In this thesis, an analysis of 11 flavonoids was carried out. These flavonoids had shown, in earlier reasearch on human liver microsomes, metabolism mediated by cytochrome P450. Flavonoids are polyphenol compounds, widely found in plants, that are at the heart of this work because of its antioxidant, anti-inflammatory, cardioprotective and antithrombotic activity. Using liquid chromatography coupled with mass spectrometry, we determined which of the 11 flavonoids were metabolised by a specific cytochrome P450 2C subfamily of enzymes. Analysis of ion isolated chromatograph yielded data on the mass, structure and molecular formula of the new metabolites, and from the mass difference we determined which metabolite was formed and by which reaction. Of all the samples tested, only two flavonoids showed metabolism via cytochrome P450 2C subfamily of enzymes, galangin and 7-hydroxyflavone. Both flavonoids are metabolised by cytochrome 2C19 in a reaction called aromatic hydroxylation during which metabolites sakuranetin and 4',7-dihydroxyflavon are formed. However, the 4',7-dihydroxyflavon is produced in an extremely small amount, so other enzymes, such as CYP3A4, are primarily responsible for the 7-hydroxyflavone metabolism. With this work, we have sumplemented our understanding of flavonoid metabolism and assisted in the future prevention of possible interactions between flavonoids and other drugs biotransformed by cytochrome 2C19.