J. C. Peters scite author profile

We compared, across several physiological variables, rats most and least susceptible to develop obesity when given a high-fat diet. After 4 wk of eating a high-fat diet (60% of calories from fat), rats in the upper (obesity prone, OP) and lower (obesity resistant, OR) quartiles for weight gain were further studied. OP rats ate significantly more than OR rats, but this did not completely explain differences in their susceptibility to dietary obesity. No differences in 24-h energy expenditure were found between groups. OR rats had a significantly lower 24-h respiratory quotient, indicative of a greater relative proportion of fat oxidation and lower plasma levels of free fatty acids (FFA) than OP rats. Thus the ability to avoid dietary obesity produced by a high-fat diet may depend on an ability to increase fat oxidation in response to increased fat intake. Insulin sensitivity, measured by a euglycemic insulin clamp, was significantly higher in OR than OP rats. We cannot determine from these data whether insulin resistance developed as a consequence of elevated FFA levels or whether the ability to oxidize FFA declined as a result of development of insulin resistance. In summary, we propose that rats able to resist becoming obese on a high-fat diet have the ability to adjust the composition of fuel oxidized to the fuel composition of the diet with a minimum increase in body fat. The specific mechanisms by which this occurs are unknown but may be related to effects of diet on insulin sensitivity.

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Effects of diet complexity and dietary lactose levels during three starter phases on postweaning pig performance123

Mahan

Fastinger

Peters

2004

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Four experiments involving 1,005 crossbred pigs weaned at 19 +/- 2 d of age evaluated the effect of diet complexity and lactose level on starter pig performances. Experiment 1 was a randomized complete block (RCB) conducted in nine replicates with 135 pigs. A complex diet using several protein sources, a semicomplex diet with fewer protein sources, and a simple diet of corn and soybean meal comprised the three treatment groups. All diets contained 25% lactose (as-fed basis) with lysine (total) constant from d 0 to 14 (1.55%) and d 14 to 28 (1.45%), respectively. Gain, feed intake, and feed efficiency (P < 0.05) improved as diet complexity increased during both periods. In Exp. 2, 240 pigs in eight replicates in a RCB design were fed complex diets, but dietary lactose (total; as-fed basis) levels ranged from 10 to 35% in 5% increments from 0 to 14 d after weaning. From 14 to 30 d, a common 17% lactose diet was fed to evaluate the effects of early lactose level on subsequent responses. Gains (P < 0.05) increased for the 0- to 7- and 0- to 14-d periods as lactose increased to 30%. Similar gains resulted for all treatment groups from 14 to 30 d after weaning, with no evidence of compensatory responses to early lactose levels. In Exp. 3, 330 pigs were fed complex diets. From 0 to 7 d after weaning, the diets contained 25% lactose (as-fed basis), and from 7 to 21 d postweaning, the lactose levels ranged from 7 to 31% in 5% increments. Gain (P < 0.01) and feed efficiency (P < 0.05) increased from 7 to 21 d to the 17% lactose level. In Exp. 4, 300 pigs were fed 25 and 17% (as-fed basis) lactose diets from 0 to 7 and 7 to 21 d postweaning, respectively. From 21 to 35 d postweaning, lactose levels of 0 to 20% in 5% increments were added to a corn-soybean meal diet. The experiment was conducted as a RCB design in 12 replicates. Gain (P < 0.05) and feed intake (P < 0.05) increased to 10 to 15% lactose. When the data from Exp. 4 were partitioned into lighter (15.0 kg) and heavier (17.7 kg) pig weight replicates, only the lighter replicates had significant improvements in gain, feed intake, and feed efficiency (P < 0.05) in response to dietary lactose. These results demonstrated that starter pigs performed better when fed complex diets, that dietary lactose levels of 25 to 30% (to 7 kg BW) during the initial week postweaning, 15 to 20% lactose during d 7 to 21 (to 12.5 kg BW), and 10 to 15% lactose during d 21 to 35 postweaning (to 25 kg BW) resulted in maximum performance.

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Medium-chain fatty acids: evidence for incorporation into chylomicron triglycerides in humans

Swift

Hill

Peters

et al. 1990

The American Journal of Clinical Nutrition

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The purpose of this study was to evaluate the fatty acid composition of chylomicron triglycerides isolated from subjects fed liquid-formula diets containing 40% of total energy as medium- (C8:0 and C10:0) or long-chain (C16-C18) triglycerides (MCT, LCT) for 6 d. Medium-chain fatty acids (MCFA) comprised 8% of total chylomicron triglyceride fatty acids after the first MCT meal. After 6 d of continued MCT feeding, chylomicron triglyceride MCFA content increased to 13%. When subjects were fed the LCT (soybean oil) diet, C16:0, C18:1, and C18:2 comprised nearly 90% of the chylomicron triglyceride fatty acids. The mass of triglyceride transported in chylomicrons isolated from subjects fed the MCT diet was approximately 20% of that found when subjects consumed the LCT diet. We conclude that although total triglyceride production during MCT ingestion is low, the chylomicron triglycerides that are synthesized contain significant amounts of MCFA.

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Dietary Fat and Human Appetite: Effects of Non-absorbable Fat on Energy and Nutrient Intakes

Blundell¹,

Burley²,

Peters³

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T-I-073 Sleep Disordered Breathing and Shift Work: Associationwith Impaired Glucosemetabolism

Carrillo¹,

Arellano²,

Peters³

et al. 2011

Sleep Medicine

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J. C. Peters

Metabolic differences between obesity-prone and obesity-resistant rats

Effects of diet complexity and dietary lactose levels during three starter phases on postweaning pig performance123

Medium-chain fatty acids: evidence for incorporation into chylomicron triglycerides in humans

Dietary Fat and Human Appetite: Effects of Non-absorbable Fat on Energy and Nutrient Intakes

T-I-073 Sleep Disordered Breathing and Shift Work: Associationwith Impaired Glucosemetabolism

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