Authors
Keywords
Abstract
From our preliminary survey (1995 to 2000), 33,092 hand tube wells water samples, collected from all 64 districts and found arsenic in 60 districts above WHO recommended value in drinking water (10 µg/L) and in 50 districts above maximum permissible limit, 50 µg/L. In these 50 districts the actual arsenic status is, 37% contains arsenic less than 10 µg/L, 63% and 42% contain arsenic above 10 µg/L and 50 µg/L, respectively. Total population of these 50 districts is about 104.9 million. This does not mean all populations in the 50 districts are drinking arsenic contaminated water or suffering, but undoubtedly, they are at risk. From our study, it appears that groundwater of Hill Tract and Table Land are almost free from arsenic contamination but that of Flood Plain and Deltaic areas are highly arsenic contaminated. During our preliminary survey, people suffering from arsenical dermal lesions have been identified in 31 out of 33 districts where we had made a preliminary dermatological investigation with medical team. From a random of 18,840 examination people in arsenic affected villages where people were drinking arsenic contaminated groundwater during last 6 years. We had registered 3,427 adults (both females and males) and 298 children (both girls and boys), having arsenical dermal lesions, such as: melanosis, leucomelanosis, keratosis, hyperkeratosis, dorsal, non-petting oedema, gangrene, cancer, etc. If children are included, then 19.77% (n=3,725) have arsenical dermal lesions and for separately adults and children these are 24.52% and 6.13%, respectively.
Thousands of hairs, nail, and urine samples from the people of arsenic affected villages were collected and analyzed. From our study we have observed that arsenic in hair, nail, and urine increases with increasing arsenic in drinking water. It appears that correlations are not strong positive [for hair samples r = 0.251, p = 0.01, n = 739; for nail samples r = 0.220, p = 0.01, n = 691, and for urine r = 0.547, p = 0.01, n = 910]. Probable reason, people are not drinking water from the same source all the times. Our field data indicates that most of the villagers drink water from more than one tube wells. From multi-elements analysis of some hair and nail samples it appears that Zn and Se concentration decreases with increasing arsenic concentration in both hair and nail. The concentration of Zn and Se also less in affected people's hair and nail than control hair and nail (drinking water contain arsenic <3 µg/L). But the linear regression shows positive correlation between As & Pb, As & Hg, and As & Sb in both hair and nail of exposed population. The concentrations of As, Pb, Hg, and Sb also high in affected people's hair and nail than control hair and nail. Our last 6 years of field experience in Bangladesh show that normally children under 11 years of age do not show arsenical dermal lesions. But we have observed few exceptions when (a) the arsenic content in water consumed by children is very high (1000 µg/L) and (b) the arsenic content is not very high (500 µg/L) but the children get poor nutrition.
Introduction
Inearly1960,physiciansin Antofagasta,Chile noticed dermal manifestations and some deathsamongthosedrinkingsuppliedwatercontaminatedwitharsenic.The contaminationculminatedfromleachingofarsenicwastesfrom miningoperationsintospringwater. The symptomsweremetamorphosisofskincolorandhyperkeratosis;childrenweresufferingfrombronchopneumoniaand bronchitis. The arseniccontaminationincidentin wellwaterofTaiwan (1961-1985)isalsowellknown.Limitedincidentofblack-footdisease and arsenismwerefoundandwasassociatedwithavariableofhighconcentrationofarsenic(100to1,810µg/L in drinking water). Somecasesofcancer (bladder,kidney,and liver) werealsonotedinendemicareas.Overtheyears,perhapsitwasbelievedthatarsenicalonewasresponsibleforthe blackfootdiseaseisthatarea. In1975, thediscoveryoffluorescentcompoundsinthese well waters led to theisolationofhumicsubstancesandnow arsenicincombinationwithhumicsubstancesisconsideredtobetheprobablecausefortheblack-footdisease.InMonteQuemadoofCordobaProvince,North Argentinasimilarincidentofarsenicingroundwaterwasreported. It is knownasthe"illness ofBell Ville(Cordoba)". FromtheobservationsinCordoba,itwasconcludedthat the regularintakeofdrinkingwatercontainingmore than 100 µg/Lof arsenicleadstoclearlyrecognizablesignsoftoxicityandultimatelycauses,insomecases,skin cancer. Chronic arsenic poisoning was also reported in some partsofRegionLagunera,situatedinthecentralpartofNorthMexicoduring1963-1983. The arsenic concentrationin groundwaterto theexposedpopulation was410µg/L.Otherincidentspertainingtogroundwater,asmallpopulationwasdrinking arsenic contaminated water only some arsenical cutaneousmanifestation was reported in Poland Ontario -Canada,Nova Scotia -Canada,Hungary,MillardCounty-Utah,USA.
In1987, Chakraborti and Sahareported arsenical dermal lesions in 5 districtsof West Bengal-India and found 197 patients’ sufferings from arsenical dermal lesionsin 48 families.During January 1989 to June 2001 survey was conductedbySchool of Environmental Studies (SOES), Jadavpur University, Kolkata in ninearsenic affected districts and present estimates indicatethat 74 blocks (2,600villages including some municipal areas) mainly by the eastern side of the riverGangaandadjoiningareasareaffected.Morethan 6 million people aredrinkingarsenic contaminatedwaterabove50µg/Land more than 300,000peoplemayhavearsenicaldermallesions.
During fieldsurvey of School ofEnvironmentalStudies(SOES)inarsenicaffecteddistrictsofWestBengal-India particularlyattheborderingareaofBangladeshin 1990, a woman arsenic patient who came to West Bengal-India afterhermarriagehadbeenidentified.Till1994morearsenicpatientsfromBangladeshwereidentifiedfromtheborderingareaofWestBengal-IndiawithBangladesh.Duringtheinternationalconference"Arsenic in groundwater,cause, effect andremedy" held at Jadavpur University, Kolkata in February1995, the problem of Bangladesh was highlighted by SOES.Subsequently thepreliminary survey during 1995-1996 by SOES, jointly with the department ofGeology, University of Rajshahi and National Institute of Preventive and SocialMedicine(NIPSOM), Bangladesh,pointed outthearsenic contaminationofgroundwaterandresultantsufferingsofpeopleinBangladesh.Inthe meantime,representativesoftheDhakaCommunityHospital(DCH),Bangladesh, came to SOES in November 1996 and analyzed water, hair, nail,urine, and skin-scale samples of some victims from arsenic affected districts ofBangladesh. For a detail study, SOES, JadavpurUniversity,Kolkata carriedout a joint survey with the Dhaka Community Hospital Trust from December1996toJanuary1997 and found groundwater highly arsenic contaminatedandarsenicaldermallesionsamongthepeopleof14affecteddistrictsofBangladesh.
To avoid microbial andchemical contamination from surface water,groundwaterisbecoming themajor source of drinking waterroundthe world,especially inthedeveloping countries. Another reason forwideuseofgroundwateris its easy access and economic viability.Not only groundwaterisusedfor drinking,butalsoby thefarmersinmanydevelopingcountries like Bangladesh,India, andChina,groundwateristheirmainsourceof irrigation.Thesecountrieshavemadegreenrevolutionwiththe help ofundergroundwater.Earlier,India andBangladeshcould get only one crop a year and thattoowasrain dependent. Butnow usuallythreeto fourcropsinayeararecommon andthe source of water for irrigation lies underground (Fig. 1). InBangladeshandWestBengal-Indiairrigationusinggroundwaterwasfirst started in and around the sixties. Inboththesecountries, there is no groundwater withdrawal regulation;as a result, groundwater exploitation goesonunchecked. InBangladeshandWestBengal-Indiamore than 95% of theRuralWaterSupplySchemes(RWSS)dependonundergroundwater. Dhaka(population about 11 million, 2000) is theonly city intheworld where more than 95%ofthedomesticwaterrequirementcomesfromundergroundwaterschemes.
Figure 1: Using groundwater for irrigation
The incidents of arsenic contaminationin groundwater and sufferings of peoplefromchronicarsenic toxicityresulting fromthe drinking of the contaminatedwater.Aroundtheworldaredocumentednow.
There are approximately 21 counties in the world where cases of arsenic contamination of groundwater are known. Out of these, Bangladesh calamity is considered to be the largest in the world.
Materials and Methods
The materials and the methods were previously described 1-7.
Results and Discussion
The total population of Bangladesh is around 120 million (2000). In our study for over last 6 years in Bangladesh, we had analyzed till December 2000, 33,092 hand tube wells water samples, collected from all 64 dis-trictsand found arsenic in 60 districts above WHO recommended value in drinking water (10 µg/L) and in 50 districts above maximum permissible limit, 50 µg/L (Figs. 2 and 3). In these 50 districts the actual arsenic status is, 37% contains arsenic less than 10 µg/L, 63% and 42% contain arsenic above 10 µg/L and 50 µg/L, respectively (Fig. 5). Total population of these 50 districts is ~104.9 million. This does not mean all populations in the 50 districts are drinking arsenic contaminated water or suffering, but undoubtedly, they are at risk.
There are four principal geomorphological areas/regions in Bangladesh, (a) Hill Tract, (b) Table Land, (c) Flood Plain, and (d) Deltaic area including coastal belt. From my study, it appears that groundwater of Hill Tract and Table Land is almost free from arsenic contamination but that of Flood Plain and Deltaic area are highly arsenic contaminated (Figs. 2-4).
During our survey we had also collected hair, nail, skin scales (skin scale from those having keratosis), and urine samples from the people of these villages. Biological samples were collected from 40-50% of those having skin lesions and rests of the samples were from those without skin lesions. Parametric presentation of arsenic situation (from six years study) in Bangladesh is shown in Table 1.
During this survey, arsenic patients were identified in 222 villages of 69 police stations under 31 out of 33 districts.
Where survey was conducted (Fig. 6). The numbers of people we had examined, including children were 18,840 and 3,725 people were identified with arsenical skin lesions. Table 2 shows our overall findings among adults and children in different districts. Normally, there were 6-8 people in our team, including at least 2 medical personnel. But I feel the number of days we spent to survey in 34 districts were negligible compared to the number of days actually needed. In most of the cases we had superficially surveyed the villages without any in-depth study. Sometimes, due to time constrain we had to leave one village for the next village without recording patients. At present, we have information of about 74 more villages where people have arsenical skin lesions, but we could not visit those sites. From our experience of the last about 6 years from arsenic affected districts of Bangladesh we feel we have identified only a small
| Table 1: Parametric presentation of arsenic situation in Bangladesh | ||
| S. No. | Parameters | |
| 01 | Total No. of districts in Bangladesh | 64 |
| 02 | No. of district we have surveyed | 64 |
| 03 | No. of districts where arsenic in groundwater>10 µg/L | 60 |
| 04 | No. of districts where arsenic in groundwater >50 µg/L | 50 |
| 05 | No. of districts where we have surveyed for arsenic patients | 33 |
| 06 | No. of districts where we have identified for arsenic patients | 31 |
| 07 | No. of police stations surveyed for arsenic patients | 77 |
| 08 | No. of police stations where we have identified arsenic patients | 69 |
| 09 | No. of villages surveyed for arsenic patients | 253 |
| 10 | No. of villages where we have identified arsenic patients | 222 |
| 11 | Total No. of people examined for arsenic patients | 18,840 |
| 12 | No. of patients identified | 3,725 |
| 13 | Total No. of adult examined | 13,976 |
| 14 | No. of adult patients identified | 3,427 (24.52%) |
| 15 | Total No. of children examined | 4,864 |
| 16 | No. of children patients identified | 298 (6.13%) |
| 17 | Total No. of hair samples analyzed | 4,386 |
| 18 | % of hair samples content arsenic above toxic level | 83 |
| 19 | Total No. of nail samples analyzed | 4,321 |
| 20 | % of nail samples content arsenic above normal level | 94 |
| 21 | Total No. of urine samples analyzed | 1,084 |
| 22 | % of urine samples content arsenic above normal level | 95 |
| 23 | Total No. of skin scales samples analyzed | 705 |
| 24 | Arsenic concentration range in skin scales samples with mean value | 600 to 53,390 µg/kg (mean value 5,730 µg/ kg) |
percentage of the total number of people affected in the villages we had surveyed. In our study procedure, the expert group (medical personnel and others) sits in a camp in the affected village and villagers were informedto come to the camp for examination. Those who came to our camp were examined and registered in the format.
But discussing with villagers it appeared that 15-20% of the total number of people suffering from arsenicosis really came to the arsenic camp for examination.
Table 2: shows overall findings among adults and children in different districts.
| Name of the districts | Area in sq.km | No. of police stations (P.S.) | Population | No. of police stations surveyed | No. of police stations where patients identified | No. of villages surveyed | No. of villages where patients identified | No. of people examined | No. of patients identified | Adult male patients | Adult female patients | Child patients |
| Bagerhat | 3959 | 9 | 1611000 | 2 | 2 | 9 | 9 | 670 | 200 | 133 | 60 | 7 |
| Barisal | 2791 | 10 | 2481000 | 3 | 2 | 5 | 5 | 358 | 57 | 25 | 32 | - |
| Bogra | 2920 | 11 | 3053000 | 1 | I | I | 1 | 280 | 21 | 6 | 11 | 4 |
| Chuadanga | 1158 | 4 | 921000 | 1 | I | 7 | 3 | 219 | 119 | 53 | 48 | 18 |
| Chandapur | 1704 | 7 | 2309000 | 6 | 5 | 33 | 33 | 1605 | 157 | 98 | 55 | 4 |
| Camilla | 3089 | 12 | 4751000 | 4 | 4 | 6 | 6 | 509 | 68 | 32 | 29 | 7 |
| Faridpur | 2073 | 8 | 1678000 | 3 | 3 | 14 | 13 | 804 | 151 | 76 | 60 | 15 |
| Gopalganj | 1490 | 5 | 1169000 | 4 | 2 | 7 | 7 | 267 | 34 | 14 | 15 | 5 |
| Gazipur | 1741 | 5 | 1899000 | 1 | 1 | 1 | I | 92 | 7 | 5 | 2 | - |
| Jessore | 2567 | 8 | 2387000 | 5 | 4 | 9 | 9 | 1871 | 476 | 187 | 218 | 71 |
| Jhenaidaha | 1961 | 6 | 1540000 | 2 | 2 | 2 | 2 | 235 | 56 | 33 | 19 | 4 |
| Jamalpur | 2032 | 7 | 2111000 | 1 | 1 | 3 | 3 | 222 | 79 | 35 | 35 | 9 |
| Kushtia | 1621 | 6 | 1691000 | 3 | 3 | 15 | 15 | 891 | 240 | 108 | 94 | 38 |
| Khulna | 4395 | 14 | 2417000 | 2 | 2 | 5 | 5 | 684 | 105 | 60 | 36 | 9 |
| Name of the districts | Area in sq.km | No. of police stations(P.S.) | Population | No. of police stationssurveyed | No. of police stations werepatient identified | No. of villages surveyed | No. of villages where patients identified | No. of people examined | No. of patients identified | Adult male patients | Adult female patients | Child patients |
| Kishoreganj | 2689 | 13 | 2574000 | 1 | 1 | 3 | 3 | 307 | 18 | 14 | 4 | - |
| Lakshmipur | 1456 | 4 | 1502000 | 3 | 3 | 27 | 25 | 2283 | 521 | 314 | 191 | 16 |
| Meherpur | 716 | 2 | 555000 | 2 | 1 | 11 | 7 | 580 | 190 | 103 | 64 | 23 |
| Madaripur | 1145 | 4 | 1185000 | 3 | 3 | 11 | 9 | 1038 | 81 | 24 | 57 | 1 |
| Magura | 1049 | 4 | 815000 | 3 | 3 | 3 | 3 | 296 | 41 | 15 | 21 | 5 |
| Munshiganj | 955 | 6 | 1309000 | 1 | 1 | 2 | 2 | 27 | 5 | 1 | 4 | - |
| Mymensingh | 4363 | 12 | 4450000 | 1 | 1 | 8 | 1 | 46 | 3 | 2 | 1 | - |
| Manikganj | 1379 | 7 | 1293000 | 3 | 2 | 7 | 3 | 103 | 8 | 3 | 2 | 3 |
| Nawabganj | 1702 | 5 | 1346000 | 2 | 2 | 7 | 7 | 459 | 212 | 119 | 88 | 5 |
| Narsingdi | 1141 | 6 | 1864000 | 3 | 2 | 2 | 2 | 178 | 12 | 8 | 3 | 1 |
| Narayanganj | 759 | 5 | 2013000 | 1 | 1 | 11 | 8 | 602 | 93 | 46 | 44 | 3 |
| Noakhali | 3601 | 6 | 2547000 | 3 | 3 | 13 | 13 | 1246 | 216 | 86 | 120 | 10 |
| Pabna | 2371 | 9 | 2266000 | 5 | 5 | 19 | 16 | 1860 | 342 | 171 | 146 | 25 |
| Rajshahi | 2407 | 13 | 2255000 | 3 | 3 | 5 | 5 | 443 | 107 | 52 | 43 | 12 |
| Rajbari | 1119 | 4 | 941000 | 1 | 1 | 2 | 2 | 103 | 8 | 4 | 4 | - |
| Rangpur | 2308 | 8 | 2475000 | 1 | 1 | 2 | 1 | 297 | 38 | 25 | 10 | 3 |
| Satkhira | 3858 | 7 | 1780000 | 3 | 3 | 3 | 3 | 266 | 60 | 34 | 26 | - |
| TOTAL=31 | 66515 | 227 | 61188000 | 77 | 69 | 253 | 222 | 18840 | 3725 | 1885 | 1542 | 298 |
People suffering from arsenical dermal lesions have been identified in 31 out of33 districts where we had made a preliminary dermatological investigation with medical team. From a random of 18,840 examination people in arsenic affected villages where people were drinking arsenic contaminated water during last 6 years. We had registered 1,885 males, 1,542 females, and 298 children, having arsenical dermal lesions, such as: melanosis, leucomelanosis, keratosis, hyperkeratosis, dorsal, non-petting oedema, gangrene, cancer, etc. (Figs. 7-9). If children are included, then 19.77% (n=3,725) have arsenical dermal lesions and for separately adults and children these are 24.52% and 6.13%, respectively.
Figure 6: Map showing the districts in Bangladesh where arsenic patients identified
Figure 7: People suffering from arsenical dermal lesions (a few examples) have been identified in Bangladesh
Figure 8: People suffering from arsenical dermal lesions (a few examples) have been identified in Bangladesh
Figure 9: Distribution of arsenical skin lesions among the 3,725 patients in 31 districts of Bangladesh
| Parameter | Arsenic in hairs (µg/kg) | Arsenic in nail (µg/kg) | Arsenic in urine (µg/L) | Arsenic in skin scales (µg/kg) |
| No. of observation | 4386 | 4321 | 1084 | 705 |
| Mean | 3390 | 8570 | 280 | 5730 |
| Median | 2340 | 6400 | 116 | 4800 |
| Minimum | 280 | 260 | 24 | 600 |
| Maximum | 28060 | 79490 | 3086 | 53390 |
| Standard deviation | 3330 | 7630 | 410 | 9790 |
| % Of samples having arsenic above normal/toxic (hair) level | 83.15 | 93.77 | 95.I I | - |
We had identified people with arsenical manifestation such as dorsum, whole body melanosis (WBM), leucomelanosis (Leuco), diffuse keratosis on sole (DKS),spotted keratosis on sole (SKS),diffuse keratosis on palm (SKP),spotted keratosis on palm (SKP), diffuse melanosis on trunk (DMT), spotted melanosis on trunk (SMT), diffuse melanosis on palm (DMP), and spotted melanosis on palm (SMP). Buccal mucus membrane melanosis (MMM) on tongue, gums, lips, etc. also found. Rough dry skin often with palpable nodules (spotted keratosis) on dorsal of hand, feet, and legs are the symptoms seen in severe cases (Figs. 7-9).
Thousands of hairs, nail, and urine samples from the people of arsenic affected villages were collected and analyzed. Statistical presentation of arsenic in hairs, nail, urine (arsenic metabolites), and skin scale samples from the villagers of the arsenic affected villages of Bangladesh where we have found arsenic patients are presented in Table 3.
Table 3: Status of biological samples collected from the people of arsenic affected villages in Bangladesh were
we have found arsenic patients.
Normallevelofarsenicinhairrangesfrom80-250µg/Kg;1000µg/Kg istheindicationoftoxicity8
Normallevel of arsenicinnailrangesfrom 430 - 1080 µg/Kg9
Normal excretion of arsenic in urine ranges from 5 - 40 µg/day10
Thereisnonormalvalueforskinscaleinliterature
About 40-50% of these samples were from people having arsenical skin lesions and rest of the samples from non-patients but they were living in the arsenic affected villages. The analytical report shows that 95.11%, 83.15%, and 93.77% of the samples we had analyzed have arsenic in urine, hair, and nail above normal/ toxic level (hair), respectively. During our dermatological survey in the affected villages, we have observed that out of 5 people drinking the same arsenic contaminated water, 2 may not show arsenical skin lesions, but their hair, nail, and urine contain high level of arsenic like other members. Thus, many of the villagers may not have arsenical skin lesions, but they are sub-clinically affected. However, we do not expect such elevated level of arsenic in biological samples from all villagers. The probable reason for such elevated levels of arsenic in hair, nail, and urine is that we have collected these samples from those villagers where arsenic patients exist and many tube wells are highly contaminated. The picture may be different in areaswhere groundwater is not much contaminated. The overall results from 50 districts show that 37% of the tube wells are safe to drink, according to the WHO recommended value (10 µg/L). Therefore, about 37% of the people should not show an elevated level of arsenic in the biological samples. A study was carried out by our group in 199811 to understand why body burden is higher among those using safe water for drinking and cooking, while living in arsenic affected villages. In this study, safe water from a source having less than 3 µg/L arsenic was supplied for 2 years to 5 affected families to study the loss of arsenic through urine, hair, and nail. The study finally showed that despite having safe water for drinking and cooking, the study group could not avoid an intake of arsenic from contaminated food, food materials contaminated by washing, and the occasional drinking of arsenic contaminated water7. Arsenic in groundwater and in hair, nail, and urine of the controlled population is presented in Table 4. From our study we have observed that arsenic in hair, nail, and urine increases with increasing arsenic in drinking water. Figures 10- 12 show our findings. It appears that correlations are not strong positive [for hair samples r = 0.251, p = 0.01, n = 739; for nail samples r = 0.220, p = 0.01, n = 691; and for urine r = 0.547, p = 0.01, n = 910]. Probable reason people are not drinking from the same source all the times. Our field data indicates that most of the villagers drink water from more than one tube wells.
Table 4: Parametric presentation of arsenic in hair, nail, and urine of control population of Patiya police station of Chittagong district, Bangladesh where arsenic in groundwater was below 3 µg/L
| Parameters | Arsenic in hair (µg/kg) | Arsenic in nail µg/kg) | Arsenic in Urine (µg/L) |
| No. of observation | 62 | 62 | 62 |
| Mean | 410 | 830 | 31 |
| Minimum | 210 | 90 | 6 |
| Maximum | 850 | 1580 | 94 |
| Standard deviation | 180 | 680 | 20 |
| Figure 10: Correlation between arsenic in water and hair | Figure 11: Correlation between arsenic in water and nail | Figure 12: Correlation between arsenic in water and urine |
From multi-elements analysis of some hair and nail samples it appears that Zn and Se concentration decreases with increasing arsenic concentration in both hair and nail. The concentration of Zn and Se also less in affected people's hair and nail than control hair and nail (drinking water contain arsenic <3 µg/L). But the linear regression shows positive correlation between As & Pb, As & Hg, and As & Sb in both hair and nail of exposed population.
Our last 6 years of field experience in Bangladesh show that normally children under 11 years of age do not show arsenical dermal lesions. But we have observed few exceptions when (a) the arsenic content in water consumed by children is very high (1000 µg/L) and (b) the arsenic content is not very high (500 µg/L) but the children get poor nutrition.
In Bangladesh and West Bengal-India more and more underground water is being extracted because of increasing demand for agricultural irrigation. It was calculated that in arsenic affected areas of Bangladesh and West Bengal-India a few thousand tons of arsenic (through underground water) is falling on agricultural land every year and it is important to know whether there is an increase concentration of arsenic in vegetable and crops that grow in this region. It appears from in our preliminary selected agricultural fields (n = 10) that average arsenic concentration in contaminated soil, rice, and vegetable are 3.81, 4 and 3.8 times higher than control samples (from non-contaminated area), respectively2. Our rice and vegetable analysis of arsenic species show 95% and 5% are inorganic arsenic and organic arsenic in rice, and 96% and 4% of inorganic arsenic and organic arsenic in vegetable, respectively. Bangladesh known as land of rivers. We finally, Bangladesh and West Bengal have huge available surface water, rainwater resources and to combat the arsenic crisis we need better watershed management.
Conclusion
According to our survey, the present arsenic (2000) situation in Bangladesh is 2000 villages in 50 out of 64 total districts groundwater contains arsenic above 50 µg/L. In a report [Pearce, F. Arsenic in the water. The Guardian (UK), 19/25 February 1998; 2-3], World Bank's local chief stated that tens of millions of people are at health risk and that 43,000 villages of total 68,000 in Bangladesh are presently at risk or could be at risk in future. In the same report, the World Health Organization (WHO) predicted that within a few years death across much southern part of Bangladesh, one in ten adults could be from cancers triggered by arsenic. Out of 21 countries in different parts of the world where groundwater arsenic contamination and suffering of people have been so far reported, the magnitude is considered highest in Bangladesh. Even after working for last 6 years in Bangladesh with School of Environmental Studies (SOES) and Dhaka Community Hospital (DCH), I feel that I have seen only the tip of the iceberg. So, for there is no medicine for chronic arsenic toxicity and millions are drinking arsenic contaminated water in Bangladesh. If scientific community and medical people all over the world will not immediately come forward to combat the arsenic problem in Bangladesh, the situation will be worse.
To eliminate arsenic crisis, I suggest the followings:
Elimination of the arsenic crisis in the Ganges Basin requires concerted action that includes:
A moratorium on the installation of more tube wells in contaminated areas until all the installed tube wells are checked for arsenic contamination. The local and national governments should frame and implement regulation of new tube wells. Around 90% of the people in Bangladesh and West Bengal, India depends on tube wells for drinking water. If the mouths of all safe tube wells are colored green, and while unsafe wells are colored red, villagers can use green tube wells for drinking and cooking purposes, and the red tube wells be closed completely. We have disturbing evidence from West Bengal, India that previously safe tube wells now show arsenic contamination. The currently safe tube wells require monitoring every 3-6 months to track this new development.
Proper watershed management.
Traditional water management like dug-well, three-Kalsi system, and rainwater harvesting with controls of bacterial and other chemical contamination.
Immediate action be taken for developing water filtration units for removing arsenic.
Public awareness of the arsenic calamity and assurance that it is not a curse of God.
Recognition that, so far, there is no effective therapy. Safe water and optimal nutrition are the only proven measures.
Investigation of the possible benefits of essential elements as we have reported for selenium. Hepatic selenium is abnormally low in patients with increased arsenic, the reverse of the normal association.
The potential benefits of selenium supplements require investigation.
A world-wide effort by the scientific community addressing the problem that has put 100 million people in Bangladesh and West Bengal-India at risk for cancer, vascular disease, and other complications.
Although tube wells provide drinking water free of microbial contamination, the merciless exploitation of groundwater for irrigation without effective watershed management to harness huge surface water resources and rainwater is seen as a gross miscalculation. In Bangladesh and West Bengal-India, there are huge surface resources of sweet water in the rivers, wetlands, flooded river basins, and ox-bow lakes. Per capita available surface water in Bangladesh is about 11,000 cubic meters. These 2 delta areas, known as the land of rivers, have approximately 2,000 mm annual rainfall. Watershed management and villager participation are needed to assure the appropriate utilization of these huge water resources.
The massive extraction of groundwater for irrigation has so altered the aquifer beneath Bangladesh and West Bengal-India that even deep tube wells are now unsafe in many arsenic-contaminated areas. Analysis of samples from almost all 374 deep (>100 m) tube-wells from Deganga block of North 24 Paraganas, West Bengal, India shows 13.9% with arsenic >50µg/L. Water held in deep aquifers takes decades, even centuries, to accumulate and is inadequately replenished by rainfall. Rapid depletion may result in a deleterious influx from the arsenic contaminated strata. The current intensive efforts to provide deeper tube wells may be counterproductive if the deep aquifer is simultaneously depleted by irrigation.
I want to dedicate this paper to the memory of the people who died or affected due to arsenic toxicity in Bangladesh, India, and all over the world.
Much of the fieldwork was carried out with the help of School of Environmental Studies (SOES), Jadavpur University, Kolkata, India and that of Dhaka Community Hospital (DCH), Dhaka, Bangladesh. I am grateful to the management of the Dhaka Community Hospital, and thankful to all the members of SOES and DCH for their moral support.
I also would like to thank to the Chairman of the Jawaharlal Nehru Memorial Fund, Teen Murti House, New Delhi, India for the financial assistance throughout my Ph.D. research work.
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