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一种在全身代谢室中评估代谢灵活性的新方法。

A Novel Approach to Assess Metabolic Flexibility Overnight in a Whole-Body Room Calorimeter.

机构信息

Pennington Biomedical Research Center, Baton Rouge, Louisiana, USA.

出版信息

Obesity (Silver Spring). 2020 Nov;28(11):2073-2077. doi: 10.1002/oby.22982. Epub 2020 Sep 27.

DOI:10.1002/oby.22982
PMID:32985108
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7644592/
Abstract

OBJECTIVE

This study aimed to investigate a novel approach for determining the effects of energy-standardized dinner meals (high-fat and low-fat) on respiratory exchange ratio (RER) dynamics and metabolic flexibility.

METHODS

Using a randomized crossover study design, energy expenditure, RER, and macronutrient oxidation rates were assessed in response to a single dinner meal during an overnight stay in a whole-body room calorimeter. Eight healthy adults completed two overnight chamber stays while fed either a high-fat (60% fat, 20% carbohydrate [CHO], 20% protein; food quotient [FQ] = 0.784) or low-fat (20% fat, 60% CHO, 20% protein; FQ = 0.899) dinner containing 40% of daily energy requirements.

RESULTS

Following the low-fat meal, CHO oxidation first increased before decreasing, resulting in a 12-hour RER:FQ ratio close to 1.0 (0.986 ± 0.019, P = 0.06) and therefore resulting in a 12-hour equilibrated fat balance (29 ± 76 kcal/12 hours). Following the high-fat meal, participants had a RER:FQ ratio above 1.0 (1.061 ± 0.017, P < 0.01), resulting in a significant positive 12-hour fat balance of 376 ± 142 kcal/12 hours. Various RER trajectory parameters were significantly different following the high-fat and low-fat meals.

CONCLUSIONS

This proof-of-concept study provides an alternative approach to quantify metabolic flexibility in response to a high-fat dinner and it can be used to derive indexes of metabolic flexibility, such as the 12-hour RER:FQ ratio or the 12-hour fat balance.

摘要

目的

本研究旨在探讨一种新方法,用于确定能量标准化正餐(高脂肪和低脂肪)对呼吸交换率(RER)动态和代谢灵活性的影响。

方法

采用随机交叉研究设计,在全身室热量计中过夜时,单次正餐摄入后评估能量消耗、RER 和宏量营养素氧化率。8 名健康成年人完成了两次过夜室停留,分别摄入高脂肪(60%脂肪、20%碳水化合物[CHO]、20%蛋白质;食物商[FQ] = 0.784)或低脂肪(20%脂肪、60% CHO、20%蛋白质;FQ = 0.899)晚餐,每餐含有 40%的日能量需求。

结果

低脂餐摄入后,CHO 氧化首先增加,然后减少,导致 12 小时 RER:FQ 比值接近 1.0(0.986 ± 0.019,P = 0.06),因此导致 12 小时均衡的脂肪平衡(29 ± 76 千卡/12 小时)。高脂餐摄入后,参与者的 RER:FQ 比值高于 1.0(1.061 ± 0.017,P < 0.01),导致显著的正 12 小时脂肪平衡 376 ± 142 千卡/12 小时。高脂餐和低脂餐后,各种 RER 轨迹参数均有显著差异。

结论

本概念验证研究提供了一种量化高脂肪晚餐代谢灵活性的替代方法,可用于衍生代谢灵活性指标,如 12 小时 RER:FQ 比值或 12 小时脂肪平衡。

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