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Thermoregulatory control of human body temperature is of paramount importance for normal bodily functions. Exposure of the upper and lower limbs to localized cold stress can cause cold-induced injuries and often lower limbs are more susceptible to damages from cold-induced injuries. In this study, we use infrared thermal imaging to probe localized cold stress induced cutaneous vasoconstriction of lower limbs in 33 healthy subjects. The cold stress is actuated by applying ice to the plantar surfaces of the lower limbs for 180 s and after removal of the cold stress, infrared thermography is utilized to non-invasively monitor the time-dependent variations in vein pixel temperatures on the dorsal surfaces of the stimulated and non-stimulated feet. It is observed that the vein pixel temperature of the stimulated foot showed a non-monotonic variation with time, consisting of an initial decrease and the presence of an inversion time, beyond which temperature is regained. The initial decrease in vein pixel temperature of the stimulated foot is attributed to the reduced blood flow caused by the cold stress induced severe vasoconstriction. Beyond the inversion time, the vein pixel temperature is found to increase due to rewarming of the surrounding skin. Experimental findings indicate that the inversion time linearly increased with the age of the subject, indicating a reduced thermoregulatory efficiency for the aged subjects. This study provides a thermal imaging-based insight into the skin temperature re-distribution during the early stages of blood perfusion in lower limbs, after an exposure to a localized acute cold stress. https://www.selleckchem.com/products/lw-6.html Statistical analyses reveal that subject height, weight, body-mass index and gender do not influence the inversion time significantly. The experimental findings are important towards rapid evaluation of personnel fitness for deployment in extreme cold environment, treatment of cold-induced injuries and probing of thermoregulatory impairments.In order to simulate the heat transfer in the process of hyperthermia, one-dimensional time-fractional Cattaneo heat transfer equation (TFHE) is established. Based on TFHE, the heat transfer model is solved by using finite difference method, because a single layer of biological tissue in vitro is irradiated by electromagnetic energy. The effect of power parameters (energy flux density P0, tissue attenuation coefficient h) and equation parameters (relaxation time τq and fractional order β) on the prediction of temperature simulated by TFHE were studied. Furthermore, comparative studies on TFHE, Pennes and CV are performed and evaluated. In the heating process, because of the existence of relaxation time τq, the temperature response of TFHE and CV are later than Pennes, leading to the lower temperature prediction of TFHE and CV than that of Pennes. The shorter the time is, the higher the energy is, and the more obvious the difference is.Many populations have evolved in response to laboratory environments (lack of predators, continual food availability, etc.). Another potential agent of selection in the lab is exposure to constant thermal environments. Here, we examined changes in growth, critical thermal maximum (CTmax), and food consumption under constant (25 °C) and fluctuating (22-28 °C and 19-31 °C) conditions in two populations of fathead minnows, Pimephales promelas one that has been kept in a laboratory setting for over 120 generations (~40 years) and a corresponding wild one. We found that under thermal fluctuations, domesticated fathead minnows grew faster than their wild counterparts, but also exhibited lower thermal tolerance. Food consumption was significantly higher in the lab population under the constant and large fluctuation thermal treatments. Our results suggest that the lab population has adjusted to the stable conditions in the laboratory and that we should carefully apply lessons learned in the lab to wild populations.Understanding how behavioural adaptations can limit thermal stress for intertidal gastropods will be crucial for climate models. Some behavioural adaptations are already known to limit desiccation and thermal stresses as shell-lifting, shell-standing, towering, aggregation of conspecifics or habitat selection. link2 Here we used the IRT (i.e. infrared thermography) to investigate the thermal heterogeneity of a rocky platform, with four different macrohabitats (i.e. bare rock, rock with barnacles, mussels and mussels incrusted by barnacles) over four thermally contrasted months. We investigated the body temperature of Littorina littorea and Patella vulgata found on this platform and the temperature of their microhabitat (i.e. the substratum within one body length around of each individual). We also considered the aggregation behaviour of each species and assessed the percentage of thermal microhabitat choice (i.e choice for a microhabitat with a temperature different than the surrounding substrate). We did not find any aggregation of L. littorea on the rocky platform during the four studied months. In contrast, P. vulgata were found in aggregates in all the studied periods and within each habitat, but there was no difference in body temperature between aggregated and solitary individuals. These two gastropods species were preferentially found on rock covered by barnacles in the four studied months. The presence of a thermal microhabitat choice in L. littorea and P. vulgata is habitat-dependent and also season-dependent. In June, July and November the choice was for a microhabitat with temperatures lower than the temperatures of the surrounding substrate whereas in December, individuals choose microhabitats with higher temperatures than the temperatures of their substratum. Taken together, these results suggest that gastropods species are able to explore their environment to find sustainable thermal macrohabitats and microhabitats and adapt this behaviour in function of the conditions of temperatures.The mammary gland is a privileged organ for mammals. Because of their high capacity for milk synthesis, dairy ruminants have been distributed throughout the world. In tropical areas, dairy animals face high ambient temperatures (HTa). The indirect effect of HTa on milk synthesis is mediated in part by a reduction in feed intake. The current experiment focused on the direct natural effect of HTa on mammary function. Multiparous Saanen goats were used in this study. The physiological responses for HTa were evaluated from the control period during the winter and from the natural HTa during the summer. Milk samples were collected for isolation of the goat milk cells to study the expression of the β-1,4 galactosyltransferase (β-GALT1), Akt, and heat shock protein 70 (HSP70) genes. Although goats in the summer maintained rectal temperature and plasma cortisol levels similar to those observed in the winter, the higher respiratory rate and lower feed intake and milk yield (MY) from the goats in the summer indicated that the goats in the summer were exposed to a higher degree of HTa. This was supported by the significantly higher level of plasma glutathione peroxidase (GPX) activity. Moreover, the relative expression levels of β-GALT1 and Akt were not different. The relative expression of HSP70 during the summer was significantly higher than what was observed in cells isolated in the winter. In conclusion, the HTa effect on MY during the summer was related to its indirect effect on feed intake. The direct HTa effect might be related to HSP70 gene expression in goat milk cells and to plasma GPX activity. link3 However, the natural HTa did not affect the expression of Akt or β-GALT1.Global warming increasingly challenges thermoregulation in endothermic animals, particularly in hot and dry environments where low water availability and high temperature increase the risk of hyperthermia. In birds, un-feathered body parts such as the head and bill work as 'thermal windows', because heat flux is higher compared to more insulated body regions. We studied how such structures were used in different thermal environments, and if heat flux properties change with time in a given temperature. We acclimated zebra finches (Taeniopygia guttata) to two different ambient temperatures, 'cold' (5 °C) and 'hot' (35 °C), and measured the response in core body temperature using a thermometer, and head surface temperature using thermal imaging. Birds in the hot treatment had 10.3 °C higher head temperature than those in the cold treatment. Thermal acclimation also resulted in heat storage in the hot group core body temperature was 1.1 °C higher in the 35 °C group compared to the 5 °C group. Hence, the thermal gradient from core to shell was 9.03 °C smaller in the hot treatment. Dry heat transfer rate from the head was significantly lower in the hot compared to the cold treatment after four weeks of thermal acclimation. This reflects constraints on changes to peripheral circulation and maximum body temperature. Heat dissipation capacity from the head region increased with acclimation time in the hot treatment, perhaps because angiogenesis was required to reach peak heat transfer rate. We have shown that zebra finches meet high environmental temperature by heat storage, which saves water and energy, and by peripheral vasodilation in the head, which facilitates dry heat loss. These responses will not exclude the need for evaporative cooling, but will lessen the amount of energy expend on body temperature reduction in hot environments.This study had the following objectives (i) to evaluate the thermoregulatory and behavioral responses of light laying hens supplemented with different types and dosages of phytases in the two day shifts; and (ii) to integrate the thermoregulatory and behavioral responses with performance of these birds raised in a hot environment. 270 light laying hens of the Hy-Line White lineage, with a body weight of 1.60 ± 0.092 kg were distributed in a completely randomized design in a 2 × 2 + 1 factorial model with two types of phytases (bacterial and fungal) and two dosages (450 and 900 FTU), and a control diet. The day shift (morning and afternoon) was considered as a fixed effect in the factorial arrangement. Principal component analysis (PCA), correspondence analysis (CA) and canonical discriminant analysis (CDA) were used. There was no interaction (P > 0.05) between phytases and dosages for thermoregulatory responses. Respiratory rate (RR), cloacal temperature (CT), and surface temperature with feathers (STWF) and uction; and (iii) phytases (450 and 900 FTU) do not interfere with productive, behavioral and thermoregulatory responses.Heat stress is one of the greatest issues of the dairy industry in regions with hot climate. Since coat color appears to be related to heat stress adaptiveness, we compared rectal temperatures and surface temperatures of Red-and-white (RW, n = 14) and Black-and-white (BW, n = 16) Holstein cows using infrared thermography in both cold (July; mean temperature 15.5 °C) and hot (March; mean temperature 30.5 °C) seasons in Southern Brazil. Thermographic images were taken from the left side of the animal at a distance of 4 m. The images obtained were then analyzed using the software Testo IRSoft. The variables obtained by thermography of the body surface include the temperature of non-pigmented patches, obtained using the average of five spots on white patches in a rectangle drawn on the body of the cow from the scapula to the ilium of the cow until the middle of the ribs; the temperature of pigmented patches, obtained using an average of 5 pigmented spots on the same rectangle; the temperature at the hottest spot and the temperature at the coldest spot, within the same rectangle.

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