Serially assessed bisphenol A and phthalate exposure and association with kidney function in children with chronic kidney disease in the US and Canada: A longitudinal cohort study
Authors:
Melanie H. Jacobson aff001; Yinxiang Wu aff002; Mengling Liu aff002; Teresa M. Attina aff001; Mrudula Naidu aff001; Rajendiran Karthikraj aff004; Kurunthachalam Kannan aff001; Bradley A. Warady aff006; Susan Furth aff007; Suzanne Vento aff008; Howard Trachtman aff008; Leonardo Trasande aff001
Authors place of work:
Division of Environmental Pediatrics, Department of Pediatrics, NYU Langone Medical Center, New York, New York, United States of America
aff001; Department of Population Health, NYU Langone Medical Center, New York, New York, United States of America
aff002; Department of Environmental Medicine, NYU Langone Medical Center, New York, New York, United States of America
aff003; Wadsworth Center, New York State Department of Health, Albany, New York, United States of America
aff004; Department of Environmental Health Sciences, School of Public Health, State University of New York at Albany, Albany, New York, United States of America
aff005; Division of Nephrology, Department of Pediatrics, Children’s Mercy Kansas City, Kansas City, Missouri, United States of America
aff006; Division of Nephrology, Department of Pediatrics, Children’s Hospital of Philadelphia, Philadelphia, Pennsylvania, United States of America
aff007; Division of Nephrology, Department of Pediatrics, NYU Langone Medical Center, New York, New York, United States of America
aff008; Wagner Graduate School of Public Service, New York University, New York, New York, United States of America
aff009; School of Global Public Health, New York University, New York, New York, United States of America
aff010
Published in the journal:
Serially assessed bisphenol A and phthalate exposure and association with kidney function in children with chronic kidney disease in the US and Canada: A longitudinal cohort study. PLoS Med 17(10): e32767. doi:10.1371/journal.pmed.1003384
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pmed.1003384
Summary
Background
Exposure to environmental chemicals may be a modifiable risk factor for progression of chronic kidney disease (CKD). The purpose of this study was to examine the impact of serially assessed exposure to bisphenol A (BPA) and phthalates on measures of kidney function, tubular injury, and oxidative stress over time in a cohort of children with CKD.
Methods and findings
Samples were collected between 2005 and 2015 from 618 children and adolescents enrolled in the Chronic Kidney Disease in Children study, an observational cohort study of pediatric CKD patients from the US and Canada. Most study participants were male (63.8%) and white (58.3%), and participants had a median age of 11.0 years (interquartile range 7.6 to 14.6) at the baseline visit. In urine samples collected serially over an average of 3.0 years (standard deviation [SD] 1.6), concentrations of BPA, phthalic acid (PA), and phthalate metabolites were measured as well as biomarkers of tubular injury (kidney injury molecule-1 [KIM-1] and neutrophil gelatinase-associated lipocalin [NGAL]) and oxidative stress (8-hydroxy-2′-deoxyguanosine [8-OHdG] and F2-isoprostane). Clinical renal function measures included estimated glomerular filtration rate (eGFR), proteinuria, and blood pressure. Linear mixed models were fit to estimate the associations between urinary concentrations of 6 chemical exposure measures (i.e., BPA, PA, and 4 phthalate metabolite groups) and clinical renal outcomes and urinary concentrations of KIM-1, NGAL, 8-OHdG, and F2-isoprostane controlling for sex, age, race/ethnicity, glomerular status, birth weight, premature birth, angiotensin-converting enzyme inhibitor use, angiotensin receptor blocker use, BMI z-score for age and sex, and urinary creatinine. Urinary concentrations of BPA, PA, and phthalate metabolites were positively associated with urinary KIM-1, NGAL, 8-OHdG, and F2-isoprostane levels over time. For example, a 1-SD increase in ∑di-n-octyl phthalate metabolites was associated with increases in NGAL (β = 0.13 [95% CI: 0.05, 0.21], p = 0.001), KIM-1 (β = 0.30 [95% CI: 0.21, 0.40], p < 0.001), 8-OHdG (β = 0.10 [95% CI: 0.06, 0.13], p < 0.001), and F2-isoprostane (β = 0.13 [95% CI: 0.01, 0.25], p = 0.04) over time. BPA and phthalate metabolites were not associated with eGFR, proteinuria, or blood pressure, but PA was associated with lower eGFR over time. For a 1-SD increase in ln-transformed PA, there was an average decrease in eGFR of 0.38 ml/min/1.73 m2 (95% CI: −0.75, −0.01; p = 0.04). Limitations of this study included utilization of spot urine samples for exposure assessment of non-persistent compounds and lack of specific information on potential sources of exposure.
Conclusions
Although BPA and phthalate metabolites were not associated with clinical renal endpoints such as eGFR or proteinuria, there was a consistent pattern of increased tubular injury and oxidative stress over time, which have been shown to affect renal function in the long term. This raises concerns about the potential for clinically significant changes in renal function in relation to exposure to common environmental toxicants at current levels.
Keywords:
biomarkers – Renal system – kidneys – chronic kidney disease – oxidative stress – Metabolites – Phthalates – Urinary biomarkers
Introduction
Chronic kidney disease (CKD) is a growing health problem in children and adults [1]. In the United States between 2002 and 2016, there was a significant increase in disability-adjusted life years and mortality related to CKD, especially in young adults [2]. Furthermore, the incidence and prevalence of CKD among children has been steadily increasing since the 1980s [3–6]. CKD can progress to end-stage kidney disease (ESKD), which requires either renal replacement therapy (such as dialysis) or transplantation, which has significant impacts on morbidity, mortality, and healthcare costs [7–9].
There are a number of traditional risk factors associated with CKD progression to ESKD in children including hypertension, obesity, diabetes, and altered divalent mineral metabolism [3,10–12]. In addition, there is growing evidence suggesting that exposure to environmental chemicals may play a role as well [13]. For example, heavy metals such as lead and arsenic have been established as environmental nephrotoxins [14]. Furthermore, several recent studies have documented associations between other more common and low-level synthetic chemical exposures, such as bisphenol A (BPA) and phthalates, and kidney function [15–17]. These exposures have been hypothesized to affect kidney function through promotion of oxidative stress [18–24]. Because it has been shown that the kidney is vulnerable to environmental toxicants, especially prenatally and in early life [14,25], these exposures may be particularly relevant to pediatric CKD.
Surveys of healthy children and adults in the US indicate that exposure to BPA and phthalates is ubiquitous [26–28], and children are disproportionately exposed [29,30]. BPA is used in the manufacturing of polycarbonate plastics, medical devices, metal food can sealants, and thermal paper receipts [31,32], and phthalates are found in personal hygiene and cosmetic products [33,34], food packaging, medical devices (e.g., in polyvinyl chloride [PVC] intravenous tubing and in medications), and construction materials [35,36]. The often unavoidable sources of exposure beginning in childhood and adolescence may lead to a greater cumulative toxicological burden over a lifetime [37,38]. This may be exacerbated in children with CKD because a reduced glomerular filtration rate and impaired tubular secretion may compromise renal excretion of BPA and phthalates [39]. In addition, sources of exposure may be greater due to medication use and frequent contact with plastics in medical devices and tubing, including dialyzer materials [40,41].
We previously reported findings from a cross-sectional analysis of urinary BPA and phthalate levels in relation to kidney function in children and adolescents with CKD enrolled in the Chronic Kidney Disease in Children (CKiD) observational study [16,42]. Our results demonstrated lower urinary excretion of BPA and phthalates in children with CKD compared with the general healthy pediatric population. Urinary BPA levels were not significantly associated with any index of kidney function, but low molecular weight phthalates were associated with lower proteinuria and greater estimated glomerular filtration rate (eGFR). However, pharmacokinetic studies have shown that BPA and phthalates are rapidly metabolized and have half-lives of less than 24 hours in the human body [43–46]. Studies with serial urinary BPA measurements have identified correlation coefficients in the range of 0.22–0.57 over 1- to 6-month periods [47,48], which suggests that spot measurements at single time points may not be sufficient to characterize chronic exposure. Furthermore, any effects of BPA and phthalates on kidney function are likely to be cumulative. Therefore, a more complete investigation of the potential adverse effects of exposure to these compounds may require serial measures over time assessed in relation to the longitudinal course of kidney function.
In this study, we evaluated the associations between longitudinally measured urinary BPA and phthalates and the trajectory of renal function over a 5-year observation period using a variety of measures over time: eGFR, proteinuria, systolic and diastolic blood pressure (SBP and DBP, respectively), and urinary biomarkers of tubular injury: kidney injury molecule-1 (KIM-1) and neutrophil gelatinase-associated lipocalin (NGAL). In addition, in order to assess the plausibility of a potential mechanism of action, we examined the associations between longitudinally measured urinary BPA and phthalates and serially assessed urinary oxidative stress biomarkers: 8-hydroxy-2′-deoxyguanosine (8-OHdG) and F2-isoprostane.
Methods
A prospective analysis plan was followed and is provided in S1 Text. This study is reported as per the Strengthening the Reporting of Observational Studies in Epidemiology (STROBE) guideline (S1 STROBE Checklist).
Study population
The CKiD study is a multi-center prospective cohort study of children aged 6 months to 16 years with mild-to-moderate CKD with the overall goal of identifying predictors and sequelae of CKD progression. The CKiD study procedures and protocol have been previously described [42,49]. Briefly, pediatric patients with prevalent CKD were recruited at 57 clinical sites throughout the US and Canada, such as Boston, Massachusetts; Kansas City, Missouri; Seattle, Washington; and Winnipeg, Manitoba [42]. Children were enrolled, assessed 3–6 months after study entry (i.e., baseline), and every year thereafter. These annual data collection study visits were conducted until the initiation of renal replacement therapy for treatment of ESKD. Annual study visits included a physical examination conducted by study staff, biological specimen collection (e.g., urine samples; specimens were stored in a biorepository for future use in ancillary studies), standardized blood pressure measurement, and questionnaire administration. Biological specimens used in this study were collected between July 21, 2005, and November 12, 2015, and were stored at −80 ºC in a central biorepository until being used for exposure and outcome assessment.
Ethics statement
The institutional review board at each CKiD study site approved the study protocol, and all research was performed in accordance with established guidelines. Written informed consent was obtained from all parents or legal guardians, and assent from all participants depending on their age and institutional guidelines. The New York University School of Medicine Institutional Review Board deemed this project exempt from review due to data collection being complete and the dataset de-identified.
Exposure measures
Longitudinally collected and stored urine samples were used for exposure assessment. Phthalic acid (PA), 21 individual phthalate metabolites, BPA, and creatinine were analyzed at the Wadsworth Center, New York State Department of Health, Albany, NY. Details on the analytic methods for the phthalates and BPA have been previously described [16]. Briefly, urine samples were processed using enzymatic deconjugation and extracted, and analysis was performed with high-performance liquid chromatography coupled with electrospray tandem mass spectrometry under negative mode of ionization.
For all exposures, measures below the limit of detection (LOD) were imputed by the LOD divided by the square root of 2 [50]. For statistical analyses, phthalates were analyzed in groups as micromolar sums of metabolites corresponding to their use in product categories: ∑di(2-ethylhexyl) phthalate (DEHP), ∑high molecular weight (HMW) phthalates (comprising metabolites ≥ 250 Da), ∑low molecular weight (LMW) phthalates (comprising metabolites < 250 Da), and ∑di-n-octyl phthalate (DOP). All calculations excluded metabolites that were detected in <50% of samples (i.e., mCHP, mOP, mIDP, mPeP, mIPrP, and mINP). Thus, sums were calculated with the following metabolites: ∑DEHP: mECPP, mEHHP, mEOHP, and mCMHP; ∑HMW phthalates: mCPP, mECPP, mEHHP, mEOHP, mBzP, mHxP, mHPP, mCMHP, mCHpP, mCIOP, and mCINP; ∑LMW phthalates: mMP, mEP, mBP, and mIBP; and ∑DOP: mCPP and mCHpP. BPA and PA were examined as individual exposures.
Outcomes
Renal function measures
Several correlates of renal function were examined over time. The primary outcome was eGFR, calculated using the modified Schwartz (i.e., bedside) equation [51]: eGFR (ml/min/1.73 m2) = 0.413 × height (cm)/serum creatinine.
Other outcome measures of interest included urinary protein-to-creatinine ratio (UPCR), SBP, and DBP. Analytical methods for these measures in the CKiD study have been previously described. All laboratory measures were conducted at the central CKiD laboratory (University of Rochester) [52,53]. Briefly, total urine protein was determined using an immunoturbidimetric assay, and UPCR was calculated as the ratio of total urinary protein concentration to urinary creatinine concentration (mg/dl:mg/dl). SBP and DBP were measured in the right arm by auscultation using an aneroid sphygmomanometer [54]. Three measurements at 30-second intervals were taken, and the average of the 3 readings was calculated. Blood pressure measures were standardized to z-scores according to the National High Blood Pressure Education Program Fourth Report [55].
Biomarkers of tubular injury
Two biomarkers of tubular injury were measured: kidney injury molecule-1 (KIM-1) and neutrophil gelatinase-associated lipocalin (NGAL). KIM-1 and NGAL were measured in urine samples at the New York University High Throughput Biology Laboratory. They were quantified by solid phase sandwich ELISAs using the Quantikine Human TIM-1 Immunoassay and Quantikine Human Lipocalin-2 Immunoassay, respectively (R&D Systems, Minneapolis, MN), according to the manufacturer protocol. All analyses were conducted in duplicate. Intra-assay coefficients of variation (CVs) ranged from 3.6% to 3.7% for KIM-1 and from 2.3% to 3.9% for NGAL. Inter-assay CVs ranged from 0.7% to 4.3% for KIM-1 and from 0.6% to 4.8% for NGAL. Measures below the LOD were imputed by the LOD divided by the square root of 2 [50].
Oxidative stress
Urine samples with sufficient volume were analyzed for 8-OHdG and F2-isoprostane at the New York University High Throughput Biology Laboratory (N = 2,465 samples, N = 618 individuals, and N = 1,287 samples, N = 522 individuals, respectively). 8-OHdG was quantified by competitive ELISA using the OxiSelect Oxidative DNA Damage ELISA (Cell Biolabs, San Diego, CA). Similarly, F2-isoprostane was measured with a competitive enzyme-linked immunoassay, the OxiSelect 8-iso-Prostaglandin F2α ELISA Kit (Cell Biolabs). All analyses were conducted in duplicate as directed by the manufacturer. Intra-assay CVs ranged from 4.6% to 11.1% for 8-OHdG and from 6.8% to 9.7% for F2-isoprostane. Inter-assay CVs ranged from 3.9% to 16.6% for 8-OHdG and from 14.2% to 15.9% for F2-isoprostane. Measures below the LOD were imputed by the LOD divided by the square root of 2 [50].
Statistical analysis
Participant characteristics were evaluated over time. Counts and percentages were calculated for categorical variables, and means and standard deviations (SDs) (or medians and interquartile ranges [IQRs], as appropriate) are presented for continuous variables. Distributions of all environmental exposures, renal outcomes, and biomarkers of tubular injury and oxidative stress were examined by study visit over time. Due to the right-skewed distributions of all urinary biomarkers of environmental exposures, they were natural-log-transformed in order to reduce the influence of extreme outliers. Biomarkers of tubular injury, KIM-1 and NGAL; oxidative stress biomarkers, 8-OHdG and F2-isoprostane; and UPCR were also natural-log-transformed before multivariable analysis in order to better approximate a normal distribution.
In order to estimate the longitudinal associations between serially assessed BPA and phthalate measures and the longitudinal course of the outcomes of interest (i.e., eGFR, UPCR, SBP, DBP, KIM-1, NGAL, 8-OHdG, and F2-isoprostane), separate linear mixed-effects (LME) models were fit for each exposure–outcome combination. Random intercepts were included to account for cross-subject heterogeneity and within-individual correlation. In addition, based on both graphic assessments of between-visit correlations of the outcomes and a likelihood ratio test, a first-order autoregressive (AR(1)) covariance structure was applied in order to model the correlation pattern over time.
For each outcome, we first fit a LME model with log-transformed exposure variable, time (i.e., months from the baseline assessment), and a quadratic term for time included as main fixed effects, as well as baseline covariates hypothesized to act as confounders and/or key predictors of the outcome based on previous literature [16,17,42,56]. These included sex, age, race/ethnicity, glomerular status, birth weight, premature birth, angiotensin-converting enzyme inhibitor (ACEI) use, angiotensin receptor blocker (ARB) use, BMI z-score for age and sex, and time-dependent log-transformed creatinine. Models were fit with chemical exposures expressed on a volume basis (ng/ml or nmol/ml), and creatinine was controlled for as a covariate instead of indexing the exposure measures by creatinine (ng/mg Cr or nmol/mg Cr), in order to separate any impacts of the chemicals and creatinine [57], and because the same urinary creatinine measure was included in one of the primary outcomes of interest (i.e., UPCR), which could induce a spurious correlation due to urinary creatinine associations rather than chemical exposure associations [39]. In models for eGFR, UPCR, KIM-1, NGAL, 8-OHdG, and F2-isoprostane, SBP z-score was additionally controlled for. In all models, the log-transformed exposure variables were standardized so that the estimates represented the average change in the outcome in response to a 1-SD change in the log-transformed exposure.
From these models, if there was a statistically significant (p < 0.05) estimate for the main effect of the exposure variable, we further examined the potential for an interaction between the exposure variable (centered with mean = 0) and time. In subsequent models, interaction cross-product terms between each exposure and time (both linear and quadratic terms) were included, and time-specific estimates of exposure were output and plotted by linear contrasts from the fitted models. Details of the modeling strategy are provided in S1 Fig.
Finally, we conducted sensitivity analyses. First, we evaluated the potential for associations of the outcomes with cumulative levels of BPA and phthalate metabolites over time. The cumulative average over time was calculated as the average of the log-transformed measures up until each visit time (i.e., cumulative average). These measures were then fitted using the same LME modeling strategy as described above. Second, we examined whether controlling for year of study enrollment affected the measures of association.
Analyses were performed using complete case analysis. All analyses were conducted in R version 3.5.0 for Windows [58], using the package “nlme” [59] version 3.1–137 for LME models.
Results
The analytic sample included 618 participants, contributing 2,469 total visits (mean number of visits ± SD: 4.0 ± 1.6), representing 1,839.3 total person-years of observation (3.0 ± 1.6 years per patient). Most study participants were male (63.8%) and white (58.3%), and participants had a median age of 11.0 years (IQR = 7.6 to 14.6) at the baseline visit (Table 1). The majority (89.2% overall and 88.3% at baseline) of the patients had non-glomerular disease. At baseline, kidney function was moderately impaired, with an average eGFR of 51.9 ml/min/1.73 m2 (standard deviation = 19.8) and most participants (60.4%) having stage G3a CKD or better (≥45 ml/min/1.73 m2). At baseline, participants had on average slightly above average body mass index (BMI) (mean ± SD z-score adjusted for age and sex: 0.4 ± 1.2) and SBP (mean ± SD z-score adjusted for age, sex, and height: 0.3 ± 1.1), which both generally decreased over the course of follow-up.
BPA was detected in 78.3% of samples (Table 2). PA was detected in 99.1% of samples, and detection frequencies for the individual phthalate metabolites included in the group sums ranged from 50% to 100%. The distributions of urinary BPA and phthalates were right-skewed, with the 95th percentile typically being an order of magnitude greater than the median level. Urinary concentrations of exposures had a substantial degree of within-individual variability over time, with intraclass correlation coefficients ranging from 0.12 for ∑DOP to 0.39 for ∑LMW phthalates (S1 Table). Over the course of the study enrollment period (i.e., 2005–2015), chemical exposure concentrations decreased over time, although within-individual concentrations of some chemicals remained steady or increased slightly over follow-up (S2 Table).
In multivariable LME models, urinary concentrations of BPA and phthalate metabolite groups were not associated with eGFR, UPCR, SBP, or DBP (Table 3). However, PA was associated with lower eGFR over time. For a 1-SD increase in ln-transformed PA, we estimated an average decrease in eGFR of 0.38 ml/min/1.73 m2 (95% CI: −0.75, −0.01). PA was not associated with UPCR, SBP, or DBP.
In contrast to the findings for clinical renal outcomes, urinary concentrations of BPA, PA, and phthalate metabolite groups were associated with increased NGAL and KIM-1 over time (Table 4). For example, a 1-SD increase in ln-transformed BPA was associated with a 9.0% increase in NGAL (95% CI: 1.4%, 17.2%) and 11.7% increase in KIM-1 (95% CI: 5.6%, 18.2%) (calculated from Table 4 by computing eβ). The associations of PA, ∑HMW phthalates, and ∑DOP with KIM-1 varied over time and are shown in Fig 1. PA and ∑HMW phthalates were positively associated with KIM-1 and increased in magnitude through 3 years, but associations attenuated at year 4 and were null by year 5 (Fig 1; S3 Table). In contrast, the association of KIM-1 with ∑DOP was strongest at baseline and attenuated over time. Associations with NGAL were all positive and did not vary over time.
In sensitivity analyses, chemical exposures were considered cumulatively over time as time-weighted averages (S5–S9 Tables). Results were largely consistent, although the association between PA and eGFR was no longer statistically significant (β = −0.31; 95% CI: −0.92, 0.30), and there was a significant positive association between ∑LMW phthalates and eGFR (β = 1.56; 95% CI: 0.66, 2.47) (S4 Table). In addition, positive associations remained between chemical exposures and NGAL and KIM-1 (S6 and S7 Tables) and between chemical exposures and 8-OHdG and F2-isoprostane (S8 and S9 Tables). Model fit diagnostics were similar comparing these models with the primary analyses. Finally, additionally controlling for calendar year of study enrollment did not measurably change the results of the primary analysis.
Discussion
In this longitudinal study of 618 children with CKD, urinary concentrations of BPA and phthalate metabolites were not associated with eGFR, UPCR, SBP, and DBP, but PA was inversely associated with eGFR. Despite the general paucity of associations with clinically relevant renal outcomes, urinary concentrations of chemical exposures were robustly associated with biomarkers of tubular injury, NGAL and KIM-1. Specifically, serially assessed urinary concentrations of BPA, PA, and phthalate metabolites were associated with increased NGAL and KIM-1 concentrations over time. Similarly, chemical exposure concentrations were associated with increases in oxidative stress biomarkers, 8-OHdG and F2-isoprostane, which suggests a potential mechanism of action through which these chemical exposures may impart renal injury. These observations were consistent when chemical exposures were considered cumulatively over time.
Our findings highlight the importance of considering environmental exposures as potentially modifiable risk factors for renal function decline and CKD progression. Although we did not detect associations of chemical exposures with clinical renal outcomes (i.e., eGFR), we report robust and consistent positive associations with biomarkers of tubular injury, NGAL and KIM-1. Although we observed some differences in these associations across time, these were mostly in magnitude and not direction, and the positive correlations between chemical exposures and NGAL and KIM-1 largely persisted. For example, the positive association of PA and ∑HMW phthalates with KIM-1 attenuated at 4 years of follow-up and was null at year 5, likely due to sparse counts in the later years of follow-up. These findings are novel and have important implications for long-term renal function. Several studies have documented NGAL and/or KIM-1 as early prognostic biomarkers of CKD and/or CKD progression [60–65], and one study identified KIM-1 as a cause of eGFR decline [61]. It is possible that we did not detect associations with clinical renal outcomes such as eGFR in this study because of the modest duration of follow-up, the relatively well-preserved eGFR over time, and the slow pace of progression of disease in children with CKD of tubular origin (i.e., congenital anomalies of the kidney and urinary tract). In addition, the incremental harm induced by environmental chemicals may be below the level of clinical detection, given the already existing underlying kidney disease of study participants, whereas subclinical impacts on tubular injury biomarkers may have been an easier signal to identify. This proposal is supported by our findings of increased oxidative stress in relation to BPA and phthalates. Given the literature supporting strong associations between both tubular injury and oxidative stress biomarkers and CKD progression and/or renal function, the observed changes in NGAL and KIM-1 and 8-OHdG and F2-isoprostane in relation to BPA and phthalates raise concerns about the potential for clinically significant alterations in chronic kidney function to emerge in the long term.
The current analysis complements our previous work in which we analyzed the cross-sectional relationships between baseline levels of BPA and phthalates and kidney function measures at CKiD enrollment [16]. That study found that ∑LMW phthalates were associated with lower proteinuria and greater eGFR, which suggests a more favorable renal profile. In contrast, another recent study among hypertensive adults examined serum BPA in relation to CKD progression and found that baseline BPA levels were associated with decrements in eGFR over time [66]. In the current longitudinal investigation, we did not find any significant associations between urinary BPA and phthalates and clinical renal outcomes, except for an association between PA and lower eGFR over time. These disparate findings, and the addition of the findings for biomarkers of tubular injury, underscore the importance of incorporating both baseline and serial assessments of exposure to short-lived organic environmental chemicals to clarify the long-term effects of these exposures on kidney function.
BPA and phthalates have consistently been shown to be related to increased oxidative stress. Both oxidative DNA damage and lipid peroxidation have been documented in association with exposure to these chemicals in diverse populations, such as adolescents and pregnant and postmenopausal women [22,23,67–69]. Toxicological studies support these associations [18–20,70–72]. This study, conducted among children with CKD, found similar results. Taken in conjunction with our results that showed links between BPA and phthalates and markers of tubular injury, as well as the other studies that have documented associations between BPA and phthalates and deterioration in other measures of renal function [15,16,73–75], this study provides preliminary evidence for oxidative stress as a potential biological pathway for environmental chemicals to influence kidney function.
This study benefited from several strengths. First, the longitudinal study design allowed us to examine chemical exposures, renal function, and biomarkers of tubular injury and oxidative stress over time. This was particularly important in this study of non-persistent chemical exposures. These chemicals have been shown to be metabolized rapidly in the human body, with half-lives ranging from 3 to 16 hours [43,44,46], and thus exhibit substantial intra-individual variability in spot urine samples [76,77]. Furthermore, we employed a time-averaged statistical approach, which allowed us to evaluate whether there were any associations with cumulative levels of these exposures over time. Second, we measured several chemical exposures, as well as diverse biomarkers of both tubular injury and oxidative stress, which complemented the clinical data we had on renal function. The measures of tubular injury, NGAL and KIM-1, were of paramount importance, in light of the lack of impact of the exposures on the clinically relevant renal endpoints. In addition, measuring both NGAL and KIM-1 was important because NGAL, normally present in the kidney but rapidly upregulated in response to renal injury, represents damage specifically to the distal tubule [78], while KIM-1, a type I cell membrane glycoprotein that is typically undetectable in the healthy kidney but is synthesized rapidly following acute kidney injury, represents damage to the proximal tubule [79]. With regard to oxidative stress, we had measures of both DNA damage (i.e., 8-OHdG) [80] and lipid peroxidation (i.e., F2-isoprostane) [81], which allowed us to gain a more comprehensive picture of the chemical influences on different types of oxidative damage. Lastly, we were able to examine a unique cohort of children with CKD from across the US and Canada that had detailed longitudinal clinical information, including eGFR and UPCR.
However, there were some limitations. Spot urine samples were used for exposure assessment, and BPA and phthalates, the targets of interest in this study, are non-persistent and rapidly metabolized in the body. Indeed, the exposures in this study had a large degree of within-person variability and poor reliability over time, which is similar to other studies of BPA and phthalates [47,77]. However, our longitudinal design and cumulative average exposure approach attempted to ameliorate this issue and represent an improvement over previous studies. Furthermore, measuring urinary analytes among those with kidney dysfunction is complex because the kidneys are responsible for filtering bodily waste products that are ultimately excreted [39]. If that process is impaired, the concentration of analytes in urine may in turn be affected. Since the exposures and many of the outcomes of interest in this study were measured in the urine, this could potentially impact study results. Another potential limitation is that we did not have information on the sources of environmental exposure, which could help translate these findings into actionable prevention efforts. We measured exposure to each of the chemicals by using biomarkers, which represent not only exposures from multiple sources, but also differences in metabolism of these exposures. For example, phthalate exposure could result from food packaging, personal care products, and medical devices or pharmaceuticals; the last of these likely has increased importance in this population of children with CKD [33–36]. In addition, if we had had information on potential sources of exposure, we could have evaluated whether the amount excreted in urine was correlated with estimated exposure dose, a particular concern among those with kidney disease or impaired excretory capacity. Another limitation was that even though we had longitudinal data over time, our sample size was not large. Lastly, as is the case with all observational studies, our study may have been vulnerable to unmeasured confounding.
In conclusion, in a longitudinal study among children with CKD, we documented consistent and robust associations between serially assessed urinary concentrations of common environmental toxicants, BPA and phthalates, and increased urinary levels of NGAL and KIM-1 over time, reflecting tubular injury in the kidney. However, it is important to note that we did not detect consistent associations between these chemicals and the longitudinal trajectory of clinically relevant renal outcomes, including eGFR, proteinuria, and blood pressure. Finally, we found that BPA and phthalates were associated with increased oxidative stress, which provides a potential pathway through which these chemical exposures may induce damage to the kidney. This detected signal of increased tubular injury and oxidative stress in relation to environmental exposures at current levels raises concern about the potential for clinically relevant changes to renal function to develop over time. Given that this study was conducted among children, these findings highlight the importance of considering environmental exposures in the context of CKD management before clinical changes are observed. Furthermore, attention to the impact of exposure to environmental chemicals on the course of CKD in children is important because it is a potentially modifiable risk factor.
Supporting information
S1 STROBE Checklist [doc]
STROBE, Strengthening the Reporting of Observational Studies in Epidemiology.
S1 Fig [docx]
Modeling strategy for linear mixed-effects models with random intercept and AR(1) error term.
S1 Table [docx]
Intraclass correlation coefficients (ICCs) and 95% confidence intervals (CIs) for ln-transformed chemical exposures and outcomes over time.
S2 Table [docx]
Associations between calendar year and urinary chemical concentrations over time from linear mixed-effects models.
S3 Table [docx]
Time-specific estimates for the associations between ln-transformed chemical exposures and ln-transformed tubular injury biomarkers from linear mixed-effects models as shown in .
S4 Table [docx]
Time-specific estimates for the associations between ln-transformed chemical exposures and ln-transformed oxidative stress biomarkers from linear mixed-effects models as shown in .
S5 Table [docx]
Associations between cumulative average ln-transformed chemical exposures and eGFR, ln-transformed urinary protein-to-creatinine ratio, SBP score, and DBP score from linear mixed-effects models.
S6 Table [docx]
Associations between cumulative average ln-transformed chemical exposures and ln-transformed kidney injury biomarkers from linear mixed-effects models.
S7 Table [docx]
Time-specific estimates for associations between cumulative average ln-transformed chemical exposures and ln-transformed biomarkers of tubular injury from linear mixed-effects models.
S8 Table [docx]
Associations between cumulative average ln-transformed chemical exposures and ln-transformed oxidative stress biomarkers from linear mixed-effects models.
S9 Table [docx]
Time-specific estimates for associations between cumulative average ln-transformed chemical exposures and ln-transformed oxidative stress biomarkers from linear mixed-effects models.
S1 Text [docx]
Analysis plan.
Zdroje
1. KDIGO 2012 clinical practice guideline for the evaluation and management of chronic kidney disease. Chapter 1: definition and classification of CKD. Kidney Int Suppl. 2013;3(1):19–62. doi: 10.1038/kisup.2012.64 25018975
2. Bowe B, Xie Y, Li T, Mokdad AH, Xian H, Yan Y, et al. Changes in the US burden of chronic kidney disease from 2002 to 2016: an analysis of the Global Burden of Disease Study. JAMA Netw Open. 2018;1(7):e184412. doi: 10.1001/jamanetworkopen.2018.4412 30646390
3. Harambat J, van Stralen KJ, Kim JJ, Tizard EJ. Epidemiology of chronic kidney disease in children. Pediatr Nephrol. 2012;27(3):363–73. doi: 10.1007/s00467-011-1939-1 21713524
4. Baum M. Overview of chronic kidney disease in children. Curr Opin Pediatr. 2010;22(2):158–60. doi: 10.1097/MOP.0b013e32833695cb 20299869
5. United States Renal Data System. 2013 USRDS annual data report: atlas of chronic kidney disease and end-stage renal disease in the United States. Bethesda: National Institutes of Health National Institute of Diabetes and Digestive and Kidney Diseases; 2013.
6. Becherucci F, Roperto RM, Materassi M, Romagnani P. Chronic kidney disease in children. Clin Kidney J. 2016;9(4):583–91. doi: 10.1093/ckj/sfw047 27478602
7. Groothoff JW. Long-term outcomes of children with end-stage renal disease. Pediatr Nephrol. 2005;20(7):849–53. doi: 10.1007/s00467-005-1878-9 15834618
8. Ferris ME, Gipson DS, Kimmel PL, Eggers PW. Trends in treatment and outcomes of survival of adolescents initiating end-stage renal disease care in the United States of America. Pediatr Nephrol. 2006;21(7):1020–6. doi: 10.1007/s00467-006-0059-9
9. Mitsnefes MM, Laskin BL, Dahhou M, Zhang X, Foster BJ. Mortality risk among children initially treated with dialysis for end-stage kidney disease, 1990–2010. JAMA. 2013;309(18):1921–9. doi: 10.1001/jama.2013.4208 23645144
10. Wong H, Mylrea K, Feber J, Drukker A, Filler G. Prevalence of complications in children with chronic kidney disease according to KDOQI. Kidney Int. 2006;70(3):585–90. doi: 10.1038/sj.ki.5001608 16788689
11. Staples AO, Greenbaum LA, Smith JM, Gipson DS, Filler G, Warady BA, et al. Association between clinical risk factors and progression of chronic kidney disease in children. Clin J Am Soc Nephrol. 2010;5(12):2172–9. doi: 10.2215/CJN.07851109 20813855
12. Warady BA, Abraham AG, Schwartz GJ, Wong CS, Munoz A, Betoko A, et al. Predictors of rapid progression of glomerular and nonglomerular kidney disease in children and adolescents: the Chronic Kidney Disease in Children (CKiD) cohort. Am J Kidney Dis. 2015;65(6):878–88. doi: 10.1053/j.ajkd.2015.01.008 25799137
13. Sullivan JB, Krieger GR. Clinical environmental health and toxic exposures. Philadelphia: Lippincott Williams & Wilkins; 2001.
14. Weidemann DK, Weaver VM, Fadrowski JJ. Toxic environmental exposures and kidney health in children. Pediatr Nephrol. 2016;31(11):2043–54. doi: 10.1007/s00467-015-3222-3 26458883
15. Trasande L, Attina TM, Trachtman H. Bisphenol A exposure is associated with low-grade urinary albumin excretion in children of the United States. Kidney Int. 2013;83(4):741–8. doi: 10.1038/ki.2012.422 23302717
16. Malits J, Attina TM, Karthikraj R, Kannan K, Naidu M, Furth S, et al. Renal function and exposure to Bisphenol A and phthalates in children with chronic kidney disease. Environ Res. 2018;167:575–82. doi: 10.1016/j.envres.2018.08.006 30172191
17. Kataria A, Trasande L, Trachtman H. The effects of environmental chemicals on renal function. Nat Rev Nephrol. 2015;11:610. doi: 10.1038/nrneph.2015.94 26100504
18. Bindhumol V, Chitra KC, Mathur PP. Bisphenol A induces reactive oxygen species generation in the liver of male rats. Toxicology. 2003;188(2):117–24. doi: 10.1016/S0300-483X(03)00056-8
19. Chitra KC, Latchoumycandane C, Mathur PP. Induction of oxidative stress by bisphenol A in the epididymal sperm of rats. Toxicology. 2003;185(1):119–27. doi: 10.1016/S0300-483X(02)00597-8
20. Wu M, Xu H, Shen Y, Qiu W, Yang M. Oxidative stress in zebrafish embryos induced by short-term exposure to bisphenol A, nonylphenol, and their mixture. Environm Toxicol Chem. 2011;30(10):2335–41. doi: 10.1002/etc.634 21805498
21. Hong Y-C, Park E-Y, Park M-S, Ko JA, Oh S-Y, Kim H, et al. Community level exposure to chemicals and oxidative stress in adult population. Toxicol Lett. 2009;184(2):139–44. doi: 10.1016/j.toxlet.2008.11.001 19049859
22. Ferguson KK, Cantonwine DE, McElrath TF, Mukherjee B, Meeker JD. Repeated measures analysis of associations between urinary bisphenol-A concentrations and biomarkers of inflammation and oxidative stress in pregnancy. Reprod Toxicol. 2016;66:93–8. doi: 10.1016/j.reprotox.2016.10.002 27751756
23. Ferguson KK, Cantonwine DE, Rivera-González LO, Loch-Caruso R, Mukherjee B, Anzalota Del Toro LV, et al. Urinary phthalate metabolite associations with biomarkers of inflammation and oxidative stress across pregnancy in Puerto Rico. Environ Sci Technol. 2014;48(12):7018–25. doi: 10.1021/es502076j 24845688
24. Li AJ, Martinez-Moral M-P, Al-Malki AL, Al-Ghamdi MA, Al-Bazi MM, Kumosani TA, et al. Mediation analysis for the relationship between urinary phthalate metabolites and type 2 diabetes via oxidative stress in a population in Jeddah, Saudi Arabia. Environ Int. 2019;126:153–61. doi: 10.1016/j.envint.2019.01.082 30798196
25. Zheng LY, Sanders AP, Saland JM, Wright RO, Arora M. Environmental exposures and pediatric kidney function and disease: a systematic review. Environ Res. 2017;158:625–48. doi: 10.1016/j.envres.2017.06.029 28727988
26. Ji K, Kho YL, Park Y, Choi K. Influence of a five-day vegetarian diet on urinary levels of antibiotics and phthalate metabolites: a pilot study with “Temple Stay” participants. Environ Res. 2010;110(4):375–82. doi: 10.1016/j.envres.2010.02.008 20227070
27. Martina CA, Weiss B, Swan SH. Lifestyle behaviors associated with exposures to endocrine disruptors. Neurotoxicology. 2012;33(6):1427–33. doi: 10.1016/j.neuro.2012.05.016 22739065
28. Colacino JA, Harris TR, Schecter A. Dietary intake is associated with phthalate body burden in a nationally representative sample. Environ Health Perspect. 2010;118(7):998–1003. doi: 10.1289/ehp.0901712 20392686
29. Calafat AM, Ye X, Wong L-Y, Reidy JA, Needham LL. Exposure of the US population to bisphenol A and 4-tertiary-octylphenol: 2003–2004. Environ Health Perspect. 2007;116(1):39–44.
30. Becker K, Goen T, Seiwert M, Conrad A, Pick-Fuss H, Muller J, et al. GerES IV: phthalate metabolites and bisphenol A in urine of German children. Int J Hyg Environ Health. 2009;212(6):685–92. doi: 10.1016/j.ijheh.2009.08.002 19729343
31. Hehn RS. NHANES data support link between handling of thermal paper receipts and increased urinary bisphenol A excretion. Environ Sci Technol. 2016;50(1):397–404. doi: 10.1021/acs.est.5b04059 26583963
32. Schecter A, Malik N, Haffner D, Smith S, Harris TR, Paepke O, et al. Bisphenol A (BPA) in U.S. food. Environ Sci Technol. 2010;44(24):9425–30. doi: 10.1021/es102785d 21038926
33. Schettler T, Skakkebæk NE, De Kretser D, Leffers H. Human exposure to phthalates via consumer products. Int J Androl. 2006;29(1):134–9. doi: 10.1111/j.1365-2605.2005.00567.x 16466533
34. Becker K, Seiwert M, Angerer J, Heger W, Koch HM, Nagorka R, et al. DEHP metabolites in urine of children and DEHP in house dust. Int J Hyg Environ Health. 2004;207(5):409–17. doi: 10.1078/1438-4639-00309 15575555
35. Wormuth M, Scheringer M, Vollenweider M, Hungerbühler K. What are the sources of exposure to eight frequently used phthalic acid esters in Europeans? Risk Anal. 2006;26(3):803–24. doi: 10.1111/j.1539-6924.2006.00770.x 16834635
36. Fromme H, Gruber L, Schlummer M, Wolz G, Böhmer S, Angerer J, et al. Intake of phthalates and di(2-ethylhexyl)adipate: results of the integrated exposure assessment survey based on duplicate diet samples and biomonitoring data. Environ Int. 2007;33(8):1012–20. doi: 10.1016/j.envint.2007.05.006 17610953
37. Von Goetz N, Wormuth M, Scheringer M, Hungerbühler K. Bisphenol A: how the most relevant exposure sources contribute to total consumer exposure. Risk Anal. 2010;30(3):473–87. doi: 10.1111/j.1539-6924.2009.01345.x 20136739
38. Wilson NK, Chuang JC, Morgan MK, Lordo RA, Sheldon LS. An observational study of the potential exposures of preschool children to pentachlorophenol, bisphenol-A, and nonylphenol at home and daycare. Environ Res. 2007;103(1):9–20. doi: 10.1016/j.envres.2006.04.006 16750524
39. Weaver VM, Kotchmar DJ, Fadrowski JJ, Silbergeld EK. Challenges for environmental epidemiology research: are biomarker concentrations altered by kidney function or urine concentration adjustment? J Expo Sci Environ Epidemiol. 2016;26(1):1–8. doi: 10.1038/jes.2015.8 25736163
40. Krieter DH, Canaud B, Lemke H-D, Rodriguez A, Morgenroth A, von Appen K, et al. Bisphenol A in chronic kidney disease. Artif Organs. 2013;37(3):283–90. doi: 10.1111/j.1525-1594.2012.01556.x 23145999
41. González-Parra E, Herrero JA, Elewa U, Bosch RJ, Arduán AO, Egido J. Bisphenol a in chronic kidney disease. Int J Nephrol. 2013;2013:437857. doi: 10.1155/2013/437857 23997953
42. Furth SL, Cole SR, Moxey-Mims M, Kaskel F, Mak R, Schwartz G, et al. Design and methods of the Chronic Kidney Disease in Children (CKiD) prospective cohort study. Clin J Am Soc Nephrol. 2006;1(5):1006–15. doi: 10.2215/CJN.01941205 17699320
43. Koch HM, Angerer J. Di-iso-nonylphthalate (DINP) metabolites in human urine after a single oral dose of deuterium-labelled DINP. Int J Hyg Environ Health. 2007;210(1):9–19. doi: 10.1016/j.ijheh.2006.11.008 17182279
44. Koch HM, Preuss R, Angerer J. Di(2-ethylhexyl)phthalate (DEHP): human metabolism and internal exposure—an update and latest results. Int J Androl. 2006;29(1):155–65. doi: 10.1111/j.1365-2605.2005.00607.x 16466535
45. Hoppin JA, Brock JW, Davis BJ, Baird DD. Reproducibility of urinary phthalate metabolites in first morning urine samples. Environ Health Perspect. 2002;110(5):515–8. doi: 10.1289/ehp.02110515 12003755
46. Volkel W, Colnot T, Csanady GA, Filser JG, Dekant W. Metabolism and kinetics of bisphenol a in humans at low doses following oral administration. Chem Res Toxicol. 2002;15(10):1281–7. doi: 10.1021/tx025548t 12387626
47. Teitelbaum S, Britton J, Calafat A, Ye X, Silva M, Reidy J, et al. Temporal variability in urinary concentrations of phthalate metabolites, phytoestrogens and phenols among minority children in the United States. Environ Res. 2008;106(2):257–69. doi: 10.1016/j.envres.2007.09.010 17976571
48. Nepomnaschy PA, Baird DD, Weinberg CR, Hoppin JA, Longnecker MP, Wilcox AJ. Within-person variability in urinary bisphenol A concentrations: measurements from specimens after long-term frozen storage. Environ Res. 2009;109(6):734–7. doi: 10.1016/j.envres.2009.04.004 19463991
49. Furth SL, Abraham AG, Jerry-Fluker J, Schwartz GJ, Benfield M, Kaskel F, et al. Metabolic abnormalities, cardiovascular disease risk factors, and GFR decline in children with chronic kidney disease. Clin J Am Soc Nephrol. 2011;6(9):2132–40. doi: 10.2215/CJN.07100810 21841064
50. Hornung RW, Reed LD. Estimation of average concentration in the presence of nondetectable values. Appl Occup Environ Hyg. 1990;5(1):46–51.
51. Schwartz GJ, Munoz A, Schneider MF, Mak RH, Kaskel F, Warady BA, et al. New equations to estimate GFR in children with CKD. J Am Soc Nephrol. 2009;20(3):629–37. doi: 10.1681/ASN.2008030287 19158356
52. Wong CS, Pierce CB, Cole SR, Warady BA, Mak RH, Benador NM, et al. Association of proteinuria with race, cause of chronic kidney disease, and glomerular filtration rate in the chronic kidney disease in children study. Clin J Am Soc Nephrol. 2009;4(4):812–9. doi: 10.2215/CJN.01780408 19297612
53. Fuhrman DY, Schneider MF, Dell KM, Blydt-Hansen TD, Mak R, Saland JM, et al. Albuminuria, proteinuria, and renal disease progression in children with CKD. Clin J Am Soc Nephrol. 2017;12(6):912–20. doi: 10.2215/CJN.11971116 28546440
54. Flynn JT, Mitsnefes M, Pierce C, Cole SR, Parekh RS, Furth SL, et al. Blood pressure in children with chronic kidney disease: a report from the Chronic Kidney Disease in Children study. Hypertension. 2008;52(4):631–7. doi: 10.1161/HYPERTENSIONAHA.108.110635 18725579
55. National High Blood Pressure Education Program Working Group on High Blood Pressure in Children and Adolescents. The fourth report on the diagnosis, evaluation, and treatment of high blood pressure in children and adolescents. Pediatrics. 2004;114(2 Suppl 4th Report):555–76.
56. Kataria A, Levine D, Wertenteil S, Vento S, Xue J, Rajendiran K, et al. Exposure to bisphenols and phthalates and association with oxidant stress, insulin resistance, and endothelial dysfunction in children. Pediatr Res. 2017;81(6):857. doi: 10.1038/pr.2017.16 28099427
57. Barr DB, Wilder LC, Caudill SP, Gonzalez AJ, Needham LL, Pirkle JL. Urinary creatinine concentrations in the US population: implications for urinary biologic monitoring measurements. Environ Health Perspect. 2004;113(2):192–200.
58. R Core Team. R: a language and environment for statistical computing. Version 3.5.0. Vienna: R Foundation for Statistical Computing; 2013.
59. Pinheiro J, Bates D, DebRoy S, Sarkar D, R Core Team. nlme: linear and nonlinear mixed effects models. R package version 3.1–137. Comprehensive R Archive Network; 2018.
60. Peralta CA, Katz R, Bonventre JV, Sabbisetti V, Siscovick D, Sarnak M, et al. Associations of urinary levels of kidney injury molecule 1 (KIM-1) and neutrophil gelatinase-associated lipocalin (NGAL) with kidney function decline in the Multi-Ethnic Study of Atherosclerosis (MESA). Am J Kidney Dis. 2012;60(6):904–11. doi: 10.1053/j.ajkd.2012.05.014 22749388
61. Panduru NM, Sandholm N, Forsblom C, Saraheimo M, Dahlström EH, Thorn LM, et al. Kidney injury molecule-1 and the loss of kidney function in diabetic nephropathy: a likely causal link in patients with type 1 diabetes. Diabetes Care. 2015;38(6):1130–7. doi: 10.2337/dc14-2330 25784666
62. Foster MC, Coresh J, Bonventre JV, Sabbisetti VS, Waikar SS, Mifflin TE, et al. Urinary biomarkers and risk of ESRD in the Atherosclerosis Risk in Communities Study. Clin J Am Soc Nephrol. 2015;10(11):1956–63. doi: 10.2215/CJN.02590315 26350438
63. Alderson HV, Ritchie JP, Pagano S, Middleton RJ, Pruijm M, Vuilleumier N, et al. The associations of blood kidney injury molecule-1 and neutrophil gelatinase-associated lipocalin with progression from CKD to ESRD. Clin J Am Soc Nephrol. 2016;11(12):2141–9. doi: 10.2215/CJN.02670316 27852662
64. Bhavsar NA, Köttgen A, Coresh J, Astor BC. Neutrophil gelatinase-associated lipocalin (NGAL) and kidney injury molecule 1 (KIM-1) as predictors of incident CKD stage 3: the Atherosclerosis Risk in Communities (ARIC) Study. Am J Kidney Dis. 2012;60(2):233–40. doi: 10.1053/j.ajkd.2012.02.336 22542304
65. Garlo KG, White WB, Bakris GL, Zannad F, Wilson CA, Kupfer S, et al. Kidney biomarkers and decline in eGFR in patients with type 2 diabetes. Clin J Am Soc Nephrol. 2018;13(3):398–405. doi: 10.2215/CJN.05280517 29339356
66. Hu J, Wang Y, Xiang X, Peng C, Gao R, Goswami R, et al. Serum bisphenol A as a predictor of chronic kidney disease progression in primary hypertension: a 6-year prospective study. J Hypertens. 2016;34(2):332–7. doi: 10.1097/HJH.0000000000000780 26628110
67. Ferguson KK, Loch-Caruso R, Meeker JD. Urinary phthalate metabolites in relation to biomarkers of inflammation and oxidative stress: NHANES 1999–2006. Environ Res. 2011;111(5):718–26. doi: 10.1016/j.envres.2011.02.002 21349512
68. Yang YJ, Hong Y-C, Oh S-Y, Park M-S, Kim H, Leem J-H, et al. Bisphenol A exposure is associated with oxidative stress and inflammation in postmenopausal women. Environ Res. 2009;109(6):797–801. doi: 10.1016/j.envres.2009.04.014 19464675
69. Lin C-Y, Chen P-C, Hsieh C-J, Chen C-Y, Hu A, Sung F-C, et al. Positive association between urinary concentration of phthalate metabolites and oxidation of DNA and lipid in adolescents and young adults. Sci Rep. 2017;7:44318. doi: 10.1038/srep44318 28290483
70. Hurst CH, Waxman DJ. Activation of PPARα and PPARγ by environmental phthalate monoesters. Toxicol Sci. 2003;74(2):297–308. doi: 10.1093/toxsci/kfg145 12805656
71. Tetz LM, Cheng AA, Korte CS, Giese RW, Wang P, Harris C, et al. Mono-2-ethylhexyl phthalate induces oxidative stress responses in human placental cells in vitro. Toxicol Appl Pharmacol. 2013;268(1):47–54. doi: 10.1016/j.taap.2013.01.020 23360888
72. Erkekoglu P, Rachidi W, Yuzugullu OG, Giray B, Favier A, Ozturk M, et al. Evaluation of cytotoxicity and oxidative DNA damaging effects of di (2-ethylhexyl)-phthalate (DEHP) and mono (2-ethylhexyl)-phthalate (MEHP) on MA-10 Leydig cells and protection by selenium. Toxicol Appl Pharmacol. 2010;248(1):52–62. doi: 10.1016/j.taap.2010.07.016 20659492
73. Kang H, Kim S, Lee G, Lee I, Lee JP, Lee J, et al. Urinary metabolites of dibutyl phthalate and benzophenone-3 are potential chemical risk factors of chronic kidney function markers among healthy women. Environ Int. 2019;124:354–60. doi: 10.1016/j.envint.2019.01.028 30660848
74. Tsai H-J, Chen B-H, Wu C-F, Wang S-L, Huang P-C, Tsai Y-C, et al. Intake of phthalate-tainted foods and microalbuminuria in children: the 2011 Taiwan food scandal. Environ Int. 2016;89:129–37. doi: 10.1016/j.envint.2016.01.015 26827184
75. Trasande L, Sathyanarayana S, Trachtman H. Dietary phthalates and low-grade albuminuria in US children and adolescents. Clin J Am Soc Nephrol. 2014;9(1):100–9. doi: 10.2215/CJN.04570413 24178978
76. Ye X, Wong L-Y, Bishop AM, Calafat AM. Variability of urinary concentrations of bisphenol A in spot samples, first morning voids, and 24-hour collections. Environ Health Perspect. 2011;119(7):983–8. doi: 10.1289/ehp.1002701 21406337
77. Townsend MK, Franke AA, Li X, Hu FB, Eliassen AH. Within-person reproducibility of urinary bisphenol A and phthalate metabolites over a 1 to 3 year period among women in the Nurses’ Health Studies: a prospective cohort study. Environ Health. 2013;12(1):80. doi: 10.1186/1476-069X-12-80 24034517
78. Devarajan P. Neutrophil gelatinase-associated lipocalin (NGAL): a new marker of kidney disease. Scand J Clin Lab Invest Suppl. 2008;241:89–94. doi: 10.1080/00365510802150158 18569973
79. Bonventre JV. Kidney injury molecule-1: a translational journey. Trans Am Clin Climatol Assoc. 2014;125:293–9. 25125746
80. Valavanidis A, Vlachogianni T, Fiotakis C. 8-hydroxy-2′-deoxyguanosine (8-OHdG): a critical biomarker of oxidative stress and carcinogenesis. J Environ Sci Health C Environ Carcinog Ecotoxicol Rev. 2009;27(2):120–39. doi: 10.1080/10590500902885684 19412858
81. Pratico D, Rokach J, Lawson J, FitzGerald GA. F2-isoprostanes as indices of lipid peroxidation in inflammatory diseases. Chem Phys Lipids. 2004;128(1–2):165–71. doi: 10.1016/j.chemphyslip.2003.09.012 15037161
Článek vyšel v časopise
PLOS Medicine
2020 Číslo 10
- Může hubnutí souviset s vyšším rizikem nádorových onemocnění?
- Polibek, který mi „vzal nohy“ aneb vzácný výskyt EBV u 70leté ženy – kazuistika
- AI může chirurgům poskytnout cenná data i zpětnou vazbu v reálném čase
- Antibiotika na nachlazení nezabírají! Jak můžeme zpomalit šíření rezistence?
- Metamizol jako analgetikum první volby: kdy, pro koho, jak a proč?
Nejčtenější v tomto čísle
- Association of technologically assisted integrated care with clinical outcomes in type 2 diabetes in Hong Kong using the prospective JADE Program: A retrospective cohort analysis
- Correction: Social distancing to slow the US COVID-19 epidemic: Longitudinal pretest–posttest comparison group study
- The impact of continuous quality improvement on coverage of antenatal HIV care tests in rural South Africa: Results of a stepped-wedge cluster-randomised controlled implementation trial
- Variation in racial/ethnic disparities in COVID-19 mortality by age in the United States: A cross-sectional study