Abstract

How humans adapt to negative energy balance is critical for understanding the physiology of energy storage and more broadly how mammals maintain energy stores during food scarcity. Also, understanding negative energy balance is crucial for understanding and treating obesity, which is epidemic in developed countries. During negative energy balance, fat stores diminish and energy expenditure declines. Previous studies have documented that during energy restriction, only small changes in basal metabolic rate and the thermic effect of food occur, implying that activity thermogenesis (AT) may contribute substantively to energy modulation during negative energy balance. In this proposal we will examine AT during negative energy balance in lean and obese human subjects.
In Specific Aim 1 we will address the hypothesis that AT decreases during energy restriction in lean individuals. Here, we will not only ascertain how non-exercise activity thermogenesis (NEAT) changes during 1000 kcal/day negative energy balance but also tease apart how the components of AT change. Specifically, we will study the effects of negative energy balance on, sitting, standing, walking, changing posture and fidgeting thermogenesis.
In Specific Aim 2 we will address the hypothesis that obesity is associated with exaggerated decline in NEAT during underfeeding. Here, we will energy restrict obese and lean subjects and measure NEAT and its components before and after underfeeding. Also, to ascertain whether differences between the obese and lean subjects relate to excess adiposity alone or to the susceptibility of an individual to obesity, we will similarly underfeed a group of post-obese subjects. Our third specific aim is incredibly exciting. Here, we want to determine whether an imposed 200 kcal/day of walking in addition to energy restriction, attenuates the decline in AT with underfeeding in lean, obese and post-obese subjects. We want to know this, in part, from a mechanistic perspective in order to gain insight into how volitional AT is impacted by imposed walking. Also, this will help us to better understand how to treat our obese patients and to define the energetic benefit of combining a walking program with energy restriction. In conclusion, this program will allow us to define for the first time how AT, NEAT and its components change during negative energy balance in lean individuals. Next, these studies will provide us with enormous insight regarding how obese patients adapt energetically during negative energy balance. Finally, we will gain fundamental information regarding the metabolic implications of combining food restriction with a walking program compatible to that advocated by statutory agencies. These studies will lead to improved understanding of the energetic adaptation that occurs during negative energy balance and how best to treat patients with obesity.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK)
Type
Research Project (R01)
Project #
5R01DK063226-04
Application #
7003636
Study Section
Nutrition Study Section (NTN)
Program Officer
Kuczmarski, Robert J
Project Start
2003-02-15
Project End
2007-12-31
Budget Start
2006-01-01
Budget End
2006-12-31
Support Year
4
Fiscal Year
2006
Total Cost
$560,529
Indirect Cost

  Institution

Name
Mayo Clinic, Rochester
Department
Type
DUNS #
006471700
City
Rochester
State
MN
Country
United States
Zip Code
55905

  Publications

Levine, James A; McCrady-Spitzer, Shelly K; Bighorse, William (2016) Obesity and sexual abuse in American Indians and Alaska Natives. J Obes Weight Loss Ther 6:
Ben-Ner, Avner; Hamann, Darla J; Koepp, Gabriel et al. (2014) Treadmill workstations: the effects of walking while working on physical activity and work performance. PLoS One 9:e88620
Koepp, Gabriel A; Manohar, Chinmay U; McCrady-Spitzer, Shelly K et al. (2013) Treadmill desks: A 1-year prospective trial. Obesity (Silver Spring) 21:705-11
Kaufman, Kenton R; Frittoli, Serena; Frigo, Carlo A (2012) Gait asymmetry of transfemoral amputees using mechanical and microprocessor-controlled prosthetic knees. Clin Biomech (Bristol, Avon) 27:460-5
Mitre, Naim; Foster, Randal C; Lanningham-Foster, Lorraine et al. (2011) The energy expenditure of an activity-promoting video game compared to sedentary video games and TV watching. J Pediatr Endocrinol Metab 24:689-95
Thomas, Diana M; Martin, Corby K; Heymsfield, Steven et al. (2011) A Simple Model Predicting Individual Weight Change in Humans. J Biol Dyn 5:579-599
Manohar, C U; McCrady, S K; Fujiki, Y et al. (2011) Evaluation of the Accuracy of a Triaxial Accelerometer Embedded into a Cell Phone Platform for Measuring Physical Activity. J Obes Weight Loss Ther 1:
Thomas, Diana M; Schoeller, Dale A; Redman, Leanne A et al. (2010) A computational model to determine energy intake during weight loss. Am J Clin Nutr 92:1326-31
McCrady-Spitzer, Shelly K; Levine, James A (2010) Integrated electronic platforms for weight loss. Expert Rev Med Devices 7:201-7
Novak, Colleen M; Escande, Carlos; Burghardt, Paul R et al. (2010) Spontaneous activity, economy of activity, and resistance to diet-induced obesity in rats bred for high intrinsic aerobic capacity. Horm Behav 58:355-67

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