Association of deoxycholic acid in organic solvents

Hyperlayer hollow-fiber flow field-flow fractionation of cells

Interest in low-cost, analytical-scale, highly efficient and sensitive separation methods for cells, among which bacteria, is increasing. Particle separation in hollow-fiber flow field-flow fractionation (HF FlFFF) has been recently improved by the optimization of the HF FIFFF channel design. The intrinsic simplicity and low cost of this HF FlFFF channel allows for its disposable usage. which is particularly appealing for analytical bio-applications. Here, for the first time, we present a feasibility study on high-performance, hyperlayer HF FIFFF of micrometer-sized bacteria (Escherichia coli) and of different types of cells (human red blood cells, wine-making yeast from Saccharomyces cerevisiae). Fractionation performance is shown to be at least comparable to that obtained with conventional, flat-channel hyperlayer FIFFF of cells, at superior size-based selectivity and reduced analysis time.

Effect of nuclear hydroxy substituents on aqueous solubility and acidic strength of bile acids

The aqueous solubility and thermodynamic dissociation constants of a representative series of bile acids with varying numbers and configuration of nuclear hydroxyl substituents were determined. The pKa values were calculated by extrapolating pKa' values determined in solutions of aqueous methanol of different mole fractions at 25 degrees C. All bile acids had the same acidic strength in water, indicating that the pattern of hydroxyl nuclear substituents does not affect the acidic strength probably because of the distance between the hydroxyl and ionizing groups. In contrast, aqueous solubility was dependent on the number, position and orientation of the hydroxyl groups. The solubility values ranged from 5 X 10(-8) M (0.05 microM) for 3 alpha-hydroxy-5 beta-cholanoic acid (lithocholic acid) to 1.67 X 10(-3) M (1,670 microM) for 3 alpha,7 beta,12 alpha-trihydroxy-5 beta-cholanoic acid (ursocholic acid). The hydroxy groups notably affect solubility by forming hydrogen bonds with water but also by reducing, according to their orientation, hydrophobicity of the steroid nucleus.

Analysis of self-associations from partition isotherms

Self-associations can be studied from the measurements of the partition of the self-associating solute between two immiscible liquids. The apparent partition coefficient, Kapp, is proportional to the ratio of the apparent weight fraction of monomer, fa, in each phase. If one assumes that the Adams-Fujita convention for the activity coefficients of the self-associating species applies, then fa is related to Mna and Mwa, the apparent values of the number and weight average molecular weights, respectively; and one can use previously developed methods to analyze the self-association. In order to use the method, one must make an independent study at the same temperature of one of the phases by an appropriate thermodynamic method, such as vapor pressure osmometry or sedimentation equilibrium. Then one can test the other phase for the type of self-association present and evaluate the equilibrium constant or constants (ki) and the nonideal term (BM1) from the partition data. One can also evaluate the partition coefficient (Kpar). From these measurements, one can obtain the free energy (delta G0) for the association in each phase and for the transfer between phases. Temperature-dependence studies will provide the enthalpy (delta H0) or entropy (delta S0) of self-association or transfer. This method should be quite useful for studying small molecules of biological importance.