Tannic acid-based sustained-release system for protein drugs.

In recent years, protein drug development has gained momentum, and simple and facile controlled-release systems without loss of activity are required. Herein, we developed a sustained-release system for protein drugs by exploiting the "astringency" mechanism, namely insoluble precipitate formation by interacting with tannic acid. Tannic acid formed insoluble precipitates with various protein drugs, such as nisin, insulin, lysozyme, ovalbumin, hyaluronidase, and human immunoglobulin G, through hydrophobic interactions and hydrogen bonds. The lysozyme/tannic acid complex retained in vitro lytic activity. Precipitates of the insulin/tannic acid complex prolonged hypoglycemic effects without loss of activity after subcutaneous administration. The ovalbumin/tannic acid complex enhanced anti-ovalbumin antibody production induced by ovalbumin, which may be attributed to its sustained-release profile. Accordingly, tannic acid is useful as a simple and user-friendly drug delivery system for protein drugs.

Polyrotaxane-Based Supramolecular Material for Improvement of Pharmaceutical Properties of Protein Drugs.

Pharmaceutical excipients, such as surfactants, amino acids, and polymers, have often been used to improve the physicochemical properties of protein drugs. However, the effects of these additives are limited because of factors such as their weak interactions with protein drugs. In the present study, we evaluated the application of a supramolecular polymer, aminated polyrotaxane (NH2-PRX), which can strongly interact with protein drugs via its dynamic and transformable properties, as a new pharmaceutical excipient for these agents. As a conventional control polymer with low mobility and average complexation ability, aminated dextran (NH2-DEX) was also prepared. NH2-PRX significantly reduced the aggregation of antibodies induced by shaking, compared with NH2-DEX. The adsorption of insulin onto glass and polypropylene containers was also reduced by the addition of NH2-PRX. In addition, the in vivo bioactivity of insulin was completely retained in the presence of NH2-PRX. Moreover, severe adverse effects were not observed following the administration of NH2-PRX. These findings indicate the potential use of NH2-PRX as a transformable pharmaceutical excipient for protein drugs.

Supramolecular polymer-based transformable material for reversible PEGylation of protein drugs.

We herein developed a transformable mixing-type material for reversible PEGylation of protein drugs using a supramolecular backbone polymer, that is, polyrotaxane possessing both amino groups and PEG chains (PEG-NH2-PRX). We expected that PEG-NH2-PRX provides amino groups to interact with protein drugs on demand because the mobility of amino groups in PEG-NH2-PRX was high. In fact, PEG-NH2-PRX formed complexes with protein drugs efficiently compared to PEGylated amino-dextran (PEG-NH2-DEX), a control material fabricated with a macromolecular backbone polymer. Moreover, PEG-NH2-PRX markedly improved the stability of antibodies and prolonged the hypoglycemic effects of insulin without loss of bioactivity, compared to PEG-NH2-DEX. These findings suggest that the supramolecular material, PEG-NH2-PRX, is a promising reversible PEGylation material for protein drugs compared to macromolecular materials.