Blood lead levels in a group of children: the potential risk factors and health problems☆

AbuShady, Mones M.; Fathy, Hanan A.; Fathy, Gihan A.; Fatah, Samer abd el; Ali, Alaa; Abbas, Mohamed A.

doi:10.1016/j.jped.2016.12.006

Abstract

Objective:

To investigate blood lead levels in schoolchildren in two areas of Egypt to understand the current lead pollution exposure and its risk factors, aiming to improve prevention politicies.

Subjects and method:

This was a cross-sectional study in children (n = 400) aged 6-12 years recruited from two areas in Egypt (industrial and urban). Blood lead levels were measured using an atomic absorption method. Detailed questionnaires on sources of lead exposure and history of school performance and any behavioral changes were obtained.

Results:

The mean blood lead level in the urban area of Egypt (Dokki) was 5.45 ± 3.90 µg/dL, while that in the industrial area (Helwan) was 10.37 ± 7.94 µg/dL, with a statistically significant difference between both areas (p < 0.05). In Dokki, 20% of the studied group had blood lead levels ≥ 10 µg/dL, versus 42% of those in Helwan. A significant association was found between children with abnormal behavior and those with pallor with blood lead level ≥ 10 µg/dL, when compared with those with blood lead level < 10 µg/dL (p < 0.05). Those living in Helwan area, those with bad health habits, and those living in housing with increased exposure were at a statistically significantly higher risk of having blood lead level ≥ 10 µg/dL.

Conclusion:

Lead remains a public health problem in Egypt. High blood lead levels were significantly associated with bad health habits and housing with increased exposure, as well as abnormal behavior and pallor.

KEYWORDS
Blood lead levels; Children; Lead exposure; Abnormal behavior; Short stature; Egypt

Resumo

Objetivo:

Investigar os níveis de chumbo no sangue (NCSs) em crianças em idade escolar em duas áreas do Egito para entender a atual exposição à poluição por chumbo e seus fatores de risco, para melhorar as políticas de prevenção.

Indivíduos e método:

Este foi um estudo transversal em crianças (400) entre 6-12 anos recrutadas de duas áreas no Egito (industrial e urbana). Os NCSs foram medidos por um método de absorção atômica. Foram obtidos questionários detalhados sobre as fontes de exposição ao chumbo e o histórico de desempenho escolar e quaisquer alterações comportamentais.

Resultados:

O NCS na área urbana do Egito (Dokki) foi de 5,45 ± 3,90 µg/dL, ao passo que na área industrial (Helwan) foi de 10,37 ± 7,94 µg/dL, com uma diferença significativa entre ambas as áreas (p < 0,05). Na área de Dokki, 20% do grupo estudado apresentaram NCSs ≥10 µg/dL, ao passo que na área de Helwan foi 42%. Foi encontrada uma associação significativa entre as crianças com comportamento anormal e aquelas com palidez com NCS ≥ 10 µg/dL, em comparação com aquelas com NCS < 10 µg/dL (p < 0,05). Aquelas que moram na área de Helwan, aquelas com hábitos de saúde ruins e aquelas que moram em moradias com maior exposição estiveram significativamente em alto risco de apresentar NCS ≥ 10 µg/dL.

Conclusão:

O chumbo ainda é um problema de saúde pública no Egito. Altos NCSs foram significativamente associados a hábitos de saúde ruins e moradia com maior exposição, bem como comportamento anormal e palidez.

PALAVRAS-CHAVE
Níveis de chumbo no sangue; Crianças; Exposição ao chumbo; Comportamento anormal; Baixa estatura; Egito

Introduction

Blood lead level (BLL) is a major health hazard, especially in children, which warrants its frequent monitoring in order to avoid lead exposure as much as possible.¹1 Needleman H. Low level lead exposure: history and discovery. Ann Epidemiol. 2009;19:235-8. Lead has been used in many products such as paint, pipes, and ceramics, and remains a public hazard. The main sources of lead and its pollution are mining operations, battery recycling plants, and smelting,²2 Mackay AK, Taylor MP, Munksgaard NC, Hudson-Edwards KA, Burn-Nunes L. Identification of environmental lead sources and pathways in a mining and smelting town: Mount Isa, Australia. Environ Pollut. 2013;180:304-11.^,³3 Were FH, Kamau GN, Shiundu PM, Wafula GA, Moturi CM. Air and blood lead levels in lead acid battery recycling and manufacturing plants in Kenya. J Occup Environ Hyg. 2012;9:340-4. as well as old lead-based peeled or chipped paint, especially during renovations of old houses,⁴4 Jacobs DE, Clickner RP, Zhou JY, Viet SM, Marker DA, Rogers JW, et al. The prevalence of lead-based paint hazards in U.S. housing. Environ Health Perspect. 2002;110:A599-606.^,⁵5 Spanier AJ, Wilson S, Ho M, Hornung R, Lanphear BP. The contribution of housing renovation to children's blood lead levels: a cohort study. Environ Health. 2013;12:72. contact with contaminated dust or soil,⁶6 Dixon SL, Gaitens JM, Jacobs DE, Strauss W, Nagaraja J, Pivetz T, et al. Exposure of U.S. children to residential dust lead, 1999-2004: II. The contribution of lead-contaminated dust to children's blood lead levels. Environ Health Perspect. 2009;117:468-74. lead in plumbing, automobile exhaust, by-products of both mining and metal working, and various consumer products.⁷7 Oyana TJ, Margai FM. Spatial patterns and health disparities in pediatric lead exposure in Chicago: characteristics and profiles of high-risk neighborhoods. Prof Geogr. 2010;62:46-65.^,⁸8 Edwards M. Lead poisoning: a public health issue. Prim Health Care. 2008;18:18. E-scrap recycling is an emerging area of concern as a source of occupational exposures among workers and a source of take-home exposures.⁹9 Newman N, Jones C, Page E, Ceballos D, Oza A. Investigation of childhood lead poisoning from parental take-home exposure from an electronic scrap recycling facility—Ohio, 2012. MMWR Morb Mortal Wkly Rep. 2015;64:743-5.

Lead is not known to serve any physiological function, but it exists in almost all biological systems. It is absorbed via different routes; however, ingestion of contaminated dietary constituents accounts for the majority of lead toxicity in children.¹⁰10 Silbergeld EK. Preventing lead poisoning in children. Annu Rev Public Health. 1997;18:187-210. Children are more likely to be exposed than adults due to a high rate of inhalation and more intestinal absorption. Intense, high-dose exposure to lead causes acute symptomatic poisoning, characterized by colic, anemia, and depression of the central nervous system that may result in coma, convulsions, and death. Low BLLs are now known to affect multiple organs in the absence of apparent symptoms. Toxicity with low lead levels in utero and during childhood constitutes brain and nervous system damage. Exposure to low BLL (less than 10 µg/dL) affects also the immune, reproductive and cardiovascular systems. Recent research indicates that, at blood levels of 5 µg/dL or lower, neurobehavioural damage is liable to occur. It appears that brain injury can happen at any blood level threshold.¹¹11 World Health Organization (WHO). Childhood lead poisoning; 2010. Available from: http://www.who.int/ceh/publications/childhoodpoisoning/en/ http://www.who.int/ceh/publications/childhoodpoisoning/en/ [cited 19.09.15].
http://www.who.int/ceh/publications/chil...

12 Gump BB, Mackenzie JA, Bendinskas K, Morgan R, Dumas AK, Palmer CD, et al. Low-level Pb and cardiovascular responses to acute stress in children: the role of cardiac autonomic regulation. Neurotoxicol Teratol. 2011;33:212-9.^-¹³13 Liu J, Gao D, Chen Y, Jing J, Hu Q, Chen Y. Lead exposure at each stage of pregnancy and neurobehavioral development of neonates. Neurotoxicology. 2014;44:1-7.

The goals of the present study were to evaluate the extent of lead exposure in schoolchildren, whose age ranged from 6 to 12 years, in industrial and urban areas in Egypt and to investigate the possible influencing factors in order to clarify the current problem of lead exposure and to improve methods of prevention and control.

Subjects and methods

Two hundred primary school children were randomly chosen in an industrial area in Egypt (Helwan); the same number of primary school children was selected in an urban area in Egypt (Dokki). The study was approved by the Medical Ethical Committee of National Research Centre, Dokki, Cairo, Egypt. Parental consents were obtained. Parents who opted to join the study answered detailed questionnaires on sources of water supply, housing (old houses with defective paints/use of lead-glazed ceramics), living with adults whose job involve battery repair, recycling, or processing, dietary habits (e.g., using newspapers to wrap the children's food), exposure to air pollution (location of the house close to main roads), and outdoor playing in dust areas. History of school performance, behavioral changes (such as anxiety and aggressiveness), and any clinical problems were investigated. Teachers and other school staff were asked to assess each child's performance and behaviors.

A thorough clinical examination was performed, including weight, height, blood pressure, cardiac, abdominal, and full neurological examinations. A psychological assessment was also performed through an interview with a specialist. Complete blood count and BLL were assessed.

Blood samples were collected according to the instructions of the Centers of Disease Control and Prevention (CDC). All sample collection tubes and materials were pre-screened for lead contamination. Blood samples were analyzed for lead level with the atomic absorption method described by Miller et al.,¹⁴14 Miller DT, Paschal DC, Gunter EW, Stroud PE, D'Angelo J. Determination of lead in blood using electrothermal atomisation atomic absorption spectrometry with a L'vov platform and matrix modifier. Analyst. 1987;112:1701-4. using heating graphite atomization (HGA 600 perkin Elmer). BLLs were considered as "elevated" or "level of concern" if equal to or greater than 10 µg/dL, in accordance with the US Centers for Disease Control and Prevention criteria.¹⁵15 Centers for Disease Control and Prevention (CDC) Advisory Committee on Childhood Lead Poisoning Prevention. Interpreting and managing blood lead levels <10 µg/dL in children and reducing childhood exposures to lead: recommendations of CDC's Advisory Committee on Childhood Lead Poisoning Prevention. MMWR Recomm Rep. 2007;56:1-16.

Statistical analysis

Statistical analysis was performed using SPSS version 16 for Windows (SPSS Inc., version 16 for Windows, IL, USA). Continuous data (BLLs) were expressed as mean ± standard deviation and were compared using Student's t-test. Categorical data were expressed as frequencies and percentages, and were analyzed with the two-tailed chi-squared test. Multiple logistic regression analysis was used to analyze the predictors of BLL ≥ 10 µg/dL and to modify the association between the clinical data and high BLL by adding the covariates. p-Values < 0.05 were considered to be statistically significant.

Results

A total of 400 children were enrolled in the present study; their age ranged from 6 to 12 years, with a mean of 9.40 ± 2.33. From the total, 205 children were males and 195 were females. Mean BLL was 10.37 ± 7.94 µg/dL in Helwan and 5.45 ± 3.90 µg/dL in Dokki, with a significant difference between both areas (p < 0.05). No significant difference was found between the genders in both areas regarding BLL (p > 0.05). In Dokki, 20% of the studied group had BLLs ≥ 10 µg/dL, while in Helwan this value was 42%. The percentage of children with BLL ≥ 5 µg/dL was 44% in Dokki, versus 64% in Helwan.

The social and clinical data of the study population are presented in Table 1, showing that children in Helwan had significantly worse results in health habits, housing with increased exposure, school achievement <60%, abnormal behavior, and pallor than children in Dokki (p < 0.05).

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Table 1
Clinical and social data of the study population (n = 400).

The association between clinical data of all children and high BLL is presented in Table 2. A significant association was observed between BLL ≥ 10 µg/dL and children with school achievement <60%, children with abnormal behavior, children with short stature, and pallor, when compared with those with BLL < 10 µg/dL (p < 0.05).

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Table 2
Association of clinical data of children and high blood lead levels (≥10 µg/dL).

Multiple logistic regression analysis was done to study the predictors of high blood lead level (≥10 µg/dL; Table 3). It was found that those living in Helwan, those with bad health habits, and those living in housing with increased exposure were at a significantly higher risk of having BLL ≥ 10 µg/dL (OR = 2.16, 95% CI 1.35-3.47; OR = 1.947, 95% CI 1.22-3.10; OR = 1.72, 95% CI 1.09-1.09, respectively, p < 0.05 in all).

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Table 3
Predictors of high blood lead level (≥10 µg/dL; multiple logistic regression analysis).

Table 4 shows the association between the clinical data and high BLL after modification by the predictors of high BLL as covariates. Abnormal behavior and pallor were associated with high BLL ≥ 10 µg/dL (p < 0.05), while school achievement <60% and short stature were not associated with high BLL (p > 0.05) after modification by the covariates.

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Table 4
Association of clinical data and high blood lead level (≥10 µg/dL) after modification by covariates (multiple logistic regression analysis).

Discussion

Childhood lead poisoning is a major problem that can be prevented worldwide. In the current study, mean BLL in an urban area of Egypt (Dokki) was 5.45 ± 3.90 µg/dL, while that in an industrial area (Helwan) was 10.37 ± 7.94 µg/dL. In Dokki, 20% of the studied group had BLLs ≥ 10 µg/dL, versus 42% in Helwan. The percentage of children with BLL ≥ 5 µg/dL was 44% in Dokki, versus 64% in Helwan. In Singapore, from 1995 to 1997, the mean reported BLL was 6.6 µg/dL in 269 children.¹⁶16 Sallmén M, Lindbohm ML, Nurminen M. Paternal exposure to lead and infertility. Epidemiology. 2000;11:148-52. Children aged 12-19 years were assessed in 1999 in the United States, and a mean BLL of 1.1 µg/dL was found¹⁷17 Fadrowski JJ, Navas-Acien A, Tellez-Plaza M, Guallar E, Weaver VM, Furth SL. Blood lead level and kidney function in US adolescents: The Third National Health and Nutrition Examination Survey. Arch Intern Med. 2010;170:75-82.; from 2007 to 2010, the geometric means at age 1-2 years and 3-5 years were found to be 1.5 µg/dL and 1.2 µg/dL, respectively.¹⁸18 Centers for Disease Control and Prevention (CDC). Blood lead levels in children aged 1-5 years - United States, 1999-2010. MMWR Morb Mortal Wkly Rep. 2013;62:245-8.

A cross-sectional survey for BLLs included 3831 children recruited at hospitals in France. The geometric mean BLL was 1.49 µg/dL; 0.09% of the children had BLL exceeding 10 µg/dL, and in 1.5%, BLL exceeded 5 µg/dL.¹⁹19 Etchevers A, Bretin P, Lecoffre C, Bidondo ML, Le Strat Y, Glorennec P, et al. Blood lead levels and risk factors in young children in France, 2008-2009. Int J Hyg Environ Health. 2014;217:528-37.

In 2011, a study of blood lead concentrations of 226 schoolchildren was conducted in Alpuyeca, Morelos, Mexico. The mean BLL was 7.23 µg/dL; BPb > 5 µg/dL and >10 µg/dL were observed in 64% and 18% of the children, respectively. In almost 50% of the households, the use of lead-glazed ceramics was reported.²⁰20 Farías P, Álamo-Hernández U, Mancilla-Sánchez L, Texcalac-Sangrador JL, Carrizales-Yáñez L, Riojas-Rodríguez H. Lead in school children from Morelos, Mexico: levels, sources and feasible interventions. Int J Environ Res Public Health. 2014;11:12668-82.

Ecuadorian infants and young children (n = 130) aged 0.33-5.8 years had their BLL assessed; the mean BLL was 29.4 µg/dL (SD: 24.3; range: 3.0-128.2; median: 21.7; geometric mean: 20.7 µg/dL).²¹21 Allen Counter S, Buchanan LH, Ortega F. Blood lead levels in Andean infants and young children in Ecuador: an international comparison. J Toxicol Environ Health A. 2015;78:778-87. To measure current lead exposure in Japanese children, blood samples were collected from 229 children aged 9-10 years in Asahikawa, Japan; The geometric mean was 0.96 µg/dL.²²22 Ilmiawati C, Yoshida T, Itoh T, Nakagi Y, Saijo Y, Sugioka Y, et al. Biomonitoring of mercury, cadmium, and lead exposure in Japanese children: a cross-sectional study. Environ Health Prev Med. 2015;20:18-27.

Children in six communities near to the now-closed Kabwe mines and smelters in Zambia were studied for BLL; the mean was 4.83 µg/dL. The lowest BLL measured was 1.36 µg/dL. The highest BLL detected using the testing system was 6.5 µg/dL.²³23 Caravanos J, Fuller R, Robinson S. Centers for Disease Control and Prevention (CDC). Notes from the field: severe environmental contamination and elevated blood lead levels among children - Zambia, 2014. MMWR Morb Mortal Wkly Rep. 2014;63:1013.

BLL was also assessed in the Bagega community in Nigeria; the median was 71 µg/dL (range: 8-332 µg/dL). Elevated BLL (≥10 µg/dL) was found in 99.5% of the studied group.²⁴24 Ajumobi OO, Tsofo A, Yango M, Aworh MK, Anagbogu IN, Mohammed A, et al. High concentration of blood lead levels among young children in Bagega community, Zamfara - Nigeria and the potential risk factor. Pan Afr Med J. 2014;18:14. In Wuhan, China, children less than 18 years were investigated throughout the entire year of 2012. For all subjects, the geometric mean was 4.48 µg/dL. Elevated BLLs (≥10 µg/dL and ≥5 µg/dL) were found in 2% and in 44%, respectively.²⁵25 Li Y, Wu S, Xiang Y, Liang X. An investigation of outpatient children's blood lead level in Wuhan China. PLOS ONE. 2014;9:e95284. In South Africa, a cross-sectional analytical studies including 160 young schoolchildren was performed. The mean BLL was 7.4 µg/dL (range: 2.2-22.4 µg/dL). BLLs ≥ 5 µg/dL were observed in 74% of the children, while 16% had BLL ≥ 10 µg/dl.²⁶26 Mathee A, Khan T, Naicker N, Kootbodien T, Naidoo S, Becker P. Lead exposure in young school children in South African subsistence fishing communities. Environ Res. 2013;126:179-83.

BLLs were assessed in children living in Riyadh, Saudi Arabia. The mean (±SD) BLL was 5.2 ± 1.7, ranging from 1.7 to 10.6 µg/dL; in 17.8% of children, BLL was greater than 10 µg/dL.²⁷27 El-Desoky GE, Aboul-Soud MA, Al-Othman ZA, Habila M, Giesy JP. Seasonal concentrations of lead in outdoor and indoor dust and blood of children in Riyadh, Saudi Arabia. Environ Geochem Health. 2014;36:583-93.

A study conducted in three schools in Nablus, Palestine, assessed BLL in 178 children (140 boys, 38 girls, age range 6-8 years). The mean BLL was 3.2 ± 2.4 µg/dL, and levels above 10 µg/dL were observed in 4.5% of children.²⁸28 Sawalha AF, Wright RO, Bellinger DC, Amarasiriwardean C, Abu-Taha AS, Sweileh WM. Blood lead level among Palestinian schoolchildren: a pilot study. East Mediterr Health J. 2013;19:151-5.

In the present study, high BLLs were found in Helwan area, which is an old industrial area with many lead-related industries and factories. Other predictors of high BLL were bad health habits (using newspapers to wrap children's food; no hand washing before meals and after playing outside; contact with contaminated dust, soil and toys; ingestion of preserved eggs; and consumption of fried food) and housing with increased exposure (old lead-based peeled or chipped paint, renovations, lead in plumbing, and use of lead glazed ceramics).

No significant differences were detected in the current study between males and females in both Dokki and Helwan regarding BLLs, which can be explained by the similar behavior and outdoor activities of both genders. This result is in agreement with those by Allen Counter et al.²¹21 Allen Counter S, Buchanan LH, Ortega F. Blood lead levels in Andean infants and young children in Ecuador: an international comparison. J Toxicol Environ Health A. 2015;78:778-87. Cao et al.²⁹29 Cao J, Li M, Wang Y, Yu G, Yan C. Environmental lead exposure among preschool children in Shanghai, China: blood lead levels and risk factors. PLOS ONE. 2014;9:e113297. found that the mean BLLs in boys (23.57 mg/L) were higher than that in girls (21.2 mg/L), which was explained by the greater distinct behavior and outdoor activities found with growing boys, leading to contact with environmental lead pollution.

In a multivariable analysis by Spanier et al.,⁵5 Spanier AJ, Wilson S, Ho M, Hornung R, Lanphear BP. The contribution of housing renovation to children's blood lead levels: a cohort study. Environ Health. 2013;12:72. mean BLLs of children whose housing underwent interior renovation was 12% higher than that of children whose housing units were not renovated (p < 0.01). Renovation, repairs, and painting rule, routine interior housing renovation were associated with a modest increase in children's BLLs, which are in agreement with the present study.

In the present study, school achievement <60%, short stature, and pallor (Hb < 10 g/dL) were associated with high BLLs (≥10 µg/dL). Liu et al.³⁰30 Liu J, Liu X, Wang W, McCauley L, Pinto-Martin J, Wang Y, et al. Blood lead concentrations and children's behavioral and emotional problems: a cohort study. JAMA Pediatr. 2014;168:737-45. conducted a prospective cohort study that assessed children in four elementary schools. They detected a significant association between BLL and increased scores for teacher-reported behavioral problems (emotional reactivity, anxiety/depression, and pervasive developmental problems), which is in agreement with the present results. Boys experience the deleterious cognitive effects of lead more than girls do.³¹31 Khanna MM. Boys, not girls, are negatively affected on cognitive tasks by lead exposure: a pilot study. J Environ Health. 2015;77:72-7.

A cross-sectional assessment in children and adolescents aged 0-17 years from six communities in the Corrientes river basin was conducted. Children and adolescents with BLLs > 5 µg/dL had twice the risk of stunting when compared with those with lower BLLs.³²32 Anticona C, San Sebastian M. Anemia and malnutrition in indigenous children and adolescents of the Peruvian Amazon in a context of lead exposure: a cross-sectional study. Glob Health Action. 2014;7:22888. Fleisch et al.³³33 Fleisch AF, Burns JS, Williams PL, Lee MM, Sergeyev O, Korrick SA, et al. Blood lead levels and serum insulin-like growth factor 1 concentrations in peripubertal boys. Environ Health Perspect. 2013;121:854-8. concluded that, in peripubertal boys, higher BLLs were associated with lower serum IGF-1, which is attributed to the inhibition of the hypothalamic-pituitary-growth axis by lead exposure, leading to growth delay. The results of the previous two studies are in agreement with the present results, which indicated a significant association between high BLLs and stunting.

The present study had some limitations, which included its small sample size; its cross-sectional design, which may not allow the follow-up of the association between clinical data and BLLs; and the questionnaire used to collect information on risk factors, which may have caused recall bias. The measurement of BLL through the gold standard method (graphite atomic absorption method) added strength to the present study.

In conclusion, BLL was measured and associated to exposure risk factors in two areas (one urban and one industrial) in Egypt. BLLs were significantly higher in the industrial area than in the urban area. High BLLs were significantly associated with bad health habits and housing with increased exposure, as well as with school achievement <60%, short stature, and pallor (Hb < 10 g/dL).

In Egypt, definitive plans and regulations should be carried out to improve the prevention and control of childhood lead poisoning. Regulatory policies are needed to reduce lead release from different industries. BLL screening and testing should be improved. In industrial areas, screening programs for BLL should be implemented. Finally, the prevention and treatment of childhood lead poisoning should be improved in Egypt.

This study examined the relationship between BLL and its risk factors in Egyptian children. The use of a representative sample of the general Egyptian children strengthened the present findings. However, there were some limitations to this study. First, it had a cross-sectional design, and lead exposure throughout the entire childhood development could not be assessed. Second, other hazardous environmental pollutants (e.g., mercury and cadmium) were not evaluated. Finally, the sample size was relatively small.

☆
Please cite this article as: AbuShady MM, Fathy HA, Fathy GA, Fatah Sa, Ali A, Abbas MA. Blood lead levels in a group of children: the potential risk factors and health problems. J Pediatr (Rio J). 2017;93:619-24.

References

¹
Needleman H. Low level lead exposure: history and discovery. Ann Epidemiol. 2009;19:235-8.
²
Mackay AK, Taylor MP, Munksgaard NC, Hudson-Edwards KA, Burn-Nunes L. Identification of environmental lead sources and pathways in a mining and smelting town: Mount Isa, Australia. Environ Pollut. 2013;180:304-11.
³
Were FH, Kamau GN, Shiundu PM, Wafula GA, Moturi CM. Air and blood lead levels in lead acid battery recycling and manufacturing plants in Kenya. J Occup Environ Hyg. 2012;9:340-4.
⁴
Jacobs DE, Clickner RP, Zhou JY, Viet SM, Marker DA, Rogers JW, et al. The prevalence of lead-based paint hazards in U.S. housing. Environ Health Perspect. 2002;110:A599-606.
⁵
Spanier AJ, Wilson S, Ho M, Hornung R, Lanphear BP. The contribution of housing renovation to children's blood lead levels: a cohort study. Environ Health. 2013;12:72.
⁶
Dixon SL, Gaitens JM, Jacobs DE, Strauss W, Nagaraja J, Pivetz T, et al. Exposure of U.S. children to residential dust lead, 1999-2004: II. The contribution of lead-contaminated dust to children's blood lead levels. Environ Health Perspect. 2009;117:468-74.
⁷
Oyana TJ, Margai FM. Spatial patterns and health disparities in pediatric lead exposure in Chicago: characteristics and profiles of high-risk neighborhoods. Prof Geogr. 2010;62:46-65.
⁸
Edwards M. Lead poisoning: a public health issue. Prim Health Care. 2008;18:18.
⁹
Newman N, Jones C, Page E, Ceballos D, Oza A. Investigation of childhood lead poisoning from parental take-home exposure from an electronic scrap recycling facility—Ohio, 2012. MMWR Morb Mortal Wkly Rep. 2015;64:743-5.
¹⁰
Silbergeld EK. Preventing lead poisoning in children. Annu Rev Public Health. 1997;18:187-210.
¹¹
World Health Organization (WHO). Childhood lead poisoning; 2010. Available from: http://www.who.int/ceh/publications/childhoodpoisoning/en/ http://www.who.int/ceh/publications/childhoodpoisoning/en/ [cited 19.09.15].
» http://www.who.int/ceh/publications/childhoodpoisoning/en/
¹²
Gump BB, Mackenzie JA, Bendinskas K, Morgan R, Dumas AK, Palmer CD, et al. Low-level Pb and cardiovascular responses to acute stress in children: the role of cardiac autonomic regulation. Neurotoxicol Teratol. 2011;33:212-9.
¹³
Liu J, Gao D, Chen Y, Jing J, Hu Q, Chen Y. Lead exposure at each stage of pregnancy and neurobehavioral development of neonates. Neurotoxicology. 2014;44:1-7.
¹⁴
Miller DT, Paschal DC, Gunter EW, Stroud PE, D'Angelo J. Determination of lead in blood using electrothermal atomisation atomic absorption spectrometry with a L'vov platform and matrix modifier. Analyst. 1987;112:1701-4.
¹⁵
Centers for Disease Control and Prevention (CDC) Advisory Committee on Childhood Lead Poisoning Prevention. Interpreting and managing blood lead levels <10 µg/dL in children and reducing childhood exposures to lead: recommendations of CDC's Advisory Committee on Childhood Lead Poisoning Prevention. MMWR Recomm Rep. 2007;56:1-16.
¹⁶
Sallmén M, Lindbohm ML, Nurminen M. Paternal exposure to lead and infertility. Epidemiology. 2000;11:148-52.
¹⁷
Fadrowski JJ, Navas-Acien A, Tellez-Plaza M, Guallar E, Weaver VM, Furth SL. Blood lead level and kidney function in US adolescents: The Third National Health and Nutrition Examination Survey. Arch Intern Med. 2010;170:75-82.
¹⁸
Centers for Disease Control and Prevention (CDC). Blood lead levels in children aged 1-5 years - United States, 1999-2010. MMWR Morb Mortal Wkly Rep. 2013;62:245-8.
¹⁹
Etchevers A, Bretin P, Lecoffre C, Bidondo ML, Le Strat Y, Glorennec P, et al. Blood lead levels and risk factors in young children in France, 2008-2009. Int J Hyg Environ Health. 2014;217:528-37.
²⁰
Farías P, Álamo-Hernández U, Mancilla-Sánchez L, Texcalac-Sangrador JL, Carrizales-Yáñez L, Riojas-Rodríguez H. Lead in school children from Morelos, Mexico: levels, sources and feasible interventions. Int J Environ Res Public Health. 2014;11:12668-82.
²¹
Allen Counter S, Buchanan LH, Ortega F. Blood lead levels in Andean infants and young children in Ecuador: an international comparison. J Toxicol Environ Health A. 2015;78:778-87.
²²
Ilmiawati C, Yoshida T, Itoh T, Nakagi Y, Saijo Y, Sugioka Y, et al. Biomonitoring of mercury, cadmium, and lead exposure in Japanese children: a cross-sectional study. Environ Health Prev Med. 2015;20:18-27.
²³
Caravanos J, Fuller R, Robinson S. Centers for Disease Control and Prevention (CDC). Notes from the field: severe environmental contamination and elevated blood lead levels among children - Zambia, 2014. MMWR Morb Mortal Wkly Rep. 2014;63:1013.
²⁴
Ajumobi OO, Tsofo A, Yango M, Aworh MK, Anagbogu IN, Mohammed A, et al. High concentration of blood lead levels among young children in Bagega community, Zamfara - Nigeria and the potential risk factor. Pan Afr Med J. 2014;18:14.
²⁵
Li Y, Wu S, Xiang Y, Liang X. An investigation of outpatient children's blood lead level in Wuhan China. PLOS ONE. 2014;9:e95284.
²⁶
Mathee A, Khan T, Naicker N, Kootbodien T, Naidoo S, Becker P. Lead exposure in young school children in South African subsistence fishing communities. Environ Res. 2013;126:179-83.
²⁷
El-Desoky GE, Aboul-Soud MA, Al-Othman ZA, Habila M, Giesy JP. Seasonal concentrations of lead in outdoor and indoor dust and blood of children in Riyadh, Saudi Arabia. Environ Geochem Health. 2014;36:583-93.
²⁸
Sawalha AF, Wright RO, Bellinger DC, Amarasiriwardean C, Abu-Taha AS, Sweileh WM. Blood lead level among Palestinian schoolchildren: a pilot study. East Mediterr Health J. 2013;19:151-5.
²⁹
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Publication Dates

Publication in this collection
Nov-Dec 2017

History

Received
15 July 2016
Accepted
22 Dec 2016

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

[1] ☆
Please cite this article as: AbuShady MM, Fathy HA, Fathy GA, Fatah Sa, Ali A, Abbas MA. Blood lead levels in a group of children: the potential risk factors and health problems. J Pediatr (Rio J). 2017;93:619-24.

Character	Helwan area n = 200 (Number - %)	Dokki area n = 200 (Number - %)	p
Bad health habits increasing exposure	122 (61%)	64 (32%)	0.000^a a p-Values < 0.05 were considered as significant.
Housing with increased exposure	119 (59.5%)	69 (34.5%)	0.000^a a p-Values < 0.05 were considered as significant.
School achievement <60%	20 (10%)	5 (2.5%)	0.004^a a p-Values < 0.05 were considered as significant.
Abnormal behavior	15 (7.5%)	3 (1.5%)	0.008^a a p-Values < 0.05 were considered as significant.
Short stature	4 (2%)	2 (1%)	0.681
Pallor (Hb < 10 gm%)	79 (39.5%)	44 (22%)	0.005^a a p-Values < 0.05 were considered as significant.
BLL ≥ 10 µg/dL	84 (42%)	40 (20%)	0.000^a a p-Values < 0.05 were considered as significant.

Character	High BLL ≥ 10 µg/dL n = 124 (Number - %)	BLL < 10 µg/dL n = 276 (Number - %)	p
School achievement <60%	18 (14.5%)	7 (2.5%)	<0.000^a a p-Values < 0.05 were considered as significant.
Abnormal behavior	10 (8%)	8 (2.9%)	0.041^a a p-Values < 0.05 were considered as significant.
Short stature	5 (4%)	1 (0.4%)	0.019^a a p-Values < 0.05 were considered as significant.
Pallor (Hb < 10 gm%)	67 (54%)	57 (20.7%)	0.000^a a p-Values < 0.05 were considered as significant.

	B	p	OR	95% CI for OR
				Lower	Upper
Residence (Dokki versus Helwan)	0.763	0.002^a a p-Values < 0.05 were considered as significant.	2.145	1.335	3.447
Health habits (Good health habits versus bad health habits)	0.664	0.005^a a p-Values < 0.05 were considered as significant.	1.943	1.220	3.095
Housing exposure (Housing with no exposure versus housing with increased exposure)	0.565	0.017^a a p-Values < 0.05 were considered as significant.	1.760	1.108	2.796
Age	-0.077	0.243	0.926	0.815	1.053
Sex	0.200	0.392	1.222	0.772	1.932
Constant	-3.410	0.000	0.033

	B	p	OR	95% CI for OR
				Lower	Upper
Covariates
Intercept	-0.07291	0.952
Residence (Dokki versus Helwan)	-0.525	0.049^a a p-Values < 0.05 were considered as significant.	0.591	0.350	1.001
Health habits (Good health habits versus bad health habits)	-0.307	0.252	0.736	0.435	1.243
Housing exposure (Housing with no exposure versus housing with increased exposure)	-0.542	0.039^a a p-Values < 0.05 were considered as significant.	0.581	0.347	0.973
Age	0.100	0.188	1.105	0.952	1.284
Sex	-0.226	0.383	0.798	0.480	1.326

Clinical data
School achievement < 60%	0.302	0.318	1.352	0.748	2.445
School achievement < 60%	0
Abnormal behavior	1.794	0.000^a a p-Values < 0.05 were considered as significant.	6.013	3.159	11.446
Abnormal behavior	0
Short stature	-0.05999	0.924	0.942	0.274	3.234
Short stature	0
Pallor (Hb < 10 gm%)	1.198	0.000^a a p-Values < 0.05 were considered as significant.	3.313	1.845	5.948
Pallor (Hb < 10 gm%)	0

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Abstract

Objective:

Subjects and method:

Results:

Conclusion:

Resumo

Objetivo:

Indivíduos e método:

Resultados:

Conclusão:

Introduction

Subjects and methods

Statistical analysis

Results

Discussion

References

Publication Dates

History