Chronic Kidney Disease in Children and Adolescents in Salvadoran Farming Communities: NefroSalva Pediatric Study (2009-2011)

ABSTRACT

INTRODUCTION

For two decades, various countries have experienced an epidemic of chronic kidney disease unexplainable by traditional causes. Typically a chronic tubulointerstitial nephritis, it predominantly affects young male agricultural workers and has been reported in several countries in Central America, as well as in Sri Lanka, India and Egypt. Recent studies in El Salvador have also reported the disease in male nonagricultural workers and in women, both those working in agriculture and not. Epidemiological information on whether this condition affects pediatric populations is virtually nonexistent. Globally, estimates of chronic kidney disease prevalence in pediatric populations range from 21 to 108 per million population.

OBJECTIVE

Determine the prevalence of urinary markers of renal damage and of chronic kidney disease in persons aged <18 years in rural Salvadoran communities.

METHODS

Pediatric NefroSalva was a descriptive epidemiologic study in three agricultural regions with known high prevalence of chronic kidney disease of uncertain etiology: Bajo Lempa, Guayapa Abajo and Las Brisas. Demographic and health data were collected and physical measurements were taken for 2115 persons aged <18 years, 1058 boys and 1057 girls. Urine samples were tested for markers of renal damage and blood samples analyzed to measure creatinine for estimating glomerular filtration rate (Schwartz formula). Median glomerular filtration rate was compared with reference values for age groups 2-12 and 13-17 years; mean glomerular filtration rate trends were assessed for age groups 2-5, 6-12 and 13-17 years. Positive test results were confirmed after three months.

RESULTS

Prevalence of urinary markers of renal damage was 4%, 4.3% in girls and 3.8% in boys. Microalbuminura (albumin:creatinine ratio 30-300 mg/g) was detected in both sexes and all age groups in all three regions, with prevalences of 2.6%-3.8% in boys and 3.3%-3.8% in girls. Macroalbuminuria (albumin:creatinine ratio >300 mg/g) was detected only in girls in Las Brisas, 2.3%. Glomerular hyperfiltration (compared to international norms) was found in all age-sex groups in all three regions. Prevalence of chronic kidney disease was 3.9%—4.1% in girls and 3.6% in boys. The prevalence of chronic renal failure was 0.1%.

CONCLUSIONS

High prevalence of chronic kidney disease in children and adolescents calls attention to the need for primary prevention from very early ages. This finding in children in areas where chronic kidney disease of uncertain etiology is common in adults is consistent with a contribution of environmental toxins to the epidemic observed in these areas.

Chronic kidney disease; chronic renal failure; chronic tubulointerstitial nephropathy; interstitial nephritis; glomerular hyperfiltration; child health; adolescent health; environmental health; El Salvador

INTRODUCTION

Over the past two decades, chronic kidney disease (CKD) has emerged as a health problem of epidemic proportions in a number of rural areas.[11. Trabanino RG, Aguilar R, Silva CR, Mercado MO, Merino RL. Nefropatia terminal en pacientes de un hospital de referencia en El Salvador. Rev Panam Salud Pùblica. 2002 Sep;12(3):202-6. Spanish.] The epidemic affects primarily young men living in farming communities in Central America,[22. Flores Reyna R, Jenkins Molieri JJ, Vega Manzano R, Chicas Labor A, Leiva Merino R, Calderón GR, et al. Enfermedad renal terminal: Hallazgos preliminares de un reciente estudio en el Salvador. San Salvador: Pan American Health Organization; 2003. Spanish.,33. Almaguer M, Herrera R, Orantes CM. Chronic kidney disease of unknown etiology in agricultural communities. MEDICC Rev. 2014 Apr;16(2):9-15.] specifically El Salvador,[44. Garcia-Trabanino R, Dominguez J, Jansa JM, Oliver A. Proteinuria e insuficiencia renal crónica en la costa de El Salvador: detección con métodos de bajo costo y factores asociados. Nefrologia. 2005;25(1):31-8. Spanish.77. Peraza S, Wfesseling C, Aragón A, Leiva R, Garcia-Trabanino RA, Torres C, et al. Decreased kidney function among agricultural workers in El Salvador. Am J Kidney Dis. 2012 Apr;59(4):531-40.] Nicaragua[88. Torres C, Aragón A, Gonzalez M, López I, Jakobsson K, Elinder CG, et al. Decreased kidney function of unknown cause in Nicaragua: a community-based survey. Am J Kidney Dis. 2010 Mar;55(3):485-96. 9. O’Donell JK, Tobey M, Weiner DE, Stevens LA, Johnson S, Stringham P, et al. Prevalence of and risk factors for chronic kidney disease in rural Nicaragua. Nephrol Dial Transplant. 2011 Sep;26(9):2798-805.1010. Lebov JF, Valladares E, Pena R, Pena EM, Sanoff SL, Cisneros EC, et al. A population-based study of prevalence and risk factors of chronic kidney disease in León, Nicaragua. Can J Kidney Health Dis. 2015 Feb 24;2:6. DOI:http://dx.doi.org/10.1186/S40697-015-0041-1.
http://dx.doi.org/10.1186/S40697-015-004...
] and Costa Rica,[1111. Cerdas M. Chronic kidney disease in Costa Rica. Kidney Int Suppl [Internet]. 2005 Aug [cited 2014 Mar 21];(97):S31-3. Available from: http://www.kidney-international.org/article/S0085-2538 %2815%2951239-8/pdf
http://www.kidney-international.org/arti...
] as well as in other countries: Sri Lanka,[1212. Athuraliya NT, Abeysekera TD, Amerasinghe PH, Kumarasiri R, Bandara P, Karunaratne U, et al. Uncertain etiologies of proteinuric-chronic kidney disease in rural Sri Lanka. Kidney Int. 2011 Dec;80(11):1212-21. 13. Jayasumana C, Gunatilake S, Siribaddana S. Simultaneous exposure to multiple heavy metals and glyphosate may contribute to Sri Lankan agricultural nephropathy. BMC Nephrol. 2015 Jul 11;16:103. DOI: http://dx.doi.org/10.1186/s12882-015-0109-2.
http://dx.doi.org/10.1186/s12882-015-010...
1414. Chandrajith R, Nanayakkara S, Itai K, Aturaliya TN, Dissanayake CB, Abeysekera T, et al. Chronic kidney diseases of uncertain etiology (CKDu) in Sri Lanka: geographic distribution and environmental implications. Environ Geochem Health. 2011 Jun;33(3):267-78.] Egypt[1515. El-Minshawy O. End stage renal disease in El-Minia Governorate, Egypt: Data of the year 2007. Nephro-Urol Monthly. 2011 May;3(2):118-21.,1616. Kamell EG, El-Minshawy O. Environmental factors incriminated in the development of end stage renal disease in El-Mina Governorate, Upper Egypt. Int J Nephrol Urol. 2010 Jan;2(3):431-7.] and India.[1717. Rajapurkar MM, John GT, Kirpalani AL, Abraham G, Agarwal SK, Almeida AF, et al. What do we know about chronic kidney disease in India: first report of the Indian CKD registry. BMC Nephrol. 2012 Mar 6;13:10. DOI: http://dx.doi.org/10.1186/1471-2369-13-10.
http://dx.doi.org/10.1186/1471-2369-13-1...
,1818. Machiraju RS, Yaradi K, Gowrishankar S, Edwards KL, Attaluri S, Miller F, et al. Epidemiology of Udhanam Endemic Nephropathy. J Am Soc Nephrol. 2009;20:643A.] This CKD, in most cases, is not due to diabetes mellitus, hypertension, primary glomerulopathy or obstructive uropathy, the main causes of CKD in adults, nor have any other causes been established with certainty. This has led many to call it chronic kidney disease of nontraditional causes (CKDnt).

However, several hypotheses have been generated about the causes of CKDnt. The two considered most plausible, not necessarily mutually exclusive,[1919. Silva LC, Ordûnez P. Chronic kidney disease in Central American agricultural communities: challenges for epidemiology and public health. MEDICC Rev. 2014 Apr;16(2):66-71.] are outlined below.

The first hypothesis holds that CKDnt is caused by occupational exposure to agrochemicals used indiscriminately and without protection during farm work, and from environmental exposure to pollutants in soil, water, air and food. This exposure is potentiated by intense labor at high temperatures coupled with inadequate hydration (leading to toxin concentration in the renal medulla), and is associated with social determinants, notably poverty.[66. Orantes CM, Herrera R, Almaguer M, Brizuela EG, Nûnez L, Alvarado NP, et al. Epidemiology of chronic kidney disease in adults of Salvadoran agricultural communities. MEDICC Rev. 2014 Apr;16(2):23-30.,2020. Herrera R, Orantes CM, Almaguer M, Alfonso P, Bayarre HD, Leiva IM, et al. Clinical characteristics of chronic kidney disease of nontraditional causes in Salvadoran farming communities. MEDICC Rev. 2014 Apr;16(2):39-48.]

The second hypothesis does not include agrochemicals as a causal factor but attributes the illness to strenuous working conditions, high temperatures and consequent dehydration, without adequate replacement of fluids and electrolytes, which could cause repeated acute kidney injury, in turn eventually leading to chronic kidney damage.[2121. Wesseling C, Crowe J, Hogstedt C, Jakobsson K, Lucas R, Wegman DH, et al. Resolving the enigma of the Mesoamerican nephropathy: a research workshop summary. Am J Kidney Dis. 2014 Mar;63(3):396-404.,2222. Correa-Rotter R, Wesseling C, Johnson RJ. CKD of unknown origin in Central America: the case for a Mesoamerican nephropathy. Am J Kidney Dis. 2014 Mar;63(3):506-20.]

Studies of renal biopsies from adults in Sri Lanka,[2323. Nanayakkara S, Komiya T, Ratnatunga N, Senevirathna ST, Harada KH, Hitomi T, et al. Tubulointerstitial damage as the major pathological lesion in endemic chronic kidney disease among farmers in North Central Province of Sri Lanka. Environ Health Prev Med. 2012 May;17(3):213-21.] Costa Rica[1111. Cerdas M. Chronic kidney disease in Costa Rica. Kidney Int Suppl [Internet]. 2005 Aug [cited 2014 Mar 21];(97):S31-3. Available from: http://www.kidney-international.org/article/S0085-2538 %2815%2951239-8/pdf
http://www.kidney-international.org/arti...
] and El Salvador[2424. López-Marin L, Chavez Y, Garcia XA, Flores WM, Garcia YM, Herrera R, et al. Histopathology of chronic kidney disease of unknown etiology in Salvadoran agricultural communities. MEDICC Rev. 2014 Apr;16(2):49-54.,2525. Wijkström J, Leiva R, Elinder CG, Leiva S, Trujillo Z, Trujillo L, et al. Clinical and pathological characterization of Mesoamerican nephropathy: a new kidney disease in Central America. Am J Kidney Dis. 2013 Nov;62(5):908-18.] suggest that kidney damage is a chronic tubulointerstitial nephritis with accompanying glomerular and vascular changes.

Most epidemiological studies of this health problem in Central American countries have focused their attention on male sugarcane farmers. In El Salvador, several studies have also reported the disease in farmers of crops other than sugarcane, in nonfarming men and in both farming and nonfarming women.[2020. Herrera R, Orantes CM, Almaguer M, Alfonso P, Bayarre HD, Leiva IM, et al. Clinical characteristics of chronic kidney disease of nontraditional causes in Salvadoran farming communities. MEDICC Rev. 2014 Apr;16(2):39-48.,2424. López-Marin L, Chavez Y, Garcia XA, Flores WM, Garcia YM, Herrera R, et al. Histopathology of chronic kidney disease of unknown etiology in Salvadoran agricultural communities. MEDICC Rev. 2014 Apr;16(2):49-54.,2626. Orantes Navarro CM, Herrera Valdés R, López MA, Calero DJ, Fuentes de Morales J, Alvarado Ascencio NP, et al. Epidemiological characteristics of chronic kidney disease of non-traditional causes in women of agricultural communities of El Salvador. Clin Nephrol. 2015;83(7 Suppl 1):S24-31.,2727. Herrera Valdés R, Orantes CM, Almaguer López M, López Marin L, Arévalo PA, Smith Gonzalez MJ, et al. Clinical characteristics of chronic kidney disease of non-traditional causes in women of agricultural communities in El Salvador. Clin Nephrol. 2015;83(7 Suppl 1):S56-63.] In a case–control study in Nicaragua of adolescents without an occupational history in agriculture, increased average levels of interleukin 18 (a tubular damage marker) were more frequent in female than in male adolescents.[2828. Brooks D, McClean M. Summary report: Boston University investigation of chronic kidney disease in Western Nicaragua. 2009-2012 [Internet]. Boston: Boston University School of Public Health; 2012 Aug [cited 2015 Oct 25]. 18 p. Available from: http://www.cao-ombudsman.org/documents/BU _SummaryReport_August122012.pdf
http://www.cao-ombudsman.org/documents/B...
] Presence of this tubular damage marker in adolescents resembles the findings of clinical and pathological studies in adults in Central America.[2020. Herrera R, Orantes CM, Almaguer M, Alfonso P, Bayarre HD, Leiva IM, et al. Clinical characteristics of chronic kidney disease of nontraditional causes in Salvadoran farming communities. MEDICC Rev. 2014 Apr;16(2):39-48.,2424. López-Marin L, Chavez Y, Garcia XA, Flores WM, Garcia YM, Herrera R, et al. Histopathology of chronic kidney disease of unknown etiology in Salvadoran agricultural communities. MEDICC Rev. 2014 Apr;16(2):49-54.,2525. Wijkström J, Leiva R, Elinder CG, Leiva S, Trujillo Z, Trujillo L, et al. Clinical and pathological characterization of Mesoamerican nephropathy: a new kidney disease in Central America. Am J Kidney Dis. 2013 Nov;62(5):908-18.]

Although CKDnt mainly affects adults, a recent study in Nicaragua established the presence of markers of renal tubular damage in adolescents aged 12–17 years in schools located in regions with high CKDnt prevalence. Adolescents were excluded if they had worked at manual labor for a month or more, paid or unpaid. The authors concluded that finding elevated urinary levels of neutrophil gelatinase associated lipocalin (NGAL) and N-acetyl-beta-D-glucosaminidase (NAG) proteins suggested the possibility of kidney injury prior to occupational exposure.[2929. Ramirez-Rubio O, Amador JJ, Kaufman JS, Weiner DE, Parikh CR, Khan U, et al. Urine biomarkers of kidney injury among adolescents in Nicaragua, a region affected by an epidemic of chronic kidney disease of unknown aetiology. Nephrol Dial Transplant. 2015 Aug 25. DOI: http://dx.doi.org/10.1093/ndt/gfv292. Epub ahead of print 2015 Aug 25.
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]

In farming communities in the Bajo Lempa region of El Salvador, a CKD prevalence of 17.9% (25.7% in men and 11% in women) has been documented in adults (aged ≥18 years). These rates are far higher than those found in other CKD studies among adults in various countries,[55. Orantes CM, Herrera R, Almaguer M, Brizuela EG, Hernandez CE, Bayarre H, et al. Chronic kidney disease and associated risk factors in the Bajo Lempa region of El Salvador. Nefrolempa study, 2009. MEDICC Rev. 2011 Oct;13(4):14-22.] where typical rates range from 10%–13%.[3030. Levey AS, Coresh J. Chronic kidney disease. Lancet. 2012 Jan 14;379(9811):165-80.] In over 50% of Salvadoran participants, CKD was not due to any of the known or traditional causes. Prevalence of chronic renal failure (CRF) is also high in this region: 9.8% (18.9% in men and 4.1% in women).[66. Orantes CM, Herrera R, Almaguer M, Brizuela EG, Nûnez L, Alvarado NP, et al. Epidemiology of chronic kidney disease in adults of Salvadoran agricultural communities. MEDICC Rev. 2014 Apr;16(2):23-30.]

Globally, epidemiological information on renal damage in the pediatric population is more limited. Unlike adults, where the greatest proportion of CKD is due to diabetes and hypertension,[3030. Levey AS, Coresh J. Chronic kidney disease. Lancet. 2012 Jan 14;379(9811):165-80.] in childhood, it is mainly attributed to congenital disorders in developed countries and to infections or other acquired diseases in developing countries. Estimates of chronic kidney disease prevalence in pediatric populations range from 21 to 108 per million.[3131. Chadha V, Warady BA. Epidemiology of pediatric chronic kidney disease. Adv Chronic Kidney Dis. 2005 Oct;12(4):343-52.]

The kidneys are susceptible to toxic damage due to, among other factors, increased renal perfusion. The high metabolic activity of the proximal tubular epithelium makes it particularly susceptible to toxic injury, though other parts of the nephron can also be affected.[3232. Weidemann DK, Weaver VM, Fadrowski JJ. Toxic environmental exposures and kidney health in children. Pediatr Nephrol. 2015 Oct 12. DOI http://dx.doi.org/10.1007/s00467-015-3222-3. Epub ahead of print.
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] Moreover, high exposure to numerous known nephrotoxic agents would have a direct, acute effect on the pediatric population. A growing body of literature supports the hypothesis that low-level exposure to several nephrotoxins can also increase risk of CKD or accelerate its progression.[3232. Weidemann DK, Weaver VM, Fadrowski JJ. Toxic environmental exposures and kidney health in children. Pediatr Nephrol. 2015 Oct 12. DOI http://dx.doi.org/10.1007/s00467-015-3222-3. Epub ahead of print.
http://dx.doi.org/10.1007/s00467-015-322...
] Prenatal exposure to nephrotoxins during renal system development can reduce nephron mass, manifested as changes in renal structure and function.[3333. Solhaug MJ, Bolger PM, Jose PA. The developing kidney and environmental toxins. Pediatrics. 2004 Apr;113(4 Suppl):1084-91.] A recent study in China detected an average of 15.3 pesticides per sample in cord blood from 336 neonates.[3434. Silver MK, Shao J, Chen M, Xia Y, Lozoff B, Meeker JD. Distribution and predictors of pesticides in the umbilical cord blood of Chinese newborns. Int J Environ Res Public Health [Internet]. 2016 Jan [cited 2016 Mar 20];13(1):94. Available from: http://www.mdpi.com/1660-4601/13/1/94
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]

The NefroSalva Pediatric Study’s objective was to determine the prevalence and distribution of CKD and of markers of kidney damage in the child and adolescent population of Salvadoran farming communities, with a view to supplementing insights into the epidemic from studies in adults.

METHODS

The study was conducted by the Renal Health Research Unit in the National Health Institute of El Salvador’s Ministry of Health. The research team included physicians, nurses, clinical laboratory technicians, epidemiologists, community health workers, staff from the Health Solidarity Fund of El Salvador, Salvadoran nephrologists and students from the University of El Salvador Medical School and Cuba’s Latin American Medical School, with active participation by community health committees in the areas studied. Experts from the Nephrology Institute and National School of Public Health of Cuba’s Ministry of Public Health served as PAHO advisors in the framework of intercountry technical cooperation.

Study type

A descriptive study was conducted from 2009 to 2011, through active screening for cases of CKD and urinary markers of kidney damage in the population aged <18 years in farming communities in 3 regions of El Salvador: Bajo Lempa (Usulután Department), Guayapa Abajo (Ahuachapán Department) and Las Brisas (San Miguel Department).

Setting

Bajo Lempa is a farming region located along the banks of the Lempa River near the southeastern coast of El Salvador. [3535. Hernandez W. Nacimiento y Desarrollo del rio Lempa [Internet]. San Salvador: SNET; 2005 [cited 2015 Oct 25]. 14 p. Available from: http://www.snet.gob.sv/Geologia/NacimientoEvolucionRLempa.pdf. Spanish.
http://www.snet.gob.sv/Geologia/Nacimien...
] Guayapa Abajo is also a farming region (known for its sugar cane), on the southwestern coast. Las Brisas is a periurban farming region in eastern El Salvador, close to the city of San Miguel (in the department of the same name). There is high prevalence of CKD in all three regions.[66. Orantes CM, Herrera R, Almaguer M, Brizuela EG, Nûnez L, Alvarado NP, et al. Epidemiology of chronic kidney disease in adults of Salvadoran agricultural communities. MEDICC Rev. 2014 Apr;16(2):23-30.]

Three general conditions characterize the regions in the study: high levels of poverty, unhealthy working conditions,[2020. Herrera R, Orantes CM, Almaguer M, Alfonso P, Bayarre HD, Leiva IM, et al. Clinical characteristics of chronic kidney disease of nontraditional causes in Salvadoran farming communities. MEDICC Rev. 2014 Apr;16(2):39-48.,3535. Hernandez W. Nacimiento y Desarrollo del rio Lempa [Internet]. San Salvador: SNET; 2005 [cited 2015 Oct 25]. 14 p. Available from: http://www.snet.gob.sv/Geologia/NacimientoEvolucionRLempa.pdf. Spanish.
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] and an environment contaminated with pesticide residue and, in the case of Bajo Lempa and Las Brisas, also heavy metals.[3636. Mejia R, Quinteros E, López A, Ribó A, Cedillos H, Orantes CM, et al. Pesticide-handling practices in agriculture in El Salvador: an example from 42 patient farmers with chronic kidney disease in the Bajo Lempa region. Occup Dis Environ Med. 2014 Aug 10;2(3):56-70. 37. López DL, Ribó A, Quinteros E, Mejia R, López A, Orantes C. Arsenic in soils, sediments, and water in an area with high prevalence for Chronic Kidney Disease of unknown etiology. In: Litter MI, Nicolli HB, Meichtry M, Quici N, Bundschuh J, Bhattacharya P, et al, editors. Proceedings of the 5th International Congress on Arsenic in the Environment, May 11-16, 2014, Buenos Aires, Argentina [Internet]. Buenos Aires: CRS Press; c2014 [cited 2016 Mar 25]. Chapter 86. p. 251-4. Available from: http://www.crcnetbase.com/doi/abs/10.1201/b16767-95
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38. López A, Ribó A, Mejia R, Quinteros E, Alfaro D, Beltetón W, et al. Exposure to nephrotoxic pollutants in Las Brisas community (El Salvador). In: Ferreira da Silva E, Reis AP, Patinha C, Dias AC, Duräes N, Candeias C, et al, editors. Book of Abstracts of the 6th International Conference on Medical Geology. Aveiro (PT): UA Editora; 2015. 137 p. ISBN - 978-972-789-449-9.3939. Nomen R, Sempere J, Chavez F, de López NA, Rovira MD. Measurement of pollution levels of organochlorine and organophosphorus pesticides in water, soil, sediment, and shrimp to identify possible impacts on shrimp production at Jiquilisco Bay. Environ Sci Pollut Res Int. 2012 Sep;19(8):3547-55.] Furthermore, working conditions for farm laborers are characterized by indiscriminate use of agrochemicals (combining several at once, some banned, used without protection with consequent environmental pollution)[3636. Mejia R, Quinteros E, López A, Ribó A, Cedillos H, Orantes CM, et al. Pesticide-handling practices in agriculture in El Salvador: an example from 42 patient farmers with chronic kidney disease in the Bajo Lempa region. Occup Dis Environ Med. 2014 Aug 10;2(3):56-70.] and heavy physical labor (causing profuse perspiration) for many hours in high temperatures and without adequate hydration.[2020. Herrera R, Orantes CM, Almaguer M, Alfonso P, Bayarre HD, Leiva IM, et al. Clinical characteristics of chronic kidney disease of nontraditional causes in Salvadoran farming communities. MEDICC Rev. 2014 Apr;16(2):39-48.]

The study had two phases:

  • A CKD screening phase, involving one-time testing for urinary markers of kidney damage and estimation of renal function.

  • A CKD confirmation phase, three months following the first phase, to validate positive findings for the above parameters.

Study population

A door-to-door census of 11 communities belonging to the 3 study regions identified 5018 individuals of all ages (1306 families). Of the 2163 children and adolescents, 2115 (97.8% of the population enumerated) aged <18 years were studied (1058 male and 1057 female). Urine samples for CKD marker studies were available in the confirmation phase from 1755 individuals, blood samples for creatinine determinations from 1960, and both samples in 1623.

Study variables

are described in Table 1.

Table 1
Variables

Recording and coding

Each participant was assigned a database code for subsequent clinical management. General information was obtained via a questionnaire and physical parameters were measured to determine glomerular filtration rate (GFR).

Laboratory tests

A first morning urine sample was tested using Multistix 10 SG (Bayer, USA) test strips, to rule out urinary infection and hematuria. If neither was detected, Microalbumin 2 (Bayer, USA) reagent strips were used to determine the albumin:creatinine ratio (to assess albuminuria). Test strips were read using a Clinitek (Bayer, USA) analyzer.

A 5-mL fasting venous blood sample was drawn from participants to measure creatinine by the enzymatic method. Samples were processed in a laboratory installed in each region and equipped with a Cobas C111 spectrophotometer (Roche, Germany), with its corresponding reagents and quality controls. Laboratory tests were performed per manufacturers’ specifications using appropriate controls. Measurements and analyses were done by trained and certified personnel.

Data management and analysis

Data were stored in a Microsoft Excel database processed with SPSS version 23.0 for Windows. General prevalence of urinary markers of kidney damage was calculated as were specific CKD prevalence rates by sex, age group and region. Hypothesis testing was done to compare means to respective pediatric reference values. Kidney Disease Outcomes Quality Initiative (KDOQI) guidelines were used as normal reference values.[4040. Hogg RJ, Furth S, Lemley KV, Portman R, Schwartz GJ, Coresh J, et al. National Kidney Foundation’s Kidney Disease Outcomes Quality Initiative Clinical Practice Guidelines for Chronic Kidney Disease in Children and Adolescents: Evaluation, Classification, and Stratification. Pediatrics. 2003 Jun;111(6 Pt 1):1416-21.] A 0.05 threshold was used to assess whether differences were statistically significant. GFR was calculated using the Schwartz formula[4141. Schwartz GJ, Brion LP, Spitzer A. The use of plasma creatinine concentration for estimating glomerular filtration rate in infants, children and adolescents. Pediatr Clin North Am. 1987 Jun;34(3):571-90.] and the average was plotted by age group.

Ethics

Written informed consent was obtained from all parents and participants respectively, who agreed to publication of the results under conditions of confidentiality. The study was approved by the Salvadoran Ministry of Health’s Executive Council. All participants received clinical followup by public health services.

RESULTS

Prevalence of urinary markers of kidney damage was 4% (95% CI 3%–5.8%) of the population studied; 4.3% in girls and 3.8% in boys. Table 2 displays detailed data on marker prevalence. Microalbuminuria was detected in both sexes and all regions, with prevalences of 2.6%–3.8% in boys and 3.3%–3.8% in girls. Macroalbuminuria was only detected in girls in Las Brisas (2.3%). The highest prevalence of hematuria was in boys in Las Brisas (1.6%). It was not detected in Bajo Lempa boys or in Guayapa Abajo girls. Testing with urine test strips found no proteinuria or evidence of urinary tract infection.

Table 2
Prevalence of kidney damage markers, by sex and region

In comparison with normal reference values,[4040. Hogg RJ, Furth S, Lemley KV, Portman R, Schwartz GJ, Coresh J, et al. National Kidney Foundation’s Kidney Disease Outcomes Quality Initiative Clinical Practice Guidelines for Chronic Kidney Disease in Children and Adolescents: Evaluation, Classification, and Stratification. Pediatrics. 2003 Jun;111(6 Pt 1):1416-21.] glomerular hyperfiltration was observed in all age groups and both sexes (Table 3). Consequently, an analysis was done comparing GFR with kidney damage markers, the latter found in 80% of children and adolescents with GFR ≥140 mL/min. Figure 1 shows average GFR by sex and age group.

Table 3
GFR compared to normal reference values (KDOQI) by region, age and sex
Figure 1
Mean GFR by age group and sex

Overall estimated CKD point prevalence was 3.9%. Prevalence in the group aged 2–5 years, 5.1%, was greater than in the other groups, but all CIs overlapped. The same happened with the regions. Similarly, prevalence in girls was greater than in boys (4.1% versus 3.6%), but with overlapping CIs. Las Brisas had the highest estimated CKD point prevalence, 4.3%, but its CI overlapped with those of the other two regions (Table 4). Two cases of CRF were found, a boy aged 13 years in stage 3a and a girl aged 10 years in stage 5, both from the Guayapa Abajo region.

Table 4
Prevalence of chronic kidney disease by stage, age group, sex and region

DISCUSSION

This is the first population-based investigation of CKD prevalence, kidney damage markers and average GFR values in minors in El Salvador. It provides clear evidence that kidney damage often begins in childhood. The results are similar to those from screening in Guatemala in the population aged 6–18 years in 2014, which found a 5% prevalence of urinary markers of persistent kidney damage.[4343. Flores Vasquez FM. Estudio piloto de tamizaje para enfermedad renal en escolares asintomaticos en la población de la Escuela Santa Teresita en el municipio de Solola, Guatemala mayo 2012 [thesis]. [Ciudad de Guatemala]: University of San Carlos de Guatemala. Spanish.] In the city of Jalisco (Mexico), screening in 2006–2007 found a 5% prevalence of persistent proteinuria and a 3.7% prevalence of GFR <80 mL/min in persons aged <18 years.[4444. Koshy SM, Garcia-Garcia G, Pamplona JS, Renoirte-López K, Pérez-Cortés G, Gutiérrez ML, et al. Screening for kidney disease in children on World Kidney Day in Jalisco, Mexico. Pediatr Nephrol. 2009 Jun;24(6):1219-25.]

In weighing the two causal hypotheses described above, it is worth noting that some population groups do not engage directly in farm work, such as preadolescent children as well as women and men who are not farmers. Thus, repeated kidney injury secondary to dehydration is not enough to explain CKD in these population groups. Logically, male and female farmers may suffer greater dehydration, and also exposure to toxic substances. However, there may also be environmental contamination that affects the population as a whole, associated with economic and social disadvantages that make these populations more vulnerable.

Reasonably, there may be different levels of exposure to toxins: the most damaging, high-level exposure would be repeated over time, consisting of multiple acute exposures that would ultimately produce a chronic ailment. This would primarily affect farmers, due to chronic circulation in blood of toxins that are eliminated by the kidneys, causing these toxins to concentrate in the renal medulla under the effects of long work hours in high temperatures with intense physical activity. Deficient hydration would potentiate the effects of such toxins. Furthermore, the general population might suffer lower-level chronic exposure, which could affect children, to a greater or lesser extent depending on their genetic susceptibility and other factors.

With regard to the effects of pesticides on child and adolescent health, low-level chronic cumulative exposure may be associated with subclinical health effects with delayed consequences that do not appear until weeks, months or years later. This exposure may begin prenatally or in infancy,[4545. Karr CJ, Rauh VA. Pesticides. In: Landrigan Philip J, Etzel RA, editors. Textbook of Children’s Environmental Health. Oxford (US): Oxford University Press; 2014. p. 296-302.] consistent with our finding of hyperfiltration even in the very youngest group, aged 2–5 years.

In rural areas, proximity to farmlands where there is high pesticide use (including periodic applications near schools, homes and playgrounds) is conducive to children and adolescents coming into contact with pesticides in water, air, soil and food. In addition, domestic exposure occurs from pesticide storage in the home. Moreover, the farmers who apply pesticides without protection have their clothes drenched with them, providing a source of exposure to the family, especially women, who are exposed when washing contaminated clothing.[3636. Mejia R, Quinteros E, López A, Ribó A, Cedillos H, Orantes CM, et al. Pesticide-handling practices in agriculture in El Salvador: an example from 42 patient farmers with chronic kidney disease in the Bajo Lempa region. Occup Dis Environ Med. 2014 Aug 10;2(3):56-70.,4545. Karr CJ, Rauh VA. Pesticides. In: Landrigan Philip J, Etzel RA, editors. Textbook of Children’s Environmental Health. Oxford (US): Oxford University Press; 2014. p. 296-302.] Other factors add to this cascade of circumstances, such as social determinants that make these communities more vulnerable to possible prior kidney damage: low birthweight, infectious diseases such as malaria and arboviruses, malnutrition and others. The data presented and environmental considerations persuade us of the importance of a possible multicausal etiopathogenesis centered on nephrotoxicity from agricultural toxins.

CKD prevalence in both sexes greater than reported internationally is consistent with observations in adults in the same regions. In Las Brisas, where the greatest prevalence of CKD has been found both in adults[66. Orantes CM, Herrera R, Almaguer M, Brizuela EG, Nûnez L, Alvarado NP, et al. Epidemiology of chronic kidney disease in adults of Salvadoran agricultural communities. MEDICC Rev. 2014 Apr;16(2):23-30.] and in children and adolescents, there is a storage warehouse for toxaphene, known for its severe effects on the kidney, liver and nervous system (banned by USEPA in 1990).[4646. United States Environmental Protection Agency, Office of Prevention, Pesticides and Toxic Substances. Protect yourself from pesticides: guide for pesticides handlers. Washington, D.C.: United States Environmental Protection Agency; 2006 Jun. 109 p.] The abandoned depot was dismantled by Las Brisas residents. According to El Salvador’s Ministry of Environment and Natural Resources, in 2009, toxaphene residue was found in nine of ten wells tested.[4747. Ministry of the Environment and Natural Resources (SV) [Internet]. San Salvador: Ministry of Environment and Natural Resources (SV); [updated 2011 Jan 3]. Las huellas del Toxafeno; 2010 Dec [cited 2013 Dec 12]. Available from: http://www.marn.gob.sv/index.php?option=com_content&view=artcle&catid=162:especiales&id=700:las-huellas-del-toxafeno. Spanish.
http://www.marn.gob.sv/index.php?option=...
]

A recent study in three regions of Nicaragua demonstrated the presence of biomarkers of tubular renal damage, particularly NGAL and NAG, in regions with high mortality from CKDnt.[2929. Ramirez-Rubio O, Amador JJ, Kaufman JS, Weiner DE, Parikh CR, Khan U, et al. Urine biomarkers of kidney injury among adolescents in Nicaragua, a region affected by an epidemic of chronic kidney disease of unknown aetiology. Nephrol Dial Transplant. 2015 Aug 25. DOI: http://dx.doi.org/10.1093/ndt/gfv292. Epub ahead of print 2015 Aug 25.
http://dx.doi.org/10.1093/ndt/gfv292...
] These fi ndings correspond to the clinical and histopathological characteristics of the chronic tubulointerstitial nephritis described in adults studied in these Salvadoran farming communities.[2020. Herrera R, Orantes CM, Almaguer M, Alfonso P, Bayarre HD, Leiva IM, et al. Clinical characteristics of chronic kidney disease of nontraditional causes in Salvadoran farming communities. MEDICC Rev. 2014 Apr;16(2):39-48.,2424. López-Marin L, Chavez Y, Garcia XA, Flores WM, Garcia YM, Herrera R, et al. Histopathology of chronic kidney disease of unknown etiology in Salvadoran agricultural communities. MEDICC Rev. 2014 Apr;16(2):49-54.]

Glomerular hyperfi ltration found in both sexes and both age groups in all the communities studied may refl ect adaptation of renal function when a given toxin, of whatever sort, functionally destroys a large number of nephrons. However, it may also result from low birth weight’s effect on total nephron mass, producing congenital oligonephropathy;[4848. Luyckx VA, Brenner BM. Low birth weight, nephron number, and kidney disease. Kidney Int Suppl. 2005 Aug;(97):S68-77.] i.e., decreased individual nephron endowment at birth, which increases susceptibility to CKD in adults.[4949. Brenner BM, Lawler EV, Mackenzie HS. The hyperfiltration theory: a paradigm shift in nephrology. Kidney Int. 1996 Jun;49(6):1774-7. 50. Brenner BM, Chertow GM. Congenital oligonephropathy: an inborn cause of adult hypertension and progressive renal injury? Curr Opin Nephrol Hypertens. 1993 Sep;2(5):691-5.5151. Lafferty HM, Brenner BM. Are glomerular hypertension and “hypertrophy” independent risk factors for progression of renal disease? Semin Nephrol. 1990 May;10(3):294-304.]

An important finding was that GFR began to decrease before age 13 years. The Nefrolempa study in adults found a monotonic decline in GFR throughout adult life, with worse renal function in men than in women, in all age groups.[55. Orantes CM, Herrera R, Almaguer M, Brizuela EG, Hernandez CE, Bayarre H, et al. Chronic kidney disease and associated risk factors in the Bajo Lempa region of El Salvador. Nefrolempa study, 2009. MEDICC Rev. 2011 Oct;13(4):14-22.] Notably, in our study the age group 13–17 years was the only one in which girls had worse renal function than boys. This could be a cohort effect, but more extensive research is needed to be able to explain the pattern and this exception.

No similar data are available from other farming communities with high prevalence of CKDnt to enable comparison of the magnitude and distribution of CKD in pediatric ages. We were unable to find any published CKD prevalence study in children, although some studies exist of CRF and end-stage renal disease prevalence. A study in Italy found a mean incidence of CRF (defined as creatinine clearance <75 mL/min/1.73 m2 of body surface area) of 12.1 cases per year per million of the age-related population, with a point prevalence of 74.7 cases per year per million individuals aged <20 years.[5252. Adissino G, Dacco V, Testa S, Bonaudo R, Claris-Appiani A, Taioli E, et al. Epidemiology of chronic renal failure in children. Data from the ItalKid project. Pediatrics. 2003 Apr;111(4 Pt 1):e382-7.] It should be borne in mind that this study used an earlier, less restrictive definition of CRF.[5353. National Kidney Foundation. K/DOQI clinical practice guidelines for chronic kidney disease, evaluation, classification and stratification. Am J Kidney Dis. 2002 Feb;39(2 Suppl 1):S1-266.] In Sweden, a study in children aged 6 months to 16 years found CRF (with GFR <30 mL/min/1.73 m2 of body surface area) incidence and prevalence of 7.7 and 21, respectively, per million children.[5454. Esbjörner E, Berg U, Hansson S. Epidemiology of chronic renal failure in children: a report from Sweden 1986-1994. Pediatr Nephrol. 1997 Aug;11(4):438-42.] The United States Renal Data System reports that among 31 countries, incidence of end-stage renal disease in children aged <20 years was the highest in Qatar (33.2 cases per million) while the highest prevalence was in the Basque Country (Spain) with 108 cases per million population.[3131. Chadha V, Warady BA. Epidemiology of pediatric chronic kidney disease. Adv Chronic Kidney Dis. 2005 Oct;12(4):343-52.] The CKF prevalence we found (0.1%) is about 10 times the highest prevalence found internationally.[3131. Chadha V, Warady BA. Epidemiology of pediatric chronic kidney disease. Adv Chronic Kidney Dis. 2005 Oct;12(4):343-52.] It is striking how debut and elevated prevalence of CKD at early ages mirrors prevalence in adulthood in these communities.

Among the limitations of this study, it should be noted that although the Schwartz formula[4141. Schwartz GJ, Brion LP, Spitzer A. The use of plasma creatinine concentration for estimating glomerular filtration rate in infants, children and adolescents. Pediatr Clin North Am. 1987 Jun;34(3):571-90.] we used to estimate GFR in the pediatric population is the most widely used in epidemiological studies, it was designed for the US population. It should be validated in the Salvadoran population for greater reliability, or a new formula developed to estimate kidney function in Salvadoran children. Also, there is an apparent contradiction between the finding of macroalbuminuria in a small percentage of children and failure to detect proteinuria with the reagent strips, which can be explained by the relative insensitivity of the strip used for proteinuria.[5555. Guh JY. Proteinuria versus albuminuria in chronic kidney disease. Nephrology (Carlton). 2010 Jun;15 Suppl 2:53-6.] Despite these limitations, the study is useful for estimating the magnitude of the problem and for generating research hypotheses.

The information obtained has been useful for planning programs to address the health care needs of the affected population. It was the basis for the prevention component in primary care launched by the Ministry of Health reform of 2009. Comprehensive care has been instituted in the regions studied. In Bajo Lempa, a community health team has been trained to provide prevention and treatment services. Methodological and practical lessons from this study have been extended to other areas and have facilitated new health screenings and interventions in other rural Salvadoran communities.

More in-depth studies are needed to establish causes of the disease and of the epidemic. These studies must consider environmental contamination by nephrotoxins as part of the explanation. For now, there is sufficient evidence of occurrence of CKD in childhood to justify clinical interventions in its early diagnosis, as well as timely treatment and rehabilitation. These actions can only be effective with an intersectoral approach that also addresses social determinants, especially those related to environmental control, best farming practices, labor conditions/occupational health and appropriate pesticide use.

CONCLUSIONS

Our results are consistent with the hypothesis that exposure to environmental toxins contributes to CKDnt in these Salvadoran communities, including children, drawing attention to the need for primary prevention starting at an early age.

REFERENCES

  • 1
    Trabanino RG, Aguilar R, Silva CR, Mercado MO, Merino RL. Nefropatia terminal en pacientes de un hospital de referencia en El Salvador. Rev Panam Salud Pùblica. 2002 Sep;12(3):202-6. Spanish.
  • 2
    Flores Reyna R, Jenkins Molieri JJ, Vega Manzano R, Chicas Labor A, Leiva Merino R, Calderón GR, et al. Enfermedad renal terminal: Hallazgos preliminares de un reciente estudio en el Salvador. San Salvador: Pan American Health Organization; 2003. Spanish.
  • 3
    Almaguer M, Herrera R, Orantes CM. Chronic kidney disease of unknown etiology in agricultural communities. MEDICC Rev. 2014 Apr;16(2):9-15.
  • 4
    Garcia-Trabanino R, Dominguez J, Jansa JM, Oliver A. Proteinuria e insuficiencia renal crónica en la costa de El Salvador: detección con métodos de bajo costo y factores asociados. Nefrologia. 2005;25(1):31-8. Spanish.
  • 5
    Orantes CM, Herrera R, Almaguer M, Brizuela EG, Hernandez CE, Bayarre H, et al. Chronic kidney disease and associated risk factors in the Bajo Lempa region of El Salvador. Nefrolempa study, 2009. MEDICC Rev. 2011 Oct;13(4):14-22.
  • 6
    Orantes CM, Herrera R, Almaguer M, Brizuela EG, Nûnez L, Alvarado NP, et al. Epidemiology of chronic kidney disease in adults of Salvadoran agricultural communities. MEDICC Rev. 2014 Apr;16(2):23-30.
  • 7
    Peraza S, Wfesseling C, Aragón A, Leiva R, Garcia-Trabanino RA, Torres C, et al. Decreased kidney function among agricultural workers in El Salvador. Am J Kidney Dis. 2012 Apr;59(4):531-40.
  • 8
    Torres C, Aragón A, Gonzalez M, López I, Jakobsson K, Elinder CG, et al. Decreased kidney function of unknown cause in Nicaragua: a community-based survey. Am J Kidney Dis. 2010 Mar;55(3):485-96.
  • 9
    O’Donell JK, Tobey M, Weiner DE, Stevens LA, Johnson S, Stringham P, et al. Prevalence of and risk factors for chronic kidney disease in rural Nicaragua. Nephrol Dial Transplant. 2011 Sep;26(9):2798-805.
  • 10
    Lebov JF, Valladares E, Pena R, Pena EM, Sanoff SL, Cisneros EC, et al. A population-based study of prevalence and risk factors of chronic kidney disease in León, Nicaragua. Can J Kidney Health Dis. 2015 Feb 24;2:6. DOI:http://dx.doi.org/10.1186/S40697-015-0041-1
    » http://dx.doi.org/10.1186/S40697-015-0041-1
  • 11
    Cerdas M. Chronic kidney disease in Costa Rica. Kidney Int Suppl [Internet]. 2005 Aug [cited 2014 Mar 21];(97):S31-3. Available from: http://www.kidney-international.org/article/S0085-2538 %2815%2951239-8/pdf
    » http://www.kidney-international.org/article/S0085-2538 %2815%2951239-8/pdf
  • 12
    Athuraliya NT, Abeysekera TD, Amerasinghe PH, Kumarasiri R, Bandara P, Karunaratne U, et al. Uncertain etiologies of proteinuric-chronic kidney disease in rural Sri Lanka. Kidney Int. 2011 Dec;80(11):1212-21.
  • 13
    Jayasumana C, Gunatilake S, Siribaddana S. Simultaneous exposure to multiple heavy metals and glyphosate may contribute to Sri Lankan agricultural nephropathy. BMC Nephrol. 2015 Jul 11;16:103. DOI: http://dx.doi.org/10.1186/s12882-015-0109-2
    » http://dx.doi.org/10.1186/s12882-015-0109-2
  • 14
    Chandrajith R, Nanayakkara S, Itai K, Aturaliya TN, Dissanayake CB, Abeysekera T, et al. Chronic kidney diseases of uncertain etiology (CKDu) in Sri Lanka: geographic distribution and environmental implications. Environ Geochem Health. 2011 Jun;33(3):267-78.
  • 15
    El-Minshawy O. End stage renal disease in El-Minia Governorate, Egypt: Data of the year 2007. Nephro-Urol Monthly. 2011 May;3(2):118-21.
  • 16
    Kamell EG, El-Minshawy O. Environmental factors incriminated in the development of end stage renal disease in El-Mina Governorate, Upper Egypt. Int J Nephrol Urol. 2010 Jan;2(3):431-7.
  • 17
    Rajapurkar MM, John GT, Kirpalani AL, Abraham G, Agarwal SK, Almeida AF, et al. What do we know about chronic kidney disease in India: first report of the Indian CKD registry. BMC Nephrol. 2012 Mar 6;13:10. DOI: http://dx.doi.org/10.1186/1471-2369-13-10
    » http://dx.doi.org/10.1186/1471-2369-13-10
  • 18
    Machiraju RS, Yaradi K, Gowrishankar S, Edwards KL, Attaluri S, Miller F, et al. Epidemiology of Udhanam Endemic Nephropathy. J Am Soc Nephrol. 2009;20:643A.
  • 19
    Silva LC, Ordûnez P. Chronic kidney disease in Central American agricultural communities: challenges for epidemiology and public health. MEDICC Rev. 2014 Apr;16(2):66-71.
  • 20
    Herrera R, Orantes CM, Almaguer M, Alfonso P, Bayarre HD, Leiva IM, et al. Clinical characteristics of chronic kidney disease of nontraditional causes in Salvadoran farming communities. MEDICC Rev. 2014 Apr;16(2):39-48.
  • 21
    Wesseling C, Crowe J, Hogstedt C, Jakobsson K, Lucas R, Wegman DH, et al. Resolving the enigma of the Mesoamerican nephropathy: a research workshop summary. Am J Kidney Dis. 2014 Mar;63(3):396-404.
  • 22
    Correa-Rotter R, Wesseling C, Johnson RJ. CKD of unknown origin in Central America: the case for a Mesoamerican nephropathy. Am J Kidney Dis. 2014 Mar;63(3):506-20.
  • 23
    Nanayakkara S, Komiya T, Ratnatunga N, Senevirathna ST, Harada KH, Hitomi T, et al. Tubulointerstitial damage as the major pathological lesion in endemic chronic kidney disease among farmers in North Central Province of Sri Lanka. Environ Health Prev Med. 2012 May;17(3):213-21.
  • 24
    López-Marin L, Chavez Y, Garcia XA, Flores WM, Garcia YM, Herrera R, et al. Histopathology of chronic kidney disease of unknown etiology in Salvadoran agricultural communities. MEDICC Rev. 2014 Apr;16(2):49-54.
  • 25
    Wijkström J, Leiva R, Elinder CG, Leiva S, Trujillo Z, Trujillo L, et al. Clinical and pathological characterization of Mesoamerican nephropathy: a new kidney disease in Central America. Am J Kidney Dis. 2013 Nov;62(5):908-18.
  • 26
    Orantes Navarro CM, Herrera Valdés R, López MA, Calero DJ, Fuentes de Morales J, Alvarado Ascencio NP, et al. Epidemiological characteristics of chronic kidney disease of non-traditional causes in women of agricultural communities of El Salvador. Clin Nephrol. 2015;83(7 Suppl 1):S24-31.
  • 27
    Herrera Valdés R, Orantes CM, Almaguer López M, López Marin L, Arévalo PA, Smith Gonzalez MJ, et al. Clinical characteristics of chronic kidney disease of non-traditional causes in women of agricultural communities in El Salvador. Clin Nephrol. 2015;83(7 Suppl 1):S56-63.
  • 28
    Brooks D, McClean M. Summary report: Boston University investigation of chronic kidney disease in Western Nicaragua. 2009-2012 [Internet]. Boston: Boston University School of Public Health; 2012 Aug [cited 2015 Oct 25]. 18 p. Available from: http://www.cao-ombudsman.org/documents/BU _SummaryReport_August122012.pdf
    » http://www.cao-ombudsman.org/documents/BU _SummaryReport_August122012.pdf
  • 29
    Ramirez-Rubio O, Amador JJ, Kaufman JS, Weiner DE, Parikh CR, Khan U, et al. Urine biomarkers of kidney injury among adolescents in Nicaragua, a region affected by an epidemic of chronic kidney disease of unknown aetiology. Nephrol Dial Transplant. 2015 Aug 25. DOI: http://dx.doi.org/10.1093/ndt/gfv292 Epub ahead of print 2015 Aug 25.
    » http://dx.doi.org/10.1093/ndt/gfv292
  • 30
    Levey AS, Coresh J. Chronic kidney disease. Lancet. 2012 Jan 14;379(9811):165-80.
  • 31
    Chadha V, Warady BA. Epidemiology of pediatric chronic kidney disease. Adv Chronic Kidney Dis. 2005 Oct;12(4):343-52.
  • 32
    Weidemann DK, Weaver VM, Fadrowski JJ. Toxic environmental exposures and kidney health in children. Pediatr Nephrol. 2015 Oct 12. DOI http://dx.doi.org/10.1007/s00467-015-3222-3 Epub ahead of print.
    » http://dx.doi.org/10.1007/s00467-015-3222-3
  • 33
    Solhaug MJ, Bolger PM, Jose PA. The developing kidney and environmental toxins. Pediatrics. 2004 Apr;113(4 Suppl):1084-91.
  • 34
    Silver MK, Shao J, Chen M, Xia Y, Lozoff B, Meeker JD. Distribution and predictors of pesticides in the umbilical cord blood of Chinese newborns. Int J Environ Res Public Health [Internet]. 2016 Jan [cited 2016 Mar 20];13(1):94. Available from: http://www.mdpi.com/1660-4601/13/1/94
    » http://www.mdpi.com/1660-4601/13/1/94
  • 35
    Hernandez W. Nacimiento y Desarrollo del rio Lempa [Internet]. San Salvador: SNET; 2005 [cited 2015 Oct 25]. 14 p. Available from: http://www.snet.gob.sv/Geologia/NacimientoEvolucionRLempa.pdf. Spanish.
    » http://www.snet.gob.sv/Geologia/NacimientoEvolucionRLempa.pdf.
  • 36
    Mejia R, Quinteros E, López A, Ribó A, Cedillos H, Orantes CM, et al. Pesticide-handling practices in agriculture in El Salvador: an example from 42 patient farmers with chronic kidney disease in the Bajo Lempa region. Occup Dis Environ Med. 2014 Aug 10;2(3):56-70.
  • 37
    López DL, Ribó A, Quinteros E, Mejia R, López A, Orantes C. Arsenic in soils, sediments, and water in an area with high prevalence for Chronic Kidney Disease of unknown etiology. In: Litter MI, Nicolli HB, Meichtry M, Quici N, Bundschuh J, Bhattacharya P, et al, editors. Proceedings of the 5th International Congress on Arsenic in the Environment, May 11-16, 2014, Buenos Aires, Argentina [Internet]. Buenos Aires: CRS Press; c2014 [cited 2016 Mar 25]. Chapter 86. p. 251-4. Available from: http://www.crcnetbase.com/doi/abs/10.1201/b16767-95
    » http://www.crcnetbase.com/doi/abs/10.1201/b16767-95
  • 38
    López A, Ribó A, Mejia R, Quinteros E, Alfaro D, Beltetón W, et al. Exposure to nephrotoxic pollutants in Las Brisas community (El Salvador). In: Ferreira da Silva E, Reis AP, Patinha C, Dias AC, Duräes N, Candeias C, et al, editors. Book of Abstracts of the 6th International Conference on Medical Geology. Aveiro (PT): UA Editora; 2015. 137 p. ISBN - 978-972-789-449-9.
  • 39
    Nomen R, Sempere J, Chavez F, de López NA, Rovira MD. Measurement of pollution levels of organochlorine and organophosphorus pesticides in water, soil, sediment, and shrimp to identify possible impacts on shrimp production at Jiquilisco Bay. Environ Sci Pollut Res Int. 2012 Sep;19(8):3547-55.
  • 40
    Hogg RJ, Furth S, Lemley KV, Portman R, Schwartz GJ, Coresh J, et al. National Kidney Foundation’s Kidney Disease Outcomes Quality Initiative Clinical Practice Guidelines for Chronic Kidney Disease in Children and Adolescents: Evaluation, Classification, and Stratification. Pediatrics. 2003 Jun;111(6 Pt 1):1416-21.
  • 41
    Schwartz GJ, Brion LP, Spitzer A. The use of plasma creatinine concentration for estimating glomerular filtration rate in infants, children and adolescents. Pediatr Clin North Am. 1987 Jun;34(3):571-90.
  • 42
    KDIGO 2012 Clinical Practice Guideline for the Evaluation and Management of Chronic Kidney Disease. Kidney International Supplements. 2013;3(1 Suppl):1-150.
  • 43
    Flores Vasquez FM. Estudio piloto de tamizaje para enfermedad renal en escolares asintomaticos en la población de la Escuela Santa Teresita en el municipio de Solola, Guatemala mayo 2012 [thesis]. [Ciudad de Guatemala]: University of San Carlos de Guatemala. Spanish.
  • 44
    Koshy SM, Garcia-Garcia G, Pamplona JS, Renoirte-López K, Pérez-Cortés G, Gutiérrez ML, et al. Screening for kidney disease in children on World Kidney Day in Jalisco, Mexico. Pediatr Nephrol. 2009 Jun;24(6):1219-25.
  • 45
    Karr CJ, Rauh VA. Pesticides. In: Landrigan Philip J, Etzel RA, editors. Textbook of Children’s Environmental Health. Oxford (US): Oxford University Press; 2014. p. 296-302.
  • 46
    United States Environmental Protection Agency, Office of Prevention, Pesticides and Toxic Substances. Protect yourself from pesticides: guide for pesticides handlers. Washington, D.C.: United States Environmental Protection Agency; 2006 Jun. 109 p.
  • 47
    Ministry of the Environment and Natural Resources (SV) [Internet]. San Salvador: Ministry of Environment and Natural Resources (SV); [updated 2011 Jan 3]. Las huellas del Toxafeno; 2010 Dec [cited 2013 Dec 12]. Available from: http://www.marn.gob.sv/index.php?option=com_content&view=artcle&catid=162:especiales&id=700:las-huellas-del-toxafeno. Spanish.
    » http://www.marn.gob.sv/index.php?option=com_content&view=artcle&catid=162:especiales&id=700:las-huellas-del-toxafeno.
  • 48
    Luyckx VA, Brenner BM. Low birth weight, nephron number, and kidney disease. Kidney Int Suppl. 2005 Aug;(97):S68-77.
  • 49
    Brenner BM, Lawler EV, Mackenzie HS. The hyperfiltration theory: a paradigm shift in nephrology. Kidney Int. 1996 Jun;49(6):1774-7.
  • 50
    Brenner BM, Chertow GM. Congenital oligonephropathy: an inborn cause of adult hypertension and progressive renal injury? Curr Opin Nephrol Hypertens. 1993 Sep;2(5):691-5.
  • 51
    Lafferty HM, Brenner BM. Are glomerular hypertension and “hypertrophy” independent risk factors for progression of renal disease? Semin Nephrol. 1990 May;10(3):294-304.
  • 52
    Adissino G, Dacco V, Testa S, Bonaudo R, Claris-Appiani A, Taioli E, et al. Epidemiology of chronic renal failure in children. Data from the ItalKid project. Pediatrics. 2003 Apr;111(4 Pt 1):e382-7.
  • 53
    National Kidney Foundation. K/DOQI clinical practice guidelines for chronic kidney disease, evaluation, classification and stratification. Am J Kidney Dis. 2002 Feb;39(2 Suppl 1):S1-266.
  • 54
    Esbjörner E, Berg U, Hansson S. Epidemiology of chronic renal failure in children: a report from Sweden 1986-1994. Pediatr Nephrol. 1997 Aug;11(4):438-42.
  • 55
    Guh JY. Proteinuria versus albuminuria in chronic kidney disease. Nephrology (Carlton). 2010 Jun;15 Suppl 2:53-6.

  • Disclosures: None

Publication Dates

  • Publication in this collection
    Jan-Apr 2016

History

  • Received
    31 Dec 2015
  • Accepted
    3 Apr 2016
Medical Education Cooperation with Cuba Oakland - California - United States
E-mail: editors@medicc.org