Green tea composition, consumption, and polyphenol chemistry

doi:10.1016/0091-7435(92)90041-F

Preventive Medicine

Volume 21, Issue 3, May 1992, Pages 334-350

https://doi.org/10.1016/0091-7435(92)90041-F Get rights and content

Abstract

Tea is grown in about 30 countries but is consumed worldwide, although at greatly varying levels. It is the most widely consumed beverage aside from water with a per capita worldwide consumption of approximately 0.12 liter per year. Tea is manufactured in three basic forms. Green tea is prepared in such a way as to preclude the oxidation of green leaf polyphenols. During black tea production oxidation is promoted so that most of these substances are oxidized. Oolong tea is a partially oxidized product. Of the approximately 2.5 million metric tons of dried tea manufactured, only 20% is green tea and less than 2% is oolong tea. Green tea is consumed primarily in China, Japan, and a few countries in North Africa and the Middle East. Fresh tea leaf is unusually rich in the flavanol group of polyphenols known as catechins which may constitute up to 30% of the dry leaf weight. Other polyphenols include flavonols and their glycosides, and depsides such as chlorogenic acid, coumarylquinic acid, and one unique to tea, theogallin (3-galloylquinic acid). Caffeine is present at an average level of 3% along with very small amounts of the other common methylxanthines, theobromine and theophylline. The amino acid theanine (5-Nethylglutamine) is also unique to tea. Tea accumulates aluminum and manganese. In addition to the normal complement of plant cell enzymes, tea leaf contains an active polyphenol oxidase which catalyzes the aerobic oxidation of the catechins when the leaf cell structure is disrupted during black tea manufacture. The various quinones produced by the enzymatic oxidations undergo condensation reactions which result in a series of compounds, including bisflavanols, theaflavins, epitheaflavic acids, and thearubigens, which impart the characteristic taste and color properties of black tea. Most of these compounds readily form complexes with caffeine. There is no tannic acid in tea. Thearubigens constitute the largest mass of the extractable matter in black tea but their composition is not well known. Proanthocyanidins make up part of the complex. Tea peroxidase may be involved in their generation. The catechin quinones also initiate the formation of many of the hundreds of volatile compounds found in the black tea aroma fraction. Green tea composition is very similar to that of the fresh leaf except for a few enzymatically catalyzed changes which occur extremely rapidly following plucking. New volatile substances are produced during the drying stage. Oolong tea is intermediate in composition between green and black teas.

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^☆: Presented at the First International Symposium on the Physiological and Pharmacological Effects of Camellia sinensis (Tea), March 4–6, 1991, American Health Foundation, New York City. Jointly sponsored by The Tea Council and the National Tea Association.

²: Formerly of the Thomas J. Lipton Co.

View full text

Green tea composition, consumption, and polyphenol chemistry☆

Abstract

Phytochemistry

J Chromatogr

Phytochemistry

Phytochemistry

Tannings of green and black tea: Nutritional value, physiological properties and determination

Farm Tijdschr Belg

Qualitative and quantitative study of the polyphenols of different organs and some cultivated varieties of tea plant

J Sci Food Agric

Natural antioxidants. I. Antioxidative components of tea leaf (Thea. sinensis)

Chem Pharm Bull

Scavenging effect of extracts of green tea and natural antioxidants on active oxygen radicals

Cell Biophys

Condensed tannins scavenge oxygen free radicals

Med Sci Res

Tannins and related compounds. LXXVII

Chem Pharm Bull

Isolation and identification of (−)quinic acid as an unidentified major tea component

Agric Biol Chem

Theanine, an amino acid N-ethylamide, present in tea

J Sci Food Agric

Tea: The plant and its manufacture; chemistry and consumption of the beverage

The purification and some properties of polyphenol oxidase from tea

Biochem J

Fermentation of tea in aqueous suspension: Influence of tea peroxidase

J Sci Food Agric

Studies on the precursors of monoterpene alcohols in tea leaves

Agric Bull Chem