Solubilization of cholesterol and polycyclic aromatic compounds into sodium bile salt micelles (part 2)

The aqueous solubility of cholesterol was determined over the temperature range from 288.2 to 318.2 K with intervals of 5 K by the enzymatic method. The solubility was (3.7+/-0.3)x10(-8) mol dm(-3) (average +/- S.D.) at 308.2 K. The maximum additive concentrations of cholesterol into the aqueous micellar solutions of sodium deoxycholate (NaDC), sodium ursodeoxycholate (NaUDC), and sodium cholate (NaC) were spectrophotometrically determined at different temperatures. The cholesterol solubility increased in the order of NaUDC相似文献   

Interaction of fatty acid sodium salts with sodium deoxycholate

Interaction of homologous fatty acids (C3-C18) with sodium deoxycholate was investigated. From NMR and ultrasonic results it was found that short chain homologues (up to C9) do not participate in the formation of mixed micelles with sodium deoxycholate. Fatty acid homologues with longer chains (starting with C9) form mixed micelles by "burying" hydrophobic chains in hydrophobic environment of a sodium deoxycholate micelle.     

Group separation of bile acids and salts by silicic acid column chromatography

Group separations of unconjugated and conjugated bile acids and salts were performed using mixtures of conventional solvents by chromatography on columns of silicic acid. The results suggest that this method is useful for group separations of mono-, di-, and trihydroxycholan-24-oic acids and their conjugates with good recoveries. This method is advantageous for synthesis work, especially for the purification of conjugated and sulfated bile acids and salts, and is applicable for the group separation of glycine and taurine conjugates. The application of this method to human gallbladder bile salts is demonstrated.     

Purification and characterization of a protein capable of binding to fatty acids and bile salts in Giardia lamblia

A specific fatty acid binding protein was isolated from Giardia lamblia, using an affinity column with butyric acid acting as a ligand in place of stearic acid. This method has proved to be more efficient than the one previously described using stearic acid as ligand. The purified fraction showed 8 electrophoretic bands of proteins, with molecular weights ranging between 8 and 80 kDa. This pattern is a consequence of the aggregation of a protein with a molecular weight of 8,215 Da, corresponding to the lower molecular weight band, the only one capable of binding to fatty acids. The labeled oleic acid bound to these purified proteins was replaced by a 100-fold greater concentration of taurocholate, glycocholate, deoxycholate, palmitic acid, and arachidonic acid, having a greater displacement of the bile salts than the free fatty acids.