• Refine Query
  • Source
  • Publication year
  • to
  • Language
  • 6
  • Tagged with
  • 8
  • 8
  • 4
  • 3
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 1
  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

The links between energetics and over-winter survival in small rodents

Jackson, Diane Margaret January 1999 (has links)
No description available.
2

Food Intake During Cold Exposure: Effects of the Quantity of Food Ingested on Shivering and Nonshivering Thermogenesis

Fortin-Lacombe, Jessica 21 December 2020 (has links)
Humans are known as homeothermic endotherms. To ensure thermic balance at rest when exposed to cold, they dispose of two main thermogenic processes: shivering thermogenesis (ST) and non-shivering thermogenesis (NST). ST consists of involuntary muscle contractions and NST represents the component of Hprod that is not ST. While ST is difficult to tolerate, it is not yet known which nutrients and how much are required to stimulate NST and lower ST in the cold. Whether or not food caloric intake has an impact on the relative contribution of ST and NST to total Hprod remains to be determined. Therefore, the purpose of this thesis was 1) to quantify the effects of ingesting two quantities (1507 vs 3015 kJ) of same relative compositions on cold-induced whole-body Hprod and 2) to establish the effects of these two quantities of food on the relative contribution of ST and NST to total Hprod. Five healthy male participants were exposed to a 3h mild cold, using a liquid conditioned suit with water flowing at 15°C (COLD) or 33 °C (CON) for a total of 4 trials. Thermal, metabolic and shivering responses were measured at baseline, before and after shake ingestion. Results demonstrated that Hprod and ST intensity increased in the cold, while no significant differences were found between the ingested shakes at two different caloric equivalents. In addition, ST intensity did not change, which confirmed that NST remained the same between the two conditions. Thus, knowing that the caloric intake will not maximize the thermogenic effects in the cold (i.e. improve the comfort of the individual), is it more advantageous to bring food or additional clothing, for any activity? Clearly, more research on the exact pathways of each processes in the cold with food consumption needs to be made. To that extent, the investigation of the effect of food quality on changes in the thermogenic processes during cold exposure strikes us as a fascinating area for future research.
3

The Effect of Cold Acclimation on Changes in Muscle Activity

Hans Christian, Tingelstad 24 October 2013 (has links)
Human beings have been exposed to different cold conditions throughout time, and have through cold acclimation developed mechanisms to survive in these conditions. Cold acclimation can be elicited through exposure to natural cold climates, or artificially induced in a laboratory to study the body’s response to repeated cold exposures. Several studies looking at the effects of cold acclimation in humans have been conducted during the last 50 years, and have reported that cold acclimation can lead to a change in skin and core temperature, heat production and shivering. An accurate quantification of shivering thermogenesis (ST) during cold acclimation has not been done before, and most previous measurements of shivering during cold acclimation have been inaccurate and inadequate. In this study a Liquid Condition Suits (LCS) was used to elicit cold acclimation (10°C, 2hr daily, for 4 weeks) while an accurate measurement of the effect of cold acclimation on changes in muscle activity was conducted. In CHAPTER 2, results showed that four weeks of cold acclimation at 10°C did not change skin and core temperature, heat production or ST. The effects on shivering pattern and fuel selection were also analysed, but no effects of cold acclimation could be observed. These measurements were a part of a larger study, in which the effects of cold acclimation on changes in BAT were the main outcome measures. These data showed that an increase in BAT volume (45%) and activity (120%) were the only observed effects of cold acclimation. In CHAPTER 3, we set out to assess if changes in shivering from pre to post cold acclimation are associated with changes in BAT volume, and if the amount of BAT a participant possesses prior to cold acclimation can be used to predict changes in shivering intensity during cold acclimation. The interindividual variability in changes in thermal responses, heat production, shivering and BAT volume occurring between subjects during four weeks of cold acclimation was also addressed in this section.
4

The Effect of Cold Acclimation on Changes in Muscle Activity

Hans Christian, Tingelstad January 2013 (has links)
Human beings have been exposed to different cold conditions throughout time, and have through cold acclimation developed mechanisms to survive in these conditions. Cold acclimation can be elicited through exposure to natural cold climates, or artificially induced in a laboratory to study the body’s response to repeated cold exposures. Several studies looking at the effects of cold acclimation in humans have been conducted during the last 50 years, and have reported that cold acclimation can lead to a change in skin and core temperature, heat production and shivering. An accurate quantification of shivering thermogenesis (ST) during cold acclimation has not been done before, and most previous measurements of shivering during cold acclimation have been inaccurate and inadequate. In this study a Liquid Condition Suits (LCS) was used to elicit cold acclimation (10°C, 2hr daily, for 4 weeks) while an accurate measurement of the effect of cold acclimation on changes in muscle activity was conducted. In CHAPTER 2, results showed that four weeks of cold acclimation at 10°C did not change skin and core temperature, heat production or ST. The effects on shivering pattern and fuel selection were also analysed, but no effects of cold acclimation could be observed. These measurements were a part of a larger study, in which the effects of cold acclimation on changes in BAT were the main outcome measures. These data showed that an increase in BAT volume (45%) and activity (120%) were the only observed effects of cold acclimation. In CHAPTER 3, we set out to assess if changes in shivering from pre to post cold acclimation are associated with changes in BAT volume, and if the amount of BAT a participant possesses prior to cold acclimation can be used to predict changes in shivering intensity during cold acclimation. The interindividual variability in changes in thermal responses, heat production, shivering and BAT volume occurring between subjects during four weeks of cold acclimation was also addressed in this section.
5

The Effects of Cold Acclimation on the Thermogenic Capacity of Skeletal Muscle in Mice Deficient in Brown Adipose Tissue

Mineo, Patrick M. 26 April 2010 (has links)
No description available.
6

Contextual Induction of Non-Shivering Thermogenesis and Skeletal Muscle Futile Calcium Cycling in Two Rat Models

Heemstra, Lydia A. 27 July 2021 (has links)
No description available.
7

The in vivo role of AMP-activated protein kinase in the metabolic function of brown and beige adipose tissue

Desjardins, Eric January 2016 (has links)
Brown (BAT) and white (WAT) adipose tissues are significant contributors to whole-body energy homeostasis. A disturbance in their metabolic function could result in the development of obesity and subsequent metabolic complications. The energy-sensing enzyme of the cell, AMP-activated protein kinase (AMPK), has been vastly studied in skeletal muscle and liver, but its role in BAT and WAT metabolism is elusive. We generated an inducible, adipocyte-specific knockout mouse model for the two AMPK β subunits (iβ1β2AKO) and found that iβ1β2AKO mice were intolerant to cold, and resistant to β3-adrenergic activation of BAT and browning of WAT. These defects in BAT activity were not due to the AMPK-ACC axis, but instead were due to compromised integrity of mitochondria. Mitochondrial morphology, function, and autophagy were all distorted in iβ1β2AKO mice, measured via transmission electron microscopy (TEM), respiration, and immunoblotting, respectively. These findings provide strong evidence that adipocyte AMPK regulates a fine-tuned program that responds to environmental and pharmacological inputs by maintaining mitochondrial integrity through autophagy and subsequent mitochondrial biogenesis in chronic settings. / Thesis / Master of Science (MSc) / Traditionally, there are two types of adipose tissue that appear and function differently. White adipose tissue (WAT) has evolved to store away energy in an efficient manner for later use. In contrast, brown adipose tissue (BAT) is a unique organ in mammals that has evolved over time to maintain body temperature. In essence, BAT has the ability to burn away calories as heat and is a promising therapeutic target to combat obesity and metabolic diseases such as type 2 diabetes. In our study, we have identified a potential factor that not only promotes BAT activity, but also promotes WAT to function more like BAT. By targeting this factor through drugs, there is potential to increase resting metabolic rate and fight the global epidemic of obesity.
8

<b>Functional Characterization of LETM1-Domain Containing 1 (LETMD1) in Brown Adipocyte Mitochondria</b>

Madigan McKenna Snyder (19174837) 18 July 2024 (has links)
<p dir="ltr">Adipose tissue consists of adipocytes that store energy within lipid droplets and are a central component of lipid metabolism. Mammals contain white, brown and beige adipocytes, which differ in their metabolic roles. White adipocytes store energy, in the form of triglycerides, within lipid droplets and predominantly take on an energy storage role. Brown and beige adipocytes promote energy expenditure and the dissipation of energy as heat through non-shivering thermogenesis. Since energy expenditure combats excess caloric intake and overeating, non-shivering thermogenesis has become heavily researched for its potential therapeutic use in combatting the continued increase in obesity and metabolic disorders worldwide.</p><p dir="ltr">In addition to ATP synthesis, mitochondria are required for a multitude of metabolic processes that maintain cellular homeostasis, including non-shivering thermogenesis. Brown and beige adipocyte mitochondria are specialized to perform non-shivering thermogenesis in response to an environmental stressor like cold exposure. Uncoupling protein 1 (UCP1) is uniquely characteristic of brown and beige adipocyte mitochondria, because it allows oxidative phosphorylation to be uncoupled from ATP synthesis. In order to enhance non-shivering thermogenesis, ongoing molecular characterization of brown adipose tissue (BAT) is being conducted to identify proteins that regulate mitochondrial function and UCP1 activity. In this study, I explored the function of LETM1-domain containing 1 (LETMD1), a novel mitochondrial inner membrane protein with unknown function in BAT. We generated a global (<i>Letmd1</i><sup><em>KO</em></sup>) and UCP1+ cell-specific <i>(Letmd1</i><sup><em>UKO</em></sup><i>) knockout</i><i> </i>mouse model to study the whole-body and cell-autonomous role of LETMD1 in BAT, respectively. Loss-of-function studies resulted in striking, BAT-specific phenotypic differences, including whitened BAT under thermoneutral, room temperature and cold exposure. Both knockout models were cold intolerant without access to food, and became hypothermic within a few hours of fasted cold exposure. Loss of normal mitochondria structure and cristae arrangement were also evident in knockout BAT, resulting in a decreased number of mitochondria and decreased number of cristae per mitochondrion. Mitochondrial DNA copy number was also significantly decreased in both knockout models. Abnormal mitochondria morphology was supported by increased reactive oxygen species (ROS) accumulation in both knockout models and the visualization of protein aggregates and mitophagy-like morphologies in <i>Letmd1</i><sup><em>UKO</em></sup><i> </i><i>mice specifically</i>. TurboID proximity labeling of brown adipocytes revealed enrichment of several respiratory chain complex proteins, mitochondrial ribosome proteins and mitochondrial protein import machinery. Moreover, the aggregation of misfolded nuclear-encoded mitochondrial proteins, including several respiratory chain and mitochondrial ribosome proteins, suggested that LETMD1 facilitates mitochondrial protein import and mitochondrial ribosome assembly, thereby compromising respiratory chain assembly and function during non-shivering thermogenesis. Overall, this study identifies LETMD1 as a novel regulator of brown adipocyte mitochondrial structure and thermogenic function and highlights the requirement of LETMD1 for mitochondrial biogenesis.</p>

Page generated in 0.1501 seconds