High cortisol levels are associated with oxidative stress and mortality in maintenance hemodialysis patients

Patients with end-stage renal disease demonstrate higher cardiovascular morbidity and mortality than those with normal renal function or mild renal failure [1]. The chronic stimulation of mineralocorticoid receptors by either aldosterone or cortisol has been suggested as a possible cause of sudden cardiac death in diabetic patients receiving hemodialysis (HD) [2]. Aldosterone is a main effector hormone that contributes to deleterious cardiac damage [3‐5]. However, there has been controversy about the harmful effect of plasma aldosterone on cardiovascular outcomes among HD patients. Some observational studies with a small number of HD patients showed a positive association [6, 7] while others reported a negative association [8‐10] with cardiovascular outcome and mortality.

Serum cortisol is another hormone that can bind to the mineralocorticoid receptor to produce adverse cardiovascular outcomes in HD patients. Under normal conditions, cortisol is converted into inactive cortisone by the 11β hydroxysteroid dehydrogenase type 2 (11βHSD2) enzyme. However, the activity of 11βHSD2 decreases as renal function declines, and therefore, cortisol levels increase disproportionately compared to aldosterone levels [11]. Since 11βHSD2 is minimally expressed in the heart, cardiac mineralocorticoid receptors may be mainly activated by cortisol rather than aldosterone in HD patients. Indeed, the serum cortisol level was reported to be one hundred to one thousand times higher than the plasma aldosterone level in such patients [12]. In addition, previous studies have shown the harmful effect of serum cortisol in HD patients: HD patients with high serum cortisol levels had high rates of cardiovascular events and mortality [2, 13, 14].

Meanwhile, low-density lipoprotein (LDL) is a major source of cholesterol for aldosterone and cortisol synthesis. Under circumstances of oxidative stress, LDL may be modified to oxidized LDL (oxLDL), which is highly atherogenic. The concentration of oxLDL is elevated in patients with chronic kidney disease in part because of the inability of high-density lipoprotein to reduce oxLDL and in part because of the increased LDL lifespan due to decreased renal clearance [15]. A previous study demonstrated that oxLDL extensively counteracts aldosterone release [16]. This finding may be related to the controversial findings of aldosterone effects on cardiovascular outcomes among HD patients. However, the effect of oxLDL on the level of circulating cortisol is not known.

Determining the effect of oxLDL on the level of serum cortisol and patient mortality in HD patients is important for the identification of candidates who are most likely to benefit from mineralocorticoid receptor blockers. Therefore, we performed an observational cohort study to evaluate whether serum cortisol affects patient mortality and whether oxLDL is an independent risk factor for elevated cortisol in maintenance HD patients.

This observational study demonstrated that a high serum cortisol level (baseline cortisol ≥ 10 μg/dL) is associated with higher cardiovascular morbidity and is an independent predictor of all-cause mortality among HD patients. In addition, oxLDL was an independent risk factor for elevated serum cortisol levels and LVSD. However, plasma aldosterone levels were not associated with serum cortisol levels.

High serum cortisol has been suggested as a risk factor for cardiovascular events and death among patients with end-stage renal disease. Drechsler et al. demonstrated in their post hoc analysis of the German Diabetes and Dialysis Study (4D Study) that the combined presence of high aldosterone (>200 pg/mL) and high cortisol (>21.1 μg/dL) levels increases the risk of all-cause death and sudden cardiac death [2]. Another study showed that serum cortisol levels were associated with inflammation and low sodium levels, and high serum cortisol among HD patients resulted in high mortality [14]. Our study also demonstrated that high serum cortisol levels result in high patient mortality. Our data also demonstrated that the high cortisol group showed lower serum sodium levels than the low cortisol group. Unfortunately, due to the small number of patients included in the analysis and some missing data, our study failed to show associations of the marker of inflammation and serum cortisol or patient death. In addition, a single measurement of C-reactive protein or serum sodium levels may not accurately reflect the status of chronic inflammation. However, our study demonstrated that serum cortisol can be a useful predictive marker for cardiovascular morbidity and all-cause mortality among HD patients under oxidative stress. Yamaji et al. also demonstrated that serum cortisol can be a useful predictive marker for cardiac events only if oxLDL was elevated in patients with chronic heart failure [13].

A previous study demonstrated that patients with end-stage renal disease have a nearly 10-fold elevation of oxLDL compared with healthy controls [20]. OxLDL may accumulate within macrophages, which may enhance chemotactic activity and result in direct injury to endothelial cells [21]. OxLDL also impairs the anti-inflammatory properties of the endothelium and enhances proinflammatory markers, including cytokines, chemokines, and growth factors [22‐24]. Therefore, oxLDL may result in endothelial cell dysfunction, microvasculature atherosclerosis, and vascular calcification. Our study also showed that plasma oxLDL levels were independently associated with high cortisol levels and LVSD. Although our study did not intend to explain the underlying pathogenesis of the effect of oxLDL on cardiac outcomes, there may be a close association among oxLDL, serum cortisol, and cardiac dysfunction.

Drechsler suggested that both cortisol and aldosterone might be important risk factors for sudden cardiac death among HD patients [2], but plasma aldosterone levels did not affect patient mortality in our study. Previous studies also showed a negative correlation with cardiovascular outcomes in dialysis patients. Kohagura et al. demonstrated that hypertensive HD patients in the low aldosterone group (<22.9 ng/dL) showed a poorer survival rate than those in the high aldosterone group (≥22.9 ng/dL) (62.5% vs. 90.6%, P=0.003). Previous studies suggested that this paradoxical relationship might be due to the confounding effect of volume overload, inflammation, or protein energy malnutrition [9, 10]. However, in our study, the patients with high and low aldosterone levels did not show differences in interdialytic weight gain, serum albumin levels, or C-reactive protein levels (Supplementary Table 1). Instead, the paradoxical effect of aldosterone on cardiovascular outcomes may be due to the dissociation of low circulating aldosterone levels and high tissue aldosterone levels [25]. In addition, oxLDL may counteract aldosterone, resulting in low to normal plasma aldosterone levels in highly oxidative stress conditions [16]. While the plasma aldosterone level shows contradictory results, the serum cortisol level consistently predicts poor cardiovascular outcomes [13, 14]. Serum cortisol may be elevated in proinflammatory conditions and has an anti-inflammatory action against elevated oxLDL [26]. In addition, serum cortisol may be highly increased in patients with end-stage renal disease because the activity of 11βHSD2, an enzyme that converts cortisol to the inactive hormone cortisone, decreases as renal function declines [11]. Therefore, patients on dialysis may demonstrate elevated oxLDL and serum cortisol while showing normal to low aldosterone levels.

Our study has several implications. First, serum cortisol should be considered together with plasma aldosterone to monitor the effect of mineralocorticoid receptor antagonists in patients with end-stage renal disease. Since cortisol concentration may be elevated due to increased oxLDL and reduced 11βHSD2 enzyme activity in cardiac tissue, cardiac mineralocorticoid receptors may be activated mainly by cortisol [12]. Therefore, to evaluate the effect of mineralocorticoid receptor antagonists in patients with end-stage renal disease, it is reasonable to consider both hormone effects. Second, the therapeutic use of corticosteroids should be reconsidered in patients with end-stage renal disease. While an adequate dose of corticosteroids should be used when necessary, the duration and dose of steroids should be minimized for patients with a high cardiovascular risk.

There are several limitations in this study. First, we did not evaluate nonfatal cardiovascular events during the study period. Second, we only measured oxLDL and plasma aldosterone in a small number of patients. Third, the blood sampling time was different between patients. Since plasma ACTH, serum cortisol, renin, and aldosterone have diurnal variation and can be influenced by various factors, our findings can have many confounding factors. Fourth, we are unable to explain the direct effect of oxLDL on cardiovascular morbidity and all-cause mortality in this study. Finally, the causal relationship between oxLDL and serum cortisol could not be demonstrated in this study.

In conclusion, serum cortisol is a useful predictive marker for all-cause death among patients receiving HD. Oxidative stress may play an important role in increasing serum cortisol levels.