Bilirubin conjugates of human bile. Isolation of phenylazo derivatives of bile bilirubin

A method is presented that allows the isolation of eight different phenylazo derivatives of bile bilirubin. In step I of the isolation procedure, three bilirubin fractions (bilirubin fractions 1, 2 and 3) from human hepatic bile are separated by reverse-phase partition chromatography on silicone-treated Celite with the use of a solvent system prepared from butan-1-ol and 5mm-phosphate buffer, pH6.0. Azo coupling is then performed with diazotized aniline. The three azo pigment mixtures are subjected to step II, in which the above chromatography system is used again. With each azo pigment mixture this step brings about the separation of a non-polar and a polar azo pigment fraction (azo 1A and azo 1B, azo 2A and azo 2B, and azo 3A and azo 3B from bilirubin fractions 1, 2 and 3 respectively). Approximately equal amounts of non-polar and polar pigments are obtained from bilirubin fractions 1 and 2, whereas bilirubin fraction 3 yields azo 3B almost exclusively. In step IIIA the non-polar azo pigment fractions are fractionated further by adsorption chromatography on anhydrous sodium sulphate with the use of chloroform followed by a gradient of ethyl acetate in chloroform. Three azo pigments are thus obtained from both azo 2A (azo 2A(1), azo 2A(2) and azo 2A(3)) and azo 3A (azo 3A(1), azo 3A(2) and azo 3A(3)). The 2A pigments occur in approximately the following proportions: azo 2A(1), 90%; azo 2A(2), 10%; azo 2A(3), traces. The pigments are purified by crystallization, except for the A(3) pigments, which are probably degradation products arising from the corresponding A(2) pigments. In step IIIB the polar azo pigment fractions are subjected to reverse-phase partition chromatography on silicone-treated Celite with the use of a solvent system prepared from octan-1-ol-di-isopropyl ether-ethyl acetate-methanol-0.2m-acetic acid (1:2:2:3:4, by vol.). Azo pigment fractions 2B and 3B each yield six azo pigments (azo 2B(1) to azo 2B(6) and azo 3B(1) to azo 3B(6) respectively) together with small amounts of products of hydrolysis (azo 2A(B) and azo 3A(B)). Only one azo B pigment is obtained from bilirubin fraction 1, and this azo pigment is probably of the B(2) type. The yields of the azo 3B pigments suggest that these pigments are present in approximately the following proportions: azo 3B(1), 0-0.4%; azo 3B(2), traces; azo 3B(3), traces; azo 3B(4), 10%; azo 3B(5), 50%; azo 3B(6), 40%. Azo pigments 2B(1) to 2B(6) are estimated to occur in similar proportions. Since pairs of correspondingly numbered azo pigments from bilirubin fractions 1, 2 and 3 do not separate on rechromatography together (e.g. azo 2A(1) co-chromatographs with azo 3A(1), and azo 2B(6) co-chromatographs with azo 3B(6)), it is concluded that such pigments are chemically identical. The structures of the isolated phenylazo derivatives are discussed in an accompanying paper (Kuenzle 1970c).