Polymere als Implantatwerkstoffe

Polymers are already being used as implant materials in several biomedical applications by today. The present paper shows actual concepts for innovative degradable biomaterials as well as established polymers. Basic terms will be explained. Methods for biocompatibility testing of polymers will be introduced. Finally, future challenges for the development of new polymer systems will be discussed.     

Complicity of degradable polymers in health-care applications

Polymeric biomaterials have revolutionized biomedical technology and related fields as biomaterials for health-care applications. Recent trend in polymeric medical technology has adapted a tendency to substitute degradable polymers instead of non-degradable synthetic polymers for the advancement of various health-care modalities. They have got considerable attention for their potential in various interdisciplinary arenas, which implies tissue engineering scaffolds, sustainable drug release, delivery agents, regenerative medicine, and development of life-saving devices, implants, dental products as well as in food technology. Various types of degradable polymers are been developed to date having stringent features applicable for various aspects in modern science. Thus, being the most renovative field of biomedicine and biomedical technology degradable polymers has gained substantial acceptance and appreciation recent times. This review critically underlines various degradative polymers and their subtypes, potential applications, types of degradation, and their possible effects in the biological system. Assessment of possible toxicological risks behind is an important criterion to be focused before validating any biomaterial safe for biomedical applications. Therefore various toxicological assessment strategies and their impact in biomedicine and technology were also included. In addition, the risk versus benefit assessment is also critically summarized.     

高分子在生物工程中的应用进展

在生物工程中所用的高分子材料一般统称为高分子生物材料,其涉及的范围很广。医用高分子是其中很重要的一类,另一类就是在生物技术中所用的高分子材料。对于高分子生物材料可根据其材料性质进行分类,也可按使用范围进行分类。如体内应用的材料,半体内应用的材料和体外应用的材料。本文着重介绍了抗凝血材料、药用高分子材料及应用于生物技术中高分子材料的研究进展,并总结分析了这几个研究领域中的发展趋势。     

Influence of branching architecture on polymer properties

Hyperbranched polymers (HBPs), invented at the end of 1980s, are one important subclass of the fourth generation macromolecular architectures following the linear, branched, and crosslinking polymers. Due to their unique topological structure and interesting physical/chemical properties, HBPs have attracted wide attention from both academia and industry. HBPs are composed of linear units, dendritic units, and terminal units. The degree of branching (DB), a term to describe the composition of these three structure units and thus the branching architecture of polymers, is one of the most important intrinsic parameters for HBPs. This review has summarized the effect of the DB on the physical and chemical properties of HBPs, including the rheological property, crystallization and melting behaviors, glass transition, thermal and hydrolytic degradations, phase characteristics, lower critical solution temperature phase transition, optoelectronic properties, encapsulation capability, self‐assembly behavior, biomedical applications, and so on. Such a structure and property relationship will build a bridge between the syntheses and applications of HBPs, especially in the application areas of functional materials, biomedical materials, and nanotechnology. © 2011 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 49: 1277–1286, 2011     

Synthesis and in vitro degradation of poly(N‐vinyl‐2‐pyrrolidone)‐based graft copolymers for biomedical applications

This work is devoted to the design of a novel family of hydrosoluble biomaterials: poly(N‐vinyl‐2‐pyrrolidone) (PVP)‐based graft copolymers. A synthesis route has been elaborated in which ω‐functionalized PVP is prepared via chain‐transfer radical polymerization, end‐group modified, and subsequently grafted onto a polyhydroxylated backbone, typically dextran or poly(vinyl alcohol). The resulting graft copolymer biomaterials are designed for use in various biomedical applications, particularly as materials with a stronger potential for plasma expansion than already existing products have. The graft copolymers are potentially degradable because the PVP grafts are connected to the polyol backbone via a hydrolytically labile carbonate or ester linkage. The degradation of the graft copolymers was performed in vitro over a period of 6 weeks. © 2002 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 40: 3652–3661, 2002     

Conducting polymers: Efficient thermoelectric materials

This review highlights the recent progress made in the area of thermoelectric (TE) applications of conducting polymers and related composites. Several examples of such materials and their TE properties are discussed. TE properties of new poly(2,7‐carbazole) derivatives are highlighted. References are also made to carbon nanotube/polymer composites and their improved electrical and TE performance. Studies on polymer/inorganic materials composites have also taken a step forward and have shown very promising TE properties. © 2011 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys, 2011     

Application of carbon fibers to biomaterials: a new era of nano-level control of carbon fibers after 30-years of development

Carbon fibers are state-of-the-art materials with properties that include being light weight, high strength, and chemically stable, and are applied in various fields including aeronautical science and space science. Investigation of applications of carbon fibers to biomaterials was started 30 or more years ago, and various products have been developed. Because the latest technological progress has realized nano-level control of carbon fibers, applications to biomaterials have also progressed to the age of nano-size. Carbon fibers with diameters in the nano-scale (carbon nanofibers) dramatically improve the functions of conventional biomaterials and make the development of new composite materials possible. Carbon nanofibers also open possibilities for new applications in regenerative medicine and cancer treatment. The first three-dimensional constructions with carbon nanofibers have been realized, and it has been found that the materials could be used as excellent scaffolding for bone tissue regeneration. In this critical review, we summarize the history of carbon fiber application to the biomaterials and describe future perspectives in the new age of nano-level control of carbon fibers (122 references).     

An in vivo study of the host response to starch-based polymers and composites subcutaneously implanted in rats

Implant failure is one of the major concerns in the biomaterials field. Several factors have been related to the fail but in general these biomaterials do not exhibit comparable physical, chemical or biological properties to natural tissues and ultimately, these devices can lead to chronic inflammation and foreign-body reactions. Starch-based biodegradable materials and composites have shown promising properties for a wide range of biomedical applications as well as a reduced capacity to elicit a strong reaction from immune system cells in vitro. In this work, blends of corn starch with ethylene vinyl alcohol (SEVA-C), cellulose acetate (SCA) and polycaprolactone (SPCL), as well as hydroxyapatite (HA) reinforced starch-based composites, were investigated in vivo. The aim of the work was to assess the host response evoked for starch-based biomaterials, identifying the presence of key cell types. The tissues surrounding the implant were harvested together with the material and processed histologically for evaluation using immunohistochemistry. At implant retrieval there was no cellular exudate around the implants and no macroscopic signs of an inflammatory reaction in any of the animals. The histological analysis of the sectioned interface tissue after immunohistochemical staining using ED1, ED2, CD54, MHC class II and alpha/beta antibodies showed positively stained cells for all antibodies, except for alpha/beta for all the implantation periods, where it was different for the various polymers and for the period of implantation. SPCL and SCA composites were the materials that stimulated the greatest cellular tissue responses, but generally biodegradable starch-based materials did not induce a severe reaction for the studied implantation times, which contrasts with other types of degradable polymeric biomaterials.     

Protein and Polysaccharide-Based Electroactive and Conductive Materials for Biomedical Applications

Electrically responsive biomaterials are an important and emerging technology in the fields of biomedical and material sciences. A great deal of research explores the integral role of electrical conduction in normal and diseased cell biology, and material scientists are focusing an even greater amount of attention on natural and hybrid materials as sources of biomaterials which can mimic the properties of cells. This review establishes a summary of those efforts for the latter group, detailing the current materials, theories, methods, and applications of electrically conductive biomaterials fabricated from protein polymers and polysaccharides. These materials can be used to improve human life through novel drug delivery, tissue regeneration, and biosensing technologies. The immediate goal of this review is to establish fabrication methods for protein and polysaccharide-based materials that are biocompatible and feature modular electrical properties. Ideally, these materials will be inexpensive to make with salable production strategies, in addition to being both renewable and biocompatible.     

Water‐mediated transport in ion‐containing polymers

Water‐mediated ion conduction enables high conductivity in hydrated polymer membranes commonly used in electrochemical devices. Understanding the coupling of the absorbed water with the polymer matrix and the dynamics of water inside the polymer network across the full range of length scales in the membrane is important for unraveling the structure–property relationships in these materials. By considering the water behavior in ion‐containing polymers, next‐generation fuel cell membranes are being designed that exceed the conductivity of the state‐of‐the‐art materials and have optimized conductivity and permeability that may be useful in other types of devices such as redox flow batteries. Water–polymer associations can be exploited to tune the transport and mechanical property tradeoffs in these polymers. Measurements of water motion provide important criteria for assessing the factors that control the performance of these types of materials. This review article discusses current understanding of water behavior in ion‐containing polymers and the relationship between water motion and ion and molecular transport. © 2011 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys, 2011     

The Development of Bioglass Ceramics for Medical Applications

The enormous progress made in the field of medicine over the past few decades has been partly due to the introduction of new instruments but also a result of the use of new materials. It is impossible to imagine modern medicine without metals, alloys, sintered corundum, organic high polymers (also as composite materials), glassy carbon, etc. Bioglass ceramics open up new possibilities for medical treatment and constitute a new area of research in the natural sciences and medicine. Owing to their widely variable combinations of properties, bioglass ceramics can be more easily adapted to suit medical requirements than can customary implants. Two properties of bioglass ceramics are of primary importance: their biocompatibility, i.e., acceptance of the material by the tissues of the human body without irritation, rejection reactions, or toxic effects; and their bioactivity, i.e., the ability to establish firm intergrowths with tissues of the human body. This property is not shared by any of the classical biomaterials. A wide range of applications is envisaged for the bioglass ceramics that have so far been developed; some are still undergoing animal tests while others are being clinically tested in humans. Possible applications are the replacement of vertebrae and use in the middle ear, throat, nose, and eye, in the entire head region, in the shoulder and leg, and in dental prosthetics, in particular the replacement of dental roots (a hard tissue substitute in the broadest sense of the word). The question as to the behavior of a bone/bioglass ceramic contact or bond on a long-term scale and on being exposed to varying mechanical stress has still not been satisfactorily answered, because interdisciplinary research in this field is still immature. All observations made so far indicate, however, that the materials do not cause any adverse effects.     

Conducting polythiophenes with a broad spectrum of reactive groups

The development of reliable and reproducible chemistries for the immobilization of biomolecules to a conducting polymer is a key challenge in the design and preparation of a CP‐based biosensor. In this article, the syntheses and electropolymerization of a series of new 3‐alkylthiophene derivatives functionalized with the most used reactive groups in immobilization chemistry, including maleimide, azide, and anhydride, are described. Despite the nucleophilic or electrophilic nature of the reactive groups, the synthesized thiophene monomers exhibit rather good polymerizability, and the reactive groups withstand the polymerization conditions and are correctly incorporated into the resulting electroactive polymers. The reactivity of the pendant reactive groups of the resulting polymers to attach biomolecules has been examined with different redox‐active, photoactive compounds as well as recognition elements as model compounds. It has been confirmed that with well‐established procedures developed for the immobilization of enzymes, the model compounds can be easily and selectively bound onto these new conducting polymers without the loss of their optical and electrochemical activity. Therefore, these conductive materials with a broad spectrum of reactive groups will provide a useful platform for developing CP‐based biosensors for a wide range of applications. © 2005 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 43: 4547–4558, 2005     

An overview of nano-polymers for orthopedic applications

This review paper presents many exciting nanotechnology and tissue engineering approaches involving polymers that have enormous potential impact on human health care, particularly for orthopedic applications. As scaffolds play a vital role in tissue engineering, the feasibility of designing polymeric nano-featured scaffolds is reviewed. Although bone is a very diverse tissue providing different functions within the body, recent work has resulted in new biomaterials with promise to solve orthopedic problems. Significant advancements in orthopedic care are required since recent data highlight a less than 15 year lifetime of current hip implants. Nanotechnology (or the use of nanomaterials) is providing a wide range of new materials to improve the current short lifetimes of orthopedic implants.     

Surface‐Grafted conjugated polymers for hybrid cellulose materials

Conjugated polymers were grafted onto cellulose substrates in an effort to create a general method for the synthesis of conjugated polymer/cellulose hybrid materials. In this report, we describe the grafting of poly(fluorene), poly(fluorenevinylene), and a poly(fluorene‐ethynylene‐phenylene) onto modified cellulose paper substrates using Suzuki, Heck, and Sonogashira‐type polymerizations, respectively. The application of these three widely used coupling chemistries to surface‐grafted conjugated polymers on cellulose provides a general route to cellulose‐based hybrid materials tunable with almost any aromatic repeat structure for specific applications. © 2011 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem, 2011     

Thermally degradable thermosetting materials

Thermosetting materials have been widely used in a variety of applications but they generally display poor tractability after curing, which limits their use in applications where degradable or re-workable polymers are advantageous. Moreover, recyclability and biodegradability of thermosetting polymer also limit their use in applications where recycling and biodegradation are important. A variety of thermally degradable linkages within thermosetting materials have been studied both in academia and industry to develop re-workable adhesives. This review reports the recent development in thermosetting materials containing thermally breakable linkages that exhibit re-workability as well as potential for recyclability and biodegradability.     

Synthesis of backbone thermo and pH dual‐responsive hyperbranched poly(amine‐ether)s through proton‐transfer polymerization

Stimuli‐responsive hyperbranched polymers have attracted great attention in recent years because of their wide applications in biomedicine. Through proton‐transfer polymerization of triethanolamine and 1,2,7,8‐diepoxyoctane with the help of potassium hydride, a series of novel backbone thermo and pH dual‐responsive hyperbranched poly(amine‐ether)s were prepared successfully in one‐pot. The degrees of branching of the resulting polymers were at 0.40–0.49. Turbidity measurements revealed that hyperbranched poly(amine‐ether)s exhibited thermo and pH dual‐responsive properties in water. Importantly, these responsivities could be readily adjusted by changing the polymer composition as well as the polymer concentration in aqueous solution. Moreover, in vitro evaluation demonstrated that hyperbranched poly(amine‐ether)s showed low cytotoxicity and efficient cell internalization against NIH 3T3 cell lines. These results suggest that these backbone thermo and pH dual‐responsive hyperbranched poly(amine‐ether)s are promising materials for biomedicine. © 2010 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem, 2011     

Recent advances in conjugated polymer energy storage

This review covers recent advances in conjugated polymers and their application in energy storage. Conjugated polymers are promising cost-effective, lightweight, and flexible electrode materials. The operating principles of conjugated polymers are presented within the framework of their potential for energy storage. Special focus is given to polyaniline electrodes. Recent advances are reviewed including new methods of synthesis, nanostructuring, and assembly. Also, covered are applications that take full advantage of the mechanical properties of conjugated polymers and future applications of these novel materials. © 2013 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys, 2013     

巯基-烯点击化学

点击化学自2001年由Sharpless提出后,由于其高效、可靠、高选择性的特点迅速成为药物和高分子材料合成的新方法。随着对点击化学研究的深入,其反应类型在不断增多,应用范围也在不断扩大。自由基或亲核试剂引发的巯基-烯反应作为其中一种新型的点击反应具有点击化学的所有特性。本文从点击化学的概念、特征和类型出发,重点介绍了巯基-烯反应的机理和在合成功能聚合物、制备拓扑结构高分子、表面修饰以及生物药物等方面的应用,并对巯基-烯反应的最新研究成果进行综述,最后展望了巯基-烯的点击化学的发展前景。     

Research progress in toughening modification of poly(lactic acid)

Renewable poly(lactic acid) (PLA) exhibits high strength and stiffness. PLA is fully biodegradable and has received great interest. However, the inherent brittleness of PLA largely impedes its wide applications. In this article, the recent progress in PLA toughening using various routes including plasticization, copolymerization, and melt blending with flexible polymers, was reviewed in detail. PLA toughening, particularly modification of impact toughness through melt blending, was emphasized in this review. Reactive blending was shown to be especially effective in achieving high impact strength. The relationship between composition, morphology, and mechanical properties were summarized. Toughening mechanisms were also discussed. © 2011 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys, 2011.