Neue Synthesestrategie zu alpha- und alpha,omega-substituierten Oligo- und Polythiophenen und deren Selbstorganisation

Ellinger, Stefan,

January 2006

Ulm, Univ. Diss., 2006.

Der Einfluss von BAY h 5800 und Bendigon auf die Aggregation der Thrombozyten und die Viskosität des Blutes bei Patienten mit obliterierenden Gefässerkrankungen

Kisslinger, Johann,

January 1979

Thesis (doctoral)--Ludwig Maximilians-Universität zu München, 1979.

Anticoagulants Platelet Aggregation

Nonnative aggregation of alpha-chymotrypsinogen A and related systems

Weiss, William F.

January 2010

Thesis (Ph.D.)--University of Delaware, 2009. / Principal faculty advisors: Christopher J. Roberts and Abraham M. Lenhoff, Dept. of Chemical Engineering. Includes bibliographical references.

Aggregation (Chemistry) Trypsinogen.

Risk Based Capital in Finanzunternehmen Aggregation und Diversifikation /

Buehler, Moreno.

January 2006

Master-Arbeit Univ. St. Gallen, 2006.

Tbx16 and Wnt11 coordinately regulate prechordal plate morphogenesis /

Muyskens, Jonathan B.,

January 2005

Thesis (Ph. D.)--University of Oregon, 2005. / Typescript. Includes vita and abstract. Includes bibliographical references (leaves 55-58). Also available for download via the World Wide Web; free to University of Oregon users.

Morphogenesis. Cells Cell aggregation.

The effects of non-DLVO forces in colloidal aggregation /

Huang, Alvin Y.

January 2005

Thesis (Ph. D.)--University of Washington, 2005. / Vita. Includes bibliographical references (p. 99-104).

Colloids. Aggregation (Chemistry)

Phase behaviour and interfacial properties of double-chain anionic surfactants

Nave, Sandrine

January 2001

No description available.

541

Adsorption ; Aggregation

A study of folded, denatured and aggregated states during the refolding of inclusion body proteins

Gilburt, James

January 2016

The need to high quality therapeutic proteins has grown significantly in the past 30 years. Recombinant proteins are often produced from vectors inserted into E. coli cell lines for large scale production. However, over-expression of the protein within the cell can lead to the formation of large, insoluble aggregates known as inclusion bodies. Native monomer protein can be isolated from inclusion bodies through a refolding process. This entails disruption of the aggregate structure with high concentrations of denaturant and renaturation in native-promoting solution. Our work characterises protein-protein interactions and aggregation between partially unfolded proteins during the refolding process. The protein-protein interactions are characterized in terms of the osmotic second virial coefficient (B22). A positive value indicates repulsive interactions while a negative value indicates attractive interactions. Measurements are carried out for lysozyme, ribonuclease A and preproinsulin as a function of pH, ionic strength and denaturant concentration, alongside a range of known refolding excipients. Past studies (Ho and Middelberg, 2004; Ho et al., 2003) have shown a link between higher B22 values in denaturant solutions and reduced aggregation during refolding. Our experiments have focused on the effects of urea and GdmHCl upon protein-protein interactions, alongside how ionic strength and refolding additives influence interactions between partially-folded states. At low ionic strength, solutions of urea increase net repulsive interactions compared to GdmHCl solutions through an attenuation of short-range attractive interactions. Electrostatic repulsive interactions are screened in solutions of GdmHCl due to the increased ionic strength of the solution; however short-range attractive interactions are also attenuated in a similar fashion to urea solutions. Protein-protein interactions in low and high concentration denaturant solutions have been shown to be highly sensitive to ionic strength and refolding experiments have shown that this correlates with increased aggregation during refolding. The solubilising additive Arg HCl has been shown to reduce short-range attraction between proteins in urea solutions, while the folding-promotor additives sucrose and hexylene glycol have been shown to have a more complex effect on protein-protein interactions in urea solutions dependent on denaturant concentration. Within the wider context of the field of protein aggregation and refolding, the work conducted here will contribute towards the understanding of how denaturants and solutes influence attractive protein-protein interactions and aggregation behaviour between unfolded or partially folded proteins.

572

Protein refolding ; Aggregation

Electrostatic Modeling of Protein Aggregation

Vanam, Ram

12 1900

Submitted to the faculty of Indiana University in partial fulfillment of the requirements for the degree Master of Science in the Department of Bioinformatics in the School of Informatics of, Indiana University December, 2004 / Electrostatic modeling was done with Delphi of insight II to explain and predict protein aggregation, measured here for β-lactoglobulin and insulin using turbidimetry and stopped flow spectrophotometry. The initial rate of aggregation of β-Lactoglobulin was studied between pH 3.8 and 5.2 in 4.5mM NaCl; and for ionic strengths from 4.5 to 500mM NaCl at pH 5.0. The initial slope of the turbidity vs. time curve was used to define the initial rate of aggregation. The highest initial rate was observed near pH < pI i.e., 4.6 (< 5.2). The decrease in aggregation rate when the pH was increased from 4.8 to 5.0 was large compared to its decrease when the pH was reduced from 4.4 to 4.2; i.e., the dependence of initial rate on pH was highly asymmetric. The initial rate of aggregation at pH 5.0 increased linearly with the reciprocal of ionic strength in the range I = 0.5 to 0.0045M. Protein electrostatic potential distributions are used to understand the pH and ionic strength dependence of the initial rate of aggregation. Similar studies were done with insulin. In contrast to BLG, the highest initial aggregation rate for insulin was observed at pH = pI. Electrostatic computer modeling shows that these differences arise from the distinctly different surface charge distributions of insulin and BLG.

electrostatic modeling

protein aggregation

A cluster model satisfying limited charge exchange /

Armbrust, Wayne Thomas

January 1975

No description available.

Physics

Aggregation

Cluster analysis