a Institute of Post Graduate Medical Education and Research, 244 Acharya Jagadish Chandra Bose Road, Calcutta 700020, India. E-mail: dngm{at} apexmail.com
b School of Public Health, University of California, Berkeley, CA 947207360, USA. E-mail: ahsmith{at}uclink4.berkeley.edu
c School of Environmental Studies, Jadavpur University, Calcutta 700032, India.
Corresponding author: DN Guha Mazumder.
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Abstract |
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Methods Participants were clinically examined and interviewed, and the arsenic content in their current primary drinking water source was measured. There were few smokers and analyses were confined to non-smokers (N = 6864 participants).
Results Among both males and females, the prevalence of cough, shortness of breath, and chest sounds (crepitations and/or rhonchi) in the lungs rose with increasing arsenic concentrations in drinking water. These respiratory effects were most pronounced in individuals with high arsenic water concentrations who also had skin lesions. Prevalence odds ratio (POR) estimates were markedly increased for participants with arsenic-induced skin lesions who also had high levels of arsenic in their current drinking water source (500 µg/l) compared with individuals who had normal skin and were exposed to low levels of arsenic (<50 µg/l). In participants with skin lesions, the age-adjusted POR estimates for cough were 7.8 for females (95% CI : 3.119.5) and 5.0 for males (95% CI : 2.69.9); for chest sounds POR for females was 9.6 (95% CI : 4.022.9) and for males 6.9 (95% CI : 3.115.0). The POR for shortness of breath in females was 23.2 (95% CI : 5.892.8) and in males 3.7 (95% CI : 1.310.6).
Conclusion These results add to evidence that long-term ingestion of inorganic arsenic can cause respiratory effects.
Keywords Arsenic, respiratory disease, keratoses, hyperpigmentation, cross-sectional study, drinking water, India
Accepted 13 March 2000
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Introduction |
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Hallmark signs of chronic arsenic toxicity include skin keratoses of the palms and soles, and hyperpigmentation of the torso and upper limbs. These skin lesions generally develop 510 years after exposure commences, although shorter latencies are possible. Chronic ingestion of inorganic arsenic causes non-melanoma skin cancer, and is also associated with increased risks of cancer of the internal organs.9 Emerging evidence shows that ingestion of inorganic arsenic may also lead to non-malignant respiratory effects.
Respiratory effects in West Bengal were first noted in 1995 when 57% of the 156 patients who lived in arsenic-affected villages reported having cough.10 Moreover, epidemiological studies in Chile have previously suggested an association between arsenic and non-malignant respiratory effects. From survey data collected between 1968 and 1972 in Antofagasta, Chile, Zaldivar and Ghai11 reported that the prevalence of cough among 398 children correlated with mean drinking water arsenic concentrations. In addition, the prevalence of reported cough declined from 38% to 7% after an arsenic removal plant was installed in Antofagasta (P < 0.001). Zaldivar12 also reported that the prevalence of bronchiectasis was 23-fold greater among children with arsenic-induced skin lesions living in Antofagasta compared to children living in the rest of Chile. Rosenberg13 conducted autopsies on five children who died between 1968 and 1969 in Antofagasta. All five children possessed characteristic signs of chronic arsenic poisoning, including hyperpigmentation and/or keratoses. Lung tissue was examined in four of these children, with abnormalities found in all four. Interstitial fibrosis was detected in two of the cases. A 1976 cross-sectional survey in Antofagasta examined 144 schoolchildren with arsenic-induced skin lesions, and bronchopulmonary disease occurred 2.5 times more often in these children (15.9%) compared with children with normal skin (6.9%).3 In a recent study, Smith et al. 4 found high relative rates for chronic obstructive pulmonary disease (COPD) mortality among young men and women living in the same arsenic-exposed region in Chile which includes Antofagasta. In those aged 3039 there were four deaths from COPD among males (0.8 expected) and six among women (0.1 expected, SMR [men and women combined] = 11.1, 95% CI : 5.320.4, P < 0.001). Since COPD mortality was not increased in older age groups, the authors suggested that exposures during childhood were important and led to the increased COPD mortality rates in young adults.
A few occupational studies conducted in the 1950s in Sweden have also reported non-malignant respiratory effects in copper smelter workers exposed to airborne arsenic. In one clinical study of 1459 copper smelter workers cited by Gerhard et al., a syndrome characterized by chronic rhino-pharyngeo-tracheobronchitis, lesions of the mucous membranes of the upper respiratory system, emphysema and decreased pulmonary function was described.14 Information on smoking habits was not presented, which might have contributed to the reported signs and symptoms.
With the exception of the study in Chile, respiratory effects of ingestion of inorganic arsenic has not been reported elsewhere. The cross-sectional survey included over 7000 individuals, one of the largest arsenic-affected populations known to date, living in the 24 South Parganas, West Bengal. The aim of the survey, which was conducted between April 1995 and March 1996, was to determine the prevalence of various health effects associated with arsenic. The most common arsenic-related health effects found were keratoses and hyperpigmentation and a clear exposure-response trend was identified according to arsenic concentrations in drinking water.15 In this paper, we focus on the prevalence of respiratory signs and symptoms assessed in the survey, including cough, chest sounds, and shortness of breath.
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Methods |
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The second area included the remaining part of the district (32 villages in 16 administrative blocks), where people were drinking from shallow tubewells. Sampling in this area was limited to villages with more than 100 households. One or more villages were randomly selected from each of the 16 blocks, depending on the population size. One village was targeted for sampling in a small block, but two or three villages were selected if the block was larger. In this area, the field team went to the centre of the village and commenced sampling in the most convenient hamlet; but this time, residents of every fourth house were invited to participate. These two areas combined have a population of 150 457.
In all 7818 individuals participated in the survey. Arsenic levels in the drinking water sources were measured for 7683 individuals (4093 females and 3590 males). There were few smokers and they were excluded from the analyses presented here; thus 6864 participants (4042 females and 2822 males) comprise the study population for consideration of respiratory signs and symptoms.
Interview and clinical exam
Participants were briefly questioned about their sources of drinking water and socio-demographic characteristics. Participants were then asked to volunteer any health problems. If the participant did not volunteer any information concerning the presence of respiratory problems, they were then specifically asked by a physician interviewer the following questions: Do you have problems with coughing? Do you have problems with shortness of breath? Chest sounds were determined by auscultation and included crepitations and/or rhonchi. In view of the potential relationship between reported shortness of breath and general weakness, the present analysis also included responses to the question, Are you troubled with feeling weak? A general medical examination was also performed, including a careful examination for skin lesions. A detailed explanation of the criteria used for diagnosing keratoses and hyperpigmentation appears elsewhere.15 Physician interviewers who were blind to the arsenic content in the drinking water diagnosed the skin lesions. Arsenic-induced skin lesions are distinctive. Diffuse keratoses appear as bilateral thickening of the palms and soles. Nodular keratoses occur as small protrusions on the palms and soles, with or without nodules on the dorsum of the hands, feet or legs. Raindrop-shaped discoloured spots, diffuse dark spots, or diffuse darkening of the skin on the limbs and trunk mark changes in pigmentation due to arsenic.
Participants were also asked if they smoked currently or had smoked in the past. In rural India, small hand-rolled cigarettes (biris) are most frequently consumed. Biris are usually filterless and are about an inch and half in length. The 819 participants (768 males and 51 females) who reported they had smoked regularly or often, either currently or in the past, were excluded from consideration because of relatively small numbers and potential confounding.
Arsenic measurements in drinking water
Water samples were obtained from the main private or public tubewells used for drinking by each household. Arsenic concentration was measured by flow-injection hydride generation atomic absorption spectrophotometry. The detection limit determined at the 90% confidence level was 3 µg/l.16
Statistical analyses
The outcomes analysed included participant-reported cough, shortness of breath, and weakness, and the presence of chest sounds recorded by the examining physician. To allow for direct comparisons without the distorting effects of age, the prevalence of each outcome was directly standardized to the age distribution of all study participants of the same sex. Each outcome was examined according to arsenic levels in the tubewell drinking water source used by each participant. The tubewells were categorized according to arsenic concentrations as follows: <50, 50199, 200499, 500799 and 800 µg/l.
Tests for trend in proportions using the midpoints of the exposure categories were based on the 2 distribution.17 In view of unidirectional a priori hypotheses, one-sided P-values are presented for the test of trend.
Prevalence odds ratios (POR) were also calculated for each outcome comparing those with very high exposure to arsenic in drinking water (500 µg/l) with those with the lowest exposures (<50 µg/l). The Mantel-Haenszel method was used to adjust for age. Data were also stratified by the presence or absence of arsenic-caused lesions.
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Results |
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The age-adjusted prevalence of weakness increased strongly with arsenic water concentrations in both sexes (from 1.7 per 100 to 11.9 per 100 among women, P < 0.0001, and from 0.9 to 9.5 per 100 among men, P < 0.0001, Table 5).
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Discussion |
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The results in Table 6 indicate that in this population, the presence of respiratory effects was largely confined to those who had the arsenic-caused skin lesions. Why this should be so is not clear, but could be related to some underlying susceptibility to arsenic effects. In Chile, it was also noted that there were differences in respiratory disease in schoolchildren with skin lesions compared to those without the lesions.3 Interestingly, this was not true for reported weakness which while dramatically increased in those with skin lesions (Table 6
, POR 15.3 and 14.2 for females and males, respectively), was still markedly elevated in those with high current exposures who did not have skin lesions (age-adjusted POR of 6.7 and 5.4). Weakness is a highly subjective symptom which has previously been reported in arsenic-exposed patients.10 The reason people exposed to high arsenic levels report feeling weak is not clear. While arsenic can cause peripheral neuropathy, it is not known to cause central nervous system effects that could explain general feelings of weakness.
Although information about the relationship between ingested arsenic and non-malignant respiratory effects has so far only been reported from Chile and now India, studies from arsenic-affected regions in Taiwan, Chile and Argentina show marked increases in lung cancer mortality.1,4,5,18,19 It is of interest to note that many established lung carcinogens, including smoking, asbestos and silica, also cause non-malignant respiratory disease. The surprising characteristic of arsenic is that it seems to increase both malignant and non-malignant respiratory disease following ingestion.
While toxicological mechanisms for pulmonary effects of inorganic arsenic are not known, some reports have demonstrated that arsenic can accumulate in human lung tissue thus enhancing the plausibility that the metal can produce respiratory effects. Figueroa et al. noted evidence of lung tissue accumulation in humans.20 They investigated mummies hundreds of years old that were found in Region II of Chile, an area that has had high arsenic levels in drinking water. Kidney, liver, nail, and lung tissues had some of the highest concentrations of total arsenic, followed by the skin, intestines, hair, ribs, and muscles, respectively. Further, case reports from poisoning deaths have also demonstrated that high levels of arsenic occur in the lungs.21,22 In the first case, the lung tissue concentration of total arsenic at autopsy of a 3-year-old boy who accidentally ingested a weed killer containing 44% sodium arsenite was 7550 µg/kg. In the second case, a 25-year-old white male ingested 8 g of arsenic trioxide. At autopsy, the largest total arsenic concentration was found in the gastrointestinal tract, but a concentration of 2750 µg/kg was also discovered in the lungs. An autopsy study determined that the mean lung tissue arsenic concentration was sixfold greater in 85 copper smelter workers in Sweden compared to 25 non-exposed controls (35 versus 6 µg/kg wet weight).14
The main drawback of the current investigation is that limited time existed for interviewing and carefully assessing each subject involved in the large population survey that included over 7000 participants. Observer bias was possible during interviews and clinical examination of patients with skin lesions. We are therefore planning a more detailed assessment of selected participants with high exposure and skin lesions, including focused interviewing, medical examination and spirometric testing. Nonetheless, the strength of the current findings in terms of trend with water concentration and the very high POR, along with the plausibility of finding non-malignant respiratory effects based on studies in Chile, suggest that non-malignant respiratory effects may indeed result from ingestion of inorganic arsenic.
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Acknowledgments |
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References |
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2 Cebrian M. Heavy metals. In: Finkelman J, Corey G, Calderon R (eds). Environmental Epidemiology: A Project for Latin America and the Caribbean. Metepec, Mexico: Pan American Center for Human Ecology and Health, World Health Organization, 1993, pp.95145.
3 Borgono JM, Vicent P, Venturino H, Infante A. Arsenic in the drinking water of the city of Antofagasta: epidemiological and clinical study before and after the installation of a treatment plant. Environ Health Perspect 1977;19:10305.[ISI][Medline]
4 Smith AH, Goycolea M, Haque R, Biggs ML. Marked increase in bladder and lung cancer mortality in a region of Northern Chile due to arsenic in drinking water. Am J Epidemiol 1998;147:66069.[Abstract]
5 Hopenhayn-Rich C, Biggs ML, Smith AH. Lung and kidney cancer mortality associated with arsenic in drinking water in Córdoba, Argentina. Int J Epidemiol 1998;27:56169.[Abstract]
6 Rahman M, Tondel M, Ahmad SA, Axelson O. Diabetes mellitus associated with arsenic exposure in Bangladesh. Am J of Epidemiol 1998;148:198203.[Abstract]
7 Das D, Chatterjee A, Samanta G et al. Arsenic contamination in groundwater in six districts of West Bengal, India: the biggest arsenic calamity in the world. Analyst 1994;119:168N170N.[Medline]
8 Chatterjee A, Das D, Mandal BK, Chowdhury TR, Samanta G, Chakraborti D. Arsenic in ground water in six districts of West Bengal, India: the biggest arsenic calamity in the world. Part 1. Arsenic species in drinking water and urine of the affected people. Analyst 1995; 120:64350.[ISI]
9 Bates MN, Smith AH, Hopenhayn-Rich C. Arsenic ingestion and internal cancers: a review. Am J Epidemiol 1992;135:46276.[Abstract]
10 Guha Mazumder DN, Das Gupta J, Santra A. Non-cancer effects of chronic arsenicosis with special reference to liver damage. In: Abernathy C, Calderon RL, Chappel WR (eds). Arsenic Exposure and Health Effects. London: Chapman and Hall, 1997, pp.11223.
11 Zaldivar R, Ghai GL. Clinical epidemiological studies on endemic chronic arsenic poisoning in children and adults, including observations on children with high- and low-intake of dietary arsenic. Zentralbl Bakteriol. 1. Abt Originale B: Hygiene, Krankenhaushygiene, Betriebshygiene, Praventive Medizin 1980;170:40921.
12 Zaldivar R. A morbid condition involving cardio-vascular, broncho-pulmonary, digestive and neural lesions in children and young adults after dietary arsenic exposure. Zentralbl Bakteriol 1. Abt Originale B: Hygiene, Krankenhaushygiene, Betriebshygiene, Praventive Medizin 1980; 170:4456.
13 Rosenberg H. Systemic arterial disease and chronic arsenicism in infants. Arch Pathol 1974;97:36065.[ISI][Medline]
14 Gerhardsson L, Brune D, Nordberg GF, Wester PO. Multielemental assay of tissues of deceased smelter workers and controls. Sci Tot Environ 1988;74:97110.[ISI]
15 Guha Mazumder DN, Haque R, Ghosh N et al. Arsenic levels in drinking water and the prevalence of skin lesions in West Bengal, India. Int J Epidemiol 1998;27:87177.[Abstract]
16 Madal BK, Chowdhury TR, Samanta G et al. Arsenic in groundwater in seven districts of West Bengal, India: the biggest arsenic calamity in the world. Curr Sci 1996;70:97686.[ISI]
17 Breslow NE, Day NE. Statistical Methods in Cancer Research. Vol. 1: The Analysis of Case-Control Studies. 1st Edn. Lyon, France: International Agency for Research on Cancer, 1980.
18 Wu M-M, Kuo T-L, Hwang Y-H, Chen C-J. Dose-response relation between arsenic concentration in well water and mortality from cancers and vascular diseases. Am J Epidemiol 1989;130:112332.[Abstract]
19 Chiou HY, Hsueh YM, Liaw KF et al. Incidence of internal cancers and ingested inorganic arsenic: a seven-year follow-up study in Taiwan. Cancer Res 1995;55:1296300.[Abstract]
20 Figueroa L, Razmilic B, Gonzalez M. Corporal distribution of arsenic in mummied bodies owned to an arsenical habitat. In: Sancha FAM (ed.). International Seminar Proceedings. Arsenic in the Environment and its Incidence on Health. 2529 May 1992, Universidad de Chile, Facultad de Ciencias Fisicas y Matematicas, Santiago, Chile, 1992, pp.7782.
21 Saady JJ, Blanke RV, Poklis A. Estimation of the body burden of arsenic in a child fatally poisoned by arsenite weedkiller. J Anal Toxicol 1989;13:31012.[ISI][Medline]
22 Quatrehomme G, Ricq O, Lapalus P, Jacomet Y, Ollier A. Acute arsenic intoxication: forensic and toxicologic aspects (an observation). J Forensic Sci 1992;37:116371.[ISI][Medline]