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Wind-chill index for sheepBarnes, Timothy Ackley January 2010 (has links)
Digitized by Kansas Correctional Industries
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Some effects of hypophsectomy on cold exposed rats裘大任, Chiu, Ta-jen, Daryl. January 1970 (has links)
published_or_final_version / Physiology / Master / Master of Science
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Wind chill effect for cattle and sheepInsley, Larry Wayne January 2010 (has links)
Digitized by Kansas Correctional Industries
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Respiratory metabolism during supercooling of the iguanid lizard Uta stansburiana Baird and GirardHalpern, Elizabeth Annette, 1942- January 1966 (has links)
No description available.
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Cold tolerance of laboratory-reared diapausing pink bollworms, Pectinophora gossypiella (Saunders)Wright, Robert John, 1953- January 1977 (has links)
No description available.
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Effects of sub-optimal temperatures on marine bacteria.Hess, Ernest. January 1933 (has links)
No description available.
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The Effects of Hypothermia on the Release of Cardiac EnzymesStrawn, William B. 08 1900 (has links)
The myocardium is known to release CPK, LDH1 , and GOT in response to ischemia as a result of myocardial infarction. This study was designed to induce the release of cardiac enzymes without adversely effecting the myocardium by perfusion hypothermia, thereby suggesting that these enzymes are not as specific in the diagnosis of myocardial infarction as once thought.
Hypothermia was by in vivo perfusion of the left anterior descending coronary artery. Enzyme activity was measured from sera samples spectrophotometrically and electrophoretically. Significant CPK and LDH1 increases were observed in animals perfused between 25 and 19 C. These results indicate that, while heart function remained unchanged, an alteration occurred in the membrane integrity of the myocardial cells.
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THE ENVIRONMENTAL AND MUSCLE PHYSIOLOGY OF WINTER-ACTIVE AND WINTER-INACTIVE LIZARDS, SCELOPORUS JARROVI AND SCELOPORUS MAGISTERSchwalbe, Cecil Robert January 1981 (has links)
Field observations indicated a difference in the ability to locomote at low body temperatures in two closely related species of lizards from very different habitats and with radically different seasonal behavior. I measured the critical thermal minimum (the body temperature at which a cooling lizard just loses the ability to right itself) in both species. The winter-active, montane Sceloporus jarrovi had a significantly lower critical thermal minimum in both summer and winter than the winter-hibernating, lowland S. magister. Critical thermal minima were significantly lower in winter than in summer for both species. To determine a physiological basis for these differences, I examined the activity of myosin ATPase, which plays the limiting role in the velocity of muscle contraction, and the energetics of muscle as reflected by high energy phosphate compounds. Microenvironmental conditions were correlated with behavior, constraints on winter activity, and muscle physiology. Ca²⁺-activated myosin ATPase activity in S. magister of valley bottoms is greater than that in the vertical rock-dwelling S. jarrovi. No seasonal acclimatization occurs in myosin ATPase activity in either species. Changes in the muscle metabolism of hibernating animals has been attributed to the lack of muscular contractions in the dormant animals. I measured levels of phosphorylated compounds in a hindlimb muscle from summer and winter lizards of both species. Significant seasonal changes occur in some of the phosphate compounds in both species even though, within a given season, respective levels of phosphorylated compounds are similar in both species. Phosphorylcreatine and total acid-soluble phosphate levels increased in winter animals of both species. Apparently the high levels of phosphorylcreatine in winter S. magister are not simply due to inactivity; winter-active S. jarrovi contain similar amounts. Seasonal cycling of phosphate compounds may relate more to parathyroid status than to muscle activity. Winter activity in S. jarrovi was site-specific and highly dependent on a favorable microclimate. Winter dormancy in S. magister apparently is not dictated by the severity of the microclimate nor physiological limitations of skeletal muscle, but may be strongly influenced by the thermal inertia of that relatively large species.
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Physiological responses to submaximal exercise in a cold and neutral temperature in childrenMarsh, Melinda L. January 1992 (has links)
Physiological and thermoregulatory responses to exercise in a cold environment have been well documented in adults. However, limited information is available regarding the physiological and perceptual responses in children exercising in a cold environment. The purpose of this study was to compare the metabolic, cardiorespiratory, and perceptual responses of children performing submaximal exercise in a cold and neutral temperature. Sixteen children (8 male, 8 female), with a mean ± SD age, height, and weight of 11.4 ± 0.9 yrs, 149.4 ± 8.8 cm, and 40.0 ± 7.2 kg, respectively, participated as subjects in this study. Laboratory assessments occurred on three different days. On the first day of testing, a graded exercise test on a cycle ergometer was administered to determine ventilatory threshold (VT) and VO2max (1.21 + 0.18 I-min-1, 1.74 + 0.21 1-min-1, respectively). On seperate days, subjects cycled in 5°C or 22°C for 30 minutes at an intensity corresponding to VT (103 ± 11 W). The order of testing was counterbalanced. V02, HR, and RPE were assessed every 5 minutes; blood samples from an indwelling catheter were taken every 10 minutes for blood lactate (LA) determination. Data were analyzed using arepeated measure ANOVA. V02, VE, HR, and LA responses were significantly (p < 0.05) higher in the cold (1.36 ± 0.18 vs 1.14 ± 0.18 1-min-1, 35.6 ± 5.3 vs 29.2 ± 5.8 1-min-1, 165.7 ± 12.3 vs 155.9 ± 12.9 bpm, and 2.18 ± 1.18 vs 1.53 ± 0.84 mmol-l-1, respectively) (Mean ± SE). RPE values tended to be higher in the cold (13.6 + 3.4 vs 12.6 + 2.9); however, the difference was not statistically significant (p > 0.05). More research is needed to determine the factors responsible for cold-induced alterations in the exercise response. / School of Physical Education
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The effects of whole body immersion in cold water upon subsequent terrestrial aerobic performance : a study in hypothermiaManley, Elizabeth 04 September 2013 (has links)
This study examined the extent to which physiological and psychological concomitants of aerobic terrestrial performance were affected by body cooling of varying degrees induced by cold water immersion (CWI). Thirteen male and 13 female subjects underwent three randomly assigned 30 min treadmill runs: a control run without prior manipulation of the subjects' thermal status and the same exercise after "central" (core temperature 1°C below pre-immersion) and "peripheral" cooling (skin heat loss 100kcal.m⁻².h⁻¹). During treadmill runs core temperature was measured, together with chest, leg, arm and hand temperatures, from which mean skin temperature (T [subscript]s[subscript]k) and mean body temperature (T[subscript]b) were calculated. Heart rate, oxygen consumption (VO₂,), carbon dioxide production (VCO₂), minute ventilation (V₂ (BTPS)), breathing frequency (f), cadence and ratings of perceived exertion (RPE) and thermal sensation (PTS) were also measured. Both central and peripheral cooling resulted in significantly reduced T[subscript]r[subscript]e (males : control 37.9±0. 3°C; central cooling : 36.8±0.5°C; peripheral cooling: 37.5±0.4°C; females: control: 37.9±0.4°C; central cooling: 37.2±0.5; p<0.05) during subsequent treadmill running, except following peripheral cooling for females (37.9±0.3°C) . For males and females T[subscript]s[subscript]k was lower following peripheral cooling than control values and lowest after central cooling (males: control: 30.0±1.3°C; central cooling: 36.8±0.5°C; peripheral cooling: 37.5±0.4°C; females: control: 30.5±1.2°C; central cooling: 25.9±1.8°C; peripheral cooling: 26.9±1.9°C; p<0.05). Female subjects experienced significantly higher T[subscript]r[subscript]e than males following central and peripheral cooling and a lower T[subscript]s[subscript]k following central cooling. Females experienced less of an increase in heart rate than males during exercise following central and peripheral cooling (control: l57.7±23.7b.min⁻¹; central cooling: 143.5±20.5b.min⁻¹; peripheral cooling 151.7±16.7b.min⁻¹; p<0 .05). Male responses were the same following central cooling but higher for peripheral cooling than control values (control: 139.1±7.3b.min⁻¹; central cooling 134.7±17.5b.min⁻¹; peripheral cooling: 145.0±16.4b.min⁻¹; p<0.05). These data indicate a depression in cardiovascular function for females following peripheral cooling that was not apparent for males. The VO₂ was not different between tests for males; only peripheral cooling resulted in a raised VO₂ of 28.6±3 .3ml.kg⁻¹.min⁻¹ (p<0 .05) for females compared to 27.6±2.6ml.kg⁻¹.min⁻¹ (control). A biphasic response was evident for VO₂ VCO₂ and V[subscript]B (BTPS). For both sexes overall RPE was lower for peripheral cooling (males: 9.4±1.9; females: 8.7±1.3; p<0 .05) than for control and central cooling. Central RPE was only changed for females following peripheral cooling. Changes in cadence and step length together with the effect of low skin and leg temperatures resulted in higher local RPE for females after central cooling (9.6±1.2; p<0.05) than control (9.4±1.9) and peripheral cooling (8.9±1.2 ). Males and females rated the same ambient temperature during the same exercise lower after peripheral cooling (males: 4.6±1.5; females : 5.3±1.3) than control values and lower still after central cooling (males: 3. 8±1.8; females: 2 .7±l. 5) In this study T[subscript]s[subscript]k was the primary determinant of PTS after precooling. / KMBT_363 / Adobe Acrobat 9.54 Paper Capture Plug-in
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