Background: Brown adipose tissue (BAT) preferentially oxidizes stored triglycerides (TAGs) to generate heat during acute exposure to cold. However, the time course of its activation is not well described as we are currently limited to BAT measurements before and after an acute stimulus. Magnetic resonance imaging (MRI) is a preferred modality to uncover such evidence, as it estimates TAG content via fat fraction (FF), and permits repeat scans in the same subject. As such, serial FF measurements in a defined BAT region of interest during a uniform whole-body temperature challenge is warranted.
Objectives: The first objective of this study was to assess the pattern of change in supraclavicular (SCV) BAT and posterior neck subcutaneous adipose tissue (SAT; a region with an unestablished role in non-shivering thermogenesis) FF during a mild cold exposure in adult males. The second objective was to evaluate if indices of body composition were related to the pattern of cold-induced change in SCV BAT FF. The final objective was to assess the influence of warming immediately following cooling on these changes.
Methods: Twelve males between the ages of 19 and 28 were recruited to this cross-sectional study. Users of tobacco, nicotine, and/or alcohol, those with contraindications for magnetic resonance imaging (MRI), and diseases, surgeries, and/or medications associated with thermogenesis were excluded. There were two study visits in total. During the initial visit, anthropometric measurements were carried out in triplicate (i.e. height and weight to determine body mass index (BMI), and body composition measurements (i.e. % body total fat and lean mass (kg)) were obtained using Dual Emission X-Ray Absorptiometry. Within 30 days of this initial visit, subjects attended a time course MRI session. At this visit, participants underwent standardized cold (3-hours at 18°C) and subsequent warm (30 minutes at 32°C) exposures using a water-perfused suit while lying in a 3 Tesla MRI scanner, and the temperature of the water entering and leaving the suit was recorded throughout. FF in the SCV region and posterior neck SAT was measured at defined intervals during both temperature challenges. Separate time course plots of the mean reduction in FF from baseline were constructed for the cooling and warming phases. For the first objective, the rate and magnitude of FF changes in SCV BAT and posterior neck SAT over defined time intervals were determined through calculations of slope and area under the curve (AUC), respectively. Identification of the earliest point of change from baseline, and the point at which changes were no longer different from those measured after 3 hours of cooling, were accomplished through paired comparisons using a random-slope linear mixed model with measures at 0 minutes and 180 minutes used as the reference values, respectively. A random-intercept multilevel regression model was used to define the cold-induced change in FF over time. For the second objective, a Spearman rank-order correlation assessed the association between indices of body composition (i.e. BMI and % total body fat) and indices of BAT activity (i.e. AUC and FF reduction) at time points of interest as identified by objective 1.
Results: The mean±SD of BMI, LMI, and % total body fat were 24.7±2.8kg/m2, 17.6±1.6kg/m2 and 25.0±7.4%, respectively. Seven of the twelve subjects completed three hours of cold exposure (58.3%), and a further five endured at least one hour. A significant cold-induced reduction in SCV BAT FF was detected at 10 minutes following the onset of cold exposure (mean difference = -1.6%; p=0.005), and changes in FF beyond 30 minutes of cooling were similar to those measured after three hours (p<0.05). Meanwhile, the posterior neck SAT did not experience significant cold-induced changes in FF. A novel attempt at identifying a quadratic model to predict one’s BAT-specific response to a cold challenge was carried out, and the intercept, time, time2, and intraclass correlation coefficient (i.e. parameters which described the relationship between FF and time) were highly significant (p<0.001). Although every participant had a measurable decline in FF, those with a higher BMI and % body fat had a smaller magnitude of change throughout the time course. In particular, a strong negative correlation between BMI and AUC FF decline existed as soon as 10 minutes following the onset of cold (rho=-0.786), indicating that those with a lower BMI had a larger magnitude of change in SCV BAT FF at this point. Finally, warming did not visually influence the trajectory of SCV BAT FF.
Limitations: Only seven of the twelve participants completed the full 180 minutes of cold exposure, which further limited the already low statistical power of this study. Moreover, complementary measures of BAT activity, such as energy expenditure, and objective measurements of shivering, such as electromyography, could not be evaluated.
Conclusions: These findings suggest that significant cold-induced changes in BAT FF occur much sooner than three hours. Thus, a shorter duration of cold exposure may be considered in future studies using MRI to detect BAT activity, as this could increase the feasibility of gathering larger and younger sample populations. / Thesis / Master of Science (MSc)
| Identifer | oai:union.ndltd.org:mcmaster.ca/oai:macsphere.mcmaster.ca:11375/23431 |
| Date | January 2018 |
| Creators | Oreskovich, Stephan Mark |
| Contributors | Morrison, Katherine, Medical Sciences |
| Source Sets | McMaster University |
| Language | English |
| Detected Language | English |
| Type | Thesis |
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