Reproductive outcomes in an area adjacent to a petrochemical plant in southern Brazil

Oliveira, Lenice Minussi; Stein, Nina; Sanseverino, Maria Teresa Vieira; Vargas, Vera Maria Ferrão; Fachel, Jandyra Maria Guimarães; Schüler, Lavínia

doi:10.1590/S0034-89102002000100013

Abstracts

OBJECTIVE: To evaluate possible adverse reproductive outcomes in an area adjacent to a petrochemical plant in southern Brazil. METHODS: A review of 17,113 birth records of the main hospital of the municipality of Montenegro, southern Brazil, from 1983 to 1998 was carried out. Three groups of cases were selected: (1) newborns with major congenital malformations; (2) newborns with low birth weight (<2,500 g); and (3) stillborns (>500 g). A control was assigned to each case. Controls were the first newborns weighing > or = 2,500 g without malformations and of case-matching sex. Mother's residence during pregnancy was used as an exposure parameter. Statistical analyses were performed using Chi-square test or Fisher test, odds ratio, 0.05 significance level, and 95% confidence interval. RESULTS: For unadjusted analysis, it was found a correlation between low birth weight and geographical proximity of mother's residence to the petrochemical plant (OR = 1.66; 95% CI = 1.01--2.72) or residence on the way of preferential wind direction (OR = 1.62; 95% CI = 1.03--2.56). When other covariates were added in the conditional logistic regression (maternal smoking habits, chronic disease and age), there was no association. CONCLUSIONS: Despite final results were negative, low birth weight could be a good parameter of environmental contamination and should be closely monitored in the studied area.

Petroleum industry; Environmental exposure; Infant, newborn; Impacts on health; Risk Factors; Infant, low birth weight; Case-control studies

OBJETIVO: Avaliar os possíveis riscos reprodutivos em uma região próxima a pólo petroquímico situado no Rio Grande do Sul. MÉTODOS: Foram analisados 17.113 registros de nascimentos ocorridos no principal hospital da região, localizado no município de Montenegro, RS, desde 1983 até 1998. Foram selecionados três diferentes grupos de casos: (1) recém-nascidos portadores de malformações congênitas maiores; (2) recém-nascidos com baixo peso ao nascer (<2.500 g); e (3) natimortos (>500 g). Para cada caso, foi atribuído um controle específico, que foi a primeira criança nascida viva, pesando 2.500 g ou mais, com ausência de malformações e tendo o mesmo sexo que o caso em questão. A residência materna durante a gravidez foi utilizada como um parâmetro para exposição. Para a análise estatística, foram usados os testes qui-quadrado ou Fisher, "odds ratio", nível de significância de 0,05 e intervalo de confiança de 95%. RESULTADOS: Foi encontrada correlação positiva para baixo peso ao nascer e para proximidade geográfica da residência materna ao Pólo Petroquímico ["odds ratio" (OR) = 1,66; 95% confidence interval (CI) = 1,01-2,72] ou residência na direção preferencial do vento ["odds ratio" (OR) = 1,62; 95% confidence interval (CI) = 1,03-2,56]. Quando outras variáveis foram incluídas na análise de regressão logística condicional (fumo, doenças crônicas e idade materna), essa associação desapareceu. CONCLUSÕES: Apesar de os resultados finais terem sido negativos, o baixo peso ao nascer pode ser um bom parâmetro para medir a contaminação ambiental, mas deve ser monitorado na região estudada.

Indústria petroquímica; Exposição ambiental; Recém-nascido; Impactos na saúde.; Fatores de risco; Recém-nascido de baixo peso; Estudos de casos e controles.

Reproductive outcomes in an area adjacent to a petrochemical plant in southern Brazil

Riscos reprodutivos em região próxima ao pólo petroquímico de Triunfo no Sul do Brasil

Lenice Minussi Oliveira^a, Nina Stein^b, Maria Teresa Vieira Sanseverino^b, Vera Maria Ferrão Vargas^a, Jandyra Maria Guimarães Fachel^d and Lavínia Schüler^a

^aDepartamento de Genética da Universidade Federal do Rio Grande do Sul. Porto Alegre, RS, Brasil. ^bSistema de Informação sobre Agentes Teratogênicos do Hospital de Clínicas. Porto Alegre, RS, Brasil. ^cFundação Estadual de Proteção Ambiental. Porto Alegre, RS, Brasil. ^dDepartamento de Estatística da Universidade Federal do Rio Grande do Sul. Porto Alegre, RS, Brasil

KEYWORDS

Petroleum industry.^# Environmental exposure.^# Infant, newborn.^# Impacts on health.^# Risk Factors. Infant, low birth weight. Case-control studies.

ABSTRACT

OBJECTIVE:

To evaluate possible adverse reproductive outcomes in an area adjacent to a petrochemical plant in southern Brazil.

METHODS:

A review of 17,113 birth records of the main hospital of the municipality of Montenegro, southern Brazil, from 1983 to 1998 was carried out. Three groups of cases were selected: (1) newborns with major congenital malformations; (2) newborns with low birth weight (<2,500 g); and (3) stillborns (>500 g). A control was assigned to each case. Controls were the first newborns weighing ³2,500 g without malformations and of case-matching sex. Mother's residence during pregnancy was used as an exposure parameter. Statistical analyses were performed using Chi-square test or Fisher test, odds ratio, 0.05 significance level, and 95% confidence interval.

RESULTS:

For unadjusted analysis, it was found a correlation between low birth weight and geographical proximity of mother's residence to the petrochemical plant (OR = 1.66; 95% CI = 1.01¾2.72) or residence on the way of preferential wind direction (OR = 1.62; 95% CI = 1.03¾2.56). When other covariates were added in the conditional logistic regression (maternal smoking habits, chronic disease and age), there was no association.

CONCLUSIONS:

Despite final results were negative, low birth weight could be a good parameter of environmental contamination and should be closely monitored in the studied area.

DESCRITORES

Indústria petroquímica.^# Exposição ambiental.^# Recém-nascido.^# Impactos na saúde.^# Fatores de risco. Recém-nascido de baixo peso. Estudos de casos e controles.

RESUMO

OBJETIVO:

Avaliar os possíveis riscos reprodutivos em uma região próxima a pólo petroquímico situado no Rio Grande do Sul.

MÉTODOS:

Foram analisados 17.113 registros de nascimentos ocorridos no principal hospital da região, localizado no município de Montenegro, RS, desde 1983 até 1998. Foram selecionados três diferentes grupos de casos: (1) recém-nascidos portadores de malformações congênitas maiores; (2) recém-nascidos com baixo peso ao nascer (<2.500 g); e (3) natimortos (>500 g). Para cada caso, foi atribuído um controle específico, que foi a primeira criança nascida viva, pesando 2.500 g ou mais, com ausência de malformações e tendo o mesmo sexo que o caso em questão. A residência materna durante a gravidez foi utilizada como um parâmetro para exposição. Para a análise estatística, foram usados os testes qui-quadrado ou Fisher, "odds ratio", nível de significância de 0,05 e intervalo de confiança de 95%.

RESULTADOS:

Foi encontrada correlação positiva para baixo peso ao nascer e para proximidade geográfica da residência materna ao Pólo Petroquímico ["odds ratio" (OR) = 1,66; 95% confidence interval (CI) = 1,01-2,72] ou residência na direção preferencial do vento ["odds ratio" (OR) = 1,62; 95% confidence interval (CI) = 1,03-2,56]. Quando outras variáveis foram incluídas na análise de regressão logística condicional (fumo, doenças crônicas e idade materna), essa associação desapareceu.

CONCLUSÕES:

Apesar de os resultados finais terem sido negativos, o baixo peso ao nascer pode ser um bom parâmetro para medir a contaminação ambiental, mas deve ser monitorado na região estudada.

INTRODUCTION

Thirty percent of petrochemical production in Brazil are generated by the Southern Petrochemical Complex (Complexo Petroquímico do Sul ¾ COPESUL). In 1997, 1.9 million of tons of raw petrochemical material was produced including hydrocarbons and volatile organic compounds (VOCs)^* * http://www.copesul.com.br - Avaitable in 2000. such as ethene, butadiene among others. In 1999 the plant was expanded and its production has increased to 3.0 million of tons per year.

Montenegro and Triunfo are two municipalities located in the southern state of Rio Grande do Sul, adjacent to a large petrochemical plant. Montenegro has an area of 467 km², population of approximately 49,000 inhabitants29,000 living in urban areas and 20,000 in rural areas. Triunfo has an area of 834 km² and only 13,000 inhabitants, half of them living in rural areas.

The Southern Petrochemical Complex was settled in 1982. It is located approximately 15 km from Montenegro's urban center and 30 km from Triunfo's urban area and 50 km from Porto Alegre, the state capital. It is also situated by one of the affluent rivers of Guaíba hydrographic basin, the largest water net in Rio Grande do Sul, where specific programs for pollution control are in place.

The Fundação Estadual de Proteção Ambiental ¾ FEPAM (State Institute for Environmental Preservation) has developed specific programs to evaluate possible ecotoxicity in the area near the petrochemical plant since 1983, and potential genotoxic substances have been identified.²¹ Hence, a case-control study was conducted in the area to evaluate whether there is a relationship between adverse reproductive outcomes and mother's place of residence. Low birth weight newborns, stillborns and newborns with major malformations were selected as outcomes for analysis.

METHODS

A case-control study was carried out and all birth records registered from 1983 to 1998 in the main hospital of the area, located in the municipality of Montenegro, were reviewed. This is a referral hospital for the Latin America Collaborative Study on Congenital Malformations (Estudo Colaborativo Latino-Americano de Malformações Congênitas ¾ ECLAMC). Three groups of cases were selected: (1) newborns with major congenital malformations; (2) newborns with low birth weight (<2,500 g); and (3) stillborns (>500 g). A control was assigned to each case. Controls were the first newborns weighing ³2,500 g without malformations and of case-matching sex.

All medical records were reviewed to collect mother's demographic data and clinical description of the newborns. Demographic characteristics were compared to available ECLAMC from six other regions with similar economic and cultural characteristics. For congenital malformations analysis all newborns with at least one major malformation diagnosed during hospital stay were initially included. Then, only newborns with one of 15 birth defects routinely monitored by ECLAMC were selected, i.e., the ones of easy clinical diagnosis and thus subjected to less ascertainment bias. These birth defects categories included cases with both isolated malformations and multiple anomalies. Expected values of birth prevalence rate of congenital anomalies were obtained from the ECLAMC data during the 1982¾1995 period. These data came from a sample of 2,595,064 births studied in 59 hospitals of eight Latin American countries.

Exposure categories were created for each birth based on geographical distance of mother's residence from the petrochemical plant at the time of birth. Three regions were arbitrarily defined according to the plan proximity: Region 1the nearest, in a perimeter of approximately 10 km from the plant; Region 2, intermediate, distant 10 to 20 km from the plant and including the municipality of Montenegro; and Region 3, reference or unexposed area, extending beyond 30 km from the plant (Figure A). The regions were further subdivided according to the prevailing wind direction in Region A (prevailing wind tunnel); Region B (lateral to A) and Region C, the same as Region 3, unexposed region (Figure B). Cases and controls were compared according to mother's residence during pregnancy in the three regions , having as reference Region 3 and C, respectively.

Initially crude comparisons between cases and controls were performed for the following maternal variables: residence, age, chronic diseases, smoking, previous abortions, parity and gestational age, using Chi-square test or Fisher test when expected values were less than 5. Odds ratio were calculated using significance level of 0.05 and confidence interval of 95%. Conditional regression analysis was then performed for mother's residence including the most significant variables: smoking, maternal age, and chronic diseases. All analyses were performed using SPSS version 8.0.

RESULTS

In these 15 years of study, 17,113 births were registered in the Montenegro hospital. Hospital records were complete for 90% of all newborns with low birth weight (n=990), 85% of stillborns (n=230) and 85% of malformed newborns (n=160). This represents 70% of all expected births for this region during the study period (Table 1). Fetal death mortality rate was 1.7% and low birth weight was seen in 6.8% of all livebirths. These frequencies are not different from that observed in the ECLAMC for six other Brazilian hospitals located in economically and developmentally similar regions.

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The observed and expected frequencies for the selected 15 congenital malformations are shown in Table 2. Lower than expected rates were observed for anencephaly, Down syndrome and nonsyndromal multiple congenital anomalies patterns (two or more apparently unrelated defects). There was no temporal variation for these congenital malformations. When the defects were plotted in the region map no cluster for any anomaly was seen.

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Table 3 presents crude comparisons between cases and controls of mother's residence and potential risk factors. More than expected cases of low-birth weight were observed for maternal residence during pregnancy in Region 1 (adjacent to the petrochemical plant) (OR=1.66; 95% CI = 1.01-2.72) and Region A (preferential wind direction) (OR=1.62; 95%CI = 1.03¾2.56). Though observed odds ratios were still higher in Region 2 than in Region 3, they were not statistically significant. The same was observed for Region B when compared to Region C. Positive associations were also seen for other risk factors: maternal age, chronic disease, and smoking.

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For stillbirths, statistically significant odds ratios were observed for advanced maternal age and chronic diseases. A lower than expected proportion of mothers of cases, compared to mothers of controls, lived in Region 2 (Region 3 used as reference). For malformed infants, the odds ratio were significantly higher for advanced maternal age.

When all risk factors were analyzed together using conditional regression analysis (Table 4 and 5), geographic impact for low birth weight didn't show any statistical significance. Maternal age (young), smoking and chronic diseases were still significant. For stillbirths, a lower than expected proportion of mothers of cases living in Region 2 and B was still significant. Chronic diseases and advanced maternal age are important risk factors. For malformed infants, advanced maternal age was the only risk factor identified.

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DISCUSSION

In the present case-control study, in the unadjusted analysis, it was found an association between low-birth weight and maternal residence during pregnancy in the vicinity of the petrochemical plant as well as having residence in the region of preferential wind direction. However there was no association when other potential risk factors were included in the analysis. Smoking is one of the best known risk factors for low birth weight. Chronic disease and young maternal age are also reasonable explanation for this outcome.⁶Uneven distribution of these confounders in the study regions could explain the fact that no association between low birth weight and mother's residence was seen in the conditional logistic regression. Advanced maternal age is well recognized as a risk factor for malformation and stillbirth and chronic disease is a known risk factor for stillbirths.⁶Other potential risk factors such as alcohol consumption, parental occupation and parental socioeconomic status were not studied because they were not available in the medical records.

It was found a lower than expected proportion of mothers of cases with residence in Region 2 than controls, compared to Region 3. A possible explanation is that Montenegro, the main city of the study area, is located in Region 2 and has a better healthcare system including a better equipped hospital, which could contribute to reduce stillbirth rates.

There was no deviation from the expected for most selected malformations. Lower than expected frequencies were observed for newborns with Down syndrome, anencephaly and nonsyndromal multiple congenital anomalies patterns. Underreporting in this hospital could have contributed to this observation. Exposure misclassification is a potential weakness of the present study and it is a common problem in most environmental epidemiological studies. The actual maternal exposure during pregnancy to chemicals from the petrochemical plant is not known. Geographic regions were arbitrarily defined based on their proximity and wind direction, surrogate measures for potential exposures. FEPAM is currently conducting studies to identify presence of volatile organic compounds in the air and water. It is possible that the petrochemical plant's pollution control measures are effective enough to avoid exposing the neighboring population to dangerous pollutants. Other studies on human health effects (cancer, lung diseases) are also being conducted by FEPAM in this area.

The sample size is another potential limitation of the study, especially to what concerns congenital malformations and stillbirths, seen in lower numbers. For example, for stillbirths in the unadjusted analysis (sample size = 287; 3.1% of controls born to mothers living in Region 1 and 5.6% in Region A), there is an 80% power with 95% confidence interval to detect an OR of approximately 3.0 for geographic proximity (Region 1) and an OR of 2.5 for wind direction (Region A). The same calculation for malformed infants (sample size = 188; 4.4% of controls born to mothers living in Region 1 and 3.7% in Region A) would permit to detect an OR of 3.5 for geographic proximity (Region 1) and an OR of 3.8 for wind direction (Region A).

Several studies have already demonstrated an association between potential environmental contamination and low-birth weight. In one study a statistically significant excess of low birth weight was found among white live-born infants in the Love Canal neighborhood, a disposal site for various chemicals.¹⁰In studies of drinking water contaminated with trialomethane and carbon tetrachloride⁵, exposed mothers gave birth to a higher proportion of small for gestational age newborns than unexposed mothers. In a study conducted in Sweden, a decline in average birth weight in a community potentially exposed to arsenic was found.¹⁷ A study of water pollution caused by benzene in a Michigan area showed an association with low birth weight.²²Another study examined the relationship between birth weight and mother's residence near a hazardous waste landfill in Lipari, New Jersey. A significant reduction in birth weight in the population living in an area immediately adjacent to the landfill was observed.⁴

However, there are also negative studies. A case controlled study from Denver did not show any association between higher neighborhood carbon monoxide levels and higher odds of low birth weight.¹ Investigations of communities living near a lead smelter,¹⁴dioxin-contaminated soil²⁰and a toxic waste landfill did not find significant declines in the average birth weight infants or elevated prevalence of low birth weight infants.¹² Two studies in communities exposed to environmental industrial pollution (New York and San Francisco Bay area, respectively) also failed to correlate with low birth weights.^3,19

Birth defects are outcomes frequently investigated for environmental contamination. For organic solvents, there are studies showing association of contamination of public drinking water with neural tube defects, major cardiac malformations, oral clefts, and central nervous system defects.^5,13 In South America, the ECLAMC⁷ analyzed the association between industrial activity and occurrence of 34 congenital anomalies in 21 counties in Argentina during the 1982¾1994 period. Significant associations (p<0.01) between textile industry and anencephaly, and between engine manufactures and microcephaly were found. Most of the studies, however, show negative associations between environment and birth defects.¹⁶

In one study on potential contamination caused by petrochemical plants, it was observed⁸ that most children with orofacial defects in Pourt Harcout came from regions of high number of petrochemical refineries. A relationship between contamination from petrochemical industries and adverse pregnancy outcomes was not observed in Stegnungsum, Sweden,² a locality close to 5 petrochemical industries.

There were fewer studies associating stillbirths and environmental contamination. One study found a negative association between PCB-contaminated fish consumption and spontaneous fetal death.¹⁵Positive association was seen between spontaneous abortions when analyzed in an industrialized Finnish community according to the occupation and workplace of both women and their husbands.¹¹ An epidemiological study was conducted to investigate adverse outcomes of pregnancies among women who resided in a census tract are in Santa Clara county, California, that was thought to be exposed to drinking water from a well contaminated with organic solvent trichloroethane. Spontaneous abortion rate was more than twice higher than that observed in a comparable control community, and the difference persisted when rates were adjusted for maternal risk factors.⁹

Spontaneous abortion is frequently linked to environment chemical contamination.¹⁸ In the present study, however, spontaneous abortions could not be ascertained. First because this information was not available in the Montenegro hospital registries. Second, abortion is illegal in Brazil and induced abortion is often misreported as spontaneous abortion for the mother's legal safeguard.

In Brazil, there are few specific studies designed to investigate reproductive effects of environmental contamination. In the highly polluted town of Cubatão, a cluster of anencephaly was suspected. After prospectively surveying 10,000 births, no increase in major malformations was possible to attribute to environmental conditions.¹⁶

In conclusion, the 15-year birth data analysis of congenital malformations, low birth weight and stillbirths in the municipalities of Montenegro and Triunfo did not reveal the presence of a major environmental hazard in the study area. However, low birth weight could be a useful parameter for evaluating possible environmental contamination and should be closely monitored in the area. Further analysis of the actual population exposure could help interpreting the data collected in the study.

AKNOWLEDGMENTS

To Eduardo Castilla da Fundação Oswaldo Cruz for his comments and help providing ECLAMC data.

Correspondence to:

Lavínia Schüler

Departamento de Genética

Universidade Federal do Rio Grande do Sul

Ag. Agronomia Caixa Postal 15053

91501-970 Porto Alegre, RS, Brasil

E-mail: lavinia.faccini@ufrgs.br

Part of the thesis (master's degree) presented to the Universidade Federal do Rio Grande do Sul, Porto Alegre, 2000.

Partially supported by Financiadora de Estudos e Projetos (FINEP - Process nº 7797116100).

Received on 16/7/2001. Approved on 26/11/2001.

1. Alderman BW, Baron AE, Savitz DA. Maternal exposure to neighborhood carbon monoxide and risk of low infant birth weight. Publ Health Rep 1987;102:410-4.
2. Axelsson G, Molin Y. Outcome of pregnancy among woman living near petrochemical industries in Sweden. Int J Epidemiol 1988;17:363-9.
3. Bell BP, Franks P, Hildreth N, Melius J. Methylene chloride exposure and birthweight in Monroe County, New York. Environ Res 1991;55:31-9.
4. Berry M, Bove F. Birth weight reduction associated with residence near a hazardous waste landfill. Environ Health Perspec 1997;105:856-61.
5. Bove FJ, Fulcomer MC, Klotz JB, Esmart J, Dufficy EM, Savrin JE. Public drinking water contamination and birth outcomes. Am J Epidemiol 1995;141:850-62.
6. Castilla EE, Lopez-Camelo JS, Paz JE, Orioli IM. Prevención primaria de los defectos congénitos Rio de Janeiro: FIOCRUZ; 1996.
7. Castilla EE, Campanã H, Lopez-Camelo JS. Economical activity and congenital abnomalities: an ecological study in Argentina. Environ Health Perspec 2000;108:193-7.
8. Datubo-Brow DD, Kejeh BM. Congenital cleft deformities in rivers state of Nigeria: is there any association with environmental pollution? J R Coll Surg Edinb 1989;34:329-31.
9. Deane M, Swan SH, Harris JA, Epstein DM, Neutra RR. Adverse pregnancy outcomes in relation to water contamination, Santa Clara County, California, 1980-1981. Am J Epidemiol 1989;129:894-904.
10. Faris PL, Mclaughlin CL, Baile CA, Olney JW. Incidence of low birth weight among Love Canal residents. Science 1984;226:1217-9.
11. Hemmink K, Kyyronën P, Niemi ML, Koskinen K, Sallmén M, Vainio H. Spontaneous abortions in a industrialized community in Finland. Am J Public Health 1982;73:32-7.
12. Hertzman C, Hayes M, Singer J, Highland J. Upper Ottawa street landfill site health study. Environ Health Perspect 1987;75:173-95.
13. Holmberg PC. Central nervous system defects in children born to mothers exposed to organic solvents during pregnancy. Lancet 1979;2:177.
14. Loiacono NJ, Graziano JH, Kline JK, Popovac D, Ahmedi X, Gashi E, et al. Placental cadmium and birthweight in women living near a lead smelter. Arch Environ Health 1992;47:250-5.
15. Mendola P, Buck GM, Vena JE, Zielezny M, Sever LE. Consumption of PCB-contaminated sport fish and risk of spontaneous fetal death. Environ Health Perspect 1995;103:498-501.
16. Monteleone Neto R, Castilla EE. Apparently normal frequency of congenital abnormalities in the highly polluted town of Cubatão, Brazil. Am J Med Genet 1994;52:319-23.
17. Nordstrom S, Berckman L, Nordstrom I. Occupational and environmental risks in an around a smelter in northern Sweden. I. Variations in birth weight. Hereditas 1978;88:43-6.
18. Pernoll ML. Abortion induced by chemicals encountered in the environment. Clin Obstet Gynecol 1986;29:953-8.
19. Shaw GM, Schulman J, Frisch JD, Cummins SK, Harris JA. Congenital malformations and birthweight in areas with potential environmental contamination. Arch Environ Health 1992;47:147-54.
20. Stockbauer JW, Hoffman RE, Cchramm WF, Edmonds LD. Reproductive outcomes of mothers with potential exposure to 2,3,7,8-tetrachlorodibenzo-p-dioxin. Am J Epidemiol 1988;128:410-9.
21. Vargas VMF, Guidobono RR, Jordão C, Henriques JAP. Use of two short-term tests to evaluate the genotoxicity of river water treated with different concentration/extraction procedures. Mutation Res 1995;343:31-52.
22. Witkowski KM, Johnson NE. Organic-solvent water pollution and low birth weight in Michigan. Soc Biol 1992;39:45-54.

*

http://www.copesul.com.br - Avaitable in 2000.

Publication Dates

Publication in this collection
12 Mar 2002
Date of issue
Feb 2002

History

Received
16 July 2001
Accepted
26 Nov 2001

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Alderman BW, Baron AE, Savitz DA. Maternal exposure to neighborhood carbon monoxide and risk of low infant birth weight. Publ Health Rep 1987;102:410-4.

[2] 2. Axelsson G, Molin Y. Outcome of pregnancy among woman living near petrochemical industries in Sweden. Int J Epidemiol 1988;17:363-9.

[3] 3. Bell BP, Franks P, Hildreth N, Melius J. Methylene chloride exposure and birthweight in Monroe County, New York. Environ Res 1991;55:31-9.

[4] 4. Berry M, Bove F. Birth weight reduction associated with residence near a hazardous waste landfill. Environ Health Perspec 1997;105:856-61.

[5] 5. Bove FJ, Fulcomer MC, Klotz JB, Esmart J, Dufficy EM, Savrin JE. Public drinking water contamination and birth outcomes. Am J Epidemiol 1995;141:850-62.

[6] 6. Castilla EE, Lopez-Camelo JS, Paz JE, Orioli IM. Prevención primaria de los defectos congénitos Rio de Janeiro: FIOCRUZ; 1996.

[7] 7. Castilla EE, Campanã H, Lopez-Camelo JS. Economical activity and congenital abnomalities: an ecological study in Argentina. Environ Health Perspec 2000;108:193-7.

[8] 8. Datubo-Brow DD, Kejeh BM. Congenital cleft deformities in rivers state of Nigeria: is there any association with environmental pollution? J R Coll Surg Edinb 1989;34:329-31.

[9] 9. Deane M, Swan SH, Harris JA, Epstein DM, Neutra RR. Adverse pregnancy outcomes in relation to water contamination, Santa Clara County, California, 1980-1981. Am J Epidemiol 1989;129:894-904.

[10] 10. Faris PL, Mclaughlin CL, Baile CA, Olney JW. Incidence of low birth weight among Love Canal residents. Science 1984;226:1217-9.

[11] 11. Hemmink K, Kyyronën P, Niemi ML, Koskinen K, Sallmén M, Vainio H. Spontaneous abortions in a industrialized community in Finland. Am J Public Health 1982;73:32-7.

[12] 12. Hertzman C, Hayes M, Singer J, Highland J. Upper Ottawa street landfill site health study. Environ Health Perspect 1987;75:173-95.

[13] 13. Holmberg PC. Central nervous system defects in children born to mothers exposed to organic solvents during pregnancy. Lancet 1979;2:177.

[14] 14. Loiacono NJ, Graziano JH, Kline JK, Popovac D, Ahmedi X, Gashi E, et al. Placental cadmium and birthweight in women living near a lead smelter. Arch Environ Health 1992;47:250-5.

[15] 15. Mendola P, Buck GM, Vena JE, Zielezny M, Sever LE. Consumption of PCB-contaminated sport fish and risk of spontaneous fetal death. Environ Health Perspect 1995;103:498-501.

[16] 16. Monteleone Neto R, Castilla EE. Apparently normal frequency of congenital abnormalities in the highly polluted town of Cubatão, Brazil. Am J Med Genet 1994;52:319-23.

[17] 17. Nordstrom S, Berckman L, Nordstrom I. Occupational and environmental risks in an around a smelter in northern Sweden. I. Variations in birth weight. Hereditas 1978;88:43-6.

[18] 18. Pernoll ML. Abortion induced by chemicals encountered in the environment. Clin Obstet Gynecol 1986;29:953-8.

[19] 19. Shaw GM, Schulman J, Frisch JD, Cummins SK, Harris JA. Congenital malformations and birthweight in areas with potential environmental contamination. Arch Environ Health 1992;47:147-54.

[20] 20. Stockbauer JW, Hoffman RE, Cchramm WF, Edmonds LD. Reproductive outcomes of mothers with potential exposure to 2,3,7,8-tetrachlorodibenzo-p-dioxin. Am J Epidemiol 1988;128:410-9.

[21] 21. Vargas VMF, Guidobono RR, Jordão C, Henriques JAP. Use of two short-term tests to evaluate the genotoxicity of river water treated with different concentration/extraction procedures. Mutation Res 1995;343:31-52.

[22] 22. Witkowski KM, Johnson NE. Organic-solvent water pollution and low birth weight in Michigan. Soc Biol 1992;39:45-54.