Salivary cortisol is not associated with incident insulin resistance or type 2 diabetes mellitus

Salivary cortisol is frequently used as a biomarker of psychological stress. However, psychobiological mechanisms, which trigger the hypothalamus-pituitary-adrenal axis (HPAA) can only indirectly be assessed by salivary cortisol measures. The different instances that control HPAA reactivity (hippocampus, hypothalamus, pituitary, adrenals) and their respective modulators, receptors, or binding proteins, may all affect salivary cortisol measures. Thus, a linear relationship with measures of plasma ACTH and cortisol in blood or urine does not necessarily exist. This is particularly true under response conditions. The present paper addresses several psychological and biological variables, which may account for such dissociations, and aims to help researchers to rate the validity and psychobiological significance of salivary cortisol as an HPAA biomarker of stress in their experiments.

Pituitary ACTH-dependent Cushing's disease (CD) is uncommon, and there are very limited data on long-term mortality. The aim was to summarize what is known about mortality in ACTH-dependent CD, to report on our own data, and to provide a meta-analysis of six other reports that addressed mortality of CD. Vital status of 60 CD patients was recorded as of December 31, 2009, and the standardized mortality ratio (SMR) was calculated and compared with the general population of England and Wales, United Kingdom. A meta-analysis of SMRs from seven studies (including ours) was performed for overall mortality in CD. Where reported (four studies), a similar meta-analysis was performed for those patients whose hypercortisolism was in remission after treatment compared to those patients from the same center with persistent disease. 1. From Stoke-on-Trent, 51 of 60 patients were female, median age at diagnosis was in the range of 36-46 yr, and median follow-up was 15 yr. There were 13 deaths, nine due to cardiovascular disease. Overall SMR for the whole cohort was 4.8 (95% confidence interval, 2.8-8.3) (P < 0001). SMR for vascular disease was 13.8 (7.2-36.5) (P < 0001). For persistent disease (n = 6), SMR was 16 (6.7-38.4) vs. remission (n = 54) SMR of 3.3 (1.7-6.7); after adjustment for age and sex, relative risk of death for persistent disease was 10.7 (2.3-48.6) (P = 0.002). Hypertension and diabetes mellitus were associated with significantly worse survival. 2. Using a random effects model meta-analysis revealed an overall (remission plus persistent disease) SMR of 2.2 (1.45-3.41) (P < 0.001). Pooled SMR was 1.2 (0.45-3.2) (P = not significant) for patients in remission and 5.5 (2.7-11.3) (P = 0.001) for patients with persistent disease. Persistence of disease, older age at diagnosis, and presence of hypertension and diabetes are the main determinants of mortality. Overall mortality in CD is double that of the general population. However, patients with CD in remission fare much better than those with persistence of hypercortisolism, and they appear not to have an increased mortality rate. Hypertension and diabetes mellitus are risk factors for worse outcome. Because diagnosis and treatment of patients are at a young age, much longer follow-up of patients in remission is required before one can be confident that their mortality outcome is no different from that of the general population, especially because cardiovascular risk factors may persist after successful biochemical control of the disease.

Cortisol has a distinct circadian rhythm regulated by the brain's central pacemaker. Loss of this rhythm is associated with metabolic abnormalities, fatigue, and poor quality of life. Conventional glucocorticoid replacement cannot replicate this rhythm. Our objectives were to define key variables of physiological cortisol rhythm, and by pharmacokinetic modeling test whether modified-release hydrocortisone (MR-HC) can provide circadian cortisol profiles. The study was performed at a Clinical Research Facility. Using data from a cross-sectional study in healthy reference subjects (n = 33), we defined parameters for the cortisol rhythm. We then tested MR-HC against immediate-release hydrocortisone in healthy volunteers (n = 28) in an open-label, randomized, single-dose, cross-over study. We compared profiles with physiological cortisol levels, and modeled an optimal treatment regimen. The key variables in the physiological cortisol profile included: peak 15.5 microg/dl (95% reference range 11.7-20.6), acrophase 0832 h (95% confidence interval 0759-0905), nadir less than 2 microg/dl (95% reference range 1.5-2.5), time of nadir 0018 h (95% confidence interval 2339-0058), and quiescent phase (below the mesor) 1943-0531 h. MR-HC 15 mg demonstrated delayed and sustained release with a mean (sem) maximum observed concentration of 16.6 (1.4) microg/dl at 7.41 (0.57) h after drug. Bioavailability of MR-HC 5, 10, and 15 mg was 100, 79, and 86% that of immediate-release hydrocortisone. Modeling suggested that MR-HC 15-20 mg at 2300 h and 10 mg at 0700 h could reproduce physiological cortisol levels. By defining circadian rhythms and using modern formulation technology, it is possible to allow a more physiological circadian replacement of cortisol.