ABSTRACT
Context: Blood pressure and plasma catecholamines normally decline during sleep and rapidly increase in early morning. This is blunted in adults with type 2 diabetes (T2D). Objective: We hypothesize that increased sympatho-adrenal activity during sleep differentiates youth with T2D from nondiabetic obese youth and lean youth. Methods: Fasting spot morning and 24-hour urines were collected in obese adolescents with and without T2D, and normal-weight controls. Fractionated free urine catecholamines (epinephrine, norepinephrine, and dopamine) were measured, and the ratio of fasting spot morning to 24-hour catecholamines was calculated. Results: Urinary 24-hour catecholamine levels were comparable across the 3 groups. Fasting morning epinephrine and the ratio of fasting morning/24-hour epinephrine were higher in youth with T2D (P = 0.004 and P = 0.035, respectively). In males, the ratio of fasting morning/24-hour epinephrine was also higher in youth with T2D (P = 0.005). In females, fasting morning norepinephrine and the ratio of fasting morning/24-hour dopamine were lower in obese youth with and without T2D (P = 0.013 and P = 0.005, respectively) compared with lean youth. Systolic blood pressure was higher in diabetic participants than other groups; males trended higher than females. Conclusion: Circadian rhythm in catecholamines is disrupted in youth-onset T2D, with a blunted overnight fall in urinary epinephrine in males. Conversely, fasting morning norepinephrine and dopamine levels were lower in obese females with or without T2D. Higher nocturnal catecholamines in males with T2D might associate with, or predispose to, hypertension and cardiovascular complications. Lower catecholamine excretion in females with obesity might serve an adaptive, protective role.
ABSTRACT
The use of progesterone following brain injury has a controversial history. On one hand, some lab-based models have showed progesterone as being neuroprotective, but on the other, clinical trials have showed quite the opposite. One of many complaints that arose from this discrepancy was the lack of a diverse pool of animal models and paradigms employed during the preclinical phase. However, over the past decade, the zebra finch has emerged as an optimal organism for the study of steroid-mediated neuroprotection. Following an injury, steroid hormones and receptors are upregulated, serving to decrease neuroinflammation and overall damage to the brain. As compared to other vertebrate models, zebra finches can upregulate expression of both estrogens and androgens at a faster and more robust response, suggesting that vertebrates differ in their neuroprotective mechanisms and timing following injury. Therefore, to expand the types organisms studied in pre-clinical trials, we chose to use zebra finches. While the majority of work in the zebra finch brain has focused on estrogens and androgens, we sought to clarify the role of progesterone following injury. Adult male zebra finches were given daily injections of progesterone following a penetrating injury and then were assessed for the size of injury and expression of various genes associated with neuroinflammation and cell survival. Treatment with progesterone decreased the injury size in zebra finches over controls and increased expression of various genes associated with cell survival and neuroinflammation. These data suggest that progesterone does mediate neuroprotection, most likely through the alteration of neuroinflammatory and cell survival pathways.
