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| Name | Class |
|---|---|
| King's College London | OTHER |
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Large postprandial glucose responses are associated with increased risk of chronic diseases, including diabetes and cardiovascular disease. Our group have previously shown that fruit polyphenol extracts, when consumed immediately before a mixed carbohydrate meal, reduce postprandial glycaemia. The aim of this study is to investigate the effects of a blackcurrant polyphenol extract and citrus polyphenol extract (and their combination), on postprandial glycaemia, insulinaemia and gastrointestinal hormone concentrations following a mixed carbohydrate test meal. It is hypothesised that blackcurrant and citrus extracts alone will inhibit glycaemia compared to placebo, and a combination of the two will have a greater effect.
Intake of carbohydrate-rich foods transiently increases blood glucose levels (known as postprandial glycaemia). Repeated high postprandial glucose responses are evidenced to dysregulate functional proteins, oxidative stress and pancreatic beta cell function; thus increasing the risk of diabetes and cardiovascular disease. Accordingly, meals that elicit a reduced, or more gradual, rise in blood glucose levels are desirable. Fruit polyphenols may help to limit the glucose excursion following a high carbohydrate meal. Previous research by our group has demonstrated that blackcurrant polyphenols significantly inhibited the average incremental area under the curve (T+0 to +30 min) of plasma glucose. Possible mechanisms include inhibition of intestinal enzymes and inhibition of intestinal glucose absorption by decreasing Sodium-glucose linked transporter 1 (SGLT-1) / Glucose transporter 2 (GLUT-2) glucose transporter activity. In vitro data suggests that citrus polyphenols may impact on carbohydrate metabolism by binding to starch molecules, however, effects on postprandial glycaemia are not yet known. Blackcurrants and citrus fruits have distinct polyphenol profiles and may therefore act on glucose homeostasis via different mechanisms. Blackcurrants are rich in anthocyanins and flavanols, whereas citrus fruits are rich in flavanones, hesperetin and naringenin. Theoretically, combining blackcurrant with citrus extracts may have synergistic effects.
The aim of this study is to investigate the effects of blackcurrant polyphenol extracts and citrus polyphenol extracts (and their combination), on postprandial glycaemia, insulinaemia and gastrointestinal hormone concentrations following a mixed carbohydrate test meal. It is hypothesised that blackcurrant and citrus extracts alone will inhibit glycaemia compared to placebo, a combination of the two will have a greater effect.
Study design: A randomised, controlled, double-blind, cross-over study will be conducted. Subjects will consume different drinks at 4 separate study visits. Drinks will contain either: blackcurrant extract (low dose), blackcurrant extract (high dose), citrus extract (low dose), blackcurrant and citrus extract (low dose + low dose), or placebo (no polyphenols). The study will utilise an incomplete block design. Subjects will consume the placebo drink and 3 out of 4 of the polyphenol-containing drinks during the study. At least a 7-day wash-out period will be required between study days. Baseline (fasted) blood samples will be taken in duplicate at T-10 min and T-5 min before consuming the test drink (T+0 min). Immediately following consumption of the drink, a mixed carbohydrate test meal will be consumed. Further blood samples will be collected at 10 min intervals for the first 30 min and then every 15 min until T+90 min and at T+120 min. Blood samples will be analysed for plasma glucose, insulin, glucose-dependent insulinotropic peptide (GIP), glucagon-like peptide 1 (GLP-1), peptide YY (PYY), C-peptide and nonesterified fatty acids (NEFA).
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| Treatment arm 1 | Experimental | Participants will receive the placebo, blackcurrant extract (low dose), blackcurrant extract (high dose), citrus extract (low dose) at 4 separate study visits, in a random order. Visits will be separated by at least 7 days. |
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| Treatment arm 2 | Experimental | Participants will receive the placebo, citrus extract (low dose), blackcurrant extract (high dose), blackcurrant and citrus extracts (low dose / low dose) at 4 separate study visits, in a random order. Visits will be separated by at least 7 days. |
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| Treatment arm 3 | Experimental | Participants will receive the placebo, blackcurrant extract (low dose), blackcurrant extract (high dose), blackcurrant and citrus extracts (low dose / low dose) at 4 separate study visits, in a random order. Visits will be separated by at least 7 days. |
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| Treatment arm 4 | Experimental |
| Name | Type | Description | Arm Group Labels | Other Names |
|---|---|---|---|---|
| Blackcurrant extract (low dose) | Dietary Supplement | Participants will consume a small beverage that contains blackcurrant extract (low dose) immediately before a high-carbohydrate meal. |
| Measure | Description | Time Frame |
|---|---|---|
| Postprandial glycaemia (iAUC 0-30 min) | The primary endpoint is iAUC 0-30 min for plasma glucose concentrations | 30 min |
| Measure | Description | Time Frame |
|---|---|---|
| Postprandial glycaemia: iAUC 0-120 min | iAUC 0-120 min for plasma glucose concentrations | 120 min |
| Postprandial glycaemia: iCmax | iCmax for plasma glucose concentrations |
| Measure | Description | Time Frame |
|---|---|---|
| Food diary (estimated/unweighed) | Habitual dietary intake analysis | 7-days, collected at screening |
| VAS measures of the palatability of the study drink | Descriptive statistics |
Inclusion Criteria:
Exclusion Criteria:
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| Name | Affiliation | Role |
|---|---|---|
| Wendy L Hall, PhD | King's College London | Principal Investigator |
| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| Metabolic Research Unit | London | England | SE1 9NH | United Kingdom |
| PubMed Identifier | Type | Citation | Retractions |
|---|---|---|---|
| 27764725 | Background | Castro-Acosta ML, Smith L, Miller RJ, McCarthy DI, Farrimond JA, Hall WL. Drinks containing anthocyanin-rich blackcurrant extract decrease postprandial blood glucose, insulin and incretin concentrations. J Nutr Biochem. 2016 Dec;38:154-161. doi: 10.1016/j.jnutbio.2016.09.002. Epub 2016 Sep 14. | |
| 37902089 | Derived |
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Incomplete block cross-over design. Each participant receives placebo plus 3 out of 4 active treatments.
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Participants will receive the placebo, blackcurrant extract (low dose), citrus extract (low dose), blackcurrant and citrus extracts (low dose / low dose) at 4 separate study visits, in a random order. Visits will be separated by at least 7 days. |
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| Placebo | Dietary Supplement | Participants will consume a small beverage that contains no fruit extracts immediately before a high-carbohydrate meal. |
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| Citrus extract (low dose) | Dietary Supplement | Participants will consume a small beverage that contains citrus extract (low dose) immediately before a high-carbohydrate meal. |
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| Blackcurrant extract (high dose) | Dietary Supplement | Participants will consume a small beverage that contains blackcurrant extract (high dose) immediately before a high-carbohydrate meal. |
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| Blackcurrant and citrus extracts (low dose / low dose) | Dietary Supplement | Participants will consume a small beverage that contains blackcurrant and citrus extracts (low dose / low dose)immediately before a high-carbohydrate meal. |
|
| 120 min |
| Postprandial glycaemia: Tmax | Tmax for plasma glucose concentrations | 120 min |
| Postprandial glycaemia: absolute concentrations at specific time points | Absolute concentrations at specific time points, for plasma glucose concentrations | 120 min |
| Postprandial insulinemia: iAUC 0-30 min | iAUC 0-30 min for serum insulin concentrations | 30 min |
| Postprandial insulinemia: iAUC 0-120 min | iAUC 0-120 min for serum insulin concentrations | 120 min |
| Postprandial insulinemia: iCmax | iCmax, for serum insulin concentrations | 120 min |
| Postprandial insulinemia: Tmax | Tmax for serum insulin concentrations | 120 min |
| Postprandial insulinemia: absolute concentrations at specific time points | Absolute concentrations at specific time points, for serum insulin concentrations | 120 min |
| Postprandial C-peptide: iAUC 0-30 min | iAUC 0-30 min for plasma C-peptide concentrations | 30 min |
| Postprandial C-peptide: iAUC 0-120 min | iAUC 0-120 min for plasma C-peptide concentrations | 30 min |
| Postprandial C-peptide: iCmax | iCmax for plasma C-peptide concentrations | 120 min |
| Postprandial C-peptide: Tmax | Tmax for plasma C-peptide concentrations | 120 min |
| Postprandial C-peptide: Absolute concentrations at specific time points | Absolute concentrations at specific time points, for plasma C-peptide concentrations | 120 min |
| Postprandial non-esterified fatty acids (NEFA): iAUC 0-30 min | iAUC 0-30 min for serum NEFA concentrations | 30 min |
| Postprandial non-esterified fatty acids (NEFA): iAUC 0-120 min | iAUC 0-120 min for serum NEFA concentrations | 120 min |
| Postprandial non-esterified fatty acids (NEFA): iCmax | iCmax for serum NEFA concentrations | 120 min |
| Postprandial non-esterified fatty acids (NEFA): Tmax | Tmax for serum NEFA concentrations | 120 min |
| Postprandial non-esterified fatty acids (NEFA): Absolute concentrations at specific time points | Absolute concentrations at specific time points, for serum NEFA concentrations | 120 min |
| Postprandial blood glucose-dependent insulinotropic peptide (GIP): iAUC 0-30 min | iAUC 0-30 min for plasma GIP concentrations | 30 min |
| Postprandial blood glucose-dependent insulinotropic peptide (GIP): iAUC 0-120 min | iAUC 0-120 min for plasma GIP concentrations | 120 min |
| Postprandial blood glucose-dependent insulinotropic peptide (GIP): iCmax | iCmax, for plasma GIP concentrations | 120 min |
| Postprandial blood glucose-dependent insulinotropic peptide (GIP): Tmax | Tmax for plasma GIP concentrations | 120 min |
| Postprandial blood glucose-dependent insulinotropic peptide (GIP): Absolute concentrations at specific time points | Absolute concentrations at specific time points, for plasma GIP concentrations | 120 min |
| Postprandial blood Glucagon-like peptide 1 (GLP-1): iAUC 0-30 min | iAUC 0-30 min for plasma GLP-1 concentrations | 30 min |
| Postprandial blood Glucagon-like peptide 1 (GLP-1): iAUC 0-120 min | iAUC 0-120 min, for plasma GLP-1 concentrations | 120 min |
| Postprandial blood Glucagon-like peptide 1 (GLP-1): iCmax | iCmax for plasma GLP-1 concentrations | 120 min |
| Postprandial blood Glucagon-like peptide 1 (GLP-1): Tmax | Tmax for plasma GLP-1 concentrations | 30 min |
| Postprandial blood Glucagon-like peptide 1 (GLP-1): Absolute concentrations at specific time points | Absolute concentrations at specific time points, for plasma GLP-1 concentrations | 120 min |
| Postprandial blood peptide YY (PYY): iAUC 0-30 min | iAUC 0-30 min for plasma PYY concentrations | 30 min |
| Postprandial blood peptide YY (PYY): iAUC 0-120 min | iAUC 0-120 minfor plasma PYY concentrations | 120 min |
| Postprandial blood peptide YY (PYY): iCmax | iCmax for plasma PYY concentrations | 120 min |
| Postprandial blood peptide YY (PYY): Tmax | Tmax for plasma PYY concentrations | 120 min |
| Postprandial blood peptide YY (PYY): Absolute concentrations at specific time points | Absolute concentrations at specific time points, for plasma PYY concentrations | 120 min |
| 10 min following the test drink |
| VAS measures of mood, satiety and digestive comfort | Descriptive statistics | 120 min |
| Buccal mouth swab | Future exploratory analysis of lactase activity via the derived allele at the European lactase persistence (LP) locus | One off sample, collected at screening |
| Pinto AM, Hobden MR, Brown KD, Farrimond J, Targett D, Corpe CP, Ellis PR, Todorova Y, Socha K, Bahsoon S, Haworth C, Marcel M, Nie X, Hall WL. Acute effects of drinks containing blackcurrant and citrus (poly)phenols and dietary fibre on postprandial glycaemia, gut hormones, cognitive function and appetite in healthy adults: two randomised controlled trials. Food Funct. 2023 Nov 13;14(22):10163-10176. doi: 10.1039/d3fo03085g. |