority of them confirm that risk involved in tobacco chewing is higher than smoking. Majority of these studies confirmed that the risks involved in tobacco chewing were higher than the risks associated with smoking. A study done by Subapriya et al. in Tamil Nadu indicated that the chewing of betel nut and tobacco, chewing of tobacco alone, bidi smoking and alcohol consumption (OR = 1.65) were all significant risk factors for oral cancer. People addicted to all three habits had a very high RR for oral cancer (OR = 11.34). Majority studies on tobacco chewing has been done in South India .One such study done by Muwonge et al. in Kerala. Showed he OR of chewing tobacco was much higher than bidi smoking (3.3 vs. 1.9). A significantly increased risk was observed among all categories of tobacco chewers, i.e., ever chewer, past chewer or present chewer. The adjusted OR of chewing tobacco was much higher than bidi smoking (3.3 vs. 1.9). A significantly increased risk was observed among all categories of tobacco chewers, i.e., ever chewer, past chewer or present chewer. A similar type of result was also depicted by other studies. Tobacco chewers had about 5-fold increased risk of oral cancer and smokers 2-fold risk. According to this study, the joint effect of smoking, chewing and drinking alcohol was greater than additive but less than multiplicative [Table 3].
However, alcohol and tobacco chewing showed multiplicative interaction, inducing a 24-fold increased risk of oral cancer. A study by Nandakumar et al. in Bangalore reported that RR associated with smoking (OR = 1.9) was much lower than RR associated with tobacco chewing (OR = 14.6). A study by Dikshit et al. found about 6-fold increase in the risk of oral cavity cancer among tobacco quid chewers. Population attributable risk percent was found to be 66.1% for tobacco chewers for the development of oral cancer.
Another case control study done by Balram et al. also stated that Relative Risk of oral cancer among men caused by chewing tobacco was higher than smoking bidis.( RR being 2.5). As per studies reported from Tata Memorial Hospital (TMH), Mumbai, one of these studies from TMH found tobacco chewing to be a significant risk factor for oral cancer among males (OR = 2.95, 95% CI: 2.34–3.71). This study also found bidi smoking and alcohol consumption as a significant risk factor for oral cancer among males. Another study from TMH by Rao and Desai showed that the type of tobacco had a direct relationship with the site of cancer. According to this study, tobacco chewing was a significant risk factor for anterior tongue cancer, whereas bidi smoking was a significant risk factor for a base of tongue cancer. A study by Gangane et al. in Wardha, and Madani et al. from Pune found the habit of tobacco chewing to be significantly associated with oral cancer.
Thomas et al. in Kerala conducted Case control study considering risk associated with tobacco chewing in multiple OPMLs like leukoplakia, erythroplakia and OSMF. The cases were patients having at least two or all the three major OPMLs, i.e., leukoplakia, erythroplakia and OSMF. The adjusted OR for continuous tobacco chewers was very high (OR = 37.8, 95% CI: 16.2–88.1). Another study was conducted among patients with only oral leukoplakia (OL) revealing tobacco chewing as a significant risk factor for OL. Hashibe et al. study was conducted among patients with only oral erythroplakic lesion. This study found tobacco chewing as a significant risk factor for erythroplakia (OR = 19.8) as compared to alcohol (OR = 3.0) and smoking (OR = 1.6) [Table 3].
A study from Kerala by Hashibe et al. investigated the association of other habits with OSMF. This study found ever-tobacco chewing as a strong risk factor for OSMF (OR = 44.1, 95% CI: 22.0–88.2) whereas alcohol drinking as a possible risk factor (OR = 2.1, 95% CI: 1.0–4.4).
A hospital-based case–control study compared 220 patients of OSMF with matched controls with regard to dietary habits, smoking history and preference for chewing substrates. Its right, mentioned in [Table 3]: Bathiraj etal study 2009.
A study from All India Institute of Medical Sciences, New Delhi, found chewing of areca nut/quid or pan-masala was directly related to OSMF [Table 3].
Studies have been done for specific subsites of oral cancer. One study found that substantial cases of cancer of the buccal and labial mucosa were attributable to paan-tobacco chewing. One study found there was a significant positive association between paan-tobacco chewing and cancer of the gingiva. The strongest predictor was daily frequency of paan-tobacco chewing. Four predictors of gingival cancer were yielded from stepwise logistic regression analysis; they were the daily frequency of paan-tobacco chewing, duration of bidi use and alcohol and snuff use (regular versus ever).
Among all the case–control studies, three studies were done on genetic polymorphism using specific markers at specific sites of affected cases that did not infer a positive association,, [Table 2].
Various notable cross-sectional studies are also available from India:
Narasannavar et al. in Belgaum and Kumar et al. in Indore reported the prevalence of OPML associated with tobacco. OSMF is the most common type in both studies. Pimple et al. also reported OPML association with tobacco usage. Pahwa et al. in from Udupi taluk reported that the prevalence of OPML was found to be 3.73%.
The recent data of cross sectional study in India include studies conducted in Chhattisgarh, Puducherry and Kanpur All of them had shown a strong association of OMLs showed prevalence of OSMF and leukoplakia among the tobacco users. Other studies including those in Lucknow in Uttar Pradesh showed that the prevalence was 13.2%, with a high incidence of OLs followed closely by oral submucous fibrosis (OSF) with a study from Gujarat by Joshi and Tailor.
As prevalence study data do not provide the concrete evidence of cause of the disease and the duration of the studies done is arbitrarily chosen, much cannot be relied on their results which are diversified.
As per the data from a decade, few of the cross-sectional studies have been stated without much emphasis on the discussion of their results.
| Conclusion|| |
As the use of tobacco is very common in India as compared to the Western world, the high incidence of oral cancer in this part of the world is attributed to SLT use. Indian studies suggest a strong association between tobacco chewing and different premalignant lesions. As per the analysis, maximum prevalence studies have shown its association with tobacco pouch keratosis, leukoplakia or OSMF, the lesions are curable by habit cessation.
As per the data collected, there are very few cohort and case–control studies done in the country for premalignant lesions and oral cancer. Majority of them are reported from South India. Further studies with adequate power and control of confounding factors are required. The studies should specifically address the product-specific association to enable clear policy decisions and also to refute the claims of tobacco industry regarding relative safety of SLT products as an alternative to quitting for smokers.
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Conflicts of interest
There are no conflicts of interest.
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[Table 1], [Table 2], [Table 3]