Synthesis and chromatographic characterization of dextran-coated zirconia high-performance liquid chromatographic stationary phases

Role of the excess monomer in the growth of urea and formaldehyde resin deposit particles

The role of excess monomer (i.e., Urea (U) or Formaldehyde (F)) in UF precipitation reaction was investigated at 28°C. The maximum output of the UF resin deposit was found around the U:F molar ratio 1.0:1.0 and this output decreased if excessive urea (or formaldehyde) was used in the reaction system. The excess monomer was considered to decrease the polymerization degree of UF resin deposit and increased the bonding saturation of its copolymerization monomer as well as the solubility of the UF resin deposit. The Influence of the excess monomer on the lamellar crystallinity of the resultant deposit, involving the polymerization degree and bonding saturation of the monomer, was examined. Three different dynamic regions containing excess monomers were revealed according to the behaviors of the deposit nucleation. The density and water absorption of the UF resin particles were finally demonstrated relative to the dynamic regions in their nucleation reactions.

Controlled release from modified amino acid hydrogels governed by molecular size or network dynamics

Hydrogels can be prepared using the commercially available Fmoc-phenylalanine or Fmoc-tyrosine as the gelator. Gelation is triggered by careful adjustment of the pH of the solution using glucono-delta-lactone (GdL). Model dyes have been entrapped in the hydrogels, and the release of the dyes from the hydrogels has been monitored. The release ratios indicate that the systems are under Fickian diffusion control. A range of dyes with different radii of gyration diffuse from the Fmoc-phenylalanine hydrogels with similar diffusion coefficients, implying that the network is not specifically retaining even relatively large (5 nm) dyes. On the other hand, the larger dyes are restricted in their diffusion from Fmoc-tyrosine hydrogels. These results correlate with the rheological measurements for the hydrogels, where those formed from Fmoc-tyrosine were shown to have significantly higher storage moduli than those formed from Fmoc-phenylalanine. In addition, the frequency-dependent behavior of the hydrogels demonstrates that Fmoc-tyrosine shows the classic response of a strong gel with a storage modulus that is nearly independent of frequency. However, for Fmoc-phenylalanine, the frequency dependence of moduli is very strong and very similar to that displayed by a transient network, where the interconnections between junction zones in the network are highly flexible and able to withstand large deformations.

Layer-by-Layer Self-Assembly of Multilayer Zirconia Nanoparticles on Silica Spheres for HPLC Packings

A novel zirconia-based HPLC packing material, ZrO2/SiO2, which consists of micrometer-sized silica spheres as core and nanometer-sized zirconia particles as surface coating, was prepared by a layer-by-layer self-assembly technique. The material exhibits favorable characteristics for HPLC applications, including high surface area and pore volume, good pore structure, narrow particle size, and pore size distribution. Not only the support ZrO2/SiO2 but also the stationary-phase C18 bonded ZrO2/SiO2 exhibits excellent chemical stability. In addition, good permeability was observed for both of them. High specific area surface and good permeability of ZrO2/SiO2 permit a high loading amount of chiral polymer on it and greatly improved the enantioselectivity and resolution for some chiral separations.

Dependence of thermal mismatch broadening on column diameter in high-speed liquid chromatography at elevated temperatures

In this paper, we compare a narrow-bore column (2.1-mm i.d.) to a conventional-bore column (4.6 mm i.d.) at elevated temperatures under conditions where thermal mismatch broadening is serious and show that narrow-bore columns offer significant advantages in terms of efficiency and peak shape at higher linear velocities. We conclude that the so-called thermal mismatch broadening effect is largely due to a radial retention factor gradient and not a radial viscosity gradient. The lower volumetric flow rates inherent with the use of narrower columns lead to lower linear velocity in the heater tubing and longer eluent residence times in the heater. Thus, with the same heater tubing at the same column linear velocity, narrow-bore columns give better thermal equilibration between the eluent and the column compared to wider bore columns. This means that high-temperature, ultrafast liquid chromatography no longer requires excessively long preheater tubing to thermally equilibrate the eluent to the column temperature. Consequently, the use of narrow-bore columns at high-temperature improves analysis speed and efficiency over wider bore columns. We also discuss the advantages of using liquid heat-transfer media as compared to air as the heat-transfer media. We show that an air bath ought not be used to heat the mobile phase because at high temperature (>80 degrees C) and high column linear velocity (> 1.5 cm/s) the length of tubing needed to heat the mobile phase to column temperature is prohibitively long. Using accurate, empirical heat-transfer correlations, we estimated the length of tubing needed to heat the eluent as a function of the column linear velocity for both air and liquid heat-transfer media.

Comparative Pore Structure Analysis of Dextran-Coated Polystyrene Particles

Porous poly(styrene-divinylbenzene) (PS-DVB) particles were modified by adsorption of hydrophobically-modified dextrans, to provide chromatographic matrices for biomolecule chromatography. The dextran distribution and the pore characteristics of various coated PS-DVB beads were examined using nitrogen adsorption-desorption, mercury intrusion, and size exclusion chromatography. It was found that the adsorption of dextran does not result in homogeneous layers but rather in inhomogeneous ones. At high dextran loading and high content of hydrophobic groups in the adsorbed polymer, most of the pores of the macroporous rigid material are filled with a soft and porous dextran network being stabilized by hydrophobic interactions. According to chromatographic experiments, most of the surface was nevertheless expected to be covered at least by a thin and dense protecting layer since proteins-even those that are small enough to penetrate the dextran network-cannot interact nonspecifically with the internal pore surface. At low content of hydrophobic groups, dextran deposits preferentially as a thicker and more diffuse layer. However, the thickness of the coating is expected to be irregular and probably contributes to an increase in the roughness of the polystyrene surface. Copyright 1999 Academic Press.

Purification of monoclonal antibodies from cell culture supernatants using a modified zirconia based cation-exchange support

A method suitable for the isolation of monoclonal antibodies (Mabs) is described. The protocol utilizes a zirconia based column modified with ethylenediamine-N,N'-tetra(methylenephosphonic) acid to create a novel cation-exchange chromatographic support. Initial experiments using a linear salt gradient demonstrate the ability of this support to efficiently separate Mab from transferrin and bovine serum albumin in a model matrix. Results of the purification of Mab from an actual cell culture supernatant over a range in protein concentrations are also shown. Analyses by enzyme-linked immunosorbent assay and gel electrophoresis demonstrate that Mabs can be recovered from a cell culture supernatant at high yield (92-98%) and high purity (> 95%) in a single chromatographic step.

Chromatographic characterization of phosphonate analog EDTA-modified zirconia support for biochromatographic applications

Zirconium dioxide (zirconia) has a great affinity for inorganic and organic phosphate. Previous work from this laboratory demonstrated the utility of phosphate-modified microparticulate zirconia as a support for protein separations. We have extended this investigation to include the study of ethylenediamine-N,N'-tetramethylphosphonic acid (EDTPA), a phosphonate analog of EDTA, as a surface modifier for zirconia. Our work explores the use of EDTPA-modified zirconia (PEZ) for its potential use as a high-performance inorganic cation-exchange support for the separation of proteins. The phosphate groups in EDTPA very effectively block the sites responsible for strong interactions of hard Lewis bases with zirconia's surface. Modification of zirconia with EDTPA provides a "biocompatible" stationary phase, resulting in high mass recoveries of proteins. We compare PEZ with inorganic phosphate-modified zirconia to show increased efficiency, as well as unique selectivities for chromatography of proteins on the chelator-modified surface. Finally, the selectivity, efficiency, and separation mechanism are reported. The studies show that PEZ is a useful high-performance ion-exchange support for the separation of cationic proteins and for modulating the sites responsible for the high affinity of zirconia toward certain classes of anions.