1.
Modulation of thermogenesis and metabolic health: a built environment perspective.
van Marken Lichtenbelt, WD, Pallubinsky, H, Te Kulve, M
Obesity reviews : an official journal of the International Association for the Study of Obesity. 2018;:94-101
Abstract
Lifestyle interventions, obviating the increasing prevalence of the metabolic syndrome, generally focus on nutrition and physical activity. Environmental factors are hardly covered. Because we spend on average more that 90% of our time indoors, it is, however, relevant to address these factors. In the built environment, the attention has been limited to the (assessment and optimization of) building performance and occupant thermal comfort for a long time. Only recently well-being and health of building occupants are also considered to some extent, but actual metabolic health aspects are not generally covered. In this review, we draw attention to the potential of the commonly neglected lifestyle factor 'indoor environment'. More specifically, we review current knowledge and the developments of new insights into the effects of ambient temperature, light and the interaction of the two on metabolic health. The literature shows that the effects of indoor environmental factors are important additional factors for a healthy lifestyle and have an impact on metabolic health.
2.
Eight weeks of overfeeding alters substrate partitioning without affecting metabolic flexibility in men.
Peterson, CM, Zhang, B, Johannsen, DL, Ravussin, E
International journal of obesity (2005). 2017;(6):887-893
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Abstract
BACKGROUND/OBJECTIVE Impairments in metabolic flexibility (MF) and substrate handling are associated with metabolic syndrome. However, it is unknown whether metabolic inflexibility causes insulin resistance. We therefore measured MF and substrate handling before and after 8 weeks of overfeeding in initially healthy adults as a model of the early stages of insulin resistance. SUBJECTS/METHODS Twenty-nine healthy men (27±5 years old; body mass index 25.5±2.3 kg m-2) were overfed by 40% above baseline energy requirements for 8 weeks and gained 7.6±2.1 kg of weight. Before and after overfeeding, energy expenditure, substrate oxidation and MF were measured in two ways: (a) during 1 day of eucaloric feeding in a whole-room indirect calorimeter and (b) during a two-step hyperinsulinemic-euglycemic clamp. RESULTS Eight weeks of overfeeding decreased insulin sensitivity at low and high doses of insulin (P=0.001 and P=0.06, respectively). This was accompanied by decreases in the respiratory quotient (RQ) while sleeping (from 0.877±0.020 to 0.864±0.026; P=0.05) and at low insulin levels during the clamp (from 0.927±0.047 to 0.907±0.032; P=0.01). Overfeeding did not affect MF as measured during a clamp (P⩾0.17), but it tended to increase 24-h MF (awake RQ-sleep RQ) as measured by chamber by 0.010±0.028 (P=0.08). In terms of substrate oxidation, overfeeding increased protein oxidation by 13±23 g day-1 (P=0.003) and tended to increase fat oxidation by 6±16 g day-1 (P=0.07) but did not affect carbohydrate oxidation (P=0.64). Individuals with greater metabolic adaptation to overfeeding had higher carbohydrate oxidation rates (r=0.66, P=8 × 10-5) but not fat oxidation rates (P=0.09). CONCLUSIONS The early stages of insulin resistance are accompanied by modest declines in the RQs during sleep and during a clamp, with no changes in fasting RQ or signs of metabolic inflexibility. Our data therefore suggest that metabolic inflexibility does not cause insulin resistance.
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The effects of indoor and outdoor temperature on metabolic rate and adipose tissue - the Mississippi perspective on the obesity epidemic.
Turner, JB, Kumar, A, Koch, CA
Reviews in endocrine & metabolic disorders. 2016;(1):61-71
Abstract
Global warming, primarily caused by emissions of too much carbon dioxide, and climate change is a reality. This will lead to more extreme weather events with heatwaves and flooding. Some studies propose an association between thermal exposures and the prevalence of obesity with an increasing trend towards time spent in the thermal comfort zone. Longterm exposure to the thermal comfort zone can lead to a reduction of brown adipose tissue activity with an impact on energy expenditure and thermogenesis. Reduced seasonal cold exposure in combination with reduced diet-induced thermogenesis by a highly palatable high-fat and high-sugar diet and reduced physical activity contribute to the prevalence of obesity and the metabolic syndrome.