Prenatal Risk Factors for Childhood CKD

Discussion

In this population-based, case-control study, we have shown significant associations between childhood CKD and primary prenatal exposures of low birth weight and maternal factors, including GDM, PDM, overweight, and obesity. We identified cases of CKD with structural kidney malformations, one of the criteria for CKD according to both Kidney Disease Outcomes Quality Initiative and Kidney Disease Improving Global Outcomes.^13,14 The WA birth record linkage enabled the largest study to date of these hypotheses. Low birth weight, a surrogate for both poor fetal growth and low nephron number,^4,15 is a risk factor for postnatal CKD in both childhood⁷ and adulthood.⁸ Although there is some data that high birth weight, in the setting of exposure to maternal DM, is associated with albuminuria¹⁶ and may contribute to postnatal CKD, we do not show an increased risk of postnatal CKD with high birth weight. Thus, our data show that only low birth weight seems to be associated with postnatal CKD.

Existing literature also suggests that maternal DM may adversely compromise fetal programming, resulting in abnormal renal development. This result is suggested by a murine model of maternal DM, which shows altered transcription of inflammatory cytokines and subsequent aberrant nephrogenesis in offspring of diabetic compared with nondiabetic mothers.¹⁷ In humans, the timing of treatment in mothers with DM is also known to reduce the risk of congenital malformations.¹⁸ When intensive education and insulin therapy were provided to women with DM both pre- and postconception, the rate of congenital anomalies in the offspring of women treated preconception was significantly lower than the rate in offspring of women treated postconception (1.2% versus 10.9%). In the human fetus, kidney development occurs between 5 and 34 weeks of gestation.¹⁹ This information, along with evidence that preconception intensive glycemic control in diabetic women is associated with a reduced risk of congenital malformations in offspring, supports the biologic plausibility of maternal DM as a risk factor for congenital malformations in offspring.

Obesity has also been shown to be associated with malformations of the urogenital system,¹⁰ although the data are conflicting.²⁰ The mechanism by which obesity is associated with CKD may be independent of its association with maternal DM. Obese women may be at increased risk of metabolic alterations, such as hyperglycemia or hyperinsulinemia, independent of the presence of DM or elevated estrogen levels. These factors may increase the risk of having an offspring with a birth defect if they were present during the period of organogenesis.²⁰ Our study supports previous findings that maternal obesity increases the risk of congenital urogenital malformations in offspring, namely obstructive kidney disease.¹⁰ This finding is independent of the presence of DM, because obese mothers were more likely to have children with obstructive CKD than nonobese mothers after adjusting for maternal DM.

Current knowledge about CKD epidemiology is based mainly on data on the most advanced stage of CKD or ESRD, when dialysis or transplantation is necessary to sustain life.²¹ Little is known about the prevalence of earlier stages of CKD. There is evidence that ESRD represents the tip of the iceberg of CKD and that earlier CKD stages may exceed in prevalence those cases reaching ESRD by as much as 50 times.²² The ItaliKid study showed that, in children with mild CKD (estimated creatinine clearance [CCr]=51–75 ml/min) at registration, the risk of developing ESRD by age 20 years was not trivial (37%), although it was smaller than the risks with moderate CKD (CCr=25–50 ml/min) and severe CKD (CCr<25 ml/min; estimated at 70% and 97%, respectively). Thus, evaluating the epidemiology of milder stages of CKD as we do here is warranted, because children with milder stages of CKD may also be at increased risk for progression to ESRD.

Our study includes 1994 CKD cases diagnosed from 1987 to 2008 compared with 1197 cases in the ItaliKid study, an Italian study that was the first prospective population-based study on the epidemiology of CKD in children.²³ We report a childhood CKD prevalence of 126.7 per 100,000, whereas the ItaliKid study reported a point prevalence of 74.7 per 1,000,000. Based on our definition of CKD, the prevalence was almost 17 times higher than the prevalence reported by the ItaliKid project. Some of this difference in prevalence may be explained by our more inclusive definition of CKD; ItaliKid included only CKD cases with estimated CCr less than 75 ml/min, whereas our study includes children with structural kidney disease, some of whom might have had normal estimated kidney function had they undergone CCr testing. It is also possible that we have a higher false positive rate for CKD cases than the ItaliKid study; whereas we used hospitalization diagnosis codes to identify cases, ItaliKid used more detailed inpatient and outpatient medical records to identify cases.

Our study has a number of limitations, which include missing maternal BMI data at the time of birth certificate completion in 44.4% of cases and 47.7% of controls, the use of self-reported data for maternal weight in the prepregnancy BMI calculation when it was not available from the mother’s medical chart or physician, and variation in ICD-9 coding for CKD between physicians. Nevertheless, birth certificate data seem to be both reliable and valid when used for research purposes, with recall or reporting bias having minimal effect.²⁴ The BMI data are thought to be missing at random, because entry into the dataset depended on documentation by WA data entry staff using medical chart data, physician report, or maternal recall, and they should not be a source of bias. Moreover, our case definition may underestimate the prevalence of CKD in WA. Although use of ICD-9 codes to identify CKD cases has variable sensitivity, it is a reliable way to identify CKD cases with high specificity.^25,26

In conclusion, using a broad definition of CKD, we identified a large number of pediatric CKD cases and found that children with CKD were highly likely to have abnormal prenatal history, including low birth weight, maternal overweight/obesity, and maternal DM. Combined with data suggesting that milder CKD can progress to ESRD,²³ we propose that there is some use in applying broader definitions of CKD in future epidemiologic studies.

As mentioned above, previous data show that, if we educate and provide intensive DM care early to diabetic mothers, the rate of congenital malformations in births to diabetic mothers decreases to levels comparable with the rate in nondiabetic mothers.¹⁸ Additionally, children with CKD were significantly more likely to have obese mothers; thus, our data underscore the potential impact of maternal obesity on future generations. Maternal overweight is also not without risk, because it was found to be associated with childhood obstructive CKD. Ultimately, we hope that our results will serve as an impetus to larger prospective studies evaluating the risk factors for and clinical outcomes of children with all stages of CKD, with the goals of elucidating the pathophysiology of and improving outcomes for CKD and whether modification of these factors can reduce the incidence of childhood CKD.