Pharmacological Effects of Polymer Therapeutics

Published on 25/01/2017

Small drug molecules and also large biomolecules like proteins or antibodies suffer rapid clearance from human body.

1. Basics and Principles of Polymer Therapeutics

1.1 Pharmacological Effects

Small drug molecules and also large biomolecules like proteins or antibodies suffer rapid clearance from human body. The concentration of the drug compound drops rapidly as it is removed from the body. Treatment has to be repeated in order to keep the concentration over the therapeutic threshold. Otherwise immunogenic reactions start. There are two major reasons why polymer therapeutics improves drug delivery and pharmacokinetics: Polymerdrug conjugates show suppressed renal clearance and reduced immunogenic reactions. The concentration is being reduced very slowly over the time of treatment. In the ideal case, only a single application is required over the time of treatment. This is due to the following two mechanisms:

  1. Preventing Degradation and Reducing Immunogenicity

    Polymer chains are covering the surface of a biopharmaceutical and thus effectively shield it against attacks by the immune system. The polymeric shield has characteristics rather like a solvent than a protein. This prevents uptake by cells of the retinal endothelial system (macrophage system). Recognition by the immune system (antibodies, proteases and other degradation enzymes etc.) is significantly reduced. The drug stays intact and is not destroyed (degraded or metabolized) during its presence in the body and journey through the physiological system.

  2. Preventing Excretion

    Poly(amino acids), PEG and PAS are naturally very hygroscopic and surrounded by a large solvating sphere of water. Thus the overall so-called “hydrodynamic radius” is increased to an order of magnitude which is larger than the diameter of the glomerular capillaries (6 to 12 nm). Therefore, the drug is not excreted through the kidneys and simply stays longer in the body. Retarded renal filtration prolongs plasma half-life of the biological drug by means of a purely biophysical size effect, without any receptor interactions that may influence pharmacodynamics or lead to side effects.

These two main effects, i.e. preventing degradation and excretion, lead to a set of advantageous properties of polymer therapeutic drugs. The polymer forms a random conformation which is stable under native buffer conditions and body temperature and generates a large hydrodynamic volume, thus increasing the apparent size. Through the choice of different chain lengths and polymer design the hydrodynamic volume can be adjusted within broad limits.

Additional references, books and review articles:

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  • Poly(ethylene glycol)-Prodrug Conjugates: Concept, Design, and Applications; S. S. Banerjee, N. Aher, R. Patil and J. Khandare; J Drug Deliv. 2012; 2012: 17. doi:10.1155/2012/103973 
  • Poly(ethylene glycol) in Drug Delivery: Pros and Cons as Well as Potential Alternatives; K. Knop, R. Hoogenboom, D. Fischer and U. S. Schubert; Angew Chem. Int. Ed. 2010; 49: 6288-6308. doi:10.1002/ anie.200902672 ff 
  • PEGylation - The Magic Wand. Turning Proteins and other Biopharmaceuticals into Super Performing Block Busters; T. Bruckdorfer; PharManufacturing 2007; 1: 34-41. 
  • Cancer siRNA therapy by tumor selective delivery with ligand-targeted sterically stabilized nanoparticle; R. M. Schiffelers, A. Ansari, J. Xu, Q. Zhou, Q. Tang, G. Storm, G. Molema, P. Y. Lu, P. V. Scaria and M. C. Woodle; Nucleic Acids Res 2004; 32: e149. doi:10.1093/nar/gnh140 
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  • The Synthesis of Substituted Methoxy-Poly(Ethyleneglycol) Derivatives Suitable for Selective Protein Modification; T. P. Kogan; Synthetic Comm 1992; 22: 2417-2424. doi:10.1080/00397919208019100