Your search keyword '"Byrne, Claire S."' showing total 13 results

1. Increased colonic propionate reduces anticipatory reward responses in the human striatum to high-energy foods1–3

Author

Byrne, Claire S, Chambers, Edward S, Alhabeeb, Habeeb, Chhina, Navpreet, Morrison, Douglas J, Preston, Tom, Tedford, Catriona, Fitzpatrick, Julie, Irani, Cherag, Busza, Albert, Garcia-Perez, Isabel, Fountana, Sofia, Holmes, Elaine, Goldstone, Anthony P, and Frost, Gary S

Published

2016

2. Carbohydrate and human health: is it all about quality?

Author

Chambers, Edward S, Byrne, Claire S, and Frost, Gary

Published

2019

3. Acute oral sodium propionate supplementation raises resting energy expenditure and lipid oxidation in fasted humans

Author

Chambers, Edward S., Byrne, Claire S., Aspey, Karen, Chen, Yanjie, Khan, Saadiyah, Morrison, Douglas J., and Frost, Gary

Subjects

energy regulation, Adult, Male, Brief Report, Rest, Administration, Oral, 1103 Clinical Sciences, Fasting, Lipid Metabolism, Endocrinology & Metabolism, Young Adult, dietary intervention, randomized trial, Humans, Brief Reports, Female, Basal Metabolism, Propionates, Energy Metabolism, Oxidation-Reduction

Abstract

Short‐chain fatty acids (SCFAs), produced from fermentation of dietary fibre by the gut microbiota, have been suggested to modulate energy metabolism. Previous work using rodent models has demonstrated that oral supplementation of the SCFA propionate raises resting energy expenditure (REE) by promoting lipid oxidation. The objective of the present study was to investigate the effects of oral sodium propionate on REE and substrate metabolism in humans. Eighteen healthy volunteers (9 women and 9 men; age 25 ± 1 years; body mass index 24.1 ± 1.2 kg/m2) completed 2 study visits following an overnight fast. Tablets containing a total of 6845 mg sodium propionate or 4164 mg sodium chloride were provided over the 180‐minute study period in random order. REE and substrate oxidation were assessed by indirect calorimetry. Oral sodium propionate administration increased REE (0.045 ± 0.020 kcal/min; P = .036); this was accompanied by elevated rates of whole‐body lipid oxidation (0.012 ± 0.006 g/min; P = .048) and was independent of changes in glucose and insulin concentrations. Future studies are warranted to determine whether the acute effects of oral sodium propionate on REE translate into positive improvements in long‐term energy balance in humans.

Published

2017

4. The effects of dietary supplementation with inulin and inulin‐propionate ester on hepatic steatosis in adults with non‐alcoholic fatty liver disease

Author

Chambers, Edward S., Byrne, Claire S., Rugyendo, Annette, Morrison, Douglas J., Preston, Tom, Tedford, Catriona, Bell, Jimmy D., Thomas, Louise, Akbar, Arne N., Riddell, Natalie E., Sharma, Rohini, Thursz, Mark R., Manousou, Pinelopi, and Frost, Gary

Abstract

The short chain fatty acid (SCFA) propionate, produced through fermentation of dietary fibre by the gut microbiota, has been shown to alter hepatic metabolic processes that reduce lipid storage. We aimed to investigate the impact of raising colonic propionate production on hepatic steatosis in adults with non‐alcoholic fatty liver disease (NAFLD). Eighteen adults were randomized to receive 20 g/d of an inulin‐propionate ester (IPE), designed to deliver propionate to the colon, or an inulin control for 42 days in a parallel design. The change in intrahepatocellular lipid (IHCL) following the supplementation period was not different between the groups (P = 0.082), however, IHCL significantly increased within the inulin‐control group (20.9% ± 2.9% to 26.8% ± 3.9%; P = 0.012; n = 9), which was not observed within the IPE group (22.6% ± 6.9% to 23.5% ± 6.8%; P = 0.635; n = 9). The predominant SCFA from colonic fermentation of inulin is acetate, which, in a background of NAFLD and a hepatic metabolic profile that promotes fat accretion, may provide surplus lipogenic substrate to the liver. The increased colonic delivery of propionate from IPE appears to attenuate this acetate‐mediated increase in IHCL.

Published

2019

5. The effect of L-rhamnose on intestinal transit time, short chain fatty acids and appetite regulation: a pilot human study using combined 13CO2/H2 breath tests

Author

Byrne, Claire S., Preston, Tom, Brignardello, Jerusa, Garcia-Perez, Isabel, Holmes, Elaine, Frost, Gary, and Morrison, Douglas J.

Subjects

digestive, oral, and skin physiology

Abstract

Background: The appetite-regulating effects of non-digestible carbohydrates (NDC) have in part previously been attributed to their effects on intestinal transit rates as well as microbial production of short chain fatty acids (SCFA). Increased colonic production of the SCFA propionate has been shown to reduce energy intake and stimulate gut hormone secretion acutely in humans.\ud \ud Objective: We investigated the effect of the propiogenic NDC, L-rhamnose, on gastrointestinal transit times using a combined 13CO2/H2 breath test. We hypothesised that L-rhamnose would increase plasma propionate leading to a reduction in appetite, independent of changes in gastrointestinal transit times.\ud \ud Design: We used a dual 13C octanoic acid/lactose 13C-ureide breath test combined with breath H2 to measure intestinal transit times following the consumption of 25g/d L-rhamnose, compared with inulin and cellulose, in 10 healthy humans in a randomised cross-over pilot study. Gastric emptying (GE) and oro-caecal transit times (OCTT) were derived from the breath 13C data and compared with breath H2. Plasma SCFA and peptide YY (PYY) were also measured alongside subjective measures of appetite.\ud \ud Results: L-rhamnose significantly slowed GE rates (by 19.5min) but there was no difference in OCTT between treatments. However, breath H2 indicated fermentation of L-rhamnose before it reached the caecum. OCTT was highly correlated with breath H2 for inulin but not for L-rhamnose or cellulose. L-rhamnose consumption significantly increased plasma propionate and PYY but did not significantly reduce subjective appetite measures.\ud \ud Conclusions: The NDCs tested had a minimal effect on intestinal transit time. Our data suggest that L-rhamnose is partially fermented in the small intestine and that breath H2 reflects the site of gastrointestinal fermentation and is only a reliable marker of OCTT for certain NDCs (e.g. inulin). Future studies should focus on investigating the appetite-suppressing potential of L-rhamnose and verifying the findings in a larger cohort.

Published

2018

6. Dietary supplementation with inulin-propionate ester or inulin improves insulin sensitivity in adults with overweight and obesity with distinct effects on the gut microbiota, plasma metabolome and systemic inflammatory responses: a randomised crossover trial

Author

Chambers, Edward S., Byrne, Claire S., Morrison, Douglas J., Murphy, Kevin G., Preston, Tom, Tedford, Catriona, Garcia-Perez, Isabel, Fountana, Sofia, Serrano-Contreras, Jose Ivan, Holmes, Elaine, Reynolds, Catherine J., Roberts, Jordie F., Boyton, Rosemary J., Altmann, Daniel M., McDonald, Julie A. K., Marchesi, Julian R., Akbar, Arne N., Riddell, Natalie E., Wallis, Gareth A., and Frost, Gary S.

Subjects

GUT microbiome, INULIN, INSULIN resistance, ESTERS, LIFE sciences

Published

2019

7. The effect of L-rhamnose on intestinal transit time, short chain fatty acids and appetite regulation: a pilot human study using combined 13CO2/H2 breath tests.

Author

Byrne, Claire S., Preston, Tom, Brignardello, Jerusa, Garcia-Perez, Isabel, Holmes, Elaine, Frost, Gary S., and Morrison, Douglas J.

Published

2018

8. Acute oral sodium propionate supplementation raises resting energy expenditure and lipid oxidation in fasted humans.

Author

Chambers, Edward S., Byrne, Claire S., Aspey, Karen, Chen, Yanjie, Khan, Saadiyah, Frost, Gary, and Morrison, Douglas J.

Subjects

*SODIUM propionate, *LIPID peroxidation (Biology), *SHORT-chain fatty acids, *ENERGY metabolism, *RANDOMIZED controlled trials

Abstract

Short‐chain fatty acids (SCFAs), produced from fermentation of dietary fibre by the gut microbiota, have been suggested to modulate energy metabolism. Previous work using rodent models has demonstrated that oral supplementation of the SCFA propionate raises resting energy expenditure (REE) by promoting lipid oxidation. The objective of the present study was to investigate the effects of oral sodium propionate on REE and substrate metabolism in humans. Eighteen healthy volunteers (9 women and 9 men; age 25 ± 1 years; body mass index 24.1 ± 1.2 kg/m2) completed 2 study visits following an overnight fast. Tablets containing a total of 6845 mg sodium propionate or 4164 mg sodium chloride were provided over the 180‐minute study period in random order. REE and substrate oxidation were assessed by indirect calorimetry. Oral sodium propionate administration increased REE (0.045 ± 0.020 kcal/min; P = .036); this was accompanied by elevated rates of whole‐body lipid oxidation (0.012 ± 0.006 g/min; P = .048) and was independent of changes in glucose and insulin concentrations. Future studies are warranted to determine whether the acute effects of oral sodium propionate on REE translate into positive improvements in long‐term energy balance in humans. [ABSTRACT FROM AUTHOR]

Published

2018

9. Effects of Inulin Propionate Ester Incorporated into Palatable Food Products on Appetite and Resting Energy Expenditure: A Randomised Crossover Study.

Author

Byrne, Claire S, Chambers, Edward S, Preston, Tom, Tedford, Catriona, Brignardello, Jerusa, Garcia-Perez, Isabel, Holmes, Elaine, Wallis, Gareth A, Morrison, Douglas J, and Frost, Gary S

Abstract

Supplementation with inulin-propionate ester (IPE), which delivers propionate to the colon, suppresses ad libitum energy intake and stimulates the release of satiety hormones acutely in humans, and prevents weight gain. In order to determine whether IPE remains effective when incorporated into food products (FP), IPE needs to be added to a widely accepted food system. A bread roll and fruit smoothie were produced. Twenty-one healthy overweight and obese humans participated. Participants attended an acclimatisation visit and a control visit where they consumed un-supplemented food products (FP). Participants then consumed supplemented-FP, containing 10 g/d inulin or IPE for six days followed by a post-supplementation visit in a randomised crossover design. On study visits, supplemented-FP were consumed for the seventh time and ad libitum energy intake was assessed 420 min later. Blood samples were collected to assess hormones and metabolites. Resting energy expenditure (REE) was measured using indirect calorimetry. Taste and appearance ratings were similar between FP. Ad libitum energy intake was significantly different between treatments, due to a decreased intake following IPE-FP. These observations were not related to changes in blood hormones and metabolites. There was an increase in REE following IPE-FP. However, this effect was lost after correcting for changes in fat free mass. Our results suggest that IPE suppresses appetite and may alter REE following its incorporation into palatable food products. [ABSTRACT FROM AUTHOR]

Published

2019

10. Dietary supplementation with inulin-propionate ester or inulin improves insulin sensitivity in adults with overweight and obesity with distinct effects on the gut microbiota, plasma metabolome and systemic inflammatory responses: a randomised cross-over trial.

Author

Chambers ES, Byrne CS, Morrison DJ, Murphy KG, Preston T, Tedford C, Garcia-Perez I, Fountana S, Serrano-Contreras JI, Holmes E, Reynolds CJ, Roberts JF, Boyton RJ, Altmann DM, McDonald JAK, Marchesi JR, Akbar AN, Riddell NE, Wallis GA, and Frost GS

Subjects

Adult, Body Mass Index, Cross-Over Studies, Dietary Supplements, Double-Blind Method, Feces microbiology, Female, Humans, Inflammation metabolism, Insulin Resistance physiology, Male, Middle Aged, Propionates administration & dosage, Propionates metabolism, Treatment Outcome, Gastrointestinal Microbiome physiology, Insulin metabolism, Inulin administration & dosage, Inulin metabolism, Metabolome physiology, Obesity diagnosis, Obesity diet therapy, Obesity metabolism, Overweight diagnosis, Overweight diet therapy, Overweight metabolism

Abstract

Objective: To investigate the underlying mechanisms behind changes in glucose homeostasis with delivery of propionate to the human colon by comprehensive and coordinated analysis of gut bacterial composition, plasma metabolome and immune responses., Design: Twelve non-diabetic adults with overweight and obesity received 20 g/day of inulin-propionate ester (IPE), designed to selectively deliver propionate to the colon, a high-fermentable fibre control (inulin) and a low-fermentable fibre control (cellulose) in a randomised, double-blind, placebo-controlled, cross-over design. Outcome measurements of metabolic responses, inflammatory markers and gut bacterial composition were analysed at the end of each 42-day supplementation period., Results: Both IPE and inulin supplementation improved insulin resistance compared with cellulose supplementation, measured by homeostatic model assessment 2 (mean±SEM 1.23±0.17 IPE vs 1.59±0.17 cellulose, p=0.001; 1.17±0.15 inulin vs 1.59±0.17 cellulose, p=0.009), with no differences between IPE and inulin (p=0.272). Fasting insulin was only associated positively with plasma tyrosine and negatively with plasma glycine following inulin supplementation. IPE supplementation decreased proinflammatory interleukin-8 levels compared with cellulose, while inulin had no impact on the systemic inflammatory markers studied. Inulin promoted changes in gut bacterial populations at the class level (increased Actinobacteria and decreased Clostridia) and order level (decreased Clostridiales) compared with cellulose, with small differences at the species level observed between IPE and cellulose., Conclusion: These data demonstrate a distinctive physiological impact of raising colonic propionate delivery in humans, as improvements in insulin sensitivity promoted by IPE and inulin were accompanied with different effects on the plasma metabolome, gut bacterial populations and markers of systemic inflammation., Competing Interests: Competing interests: A patent application for ’Compounds and their effects on appetite control and insulin sensitivity' surrounding the use of inulin-propionate ester has been filed by GSF and DJM (WO2014020344). None of the other authors reported a conflict of interest related to the study., (© Author(s) (or their employer(s)) 2019. Re-use permitted under CC BY. Published by BMJ.)

Published

2019

11. A study protocol for a randomised crossover study evaluating the effect of diets differing in carbohydrate quality on ileal content and appetite regulation in healthy humans.

Author

Byrne CS, Blunt D, Burn J, Chambers E, Dagbasi A, Franco Becker G, Gibson G, Mendoza L, Murphy K, Poveda C, Ramgulam A, Tashkova M, Walton G, Washirasaksiri C, and Frost G

Subjects

Cross-Over Studies, Female, Humans, Male, Randomized Controlled Trials as Topic, Appetite Regulation, Diet, Dietary Carbohydrates analysis, Dietary Fiber administration & dosage, Ileum

Abstract

Introduction: A major component of the digesta reaching the colon from the distal ileum is carbohydrate. This carbohydrate is subject to microbial fermentation and can radically change bacterial populations in the colon and the metabolites they produce, particularly short-chain fatty acids (SCFA). However, very little is currently known about the forms and levels of carbohydrate in the ileum and the composition of the ileal microbiota in humans. Most of our current understanding of carbohydrate that is not absorbed by the small intestine comes from ileostomy models, which may not reflect the physiology of an intact gastrointestinal tract. Methods: We will investigate how ileal content changes depending on diet using a randomised crossover study in healthy humans. Participants will be inpatients at the research facility for three separate 4-day visits. During each visit, participants will consume one of three diets, which differ in carbohydrate quality: 1) low-fibre refined diet; 2) high-fibre diet with intact cellular structures; 3) high-fibre diet where the cellular structures have been disrupted (e.g. milling, blending). On day 1, a nasoenteric tube will be placed into the distal ileum and its position confirmed under fluoroscopy. Ileal samples will be collected via the nasoenteric tube and metabolically profiled, which will determine the amount and type of carbohydrate present, and the composition of the ileal microbiota will be measured. Blood samples will be collected to assess circulating hormones and metabolites. Stool samples will be collected to assess faecal microbiota composition. Subjective appetite measures will be collected using visual analogue scales. Breath hydrogen will be measured in real-time as a marker of intestinal fermentation. Finally, an in vitro continuous fermentation model will be inoculated with ileal fluid in order to understand the shift in microbial composition and SCFA produced in the colon following the different diets. Registration: ISRCTN11327221., Competing Interests: No competing interests were disclosed., (Copyright: © 2019 Byrne CS et al.)

Published

2019

12. The effects of dietary supplementation with inulin and inulin-propionate ester on hepatic steatosis in adults with non-alcoholic fatty liver disease.

Author

Chambers ES, Byrne CS, Rugyendo A, Morrison DJ, Preston T, Tedford C, Bell JD, Thomas L, Akbar AN, Riddell NE, Sharma R, Thursz MR, Manousou P, and Frost G

Subjects

Adolescent, Adult, Aged, Esters pharmacology, Female, Gastrointestinal Microbiome drug effects, Humans, Lipid Metabolism drug effects, Liver drug effects, Liver metabolism, Male, Middle Aged, Non-alcoholic Fatty Liver Disease metabolism, Non-alcoholic Fatty Liver Disease pathology, Young Adult, Dietary Supplements, Fatty Acids, Volatile pharmacology, Inulin pharmacology, Non-alcoholic Fatty Liver Disease diet therapy, Propionates pharmacology

Abstract

The short chain fatty acid (SCFA) propionate, produced through fermentation of dietary fibre by the gut microbiota, has been shown to alter hepatic metabolic processes that reduce lipid storage. We aimed to investigate the impact of raising colonic propionate production on hepatic steatosis in adults with non-alcoholic fatty liver disease (NAFLD). Eighteen adults were randomized to receive 20 g/d of an inulin-propionate ester (IPE), designed to deliver propionate to the colon, or an inulin control for 42 days in a parallel design. The change in intrahepatocellular lipid (IHCL) following the supplementation period was not different between the groups (P = 0.082), however, IHCL significantly increased within the inulin-control group (20.9% ± 2.9% to 26.8% ± 3.9%; P = 0.012; n = 9), which was not observed within the IPE group (22.6% ± 6.9% to 23.5% ± 6.8%; P = 0.635; n = 9). The predominant SCFA from colonic fermentation of inulin is acetate, which, in a background of NAFLD and a hepatic metabolic profile that promotes fat accretion, may provide surplus lipogenic substrate to the liver. The increased colonic delivery of propionate from IPE appears to attenuate this acetate-mediated increase in IHCL., (© 2018 John Wiley & Sons Ltd.)

Published

2019

13. The effect of L-rhamnose on intestinal transit time, short chain fatty acids and appetite regulation: a pilot human study using combined 13 CO 2 /H 2 breath tests.

Author

Byrne CS, Preston T, Brignardello J, Garcia-Perez I, Holmes E, Frost GS, and Morrison DJ

Subjects

Cecum drug effects, Cellulose administration & dosage, Cellulose pharmacology, Cross-Over Studies, Fatty Acids, Volatile blood, Female, Gastric Emptying drug effects, Gastrointestinal Transit physiology, Humans, Inulin administration & dosage, Inulin pharmacology, Male, Middle Aged, Peptide YY blood, Pilot Projects, Time Factors, Appetite Regulation drug effects, Breath Tests methods, Carbon Dioxide analysis, Carbon Isotopes chemistry, Fatty Acids, Volatile metabolism, Gastrointestinal Transit drug effects, Hydrogen analysis, Rhamnose pharmacology

Abstract

Background: The appetite-regulating effects of non-digestible carbohydrates (NDC) have in part previously been attributed to their effects on intestinal transit rates as well as microbial production of short chain fatty acids (SCFA). Increased colonic production of the SCFA propionate has been shown to reduce energy intake and stimulate gut hormone secretion acutely in humans., Objective: We investigated the effect of the propiogenic NDC, L-rhamnose, on gastrointestinal transit times using a combined 13 CO 2 /H 2 breath test. We hypothesised that L-rhamnose would increase plasma propionate leading to a reduction in appetite, independent of changes in gastrointestinal transit times., Design: We used a dual 13 C-octanoic acid/lactose 13 C-ureide breath test combined with breath H 2 to measure intestinal transit times following the consumption of 25 g d -1 L-rhamnose, compared with inulin and cellulose, in 10 healthy humans in a randomised cross-over design pilot study. Gastric emptying (GE) and oro-caecal transit times (OCTTs) were derived from the breath 13 C data and compared with breath H 2 . Plasma SCFA and peptide YY (PYY) were also measured alongside subjective measures of appetite., Results: L-rhamnose significantly slowed GE rates (by 19.5 min) but there was no difference in OCTT between treatments. However, breath H 2 indicated fermentation of L-rhamnose before it reached the caecum. OCTT was highly correlated with breath H 2 for inulin but not for L-rhamnose or cellulose. L-rhamnose consumption significantly increased plasma propionate and PYY but did not significantly reduce subjective appetite measures., Conclusions: The NDCs tested had a minimal effect on intestinal transit time. Our data suggest that L-rhamnose is partially fermented in the small intestine and that breath H 2 reflects the site of gastrointestinal fermentation and is only a reliable marker of OCTT for certain NDCs (e.g. inulin). Future studies should focus on investigating the appetite-suppressing potential of L-rhamnose and verifying the findings in a larger cohort.

Published

2018