Metabolic Adaptations During Negative Energy Balance and Their Potential Impact on Appetite and Food Intake

Overview

Journal Proc Nutr Soc

Specialty Nutritional Sciences

Date 2019 Feb 20

PMID 30777142

Citations 14

Authors

Nuno Casanova

Kristine Beaulieu

Graham Finlayson

Mark Hopkins

Affiliations

Soon will be listed here.

Abstract

This review examines the metabolic adaptations that occur in response to negative energy balance and their potential putative or functional impact on appetite and food intake. Sustained negative energy balance will result in weight loss, with body composition changes similar for different dietary interventions if total energy and protein intake are equated. During periods of underfeeding, compensatory metabolic and behavioural responses occur that attenuate the prescribed energy deficit. While losses of metabolically active tissue during energy deficit result in reduced energy expenditure, an additional down-regulation in expenditure has been noted that cannot be explained by changes in body tissue (e.g. adaptive thermogenesis). Sustained negative energy balance is also associated with an increase in orexigenic drive and changes in appetite-related peptides during weight loss that may act as cues for increased hunger and food intake. It has also been suggested that losses of fat-free mass (FFM) could also act as an orexigenic signal during weight loss, but more data are needed to support these findings and the signalling pathways linking FFM and energy intake remain unclear. Taken together, these metabolic and behavioural responses to weight loss point to a highly complex and dynamic energy balance system in which perturbations to individual components can cause co-ordinated and inter-related compensatory responses elsewhere. The strength of these compensatory responses is individually subtle, and early identification of this variability may help identify individuals that respond well or poorly to an intervention.

Citing Articles

Testing a proposed mathematical model of weight loss in women enrolled on a commercial weight-loss programme: the LighterLife study.

Egan A, Rayman J, Collins A J Nutr Sci. 2024; 13:e92.

PMID: 39703899 PMC: 11658952. DOI: 10.1017/jns.2024.85.

Associations of dietary factors with gastric cancer risk: insights from NHANES 2003-2016 and mendelian randomization analyses.

Zhang Y, Wang S, Li Q, Liu H, Xuan Z, Li F Front Genet. 2024; 15:1377434.

PMID: 38756450 PMC: 11096504. DOI: 10.3389/fgene.2024.1377434.

The Possible Role of Food and Diet in the Quality of Life in Patients with COPD-A State-of-the-Art Review.

Fekete M, Csipo T, Fazekas-Pongor V, Balint M, Csizmadia Z, Tarantini S Nutrients. 2023; 15(18).

PMID: 37764686 PMC: 10536642. DOI: 10.3390/nu15183902.

The Influence of Energy Balance and Availability on Resting Metabolic Rate: Implications for Assessment and Future Research Directions.

Siedler M, De Souza M, Albracht-Schulte K, Sekiguchi Y, Tinsley G Sports Med. 2023; 53(8):1507-1526.

PMID: 37213050 DOI: 10.1007/s40279-023-01856-7.

The Effects of Intermittent Diet Breaks during 25% Energy Restriction on Body Composition and Resting Metabolic Rate in Resistance-Trained Females: A Randomized Controlled Trial.

Siedler M, Lewis M, Trexler E, Lamadrid P, Waddell B, Bishop S J Hum Kinet. 2023; 86:117-132.

PMID: 37181269 PMC: 10170537. DOI: 10.5114/jhk/159960.