Risk Factors for Chronic Kidney Disease: A Prospective Study of 23,534 Men and Women in Washington County, Maryland

Methods

Results

Survival Analysis of CKD

Kaplan-Meier curves of the risk of CKD by age at baseline and JNC-VI BP category are shown in Figure 1. When compared with optimal BP, stages 2 to 4 hypertension were all significantly associated with the subsequent development of CKD when adjusted for age, treated diabetes, and cigarette smoking (Table 3). The associations of high-normal BP and stage 1 hypertension neared statistical significance (P = 0.075 and 0.055, respectively). The results were similar when stratified by gender, though statistical significance was only achieved in stages 2 and 3 or 4 in women and in stage 3 or 4 in men. Treated diabetes and cigarette smoking were also significantly associated with the later development of CKD. Analyses combining optimal and normal BP as the reference group should similar results to those presented. The above associations were similar when excluding cases with an elevated serum creatinine at baseline (7 values greater than 1.4 mg/dl and 11 values greater than 1.2 mg/dl). The attributable risks, which combine the relative risks and prevalence of the risk factors in this population, are shown in Figure 2. The BP category with the greatest attributable risk is stage 1 hypertension, though even high-normal BP is important in its association with the outcome of CKD. The attributable risk for cigarette smoking is staggering, at nearly half that seen for all BP categories combined. The low attributable risk for treated diabetes is likely secondary to the fact that we could only detect diabetes on the basis of the presence of medications for hyperglycemia on the medication list from 1974.

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Figure 1. Kaplan-Meier curves of the risk of chronic kidney disease (CKD) in 23,534 people in Washington County, MD, by age and the following risk factors: (A) JNC-VI BP category in the total population; (B) JNC-VI BP category in men; (C) JNC-VI BP category in women; (D) smoking status at entry into CLUE Study. (A through C), stage 3 or 4, –·–·–·; stage 2, ·-·-·; stage 1, ——; high-normal, ····; normal, – – – –; optimal, ——;. (D) current smoker, – – – –; former/never smoker, ——.

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Table 3. Adjusted relative hazard of CKD^a in total population and stratified by gender in 23,534 participants in the CLUE Study, followed from 1974 to 1994^b

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Figure 2. Adjusted attributable risk of CKD per 1 million population for each JNC-VI BP category and for smoking and diabetes in 23,534 participants of the CLUE Study, 1974-1994. Adjusted in a model including JNC-VI BP category, treated diabetes, smoking, and gender with age as the time variable. CKD is defined as treated ESRD or death with kidney disease noted on the death certificate and confirmed as CKD on medical chart review.

Analyses of BP as a continuous variable yielded similar results. Higher systolic and higher diastolic BP were associated with an relative hazards of CKD of 1.02 (95% CI 1.01-1.03) and 1.04 (95% CI 1.03-1.06), respectively after adjustment for age, gender, smoking, and diabetes treatment (P < 0.001). In a model containing both systolic and diastolic BP, the latter were no longer statistically significant.

Discussion

This study demonstrates a strong graded increased risk of developing CKD with JNC-VI criteria for hypertension in a community-based cohort of predominantly white persons. Stages 2, 3, and 4 of hypertension were significantly associated with the outcome of CKD when adjusted for age, gender, treated diabetes, and cigarette smoking. When stratifying by gender, statistical significance was also reached for stages 2, 3, and 4 hypertension in women and for stage 3 and 4 in men. There was also a strong association between CKD and both treated diabetes and cigarette smoking. Among BP categories, stage 1 hypertension was the most common and thus had the greatest attributable risk of CKD at 2650 per million population (23% of CKD risk). The attributable risk of cigarette smoking in this population was staggering at 3640 per million population (31% of CKD risk).

The strong relationship between hypertension and CKD has been shown prospectively in men. The MRFIT study looked at over 330,000 men and found that higher BP is associated with a higher incidence of end-stage renal disease (4,5⇓). Perry et al. (3) looked at nearly 12,000 hypertensive male veterans and found that the risk ratio of end-stage renal disease for pretreatment systolic BP of 165 to 180 mmHg was 2.8 and for levels greater then 180 mmHg was 7.6 when compared with a systolic BP of ≤140 mmHg. A prospective study of over 100,000 men and women in Japan showed that diastolic BP was the strongest predictor of the later development of end-stage renal disease, though the results were not stratified by gender (31). None of these studies reported the risk in women, a group that constituted 47% of new cases of treated end-stage renal disease in 1999 (32).

Current recommendations from the JNC-VI are to aim for a BP below 130/85 mmHg only if certain conditions are present, such as diabetes, heart failure, and renal insufficiency (33). Our data from a community-based cohort show that the bulk of CKD comes from those individuals in the stage 1 category for hypertension, and even high-normal BP is important in its association with CKD. While the relative risk of CKD is higher in more severe hypertension, there are many more people who fall into the high-normal category so the attributable risk of CKD in these lower BP categories has a marked public health impact. This is supported by cross-sectional data from the Third National Health and Nutrition Examination Survey, which shows that elevated serum creatinine is common, underdiagnosed, and strongly related to inadequate treatment of high BP (34). Given that over 50% of CKD in our study arose from individuals with high-normal BP or with stage 1 hypertension, the strategies used to treat hypertension in these individuals will have a strong impact on the future trajectory of the epidemic increase in CKD in the United States.

Clinical trial data show that antihypertensive therapy can retard the progression of kidney disease, with greatest protection found with the use of angiotensin-converting enzyme (ACE) inhibitors and angiotensin II receptor antagonists, particularly among patients with proteinuria (35–42⇓⇓⇓⇓⇓⇓⇓). The African-American Study of Kidney Disease (AASK) trial showed that ACE inhibitors were more effective than β-blockers and dihydropyridine calcium channel blockers in slowing the decline in GFR in people with hypertension (43), though surprisingly this study did not find that aggressive hypertensive control slowed the progression of renal disease compared with good BP control (MAP 102 to 107 to a MAP < 92). Our observational results show a gradient of risk even between optimal (<120/80 mmHg) and high-normal BP (130–139/85–89 mmHg). The risk in this limited BP range was not statistically significant in our study, although it was in the MRFIT study. Hypertension in observational studies reflects a long period, often decades before the baseline and decades of follow-up time, in marked contrast to the limited follow-up in clinical trials. Thus, observational studies and clinical trials are in agreement supporting BP lowering to below the hypertensive range; the benefits of further lowering are more difficult to determine. Results from recent clinical trials have shown that low BP goals can be successfully achieved, even in patients with CKD. For example, the African-American Study of Hypertension reported mean treated systolic and diastolic BP of 134 and 84 mmHg (37). In the Hypertension Optimal Treatment (HOT) trial, the subset of participants who had serum creatinine values of 1.5 mg/dl or higher (n = 470) were able to achieve their target BP as often as those who did not, though they required more antihypertensive medications to do so (44). Thus, to quell the morbidity and mortality associated with the current epidemic of CKD, it is important to pursue more aggressive BP control among both men and women than practiced currently (34), particularly among patients with stage 1 hypertension.

While diabetes and hypertension are well-described risk factors for CKD, cigarette smoking is not widely appreciated to be a risk factor for CKD. Regalado et al. (45) showed in a prospective study of 53 patients with hypertensive nephropathy that the decline in kidney function that occurred after a mean of 35 mo was best predicted by cigarette smoking, confirming prior discoveries that cigarettes increase the risk for progression of kidney disease (12,18⇓). These authors proposed that the likely mechanism by which smoking contributes to the progression of kidney disease is via damage to arterioles and progressive vascular injury. Two cohort studies suggest that cigarette smoking plays a role in the development of kidney disease in the general population. Whelton et al. (24) showed a graded increase in the incidence of ESRD by number of cigarettes smoked in men screened for the MRFIT study, and Mulder et al. (25) showed an increase in urinary albumin excretion in smokers. Our data show that current smoking is associated with a 2.5 times greater risk of later developing CKD in the population as a whole and when stratified by gender. Possible mechanisms for smoking-related renal injury include the following: an increase in BP and heart rate; alteration of diurnal BP rhythm; an increase in sympathetic nerve activity; an increase in renal vascular resistance leading to a decrease in GFR; arteriosclerosis of renal and intrarenal arteries and arterioles; tubulotoxicity; a direct toxic effect on endothelial cells; increased clotting of platelets (46).

There are several limitations to our study. First of all, as in other very large cohorts, follow-up was passive. We did not have data on losses due to migration. Because we could only detect CKD when people either started on renal replacement therapy or when evidence of CKD was noted in the medical record of participants who died, we had low sensitivity to detect milder CKD. Fortunately, a low sensitivity of detecting a rare disease will result in a loss of power but little bias in estimates of relative hazard. However, it is important to note that detected CKD in this study is only a small subset of all CKD, and absolute risk estimates from this study cannot be used to infer the risk of all stages of CKD as defined by the National Kidney Foundation (47). Furthermore, we did not have serial serum creatinine values, so we could not comment on progression of disease. It is possible that there was some prevalent CKD in the cohort on entry into the study that was unrecognized because we did not have baseline serum creatinine values on all participants, though analysis of a subgroup of cases and matched controls who did have serum creatinine values showed only a small fraction had reduced kidney function at baseline. Furthermore, the outcome of CKD was heterogeneous, as we included those people requiring renal replacement therapy as well as those who died with chronic renal insufficiency. Those who died with renal insufficiency made up the majority of the cases and were significantly older than the group with end-stage renal disease, though the rest of their demographics were similar. Similarly, CKD encompasses a broad range of etiologies that could have different risk factors in terms of development and progression, and it is possible that the presence of CKD may indicate large vessel renal artery disease in this largely white population. While we adjust for age, gender, treated diabetes, and hypertension, we acknowledge that residual confounding by other conditions associated with hypertension remains in our adjusted estimates. Finally, our population was predominantly white, so our results cannot necessarily be generalized to nonwhites.

The most important strength of our study is the powerful study design—a large prospective study of 20-yr duration. The benefit of such a long follow-up time outweighs the potential downside one faces when conducting such a study; namely, that risk factors and treatments have changed over time. Furthermore, it was conducted in a community setting where approximately 25 percent of the residents of the county enrolled. The relative homogeneity of the population enhances internal validity.

There is great debate as to whether hypertension causes kidney disease or vice versa. However, the data certainly show an increased risk of CKD subsequent to both hypertension and smoking in women as well as men. This suggests that hypertensive women, too, must be aggressively targeted in an effort to stop the current epidemic of CKD. Furthermore, the fact that the attributable risk of CKD among BP categories was the highest for stage 1 hypertension shows that it is these individuals who will go on to make up the bulk of CKD. While we traditionally think of targeting people with malignant hypertension for aggressive intervention, our findings would suggest that optimal treatment of stage 1 hypertension would have a greater public health impact on reducing CKD than would targeting only patients with stages 3 and 4 hypertension, even though the relative risks are higher for higher stages of hypertension. Lastly, physicians already know to advise patients not to smoke; this study suggests that cigarette smoking contributes to the development and/or progression of CKD and thus adds another important reason to quit and patients should be advised of this.