View clinical trials related to Thermoregulation.
Filter by:Chilblains, also known as perniosis, is a non-freezing cold injury causing painful inflammatory skin lesions. Chilblains typically affect the dorsal feet or hands, causing inflammatory skin lesions that are often painful, and their pathogenesis remains only partly understood. To improve diagnosis and management, it is vital to focus entirely on chilblains and consider the patient-related and environmental factors that characterize this disorder. Because of this, it's critical to investigate the thermoregulatory function, of individuals with idiopathic chilblains while they are exposed to various environmental conditions (cold and neutral environments).
Acute mirabegron administration has been shown to increase brown fat activity in humans. Long-term mirabegron administration upregulates brown fat, and appears to improve glucose regulation, and change skeletal muscle phenotype.
Aging is associated with impairments in heat loss responses of skin blood flow and sweating leading to reductions in whole-body heat loss. Consequently, older adults store more body heat and experience greater elevations in core temperature during heat exposure at rest and during exercise. This maladaptive response occurs in adults as young as 40 years of age. Recently, heat acclimation associated with repeated bouts of exercise in the heat performed over 7 successive days has been shown to enhance whole-body heat loss in older adults, leading to a reduction in body heat storage. However, performing exercise in the heat may not be well tolerated or feasible for many older adults. Passive heat acclimation, such as the use of warm-water immersion may be an effective, alternative method to enhance heat-loss capacity in older adults. Thus, the following study aims to assess the effectiveness of a 7-day warm-water immersion (~40°C) protocol in enhancing whole-body heat loss in older adults. Warm-water immersion will consist of a one-hour immersion in warm water with core temperature clamped at 38.5°C. Improvements in whole-body heat loss will be assessed during an incremental exercise protocol performed in dry heat (i.e., 40°C, ~15% relative humidity) prior to and following the 7-day passive heat acclimation protocol. The incremental exercise protocol will consist of three 30 minute exercise bouts performed at increasing fixed rates of metabolic heat production (i.e., 150, 200, and 250 W/m2), each separated by 15-minutes of recovery, with exception final recovery will be 1-hour in duration) performed in a direct calorimeter (a device that provides a precise measurement of the heat dissipated by the human body).
Sleep deprivation has long been thought to modulate thermoregulatory function. Seminal work on sleep deprivation and thermoregulation has demonstrated that sleep-deprived individuals experience greater elevations in core temperature during exercise-heat stress due to reductions in the activation of local heat loss responses of cutaneous vasodilation and sweating. However, it remains unclear 1) if reductions in local heat loss responses would compromise whole-body heat loss (evaporative + dry heat exchange) and 2) if differences exist, are they dependent on the heat load generated by exercise (increases in metabolic rate augments the rate that heat must be dissipated by the body). Further, much of the understanding of the effects of sleep deprivation on thermoregulation has been limited to assessments in young adults. Studies show that aging is associated with reduction in cutaneous vasodilation and sweating that compromise whole-body heat loss exacerbating body heat storage during moderate- and especially more vigorous-intensity exercise in the heat. However, it remains unclear if sleep deprivation may worsen this response in older adults. The purpose of this study is therefore to evaluate the effects of sleep-deprivation on whole-body total heat loss during light, moderate, and vigorous exercise-heat stress and to assess if aging may mediate this response. To achieve this objective, direct calorimetry will be employed to measure whole-body total heat loss in young (18-30 years) and older (50-65 years) men during exercise at increasing, fixed rates of metabolic heat production of 150 (light), 200 (moderate), and 250 W/m2 (vigorous) in dry heat (40°C, ~15% relative humidity) with and without 24 hours of sleep deprivation.
It is still unknown when the first bath should be done in premature newborns. Investigators think that delaying the time of the first bath compared to the time in the clinic will show some positive changes in preterm newborns.
Sleep propensity was assessed in terms of the duration of a spontaneous episode of wakefulness (W). Skin temperatures at six body sites (the abdomen, pectoral region, eye, hand, thigh and foot) were measured (using infrared thermography) during nocturnal polysomnography in 29 9-day-old preterm neonates (postmenstrual age: 209 9 days). Te investigators then determined whether the duration of the W episode depended upon the local skin temperatures measured at the start, during and end of the episode.
This study evaluates the impact of active thermoregulation on free flap microcirculation following free flap transfer. Thermoregulation is performed by passive warming, active warming (water circulation based device) and active cooling. Changes in microcirculation are assessed using combined laser Doppler flowmetry and remission spectroscopy.
In humans, the primary means of cooling the body during exercise is through the evaporation of sweat from the skin surface. Clothing represents a layer of insulation that hinders the evaporation of sweat from the surface of the skin. It follows that clothing that imposes the least amount of resistance to evaporative heat loss may prove beneficial to the thermoregulatory, physiological and perceptual response to exercise, particularly in elite endurance-trained athletes. Thus, the purpose on this study is to examine the influence of wearing a sportswear garment made of a fabric (100% nylon) with superior evaporative characteristics on detailed thermoregulatory, cardiorespiratory, metabolic and perceptual responses to maximal exercise testing at normal room temperature and relatively humidity in a group of 25 endurance-trained cyclists and triathletes aged 20-60 years. It is hypothesized that wearing a garment made of 100% nylon will improve exercise performance (e.g., exercise endurance time) and that this improvement will reflect improvements in thermoregulatory, cardiorespiratory, metabolic and perceptual responses to exercise. Athletes will be recruited via contact with coaches of the McGill University Cycling and Triathlon teams as well as through contact with coaches of competitive cycling and triathlon teams/training groups in the Montreal and surrounding area. Initial contact will consist of a thorough explanation of the study procedures and pre-screening for the inclusion/exclusion criteria prior to study consent by the Principal Investigator and/or his delegate, either in person or by telephone or email. Eligible participants will visit McGill's Clinical Exercise & Respiratory Physiology Laboratory on 3 separate occasions over a period of 10-14 days. Visit 1 will include a maximal incremental bicycle exercise test for familiarization purposes and to determine maximal power output (MPO). Visits 2 and 3 will include a constant-power-output bicycle exercise test at 85% MPO under one of two conditions, in randomized order: (1) while wearing a garment made of 100% polyester, i.e., placebo; and (2) while wearing a garment made of 100% nylon, i.e., cooling fabric. At rest and during exercise at visits 2 and 3, detailed assessments of core body temperature will be made using a temperature sensor placed into the esophagus, while skin temperature and other physiological and perceptual parameters will be measured using standard techniques.