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Query: UMLS:C0848237 (
acute stress
)
4,619
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Psychoneuroendocrine stress-induced syndromes were characterised as expression of the activity of neuroendocrine transducers. A physiopathologic classification delineated the diseases which appeared as a result of the increase of the endocrine response to
acute stress
, i.e., catecholamine cardiomyopathy, reactive
hypercortisolism
, amenorrhea, infertility, sexual dysfunction of euthyroid sick syndrome in man and immunosuppression. The clinical diseases secondary to chronic stress, together with their physiopathologic therapy, i.e., central hypocorticism and psychosocial dwarfism, are described. They are produced by active inhibition of the endocrine response mechanism called by us: dysprotection.
...
PMID:Psychoneuroendocrine stress-induced syndromes. 251 Feb 3
Neuroendocrine changes contribute to female reproductive aging, but changes in other tissues also play a role. In C57BL/6J mice, neuroendocrine changes contribute to estrous cycle lengthening and reduced plasma estradiol levels, but the midlife loss of cyclicity is mainly due to ovarian failure. Hypothalamic estrogen receptor dynamics and estrogenic modulation of gene expression are altered in middle-aged cycling mice. Although insufficient to arrest cyclicity, these neuroendocrine changes may contribute to other reproductive aging phenomena, such as altered gonadotropin secretion and lengthened estrous cycles. In women, the loss of ovarian oocytes, the cause of menopause, accelerates in the decade before menopause. Accelerated oocyte loss may in turn be caused by a selective elevation of plasma follicle stimulating hormone, and neuroendocrine involvement may thus be implicated in menopausal oocyte loss. Chronic calorie restriction retards both neural and ovarian reproductive aging processes, as well as age-related change in many other physiological systems. The diverse effects of food restriction raises the possibility of an underlying coordinated regulatory response of the organism to reduced caloric intake, possibly effected through alterations of neural and/or endocrine signalling. We are therefore attempting to identify neuroendocrine changes that may coordinate the life prolonging response of animals to food restriction. Our initial focus is on the glucocorticoid system. Food restricted rats exhibit daily periods of
hyperadrenocorticism
, manifest as elevated free corticosterone during the diurnal peak. We hypothesize that this hyperadrenocortical state potentiates cellular and organismic homeostasis throughout life in a manner similar to that achieved during
acute stress
, thereby retarding aging processes and extending life span.
...
PMID:Neuroendocrine involvement in aging: evidence from studies of reproductive aging and caloric restriction. 853 19
Stress is a powerful modulator of neuroendocrine, behavioral, and immunological functions. After 4.5-d repeated combined acoustic and restraint stress as a murine model of chronic psychological stress, severe metabolic dysregulations became detectable in female BALB/c mice. Stress-induced alterations of metabolic processes that were found in a hepatic mRNA expression profiling were verified by in vivo analyses. Repeatedly stressed mice developed a hypermetabolic syndrome with the severe loss of lean body mass, hyperglycemia, dyslipidemia, increased amino acid turnover, and acidosis. This was associated with
hypercortisolism
, hyperleptinemia, insulin resistance, and hypothyroidism. In contrast, after a single
acute stress
exposure, changes in expression of metabolic genes were much less pronounced and predominantly confined to gluconeogenesis, probably indicating that metabolic disturbances might be initiated already early but will only manifest in repeatedly stressed mice. Thus, in our murine model, repeated stress caused severe metabolic dysregulations, leading to a drastic reduction of the individual's energy reserves. Under such circumstances stress may further reduce the ability to cope with new stressors such as infection or cancer.
...
PMID:Hypermetabolic syndrome as a consequence of repeated psychological stress in mice. 1832 86
Cortisol measurements in blood, saliva and urine are frequently used to examine the hypothalamus-pituitary-adrenal (HPA) axis in clinical practice and in research. However, cortisol levels are subject to variations due to
acute stress
, the diurnal rhythm and pulsatile secretion. Cortisol measurements in body fluids are not always a reflection of long-term cortisol exposure. The analysis of cortisol in scalp hair is a relatively novel method to measure cumulative cortisol exposure over months up to years. Over the past years, hair cortisol concentrations (HCC) have been examined in association with a large number of somatic and mental health conditions. HCC can be used to evaluate disturbances of the HPA axis, including Cushing's syndrome, and to evaluate hydrocortisone treatment. Using HCC, retrospective timelines of cortisol exposure can be created which can be of value in diagnosing cyclic
hypercortisolism
. HCC have also been shown to increase with psychological stressors, including major life events, as well as physical stressors, such as endurance exercise and shift work. Initial studies show that HCC may be increased in depression, but decreased in general anxiety disorder. In posttraumatic stress disorder, changes in HCC seem to be dependent on the type of traumatic experience and the time since traumatization. Increased hair cortisol is consistently linked to obesity, metabolic syndrome and cardiovascular disease. Potentially, HCC could form a future marker for cardiovascular risk stratification, as well as serve as a treatment target.
...
PMID:Clinical applications of cortisol measurements in hair. 2592 11
Chronic glucocorticoid (GC) treatment represents a widely-prescribed therapy for several diseases in consideration of both anti-inflammatory and immunosuppressive activity but, if used at high doses for prolonged periods, it can determine the systemic effects characteristic of Cushing's syndrome. In addition to signs and symptoms of
hypercortisolism
, patients on chronic GC therapy are at risk to develop tertiary adrenal insufficiency after the reduction or the withdrawal of corticosteroids or during
acute stress
. This effect is mediated by the negative feedback loop on the hypothalamus-pituitary-adrenal (HPA) axis, which mainly involves corticotropin-release hormone (CRH), which represents the most important driver of adrenocorticotropic hormone (ACTH) release. In fact, after withdrawal of chronic GC treatment, reactivation of CRH secretion is a necessary prerequisite for the recovery of the HPA axis. In addition to the well-known factors which regulate the degree of inhibition of the HPA during synthetic GC therapy (type of compound, method of administration, cumulative dose, duration of the treatment, concomitant drugs which can increase the bioavailability of GCs), there is a considerable variation in individual physiology, probably related to different genetic profiles which regulate GC receptor activity. This may represent an interesting basis for possible future research fields.
...
PMID:Treatment with Synthetic Glucocorticoids and the Hypothalamus-Pituitary-Adrenal Axis. 2905 78
