Lan Zhao

Pore size analysis from low field NMR spin–spin relaxation measurements of porous microspheres

Abstract The porous structure characteristics of twenty-one porous microspheres with agarose framework were investigated based on the low-field nuclear magnetic resonance (LF NMR) relaxation time (T2) distribution measurements. The feasibility of the technique was confirmed by direct relationship between T2 and the mean pore size of the polymer networks (Rh) of agarose hydrogel which was established using the “Fiber-Cell” model. The expected pore radius distribution curve was obtained and the reliability was validated by comparing them with the results obtained by inverse size-exclusion chromatography. Thereafter, the technique was applied to characterize the pore size distribution (PSD) of soft microspheres and the pore size transformation of microspheres with or without grafted polymers in the process of protein adsorption. All of these results strongly support LF NMR as a promising, rapid and nondestructive technique for the determination of PSDs in many kinds of soft porous microspheres.

Efficient fabrication of high‐capacity immobilized metal ion affinity chromatographic media: The role of the dextran‐grafting process and its manipulation

Novel high-capacity Ni(2+) immobilized metal ion affinity chromatographic media were prepared through the dextran-grafting process. Dextran was grafted to an allyl-activated agarose-based matrix followed by functionalization for the immobilized metal ion affinity chromatographic media. With elaborate regulation of the allylation degree, dextran was completely or partly grafted to agarose microspheres, namely, completely dextran-grafted agarose microspheres and partly dextran-grafted ones, respectively. Confocal laser scanning microscope results demonstrated that a good adjustment of dextran-grafting degree was achieved, and dextran was distributed uniformly in whole completely dextran-grafted microspheres, while just distributed around the outside of the partly dextran-grafted ones. Flow hydrodynamic properties were improved greatly after the dextran-grafting process, and the flow velocity increased by about 30% compared with that of a commercial chromatographic medium (Ni Sepharose FF). A significant improvement of protein binding performance was also achieved by the dextran-grafting process, and partly dextran-grafted Ni(2+) chelating medium had a maximum binding capacity for His-tagged lactate dehydrogenase about 2.5 times higher than that of Ni Sepharose FF. The results indicated that this novel chromatographic medium is promising for applications in high-efficiency and large-scale protein purification.

Deliberate manipulation of the surface hydrophobicity of an adsorbent for an efficient purification of a giant molecule with multiple subunits.

Hydrophobic interaction chromatography (HIC) is often an inevitable step for a satisfying purification in giant vaccine molecules production. But great mass and activity loss associated with poor purity often occur simultaneously. In this paper, high purity and high bioactivity recovery for the HIC process of hepatitis B surface antigen (rHBsAg) purification were achieved through manipulation of surface hydrophobicity of the adsorbent. Spacer arm length and ligand density were regulated, respectively, through which the interaction between the vaccine and the adsorbent was manipulated deliberately. It was found even in a narrow scope, varying spacer arm length and ligand density resulted in purification factor changing from 1 to 96.5, and rHBsAg recovery from 3 to 91%. The optimal purification performance was achieved when the spacer arm was C8 and the ligand density was 9.2 μmol/g suction-dried wet gel with an average distance of ligands of 3.6 nm. This deliberate regulation strategy represents a new approach of improving purification of giant multi-subunit proteins.

Determination of leakage from antibody adsorbent: composition analysis and pH effect

To study the leakage at different solution pH values, IgG Sepharose 6FF®, a commercially available immunoadsorbent, was used as a model. The leaked substance consists of three parts: (1) ligands and its fragments; (2) ligands plus matrix fragments in which ligands are chemically attached to the adsorbent matrix; and (3) matrix fragments. Buffer solution pH values had a great effect on both the kinetics and the amount of ligand leakage. Cross-linking of the adsorbent matrix could reduce both matrix leakage and antibody leakage at pH 3.0, but its effect was limited at pH 11.0 for ligand leakage.

Functional hydrophilic polystyrene beads with uniformly size and high cross-linking degree facilitated rapid separation of exenatide

A high cross-linking polystyrene(PSt)-based anion-exchange material with uniformly size, high ion exchange capacity, and high hydrophilicity was synthesized by a novel surface functionalization approach in this study. Uniformly sized PSt microspheres were prepared by the membrane emulsion polymerization strategy, and then modified by (1) conversing resid ual surface vinyl groups to epoxy groups followed by quaternization, and (2) decorating aromatic ring matrix including nitration, reduction and attachment of glycidyltrimethylammonium chloride. The 3-D morphology and porous features of microspheres were observed by scanning electron microscopy (SEM) and atomic force microscopy (AFM). The surface of the modified PSt became roughness but the particle size remained same. Meanwhile, FT-IR spectra and laser scanning confocal microscope (LCSM) indicated that the modification groups had been successfully covalently coated onto the PSt microspheres. Modified PSt microspheres showed greatly improved hydrophilicity and biocompatibility with 0.387mmol/mL ion exchange capacity (IEC). In the application evaluation procedure, exenatide can be purified from 42.9% (peptide crudes) to 88.6% by modified PSt column with 97.1% recovery yield. This modified PSt microspheres had a large potential in application for efficient separation of peptides.

A novel rProtein A chromatographic media for enhancing cleaning-in-place performance

Protein A chromatography has been a popular method for purification of therapeutic monoclonal antibodies (mAb). Protein A chromatographic media using alkali-resistant rProtein A ligands from site-directed coupling method have been pursued for both high dynamic capacities and excellent stabilities. However, the mechanism of rProtein A leaking under cleaning-in-place (CIP) conditions is not very clear and difficulties have been commonly encountered when improving the medias chromatographic performance. We investigated the chromatographic performance of site-directed coupled rProtein A chromatographic media during CIP procedure. Trace amount of ligands leaked during the chromatographic medias incubation in 0.5 M NaOH was detected, explaining for the decline of chromatographic medias CIP performance. Decrease of rProtein As concentration in 0.5 M NaOH was consistent with chromatographic medias binding capacity. A novel rProtein A chromatographic media were prepared by site-directed coupling a newly-constructed alkali-resistant rProtein A to highly cross-linked agarose-based matrix. The media had a dynamic binding capacity of 63.2 mg hIgG/mL higher than 48.1 mg hIgG/mL of the commercial one, and the CIP performance was improved greatly with the remained dynamic binding capacity increased from 86% to 95% of the initial value after 40 CIP cycles.

Microscopic insight into role of protein flexibility during ion exchange chromatography by nuclear magnetic resonance and quartz crystal microbalance approaches.

Driven by the prevalent use of ion exchange chromatography (IEC) for polishing therapeutic proteins, many rules have been formulated to summarize the different dependencies between chromatographic data and various operational parameters of interest based on statically determined interactions. However, the effects of the unfolding of protein structures and conformational stability are not as well understood. This study focuses on how the flexibility of proteins perturbs retention behavior at the molecular scale using microscopic characterization approaches, including hydrogen-deuterium (H/D) exchange detected by NMR and a quartz crystal microbalance (QCM). The results showed that a series of chromatographic retention parameters depended significantly on the adiabatic compressibility and structural flexibility of the protein. That is, softer proteins with higher flexibility tended to have longer retention times and stronger affinities on SP Sepharose adsorbents. Tracing the underlying molecular mechanism using NMR and QCM indicated that an easily unfolded flexible protein with a more compact adsorption layer might contribute to the longer retention time on adsorbents. The use of NMR and QCM provided a previously unreported approach for elucidating the effect of protein structural flexibility on binding in IEC systems.