The Effect of Green Tea Extract on Fat Oxidation at Rest and during Exercise: Evidence of Efficacy and Proposed Mechanisms

Green tea is made from the leaves of the Camellia sinensis L plant, which is rich in polyphenol catechins and caffeine. There is increasing interest in the potential role of green tea extract (GTE) in fat metabolism and its influence on health and exercise performance. A number of studies have obser...

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Bibliographic Details
Published inAdvances in nutrition (Bethesda, Md.) Vol. 4; no. 2; pp. 129 - 140
Main Authors Hodgson, Adrian B., Randell, Rebecca K., Jeukendrup, Asker E.
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 01.03.2013
American Society for Clinical Nutrition
Subjects
Adipose Tissue - metabolism
bioavailability
caffeine
Camellia sinensis
Camellia sinensis - chemistry
catechol O-methyltransferase
exercise
Exercise - physiology
flavanols
gene expression
Gene Expression - drug effects
gene expression regulation
genes
green tea
Humans
leaves
lipid metabolism
Lipolysis - drug effects
Lipolysis - genetics
liver
Liver - drug effects
Liver - metabolism
Muscle, Skeletal - drug effects
Muscle, Skeletal - metabolism
Plant Extracts - pharmacology
polyphenols
Rest - physiology
skeletal muscle
Treatment Outcome
EE
EGC
PDE
PGC1α
EGCG
GTE
SNS
FA
COMT
RER
RQ
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Summary:Green tea is made from the leaves of the Camellia sinensis L plant, which is rich in polyphenol catechins and caffeine. There is increasing interest in the potential role of green tea extract (GTE) in fat metabolism and its influence on health and exercise performance. A number of studies have observed positive effects of GTE on fat metabolism at rest and during exercise, following both shorter and longer term intake. However, overall, the literature is inconclusive. The fact that not all studies observed effects may be related to differences in study designs, GTE bioavailability, and variation of the measurement (fat oxidation). In addition, the precise mechanisms of GTE in the human body that increase fat oxidation are unclear. The often-cited in vitro catechol-O-methyltransferase mechanism is used to explain the changes in substrate metabolism with little in vivo evidence to support it. Also, changes in expression of fat metabolism genes with longer term GTE intake have been implicated at rest and with exercise training, including the upregulation of fat metabolism enzyme gene expression in the skeletal muscle and downregulation of adipogenic genes in the liver. The exact molecular signaling that activates changes to fat metabolism gene expression is unclear but may be driven by PPAR-γ coactivator 1-α and PPARs. However, to date, evidence from human studies to support these adaptations is lacking. Clearly, more studies have to be performed to elucidate the effects of GTE on fat metabolism as well as improve our understanding of the underlying mechanisms.
Bibliography:http://dx.doi.org/10.3945/an.112.003269
ISSN:2161-8313
2156-5376
2156-5376
DOI:10.3945/an.112.003269