Green Tea Supplementation, Fat Oxidation and Body Composition in Overweight Individuals

Not Applicable

Completed

• Conditions: Overweight and Obesity; Fat Burn
• Interventions: Dietary Supplement: Placebo control; Dietary Supplement: GTE 2; Dietary Supplement: GTE 1

• Registration Number: NCT04628624
• Lead Sponsor: Anglia Ruskin University

Brief Summary

The purpose of this study is to investigate the effects of green tea extract (GTE) on fat oxidation, body composition and exercise performance in overweight individuals. The study will be conducted under laboratory conditions following an 8 week supplemental period. Participants will be required to attend the laboratory for a pre-screening/familiarisation trial followed by assessments at week 0 (baseline), week 2, 4 and 8. Across the intervention, participants will maintain habitual dietary intake and follow a prescribed exercise programme. Additionally participants will be randomised to either a placebo, green tea extract or GTE with antioxidant supplementation.

It is hypothesised that the addition of antioxidants with GTE will enhance fat oxidation in overweight individuals more than GTE or placebo. It is further hypothesised that such improvements in fat oxidation due to GTE will lead to improvements in both body composition variables and submaximal exercise performance (metabolic efficiency) in overweight, but otherwise healthy persons.

Detailed Description

The health benefits of polyphenols found in green tea (GT), the unfermented leaves of the tea plant, Camellia sinensis, are of current scientific interest. These health benefits, in part, relate to the bioactive catechin polyphenol content of GT, of which (-)-epigallocatechin-3-gallate (EGCG) can account for between 50-80% of the total catechin content. GT catechins have been proposed to influence metabolic and thermogenic activities in the short term, leading to enhanced fat oxidation capacity, although this has been disputed.

Research investigating GT extracts (GTE) and exercise have produced conflicting results. Modest EGCG dosage in the short term (270 mg·d-1 EGCG for 6 days, and 68 mg·d-1 EGCG for 3 weeks) did not alter metabolic or performance variables in healthy or endurance trained volunteers. However, the inclusion of 100.5 mg·d-1 EGCG over a 10 week training period enhanced whole-body metabolic efficiency elsewhere. One confounding factor though is the use of caffeinated GTE in these studies. When decaffeinated GTE (dGTE) has been employed, 366 mg EGCG was found to acutely increase fat oxidation by 17%. Indeed a recent publication from our research group investigating the short term use of dGTE demonstrated positive changes in fat oxidation in healthy volunteers. However, less is known as to whether dGTE (or indeed combinations of dGTE with antioxidant nutrients which may improve GTE bioavailability) could provide similar results in overweight or sedentary individuals embarking on an exercise programme.

The aim of this research proposal is therefore to assess the impact of two GTE strategies on fat oxidation, cardiometabolic health, visceral fat reduction, and exercise performance in a healthy, but overweight cohort undertaking a standardised exercise training programme.

Research Questions:

Q1: Does regular consumption of dGTE favourably enhance fat oxidation and/or improve variables associated with cardiometabolic health and body composition in comparison to a placebo supplement in healthy, but overweight individuals? Q2: Does a dGTE complex (including key antioxidant nutrients) enhance fat oxidation and/or improve variables associated with cardiometabolic health and body composition more so than dGTE or placebo supplementation in healthy, but overweight individuals?

This study will involve participants attending sessions at Compass House, ARU, undertaking the following:

* Baseline trial: all participants will attend a subject briefing, provide written, informed consent prior to participation. Following this, all participants will undertake a baseline test for maximal fat oxidation rates (FATmax) and oxygen uptake using a standardised incremental cycling exercise protocol and expired air analysis

* Intervention period: participants will be randomly assigned to either dGTE (400mg EGCG daily), dGTE with antioxidants (150mg quercetin, 150mg alpha-lipoic acid) or placebo for 8 weeks. During this period, participants will undertake regular aerobic exercise (3x/ week; 45mins; at \~ FATmax intensity)

* Experimental evaluation of progress will be assessed at weeks 0,2,4, and 8. During laboratory visits, participants will be required to have a single venepuncture blood sample, assessment of blood pressure/ body composition (skinfold, bioelectrical impedance, waist circumference), assessment of FATmax, and assessment of fat oxidation during steady state exercise at FATmax.

Study Timeline

• Study Start: 2018-12-01
• Primary Completion: 2019-12-01
• Study Completion: 2020-03-01
• Status Verified: 2020-11
• Study First Submitted: 2020-11-05
• Study First Submitted QC: 2020-11-09
• Last Update Submitted: 2020-11-09
• Study First Posted: 2020-11-13
• Last Update Posted: 2020-11-13

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 30

Inclusion Criteria

1. Men and women, UK based, above 18 years of age
2. Below 45 years of age (for men) and below 55 years of age (for women)
3. Baseline maximal oxygen uptake >25ml/kg/min and <45ml/kg/min representative of normal (but not high) fitness levels; and a body mass index (BMI) >25kg/m2 and <33kg/m2
4. All participants: No known history (including family history) of heart abnormalities, hypertension, coronary heart disease or diabetes (determined from pre-study health screen questionnaire)
5. All participants: No known history of liver related disorders (e.g. hepatitis, Wilsons disease, cirrhosis).
6. All participants: Not currently suffering from any musculo-skeletal injury, or any other reason that may prevent participation in cardiovascular exercise
7. All participants: Have not suffered from recent viral infections ie: influenza (defined within the prior 2 months)
8. All participants: Not suffering from any known blood related disorders, including blood coagulation abnormalities, or have any adverse reactions to blood taking
9. All participants: Not taking any prescribed or over-the-counter medication which may influence exercise training (with the exception of inhalers for exercise induced asthma or contraceptive pill)
10. All participants: Not consuming or prepared to refrain from consumption, any commercial supplementation which conflicts with the study parameters ie: creatine, other green tea or weight loss products.

Exclusion Criteria

1. Anyone below the age of 18 years, or above 45 years (for men) and 55 years (for women) - based on exercise testing guidelines by the American College of Sports Medicine (ACSM).
2. Those who do not meet the criteria for baseline maximal oxygen uptake or BMI assessment
3. All participants: anyone with a known history (including family history) of heart abnormalities, hypertension, coronary heart disease or diabetes (determined from pre-study health screen questionnaire)
4. All participants: anyone with a known previous history of liver related disorders.
5. All participants: Anyone suffering from a current musculo-skeletal injury, or any other reason that may prevent participation in cardiovascular exercise
6. All participants: those suffering from recent viral infections ie: influenza (defined within the prior 2 months)
7. All participants: Those with known blood related disorders, including blood coagulation abnormalities, or have any adverse reactions to blood taking. This includes any participant who has or potentially has an infectious disease, inc. HIV, and all types of hepatitis.
8. All participants: Anyone taking any prescribed or over-the-counter medication which may influence exercise training (with the exception of inhalers for exercise induced asthma or contraceptive pill)
9. All participants: Anyone consuming or not prepared to refrain from consumption, any commercial supplementation which conflicts with the study parameters ie: creatine, other green tea or weight loss products.
10. FEMALE ONLY: Any participant who is, suspects they may be or becomes pregnant during the study.

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
Placebo group	Placebo control	Placebo - capsulated, colour matched potato starch (\~450mg per capsule) - provided by Biocare Ltd., UK using standard 00 vegetable capsules (hydroxypropyl methylcellulose). Dosage: 2 divided doses (1 capsule mid morning, 1 capsule mid afternoon) - daily for 8 weeks.
Green tea 2	GTE 2	Capsulated decaffeinated green tea extract (dGTE) (standardised to 70% EGCG concentration, 571mg total per day, containing 400mg EGCG + 150mg quercitin and 150mg alpha lipoic acid - provided by Biocare Ltd., UK using standard 00 vegetable capsules (hydroxypropyl methylcellulose). Dosage: 2 divided doses (1 capsule mid morning, 1 capsule mid afternoon) - daily for 8 weeks.
Green tea 1	GTE 1	Capsulated decaffeinated green tea extract (dGTE) (standardised to 70% EGCG concentration, 571mg total per day, containing 400mg EGCG - provided by Biocare Ltd., UK using standard 00 vegetable capsules (hydroxypropyl methylcellulose). Dosage: 2 divided doses (1 capsule mid morning, 1 capsule mid afternoon) - daily for 8 weeks.

Primary Outcome Measures

Name	Time	Method
Fat oxidation (max)	Change from Baseline maximal fat oxidation at 2 months	Assessment of maximal fat oxidation rate (via expired air) during incremental exercise
Fat oxidation (min)	Change from Baseline minimum fat oxidation at 2 months	Assessment of exercise intensity at which point fat oxidation is negligable

Secondary Outcome Measures

Name	Time	Method
Blood glucose	Change from Baseline blood glucose at 2 months	Assessment of blood glucose (in mmol/L)
Height	Change from baseline height at 2 months	Assessment of height (in metres)
Weight	Change from baseline weight at 2 months	Assessment of weight (in kilograms)
Bodyfat percentage	Change from baseline bodyfat percentage at 2 months	Assessment of bodyfat (%)
Central abdomen depth	Change from baseline central abdominal depth at 2 months	Assessment of central abdomen depth (in cm)
Blood insulin	Change from Baseline blood insulin at 2 months	Assessment of blood glucose (in pmol/L)
Blood leptin	Change from Baseline blood leptin at 2 months	Assessment of blood leptin (in ng/ml)
Blood adiponectin	Change from Baseline blood adiponectin at 2 months	Assessment of blood adiponectin (in ug/ml)
Blood liver enzymes	Change from baseline at 2 months	Assessment of blood liver enzymes including alanine aminotransferase(ALT), aspartate aminotransferase (AST) and alkaline phosphatase (ALP) (all measured in U/L)
Blood bilirubin	Change from baseline bilirubin at 2 months	Assessment of blood concentration of bilirubin (in umol/L)
Respiratory measures (oxygen, carbon dioxide) during steady state exercise	Change from baseline at 2 months	Assessment of mean expired oxygen and carbon dioxide (in litres per minute)
Waist to hip ratio	Change from baseline waist to hip ratio at 2 months	Assessment of waist to hip ratio (cm)
Body mass index	Change from baseline BMI at 2 months	Assessment of body mass index or BMI (measured in kilograms per metre squared)
Blood cholesterol	Change from Baseline at 2 months	Assessment of total cholesterol, triglycerides, HDL-c and LDL-c (all in mmol/L)
Blood fatty acids and glycerol	Change from Baseline at 2 months	Assessment of blood free fatty acids and glycerol (both in umol/L)

Trial Locations

Locations (1)

Anglia Ruskin University; 🇬🇧 Cambridge, United Kingdom