Assessing metabolic flexibility response to a multifibre diet: a randomised‐controlled trial
Introduction Metabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker for assessing responses to dietary interventions. Previously, we showed that the consumption of multifibre bread improved insulin sensitivity...
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| Published in | Journal of human nutrition and dietetics Vol. 37; no. 5; pp. 1186 - 1196 |
|---|---|
| Main Authors | , , , , , , , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
England
Blackwell Publishing Ltd
01.10.2024
Wiley |
| Subjects | |
| Online Access | Get full text |
| ISSN | 0952-3871 1365-277X 1365-277X |
| DOI | 10.1111/jhn.13350 |
Cover
| Abstract | Introduction
Metabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker for assessing responses to dietary interventions. Previously, we showed that the consumption of multifibre bread improved insulin sensitivity and reduced low‐density lipoprotein cholesterol (LDLc) levels in overweight and obese individuals. As a secondary objective, we aimed to explore whether our intervention could also improve MetF.
Methods
In this study, 39 subjects at cardiometabolic risk participated in a double‐blind, randomised, crossover trial lasting 8 weeks, repeated twice. During each phase, participants consumed either 150 g of standard bread daily or bread enriched with a mixture of seven dietary fibres. MetF response was assessed using a mixed‐meal tolerance test (MMTT), analysing changes in respiratory quotient (∆RQ) measured using indirect calorimetry.
Results
Although there were no significant differences in ∆RQ changes induced by dietary fibre between the two diets, these changes were positively correlated with postprandial triglyceride excursion (∆TG) at baseline. Subgroup analysis of baseline fasting and postprandial plasma metabolites was conducted to characterise MetF responders. These responders exhibited higher baseline fasting LDLc levels and greater post‐MMTT ∆TG.
Conclusion
In conclusion, although dietary fibres did not directly impact MetF in this study, our findings highlight potential determinants of MetF response, warranting further investigation in dedicated future interventions.
An 8‐week multifibre diet did not improve metabolic flexibility in 39 subjects at cardiometabolic risk. However, the subjects with worse lipid profile might be those who would benefit from this intervention.
Highlights
The term ‘metabolic flexibility’ (MetF) was initially used to describe the ability of helminths to generate energy through either aerobic respiration or anaerobic respiration, enabling them to adapt to environmental changes. This concept was later applied to human metabolism, emphasising the body's capacity to switch between different energy sources, such as carbohydrates and fats, based on energy requirements.
MetF has been studied in the context of transitions between fasting and fed states, or in response to insulin stimulation. It refers to the body's ability to adapt its energy utilisation in response to changing metabolic demands.
Research has shown that insulin resistance, often linked to type 2 diabetes and obesity, may be associated with reduced MetF, characterised by altered patterns of carbohydrate and fat oxidation. |
|---|---|
| AbstractList | Introduction
Metabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker for assessing responses to dietary interventions. Previously, we showed that the consumption of multifibre bread improved insulin sensitivity and reduced low‐density lipoprotein cholesterol (LDLc) levels in overweight and obese individuals. As a secondary objective, we aimed to explore whether our intervention could also improve MetF.
Methods
In this study, 39 subjects at cardiometabolic risk participated in a double‐blind, randomised, crossover trial lasting 8 weeks, repeated twice. During each phase, participants consumed either 150 g of standard bread daily or bread enriched with a mixture of seven dietary fibres. MetF response was assessed using a mixed‐meal tolerance test (MMTT), analysing changes in respiratory quotient (∆RQ) measured using indirect calorimetry.
Results
Although there were no significant differences in ∆RQ changes induced by dietary fibre between the two diets, these changes were positively correlated with postprandial triglyceride excursion (∆TG) at baseline. Subgroup analysis of baseline fasting and postprandial plasma metabolites was conducted to characterise MetF responders. These responders exhibited higher baseline fasting LDLc levels and greater post‐MMTT ∆TG.
Conclusion
In conclusion, although dietary fibres did not directly impact MetF in this study, our findings highlight potential determinants of MetF response, warranting further investigation in dedicated future interventions.
An 8‐week multifibre diet did not improve metabolic flexibility in 39 subjects at cardiometabolic risk. However, the subjects with worse lipid profile might be those who would benefit from this intervention.
Highlights
The term ‘metabolic flexibility’ (MetF) was initially used to describe the ability of helminths to generate energy through either aerobic respiration or anaerobic respiration, enabling them to adapt to environmental changes. This concept was later applied to human metabolism, emphasising the body's capacity to switch between different energy sources, such as carbohydrates and fats, based on energy requirements.
MetF has been studied in the context of transitions between fasting and fed states, or in response to insulin stimulation. It refers to the body's ability to adapt its energy utilisation in response to changing metabolic demands.
Research has shown that insulin resistance, often linked to type 2 diabetes and obesity, may be associated with reduced MetF, characterised by altered patterns of carbohydrate and fat oxidation. Introduction Metabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker for assessing responses to dietary interventions. Previously, we showed that the consumption of multifibre bread improved insulin sensitivity and reduced low‐density lipoprotein cholesterol (LDLc) levels in overweight and obese individuals. As a secondary objective, we aimed to explore whether our intervention could also improve MetF. Methods In this study, 39 subjects at cardiometabolic risk participated in a double‐blind, randomised, crossover trial lasting 8 weeks, repeated twice. During each phase, participants consumed either 150 g of standard bread daily or bread enriched with a mixture of seven dietary fibres. MetF response was assessed using a mixed‐meal tolerance test (MMTT), analysing changes in respiratory quotient (∆RQ) measured using indirect calorimetry. Results Although there were no significant differences in ∆RQ changes induced by dietary fibre between the two diets, these changes were positively correlated with postprandial triglyceride excursion (∆TG) at baseline. Subgroup analysis of baseline fasting and postprandial plasma metabolites was conducted to characterise MetF responders. These responders exhibited higher baseline fasting LDLc levels and greater post‐MMTT ∆TG. ConclusionIn conclusion, although dietary fibres did not directly impact MetF in this study, our findings highlight potential determinants of MetF response, warranting further investigation in dedicated future interventions. The term ‘metabolic flexibility’ (MetF) was initially used to describe the ability of helminths to generate energy through either aerobic respiration or anaerobic respiration, enabling them to adapt to environmental changes. This concept was later applied to human metabolism, emphasising the body's capacity to switch between different energy sources, such as carbohydrates and fats, based on energy requirements. MetF has been studied in the context of transitions between fasting and fed states, or in response to insulin stimulation. It refers to the body's ability to adapt its energy utilisation in response to changing metabolic demands. Research has shown that insulin resistance, often linked to type 2 diabetes and obesity, may be associated with reduced MetF, characterised by altered patterns of carbohydrate and fat oxidation. IntroductionMetabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker for assessing responses to dietary interventions. Previously, we showed that the consumption of multifibre bread improved insulin sensitivity and reduced low‐density lipoprotein cholesterol (LDLc) levels in overweight and obese individuals. As a secondary objective, we aimed to explore whether our intervention could also improve MetF.MethodsIn this study, 39 subjects at cardiometabolic risk participated in a double‐blind, randomised, crossover trial lasting 8 weeks, repeated twice. During each phase, participants consumed either 150 g of standard bread daily or bread enriched with a mixture of seven dietary fibres. MetF response was assessed using a mixed‐meal tolerance test (MMTT), analysing changes in respiratory quotient (∆RQ) measured using indirect calorimetry.ResultsAlthough there were no significant differences in ∆RQ changes induced by dietary fibre between the two diets, these changes were positively correlated with postprandial triglyceride excursion (∆TG) at baseline. Subgroup analysis of baseline fasting and postprandial plasma metabolites was conducted to characterise MetF responders. These responders exhibited higher baseline fasting LDLc levels and greater post‐MMTT ∆TG.ConclusionIn conclusion, although dietary fibres did not directly impact MetF in this study, our findings highlight potential determinants of MetF response, warranting further investigation in dedicated future interventions. Metabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker for assessing responses to dietary interventions. Previously, we showed that the consumption of multifibre bread improved insulin sensitivity and reduced low-density lipoprotein cholesterol (LDLc) levels in overweight and obese individuals. As a secondary objective, we aimed to explore whether our intervention could also improve MetF.INTRODUCTIONMetabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker for assessing responses to dietary interventions. Previously, we showed that the consumption of multifibre bread improved insulin sensitivity and reduced low-density lipoprotein cholesterol (LDLc) levels in overweight and obese individuals. As a secondary objective, we aimed to explore whether our intervention could also improve MetF.In this study, 39 subjects at cardiometabolic risk participated in a double-blind, randomised, crossover trial lasting 8 weeks, repeated twice. During each phase, participants consumed either 150 g of standard bread daily or bread enriched with a mixture of seven dietary fibres. MetF response was assessed using a mixed-meal tolerance test (MMTT), analysing changes in respiratory quotient (∆RQ) measured using indirect calorimetry.METHODSIn this study, 39 subjects at cardiometabolic risk participated in a double-blind, randomised, crossover trial lasting 8 weeks, repeated twice. During each phase, participants consumed either 150 g of standard bread daily or bread enriched with a mixture of seven dietary fibres. MetF response was assessed using a mixed-meal tolerance test (MMTT), analysing changes in respiratory quotient (∆RQ) measured using indirect calorimetry.Although there were no significant differences in ∆RQ changes induced by dietary fibre between the two diets, these changes were positively correlated with postprandial triglyceride excursion (∆TG) at baseline. Subgroup analysis of baseline fasting and postprandial plasma metabolites was conducted to characterise MetF responders. These responders exhibited higher baseline fasting LDLc levels and greater post-MMTT ∆TG.RESULTSAlthough there were no significant differences in ∆RQ changes induced by dietary fibre between the two diets, these changes were positively correlated with postprandial triglyceride excursion (∆TG) at baseline. Subgroup analysis of baseline fasting and postprandial plasma metabolites was conducted to characterise MetF responders. These responders exhibited higher baseline fasting LDLc levels and greater post-MMTT ∆TG.In conclusion, although dietary fibres did not directly impact MetF in this study, our findings highlight potential determinants of MetF response, warranting further investigation in dedicated future interventions.CONCLUSIONIn conclusion, although dietary fibres did not directly impact MetF in this study, our findings highlight potential determinants of MetF response, warranting further investigation in dedicated future interventions. Metabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker for assessing responses to dietary interventions. Previously, we showed that the consumption of multifibre bread improved insulin sensitivity and reduced low-density lipoprotein cholesterol (LDLc) levels in overweight and obese individuals. As a secondary objective, we aimed to explore whether our intervention could also improve MetF. In this study, 39 subjects at cardiometabolic risk participated in a double-blind, randomised, crossover trial lasting 8 weeks, repeated twice. During each phase, participants consumed either 150 g of standard bread daily or bread enriched with a mixture of seven dietary fibres. MetF response was assessed using a mixed-meal tolerance test (MMTT), analysing changes in respiratory quotient (∆RQ) measured using indirect calorimetry. Although there were no significant differences in ∆RQ changes induced by dietary fibre between the two diets, these changes were positively correlated with postprandial triglyceride excursion (∆TG) at baseline. Subgroup analysis of baseline fasting and postprandial plasma metabolites was conducted to characterise MetF responders. These responders exhibited higher baseline fasting LDLc levels and greater post-MMTT ∆TG. In conclusion, although dietary fibres did not directly impact MetF in this study, our findings highlight potential determinants of MetF response, warranting further investigation in dedicated future interventions. INTRODUCTION: Metabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker for assessing responses to dietary interventions. Previously, we showed that the consumption of multifibre bread improved insulin sensitivity and reduced low‐density lipoprotein cholesterol (LDLc) levels in overweight and obese individuals. As a secondary objective, we aimed to explore whether our intervention could also improve MetF. METHODS: In this study, 39 subjects at cardiometabolic risk participated in a double‐blind, randomised, crossover trial lasting 8 weeks, repeated twice. During each phase, participants consumed either 150 g of standard bread daily or bread enriched with a mixture of seven dietary fibres. MetF response was assessed using a mixed‐meal tolerance test (MMTT), analysing changes in respiratory quotient (∆RQ) measured using indirect calorimetry. RESULTS: Although there were no significant differences in ∆RQ changes induced by dietary fibre between the two diets, these changes were positively correlated with postprandial triglyceride excursion (∆TG) at baseline. Subgroup analysis of baseline fasting and postprandial plasma metabolites was conducted to characterise MetF responders. These responders exhibited higher baseline fasting LDLc levels and greater post‐MMTT ∆TG. CONCLUSION: In conclusion, although dietary fibres did not directly impact MetF in this study, our findings highlight potential determinants of MetF response, warranting further investigation in dedicated future interventions. |
| Author | Hornero‐Ramirez, Hugo Van Den Berghe, Laurie Laville, Martine Doré, Joël Béra‐Maillet, Christel Favier, Nathalie Feugier Simon, Chantal Aubin, Adrien Dussous, Isabelle Roger, Loïc Ranaivo, Harimalala Nazare, Julie‐Anne Caussy, Cyrielle |
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| Keywords | cardiometabolic risk metabolic flexibility dietary fibre cardiometabolic profile mixed‐meal test dietary intervention |
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| Snippet | Introduction
Metabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker... The term ‘metabolic flexibility’ (MetF) was initially used to describe the ability of helminths to generate energy through either aerobic respiration or... Metabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker for assessing... IntroductionMetabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker... INTRODUCTION: Metabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker... Introduction Metabolic flexibility (MetF), defined as the ability to switch between fat and glucose oxidation, is increasingly recognised as a critical marker... |
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| SubjectTerms | Adult Aerobic capacity Aerobic respiration Anaerobic respiration Blindness Blood Glucose - metabolism Bread breads Calorimetry Calorimetry, Indirect Carbohydrates cardiometabolic profile cardiometabolic risk Cholesterol Cholesterol, LDL - blood Cross-Over Studies Diabetes mellitus (non-insulin dependent) Diet Diet - methods Dietary fiber Dietary Fiber - administration & dosage dietary fibre Dietary guidelines dietary intervention dietetics Double-Blind Method Energy metabolism Energy requirements Energy sources Energy utilization Environmental changes Fasting Female Fibers Flexibility Glucose Health risks Humans Insulin Insulin Resistance Laboratory testing Life Sciences low density lipoprotein cholesterol Male metabolic flexibility Metabolism Metabolites Middle Aged mixed‐meal test Obesity Obesity - diet therapy overweight Overweight - blood Overweight - diet therapy Overweight - metabolism Oxidation Oxidation resistance Postprandial Period Respiration Respiratory quotient risk Subgroups triacylglycerols Triglycerides Triglycerides - blood |
| Title | Assessing metabolic flexibility response to a multifibre diet: a randomised‐controlled trial |
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