Quantitative structure-antimicrobial activity relationship in 5 beta-cholanyl-24-benzylamine derivatives.

Some representative physicochemical properties of benzylamido and amino derivatives of common bile acids have been determined and correlated with their antimicrobial activity against gram-positive bacterial strains. Steroid hydroxyls do not affect the basicity of amino derivatives; they promote solubility in a parallel way to unconjugated bile acids and mainly control hydrophobicity of this class of compounds as measured by log P values. Activity was correlated to hydrophobicity; that is, the nature of the side chain modulated activity, affected basicity, and facilitated changes in partition ability. Benzylamino derivatives proved to be even more active than the corresponding amides when ionization is taken into account. Trihydroxy derivatives possess the lowest log P values and were practically inactive. Decreased activity was also observed in those cases where, due to the orientation of the hydroxy group in the 6 or 7 position, the back beta face of the molecule had a reduced hydrophobic surface area. Antimicrobial activity, in terms of -log MIC (minimal inhibitory concentration), was found to correlate linearly with log P values of uncharged species. This linear relationship is discussed with respect to the structure of the steroid moiety and the ability of these molecules to cross cellular membranes.

Synthesis of 6-hydroxylated bile acids and identification of 3 alpha,6 alpha,7 alpha,12 alpha-tetrahydroxy-5 beta-cholan-24-oic acid in human meconium and neonatal urine.

Three 6-hydroxylated bile acids, 3 alpha,6 alpha,7 alpha,12 alpha-, 3 alpha,6 beta,7 alpha,12 alpha- and 3 alpha,6 beta,7 beta,12 alpha-tetrahydroxy-5 beta-cholan-24-oic acids, were synthesized from methyl cholate, and a sensitive method was developed for analyzing them by gas chromatography-mass spectrometry for the stoichiometric study of fetal bile acids. 3 alpha,6 alpha,7 alpha,12 alpha-Tetrahydroxy-5 beta-cholan-24-oic acid (6 alpha-hydroxylated cholic acid) was identified from human meconium and healthy neonatal urine by comparison with the mass spectrum of the reference compound. In human meconium, 6 alpha-hydroxylated cholic and chenodeoxycholic acids were determined in 1.2% and 29.0% of the total bile acids, respectively. We discuss the significance of hydroxylation at the C-1 beta and C-6 alpha positions of bile acids and their elimination in fetal and neonatal periods.

[Evaluation of liver function in chronic liver diseases using the bile acid spectrum]. / Die Beurteilung der Leberfunktion bei chronischen Hepatopathien mit Hilfe des Gallensäurenspektrums.

In 24 persons with healthy liver and 44 patients with without exception morphologically ascertained chronic hepatopathies of different degree of severity the diagnostic valency of the bile acids was tested. In these cases the bile acids estimated in the C-bile proved as sensitive indicators of a chronic lesion of the liver parenchyma. Quantitative deviations of the bile acids, the relation from tri- to dihydroxycholan acids, qualitative alterations in the spectre of the free bile acids as well as changes of the form of conjugation were of importance concerning the functional diagnosis. The concentration of bile acids decreased the more expressed was the chronic lesion of the liver parenchyma. Trihydroxycholan acids and dihydroxycholan acids variably participated in the reduction of the bile acids in different forms of chronic hepatopathies. From the change of the quotient tri- to dihydroxycholan acids causal connections between the degree of severity of the chronic hepatopathy and the dominance of the chenodesoxycholic acid could be derived. Moreover, the conjugation of the bile acids with glycine prevailing in chronic hepatopathies underwent a degradated change. From the examinations results that quantitative and qualitative deviations of the bile acid spectre under defined morphological prerequisites render possible a differentiated judgment of the liver function in chronic hepatopathies.

Nuclear magnetic resonance spectroscopy of bile acids. Development of two-dimensional NMR methods for the elucidation of proton resonance assignments for five common hydroxylated bile acids, and their parent bile acid, 5 beta-cholanoic acid.

The complete 1H nuclear magnetic resonance assignments have been made for the common mono-, di-, and trihydroxy 5 beta-cholanoic acids; lithocholic acid, chenodeoxycholic acid, ursodeoxycholic acid, deoxycholic acid, cholic acid, and the unsubstituted parent compound, 5 beta-cholanoic acid, by heteronuclear-correlated two-dimensional NMR. The known 13C chemical shifts of these compounds were used to make the proton resonance assignments, and consistency of the carbon and proton assignments was verified by expected changes due to substituent effects. This has led to clarification of previously published 13C NMR resonance assignments. Addition of the 3 alpha, 7 alpha, and 12 alpha hydroxyl substituent effects derived from the mono- and dihydroxycholanoic acids yielded predicted values for proton chemical shifts of the trihydroxy-substituted 5 beta-cholanoic acid, cholic acid, that agreed well with experimental values. It is suggested that the individual substituent effects can be used to predict proton chemical shifts for hydroxycholanic acids containing other combinations of 3 alpha, 7 alpha, 7 beta, and 12 alpha hydroxyl groups.