Stephan Harnisch scite author profile

The two-dimensional polyacrylamide electrophoresis (2-D PAGE) of the plasma protein adsorption pattern previously established for polymeric nanoparticles was modified and transferred to oil in water emulsions for intravenous administration. The emulsions were incubated with citrated plasma, and separation from excess plasma was performed by centrifugation under optimized conditions: 15000 g and three washing steps with 0.05 M phosphate buffer, pH 7.4. With this sample preparation, coalescence of droplets could be avoided and an unchanged surface area maintained, in addition the phosphate buffer minimized artificial IgG adsorption. Critical factors affecting sensitivity were contamination of the sample by oil residues and the use of thiourea in the immobilized pH gradients. Changes in the protein adsorption pattern caused by altered surface properties of the emulsion (i.e. adsorbed Poloxamer 407) were detectable when applying the optimized protocol. Knowledge of the protein adsorption patterns and their correlation to in vivo behavior opens the perspective for the development of intravenous emulsions for controlled drug delivery.

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Identification of plasma proteins facilitated by enrichment on particulate surfaces: Analysis by two‐dimensional electrophoresis and N‐terminal microsequencing

Lück

Schröder

Harnisch

et al. 1997

Electrophoresis

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Plasma protein adsorption on intravenously injectable drug carriers is regarded as an important factor for the fate of the particles in the body after their administration. Therefore, the plasma protein adsorption patterns on a number of different carrier systems were analyzed in vitro employing two-dimensional electrophoresis (2-DE). The particulate systems presented in this study were polystyrene (PS) model particles, PS nanoparticles surface-modified by adsorption of a surfactant, a commercial fat emulsion, and magnetic iron oxide particles used as contrast agents in magnetic resonance imaging. Most of the spots in the plasma protein adsorption patterns could be identified by matching the resulting 2-DE gels with a reference map of human plasma proteins. Several other proteins that indicated preferentially adsorbed proteins on the surface of the particles investigated have either not been identified on the reference map, or their identity was found to be ambiguous. The relevant proteins are all present in plasma in low abundance. Since these proteins were strongly enriched on the surface of the particles, the resulting spots on the 2-DE gels were successfully identified by N-terminal microsequencing. With this approach, two chains of spots, designated PLS:6 and PLS:8, were determined on a plasma reference map: inter-alpha-trypsin inhibitor family heavy chain-related protein (also named PK-120) and a dimer of fibrinogen gamma, respectively. Plasma gelsolin is presented in a 2-DE adsorption pattern of PS model particles. One of the main proteins adsorbed by droplets of a commercial fat emulsion was identified as apoliprotein H. Moreover, the positions of apolipoproteins apoC-II and apoC-III were also verified on the 2-DE protein map of human plasma. Thus, protein adsorption experiments of the kind presented in this study are increasing our insight into human plasma proteins.

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Stephan Harnisch

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Identification of plasma proteins facilitated by enrichment on particulate surfaces: Analysis by two‐dimensional electrophoresis and N‐terminal microsequencing

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