and TKT accumulated up to 0.34 mg m

and TKT accumulated up to 0.34 mg mL−1 and 0.33 mg mL−1 gallic acid equivalent at the eighth day of fermentation, while it was only about 0.15 mg mL−1 in SBT. These observations were in accordance with those reported by Ponmurugan etal.9 Jayabalan etal.21 considered complex phenolic compounds in KT might be depolymerised in an acidic environment and by the enzymes liberated by bacteria and yeasts in the tea fungus consortium, whichinturnresultedintheincreaseoftotalphenoliccompounds. They also observed the degradation of epigallocatechin gallate (EGCG) and epicatechin gallate (ECG) during KT fermentation.31 Both were assumed to be converted to their corresponding catechin epigallocatechin (EGC) and epicatechin (EC) by enzymes excreted by micro-organisms in the kombucha culture. Duenas etal.32 demonstrated that bioactive polyphenolic compounds of lentilscouldbemodifiedduetoexogenousapplicationofenzymes likephytase,α-galactosidaseandtannase.Theyalsodemonstrated the increased antioxidant activity of enzyme-treated lentils. Because of the high content of phenolic compounds, MKT and TKT significantly (P < 0.01) elevated the free, hydroxyl and superoxide radical scavenging activity of SBT (Fig. 2). Asreported,Cu2+-inducedLDLperoxidationwasmorerelevant to the in vivo situation than other peroxidation [e.g., 1-(2,6- dimethylphenoxy)-2-(3,4-dimethoxyphenylethylamino) propane hydrochloride (DDPH), 2,2 -azobis (2-amidinopropane) dihy- drochloride (AAPH)], since the former system most likely involved a site-specific attack of the apolipoprotein B in LDL, whereas the latter produced more or less random attack of free radicals.33 Therefore, protection effect of SBT, MKT and TKT on human LDL
was initially investigated in present study. As can be seen from Fig. 3,alltheSBT,MKTandTKTcontributedtoLDLprotectionfrom oxidation by significantly prolonging the lag phase (P < 0.01). Various studies have demonstrated that KT had in vivo antioxi- dantactivity,butthecauseofthisremainsunclear.21 Theincreased potential against radicals might explain the phenomenon that feeding KT significantly reversed chromate(IV)- or lead-induced oxidative injury in rats.19,20 Therefore, KT may possess some other curative effects such as reduction of atherosclerosis, arthritis and inflammation, which might be related to its antioxidative activ- ity compared to black tea broth,30 although this has not been validated scientifically. In addition, Figs 2 and 3 show that there was no significant difference between MKT and TKT in total polyphenol content, radical scavenging activity and LDL oxidation inhibitory effect. That means that MKT and TKT have equal antioxidant activities in vitro. DSL had no antioxidant activity in vitro (data not shown). The following experiments were carried out to evaluate their hypocholesterolaemic and antioxidant effects in vivo.