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Scientific opinion on the safety of green tea catechins

2018; Wiley; Volume: 16; Issue: 4 Linguagem: Inglês

10.2903/j.efsa.2018.5239

1831-4732

Maged Younes, Peter Aggett, Fernando Aguilar, Riccardo Crebelli, Birgit Dusemund, Metka Filipič, María José Frutos Fernández, Pierre Galtier, David Michael Gott, Ursula Gundert‐Remy, Claude Lambré, Jean‐Charles Leblanc, Inger Therese Lillegaard, Peter Moldéus, Alicja Mortensen, Agneta Oskarsson, Ivan Stanković, Ine Waalkens‐Berendsen, Rudolf Antonius Woutersen, Raúl J. Andrade, Cristina Fortes, Pasquale Mosesso, Patrizia Restani, Davide Arcella, Fabiola Pizzo, Camilla Smeraldi, Matthew Wright,

Heavy Metals in Plants

EFSA JournalVolume 16, Issue 4 e05239 Scientific OpinionOpen Access Scientific opinion on the safety of green tea catechins EFSA Panel on Food Additives and Nutrient Sources added to Food (ANS), EFSA Panel on Food Additives and Nutrient Sources added to Food (ANS)Search for more papers by this authorMaged Younes, Maged YounesSearch for more papers by this authorPeter Aggett, Peter AggettSearch for more papers by this authorFernando Aguilar, Fernando AguilarSearch for more papers by this authorRiccardo Crebelli, Riccardo CrebelliSearch for more papers by this authorBirgit Dusemund, Birgit DusemundSearch for more papers by this authorMetka Filipič, Metka FilipičSearch for more papers by this authorMaria Jose Frutos, Maria Jose FrutosSearch for more papers by this authorPierre Galtier, Pierre GaltierSearch for more papers by this authorDavid Gott, David GottSearch for more papers by this authorUrsula Gundert-Remy, Ursula Gundert-RemySearch for more papers by this authorClaude Lambré, Claude LambréSearch for more papers by this authorJean-Charles Leblanc, Jean-Charles LeblancSearch for more papers by this authorInger Therese Lillegaard, Inger Therese LillegaardSearch for more papers by this authorPeter Moldeus, Peter MoldeusSearch for more papers by this authorAlicja Mortensen, Alicja MortensenSearch for more papers by this authorAgneta Oskarsson, Agneta OskarssonSearch for more papers by this authorIvan Stankovic, Ivan StankovicSearch for more papers by this authorIne Waalkens-Berendsen, Ine Waalkens-BerendsenSearch for more papers by this authorRudolf Antonius Woutersen, Rudolf Antonius WoutersenSearch for more papers by this authorRaul J Andrade, Raul J AndradeSearch for more papers by this authorCristina Fortes, Cristina FortesSearch for more papers by this authorPasquale Mosesso, Pasquale MosessoSearch for more papers by this authorPatrizia Restani, Patrizia RestaniSearch for more papers by this authorDavide Arcella, Davide ArcellaSearch for more papers by this authorFabiola Pizzo, Fabiola PizzoSearch for more papers by this authorCamilla Smeraldi, Camilla SmeraldiSearch for more papers by this authorMatthew Wright, Matthew WrightSearch for more papers by this author EFSA Panel on Food Additives and Nutrient Sources added to Food (ANS), EFSA Panel on Food Additives and Nutrient Sources added to Food (ANS)Search for more papers by this authorMaged Younes, Maged YounesSearch for more papers by this authorPeter Aggett, Peter AggettSearch for more papers by this authorFernando Aguilar, Fernando AguilarSearch for more papers by this authorRiccardo Crebelli, Riccardo CrebelliSearch for more papers by this authorBirgit Dusemund, Birgit DusemundSearch for more papers by this authorMetka Filipič, Metka FilipičSearch for more papers by this authorMaria Jose Frutos, Maria Jose FrutosSearch for more papers by this authorPierre Galtier, Pierre GaltierSearch for more papers by this authorDavid Gott, David GottSearch for more papers by this authorUrsula Gundert-Remy, Ursula Gundert-RemySearch for more papers by this authorClaude Lambré, Claude LambréSearch for more papers by this authorJean-Charles Leblanc, Jean-Charles LeblancSearch for more papers by this authorInger Therese Lillegaard, Inger Therese LillegaardSearch for more papers by this authorPeter Moldeus, Peter MoldeusSearch for more papers by this authorAlicja Mortensen, Alicja MortensenSearch for more papers by this authorAgneta Oskarsson, Agneta OskarssonSearch for more papers by this authorIvan Stankovic, Ivan StankovicSearch for more papers by this authorIne Waalkens-Berendsen, Ine Waalkens-BerendsenSearch for more papers by this authorRudolf Antonius Woutersen, Rudolf Antonius WoutersenSearch for more papers by this authorRaul J Andrade, Raul J AndradeSearch for more papers by this authorCristina Fortes, Cristina FortesSearch for more papers by this authorPasquale Mosesso, Pasquale MosessoSearch for more papers by this authorPatrizia Restani, Patrizia RestaniSearch for more papers by this authorDavide Arcella, Davide ArcellaSearch for more papers by this authorFabiola Pizzo, Fabiola PizzoSearch for more papers by this authorCamilla Smeraldi, Camilla SmeraldiSearch for more papers by this authorMatthew Wright, Matthew WrightSearch for more papers by this author First published: 18 April 2018 https://doi.org/10.2903/j.efsa.2018.5239Citations: 65 Correspondence: FIP@efsa.europa.eu Requestor: European Commission Question number: EFSA-Q-2016-00627 Panel members: Peter Aggett, Fernando Aguilar, Riccardo Crebelli, Birgit Dusemund, Metka Filipič, Maria Jose Frutos, Pierre Galtier, David Gott, Ursula Gundert-Remy, Gunter Georg Kuhnle, Claude Lambré, Jean-Charles Leblanc, Inger Therese Lillegaard, Peter Moldeus, Alicja Mortensen, Agneta Oskarsson, Ivan Stankovic, Ine Waalkens-Berendsen, Rudolf Antonius Woutersen, Matthew Wright and Maged Younes. Competing interests: In line with EFSA's policy on declarations of interest, Panel member Gunter Georg Kuhnle did not participate in the development and adoption of this scientific output. Acknowledgements: The Panel wishes to thank the following for the support provided to this scientific output: EFSA staff members: Eleonora Alquati, Adamantia Papaioannou and Rita Sousa. The Panel wishes to acknowledge all European competent institutions, Member State bodies and other organisations that provided data for this scientific output. Adopted: 14 March 2018 AboutSectionsPDF ToolsExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onFacebookTwitterLinkedInRedditWechat Abstract The EFSA ANS Panel was asked to provide a scientific opinion on the safety of green tea catechins from dietary sources including preparations such as food supplements and infusions. Green tea is produced from the leaves of Camellia sinensis (L.) Kuntze, without fermentation, which prevents the oxidation of polyphenolic components. Most of the polyphenols in green tea are catechins. The Panel considered the possible association between the consumption of (-)-epigallocatechin-3-gallate (EGCG), the most relevant catechin in green tea, and hepatotoxicity. This scientific opinion is based on published scientific literature, including interventional studies, monographs and reports by national and international authorities and data received following a public 'Call for data'. The mean daily intake of EGCG resulting from the consumption of green tea infusions ranges from 90 to 300 mg/day while exposure by high-level consumers is estimated to be up to 866 mg EGCG/day, in the adult population in the EU. Food supplements containing green tea catechins provide a daily dose of EGCG in the range of 5–1,000 mg/day, for adult population. The Panel concluded that catechins from green tea infusion, prepared in a traditional way, and reconstituted drinks with an equivalent composition to traditional green tea infusions, are in general considered to be safe according to the presumption of safety approach provided the intake corresponds to reported intakes in European Member States. However, rare cases of liver injury have been reported after consumption of green tea infusions, most probably due to an idiosyncratic reaction. Based on the available data on the potential adverse effects of green tea catechins on the liver, the Panel concluded that there is evidence from interventional clinical trials that intake of doses equal or above 800 mg EGCG/day taken as a food supplement has been shown to induce a statistically significant increase of serum transaminases in treated subjects compared to control. Summary Following a request from the European Commission to the European Food Safety Authority (EFSA), the Scientific Panel on Food Additives and Nutrient Sources added to Food (ANS) was asked to provide a scientific opinion on the safety of green tea catechins from dietary sources from all sources in foods including preparations such as food supplements and infusions. Teas produced from the leaves of Camellia sinensis (L.) Kuntze are classified according to the processing used into four different subtypes: green tea, black tea, white tea and oolong tea. Green tea is produced without fermentation and thus oxidation of the polyphenolic components is prevented. White tea is produced with minimal fermentation from new buds and young leaves, which are harvested only once a year in early spring. Black tea manufacture is carried out by fermentation ensuring a high degree of enzymatically catalysed aerobic oxidation of the polyphenols followed by a series of chemical condensations. Oolong tea is a semi-fermented tea, where polyphenols are partially oxidised. Green tea as an infusion has been extensively consumed as a beverage in Asian countries for centuries. Green tea and its extracts are rich in polyphenolic compounds, most of which are flavanols, commonly known as catechins. The primary catechins in green tea are (–)-epicatechin (EC), (–)-epicatechin-3-gallate (ECG), (–)-epigallocatechin (EGC) and (–)-epigallocatechin-3-gallate (EGCG). Furthermore, (+)-catechin (C), (+)-gallocatechin (GC), (–)-gallocatechin-3-gallate (GCG) and (+)-catechin-3-gallate (CG). Green tea has been associated with various health benefits, such as prevention of cancer, obesity, diabetes and neurodegenerative diseases. Concerns have been raised concerning possible harmful effects associated with the use of green tea extracts and infusions, including reported cases of liver toxicity possibly associated with the intake of green tea catechins. This risk assessment of green tea catechins is carried out in the framework of the procedure under Article 8 (2) of Regulation (EC) No 1925/2006 on the addition of vitamins and minerals and of certain other substances to foods, initiated by the European Commission. Article 8 (2) of Regulation (EC) No 1925/2006 is referring to a possible prohibition, restriction or Community scrutiny of a substance or ingredient by placement in Annex III, Part A, B or C of this Regulation. The Panel considered the possible association between the consumption of EGCG, the most relevant catechin in green tea, and hepatotoxicity. The Panel based this assessment on the content of EGCG in green tea extracts and infusions due to the fact that this is the major catechin found in green tea, it is present in plasma in the unconjugated form after oral intake, and it is the most cytotoxic catechin (compared to EGC and ECG) in primary rat hepatocytes. The Panel is aware that in the current risk assessment, a number of aspects have not been considered such as beneficial effects associated with the intake of green tea catechins, as these fall outside the remit of the Panel and the scope of the current mandate. C. sinensis (L.) Kuntze (Thea sinensis L.) is included in the EFSA 'Compendium of botanicals' reported to contain naturally occurring substances of possible concern for human health when used in food and food supplements. Hepatotoxicity is the adverse effect listed in the compendium, which also states that the doses causing hepatotoxicity are not indicated in human case reports. The Panel noted that, according to the USDA Database, EGCG can be found in a number of other botanical species in addition to C. sinensis. The Panel noted that there are no specifications for green tea preparations used as food including food supplements in EU Regulations or any monographs on green tea preparations in the current edition of the European Pharmacopeia. The Panel noted that green tea may be contaminated by pyrrolizidine alkaloids (PA) and that 1,2-unsaturated PA can be activated by CYP450 enzymes to form hepatotoxic metabolites. The Panel considered that the levels of PA present in green tea products is unlikely to induce non-neoplastic hepatotoxicity alone, but could not exclude the possibility that contamination by PA in green tea products may be a contributory factor to the hepatotoxicity of green tea catechins. Catechin supplements, green tea infusions or reconstituted tea drinks from green tea extracts can be prepared and consumed together with other foods, such as milk or eggs. Interactions between tea polyphenols and dietary proteins have been described. Tea catechins can bind to milk proteins and form a network of casein micelles. The non-covalent interactions between polyphenols and proteins could affect the protein conformation, secondary structure, unfolding and precipitation. It has been reported that for EGCG, the galloyl functional group is responsible for this affinity between polyphenols and β-lactoglobulin through the formation of hydrogen bonds and hydrophobic interactions. The Panel noted that the free catechins that could be absorbed in vivo from green tea infusions could be influenced by the interactions with milk proteins. Dried green tea extracts are used as food, including beverages and food supplements and as pharmaceuticals. With respect to food supplements, the exposure to green tea components may vary considerably depending on the composition of the actual product and the daily dose recommended by the food supplement manufacturers/providers. The Panel estimated chronic exposure to EGCG from green tea infusions for the following population groups: infants; toddlers, children, adolescents, adults and the elderly. Exposure to EGCG was calculated by multiplying EGCG concentrations (mg/g) for the consumption amount expressed as g/day for each individual in the Comprehensive Database (consumers only). The concentration of EGCG used for the calculation of exposure has been extracted from the 'USDA database for flavonoid content of selected foods' (USDA, 2014 version 3.1). Exposure to EGCG was assessed by using the EGCG mean level reported for 100 brewed green tea samples (from 12 references) that was equal to 0.7 mg EGCG/g of brewed green tea. The mean exposure EGCG from brewed green tea ranged from 5 mg/day in toddlers to 321 mg/day in adults. The high level exposure to EGCG (95th percentile) ranged from 238 mg/day in adolescents to 866 mg/day in adults. In response to a public 'Call for data' launched by EFSA, no data were received from interest parties on the levels of catechins in green tea extracts used for the manufacturing of food supplement. For the purpose of this Scientific Opinion, the Mintel Global New Products Database (GNPD) was used for checking the labelling of products containing green tea within the EU countries' food products as the Mintel GNPD shows the compulsory ingredient information presented in the labelling of products. The daily consumption in terms of EGCG for each product was calculated multiplying the dose unit of EGCG for the daily number of recommended doses of the product. The daily intake of EGCG for these products ranged from 5 to 1,000 mg/day, for the adult population. In particular, among the 23 products retrieved with Mintel GNPD, there were six products with a recommended daily dose of EGCG below 100 mg; eight products with recommended daily dose ranging from 100 to 300 mg; three products with daily recommended dose above 800 mg. The maximum daily dose was reported for one product at 1,000 mg per day. In humans, plasma contained intact EGCG and ECG and several catechin metabolites in the form of O-methylated, sulfated and glucuronide conjugates of EC and EGC. The intestinal microbiota is responsible for the high degree of metabolism to polyhydroxyphenyl-γ-valerolactones which are the main urinary catabolites, averaging 10 times greater concentrations than catechin conjugates. Human data show that administration of green tea extract under fasting conditions, and as a bolus, leads to a significant increase in the area under the plasma concentration–time curve of EGCG compared to administration with food and in split doses. Green tea extracts have been associated with cases of hepatotoxicity, especially when used for weight control. A large number of clinical trials have been performed to investigate purported beneficial effects of green tea catechins. Serum levels of the enzymes alanine aminotransferase (ALT) and in some of the studies also aspartate aminotransferase (AST) have been investigated routinely in many of the trials as biomarkers of liver toxicity. In total 49 Intervention studies with green tea products stating to include data on liver parameters were retrieved from the literature. The Panel considered that the intervention studies varied widely in dose, composition of the administered green tea catechins, duration of treatment, number and health status of treated subjects as well as in the outcome on liver parameters. These limitations combined give an uncertainty in the identification of a maximum dose of EGCG that will not cause an increase of serum liver enzyme level or a minimum dose causing a significant (biological) effect. However, after reviewing the evidence from the 38 intervention studies, which included data on effects of green tea extracts and infusions on serum transaminases, the Panel considered that exposure to green tea extracts at doses at or above 800 mg EGCG/day for 4 months or longer are associated with elevations of ALT and AST in a small percentage (usually less than 10%) of the population. Moderate or more severe abnormalities in any liver function were observed in 5.1% of the treated subjects in a study with more than 500 subjects treated with 843 mg EGCG/day for one year. Statistically significant odds ratios were 7.0 (95% CI = 2.4–20.3; p = 0.0002) (Dostal et al., 2015; Yu et al., 2017). Various contributing risk factors to hepatotoxicity were studied in this study and the previously suggested risk factors, such as COMT genotype, use of non-steroidal anti-inflammatory drug, paracetamol, statins or weekly alcohol consumption did not increase the liver effect of green tea catechins. However, the Panel noted that in this study the liver effects were more pronounced in subjects with high body mass index (BMI), which is an important finding as green tea extracts are used in food supplements for weight control. A large number of subjects were treated with green tea extracts in intervention studies at or below 316 mg EGCG/day and did not show elevated serum levels of transaminases. The Panel also noted that during the intervention studies serum transaminases were continuously monitored, and cases with serious effects were excluded from further exposure, thus preventing liver injuries. Furthermore, elevated transaminases returned to normal after dechallenge and increased again after one or more rechallenges, which strongly suggests a causality between exposure to green tea extracts and liver effects. The Panel considered the sparse data on green tea exposure from traditional green tea infusions and noted that there was no evidence of elevated ALT levels at a consumption of green tea infusion of ≥ 5 cups per day or containing 700 mg EGCG/day. None of the intervention studies addressed pregnant women, breast-fed infants or children. Case reports of hepatotoxicity induced by the exclusive use of green tea products were evaluated and 22 cases were found where green tea was claimed to be the only causative agent leading to an almost exclusive hepatocellular pattern of liver injury (1 out of 22 cases was mixed). Eight of the cases were reported to occur after consumption of green tea infusion, whereas most cases were associated with green tea supplements. In seven of the cases, subjects were exposed to Exolise®. Most cases were reported in middle-aged females, which could be associated with this subpopulation's use of green tea extracts for body weight control. In most of the cases, hepatotoxicity is induced after the ingestion of green tea extracts for a period of at least several weeks up to 8 months although some cases were reported after a shorter period of regular intake (5 days). No fatal cases were associated solely with the use of green tea products and the majority of cases resolved following green tea preparation discontinuation. Although the quality and precision of causality assessment procedures vary from one case to another, temporal relationship and the exclusion of other potential causes of liver injury were appropriately satisfied in the majority of the cases. In addition, positive rechallenge in many cases further supports the role of green tea preparations in liver injury. Based on the current literature review on case reports, it is difficult to draw conclusions concerning the minimal dose of EGCG present in green tea products capable of inducing liver injury. There was a great variability in the ingested daily dose of green tea products with cases of hepatotoxicity being induced at doses exceeding three cups of green tea infusion to cases with exposure up to 1,800 mg green tea extract/day (content of EGCG not stated in these case reports). The Panel considered that the liver injury in many of the case reports is likely due to idiosyncratic reactions. Idiosyncratic drug-induced liver injury (IDILI) is a term used to define those adverse reactions to medications and other xenobiotic substances, including herbal and dietary supplements, which are not clearly related to dose, route or duration of drug administration. Although not dose-related in a strict sense, these reactions largely occur after exposure to drugs and may require either repeated exposure or exceedance of a threshold dose which is highly variable between individuals. The pathogenesis of IDILI is complex and not yet fully understood. Overall, the Panel noted that the number of human cases with hepatotoxicity associated with consumption of green tea infusions is extremely low compared to the large number of consumers of green tea infusions. However, in the case reports, both from exposure to green tea extracts and to green tea infusions, more severe hepatotoxicity is reported compared to hepatotoxicity reported in the clinical trials, where mild liver effects are discovered early in the clinical monitoring and exposure is discontinued preventing more severe liver injury. Data from animal experiments demonstrate that liver is a target tissue for green tea catechin toxicity. At high oral bolus doses or parenteral administration, when higher tissue levels can be expected, ALT elevation and liver toxicity occurs with a higher incidence and with more severe effects, than from exposure via peroral administration or via feed. Thus, oral bolus doses of 750 mg EGCG/kg body weight (bw) (2 daily doses) caused hepatotoxicity in mice. A single intraperitoneal administration of EGCG at 100 mg/kg bw was sufficient to generate an hepatic injury in mice. Fasting is also demonstrated to increase the toxicity of green tea catechins in experimental animals, probably due, in part, to a higher bioavailability of green tea catechins, which may be due to less binding of catechins to dietary proteins, and reduced hepatic glycogen levels. When EGCG or green tea extracts were administered orally to experimental animals, liver toxicity was observed in some, but not all studies. In subchronic studies where liver toxicity was observed, the lowest no observed adverse effect level (NOAEL) for this effect was 242 mg EGCG/kg bw per day in rats administered a green tea extract via oral gavage. Severe toxicity, mainly in the gastro-intestinal tract but also the liver, was demonstrated in fasted dogs, administered green tea extracts in capsules at doses, which were non-toxic to fed dogs. The NOAEL in fasted dogs was 40 mg EGCG/kg bw per day, which was 10 times lower than the NOAEL identified in fed dogs. The Panel considered that there was no evidence of carcinogenic activity of green tea extract in rats or mice. Based on histopathological effects in the liver in male and female rats, the Panel considered that a NOAEL could be identified of 145 mg EGCG/kg bw per day (administered by gavage, 5 days/week). Based on only the liver effects in male mice, the NOAEL identified would be 48.4 mg EGCG/kg bw per day. No clinical chemistry was performed in this study. When a green tea catechin mixture was added to the diet, no liver effects were reported in rats with doses up to 838 mg/kg bw per day, the highest dose tested. Overall, the Panel considered that there were a number of uncertainties regarding green tea catechin exposures, biological and toxicological effects: The chemical composition of green tea varies widely due to plant variety, growing environment, season, age of leaves and manufacturing conditions with EGCG content ranging from 1,600 to 20,320 mg/100 g dried leaves (13-fold). With regard to green tea infusions, EGCG content varied over a greater than 88-fold range (2.3–203 mg/100 g infusion). Given that EGCG/catechins concentrations in green tea infusions decrease during storage and preparation (at tea-brewing temperatures), there is uncertainty regarding actual EGCG exposures from green tea infusions based on content in dried leaves. There remain uncertainties regarding the presence of hepatotoxic contaminants such as PA in green tea preparations. There remain uncertainties regarding the extent to which manufacturing procedures influence extraction yield and the composition of extracted catechins and other substances used to prepare green tea extracts. There are additional uncertainties surrounding the proportion of EGCG/catechins that can be absorbed after oral exposure to green tea infusions due to precipitation of EGCG/catechins in infusions during cooling. Uncertainties persist regarding the effects of dietary proteins on the absorption of EGCG/catechins from both infusions and supplements. Even if EGCG is considered the primary causative hepatotoxic agent in green tea, there are uncertainties to what extent other catechins present would also be causative hepatotoxic agents and/or modulate EGCG hepatotoxicity. Due to limited dose–response data after daily EGCG exposures up to 800 mg/day, there is uncertainty regarding the starting point for the derivation of a health-based guidance value for EGCG for the general population. There is an uncertainty whether more serious liver effects may develop after long-term use of green tea extracts. There are uncertainties around the mechanism(s) leading to both the dose-dependent hepatotoxicity of EGCG and the mechanism(s) leading to idiosyncratic hepatotoxicity to EGCG. On the basis of the information available, the Panel concluded that catechins from green tea infusion, prepared in a traditional way, and reconstituted drinks with an equivalent composition to traditional green tea infusions, are in general considered safe according to the presumption of safety approach, provided the intake corresponds to reported intakes in European Member States. However, rare cases of liver injury have been reported after consumption of green tea infusions, most probably due to an idiosyncratic reaction. Based on the available data on the potential adverse effects of green tea catechins on the liver, the Panel further concluded that there is evidence from interventional clinical trials that intake of doses equal or above 800 mg EGCG/day taken as a food supplement statistically significant increase serum transaminases in treated subjects compared to control. Catechins in green tea extracts, either consumed as a beverage or in liquid or dry form as dietary supplements, may be more concentrated, may differ in composition and pattern of consumption compared to catechins from traditional green tea infusions and cannot be regarded as safe according to the presumption of safety approach, as exposure to green tea extracts at and above 800 mg EGCG/day in intervention studies causes elevated serum transaminases which is indicative of liver injury. The Panel concluded that it was not possible to identify an EGCG dose from green tea extracts that could be considered safe. From the clinical studies reviewed there is no evidence of hepatotoxicity below 800 mg EGCG/day up to 12 months. However, hepatotoxicity was reported for one specific product containing 80% ethanolic extract at a daily dose corresponding to 375 mg EGCG. The Panel noted that the level of 800 mg EGCG/day is outside the range of the mean daily intake of EGCG (90–300 mg/day) resulting from the consumption of green tea infusions in the EU, however this level of exposure falls within the upper range (300–866 mg/day) of exposure by high-level consumers of green tea infusions in the EU in the adult population. The Panel recognised that it is plausible that the kinetics, as well as the toxicity of green tea catechins, could be modified by the matrix in which they are present. The Panel recommended that studies should be performed to determine a dose–response of hepatotoxicity of green tea catechins and examine inter and intra species variability. Maximum limits for pyrrolizidine alkaloids in green tea preparations, including food supplements should be established, since they may contribute to hepatotoxicity. Labels of green tea products (with particular reference to food supplements) should include content of catechins and the proportion of EGCG. 1 Introduction Following a request from the European Commission to the European Food Safety Authority (EFSA), the Scientific Panel on Food Additives and Nutrient Sources added to Food (ANS) was asked to provide a scientific opinion on the safety of green tea catechins from dietary sources from all sources in foods including preparations such as food supplements and infusions. Teas produce