Liu Shuang, Maheshwari Ronak, Kiick Kristi L
Department of Materials Science and Engineering, University of Delaware, 201 DuPont Hall, Newark, Delaware 19716, and Delaware Biotechnology Institute, 15 Innovation Way, Newark, Delaware 19711.
Macromolecules. 2009 Jan 13;42(1):3-13. doi: 10.1021/ma801782q.
Polymeric materials have been applied in therapeutic applications, such as drug delivery and tissue regeneration, for decades owing to their biocompatibility and suitable mechanical properties. In addition, select polymer-drug conjugates have been used as bioactive pharmaceuticals owing to their increased drug efficacy, solubility, and target specificity compared with small-molecule drugs. Increased synthetic control of polymer properties has permitted the production of polymer assemblies for the targeted and controlled delivery of drugs, and polymeric sequestrants take advantage of their lack of solubility for the sequestration of target molecules in vivo. In more recent studies reviewed in greater detail here, the properties of polymers that distinguish them from small-molecule drugs, such as their high molecular weight and their ability to display multiple pendant moieties, have been specifically exploited for activating cellular targets or inhibiting the binding of pathogens. The elucidation of relevant structure-function relationships in investigations of this kind has relied on the combination of living polymerization methods with chemical conjugation methods, and protein engineering methods have shown increasing potential in the manipulation of architectural features of such polymer therapeutics. Garnering a detailed understanding of the various mechanisms by which multivalent polymers engage biological targets is certain to expand the role of polymers as therapeutics, by enabling highly specific activities of designed polymers in the biological environment.
几十年来,聚合物材料因其生物相容性和合适的机械性能而被应用于治疗领域,如药物递送和组织再生。此外,与小分子药物相比,一些特定的聚合物-药物缀合物因其提高的药物疗效、溶解度和靶向特异性,已被用作生物活性药物。对聚合物性质合成控制的增强使得能够生产用于药物靶向和控释的聚合物组装体,而聚合物螯合剂则利用其在体内不溶性来螯合靶分子。在本文更详细综述的最近研究中,聚合物区别于小分子药物的性质,如它们的高分子量以及展示多个侧链部分的能力,已被专门用于激活细胞靶点或抑制病原体的结合。这类研究中相关结构-功能关系的阐明依赖于活性聚合方法与化学偶联方法的结合,并且蛋白质工程方法在操纵此类聚合物治疗剂的结构特征方面已显示出越来越大的潜力。通过使设计的聚合物在生物环境中具有高度特异性活性,详细了解多价聚合物与生物靶点相互作用的各种机制必将扩大聚合物作为治疗剂的作用。