4 edition of Degradation phenomena on polymeric biomaterials found in the catalog.
|Statement||H. Planck, M. Dauner, M. Renardy, eds.|
|Contributions||Planck, H., 1947-, Dauner, M. 1957-, Renardy, M. 1958-, Institut für Textil- und Verfahrenstechnik (Denkendorf, Baden-Württemberg, Germany), International ITV Conference on Biomaterials (4th : 1991 : Denkendorf, Baden-Württemberg, Germany)|
|LC Classifications||R857.P6 D44 1992|
|The Physical Object|
|Pagination||x, 197 p. :|
|Number of Pages||197|
|ISBN 10||354055548X, 038755548X|
|LC Control Number||92014876|
This book reviews the current understanding of the mechanical, chemical and biological processes that are responsible for the degradation of a variety of implant materials. All 18 chapters will be written by internationally renowned experts to address both fundamental and Brand: Springer New York.
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Degradation Phenomena on Polymeric Biomaterials Softcover reprint of the original 1st ed. Edition by Heinrich Planck (Editor), Martin Dauner (Series Editor) ISBN ISBN Why is ISBN important. ISBN. This bar-code number lets you verify that you're getting exactly the right version or edition of a book.
Format: Paperback. Degradation Phenomena on Polymeric Biomaterials. Editors: Planck, Heinrich, Dauner, Martin, Renardy, Monika (Eds.) Free Preview. These proceedings contain the papers and discussions presented at the conference on "Degradation Phenomena on Polymeric Biomaterials". The constraints of the degradation behavior of polymers in a biological environment, i.e.
in the human body, are presented, from the manufacturing processes to differents species and implantation sites. Degradation phenomena on polymeric biomaterials. Berlin ; New York: Springer-Verlag, © (OCoLC) Material Type: Conference publication: Document Type: Book: All Authors / Contributors: H Planck; M Dauner; M Renardy; Institut für Textil- und Verfahrenstechnik (Denkendorf, Baden-Württemberg, Germany).
Again the problem of degradation was discussed intensively and demonstrated by the failure of textile implants, the degradation of aramide polymers or the degradation of resorbable suture materials. The examples make clear, that degradation may be a desired or undesired property of an implant.
Chain Scission and Polymer Degradation. For polymeric biomaterials, the most important degradation reaction is hydrolysis. There are several factors that influence the rate of this reaction: the nature of the chemical bond, the pH, the copolymer composition, and the extend of water uptake are the most relevant.
Of these factors, it Cited by: 1. Degradation rate of bioresorbable materials provides a comprehensive review of the most important techniques in safely predicting and evaluating the degradation rate of polymer, ceramic and composite based biomaterials.
Part one provides an introductory review of bioresorbable materials and the biological environment of the body. Polymeric biomaterials are widely used as carriers for cells and therapeutic agents. Until recently, most research has been limited to a relatively narrow number of monomers and chemistries.
A fundamental challenge in developing clinically relevant polymeric biomaterials is to independently control their chemical and physical properties across.
Offering nearly references more than the first edition-Polymeric Biomaterials, Second Edition is an up-to-the-minute source for plastics and biomedical engineers, polymer scientists, biochemists, molecular biologists, macromolecular chemists, pharmacists, cardiovascular and plastic surgeons, and graduate and medical students in these disciplines.4/5(1).
Holland S.J., Jolly A.M., Jasin M., and Tighe B.J () Polymers for biodegradable medical devices, Biomaterials 8 pp– CrossRef Google Scholar 7. Miller M.D. and Williams D.F () Ori the biodegradation of poly-ß-hydroxybuyrate (PHB) homopolymer and poly-ß-hydroxybuty-rate-hydroxyvalerate copolymers 8: – Google ScholarCited by: 1.
Get this from a library. Degradation Phenomena on Polymeric Biomaterials. [Heinrich Planck; Martin Dauner; Monika Renardy] -- These proceedings contain the papers and discussions presented at the conference on "Degradation Phenomena on Polymeric Biomaterials".
Following polymer chemistry and degradation mechanisms, methods. In book: Biomaterials Science, pp A first order degradation kinetics, Polymeric biomaterials represent large and very adaptable class of biomaterials, which makes them very.
physical properties. The required properties of polymeric biomaterials are similar to other biomaterials, that is, biocompatibility, sterilizability, adequate mechanical and physical properties, and manuflicturability as given in Table TABLE Requirements for Biomedical PolymersFile Size: KB.
Synthetic polymers degrade by hydrolysis  which can be in the form of bulk degradation or surface erosion [74, 75]. Most of the available polyesters degrade by the former mechanism [ Characterization of Polymeric Biomaterials presents a comprehensive introduction on the topic before discussing the morphology and surface characterization of biomedical polymers.
The structural, mechanical, and biological characterization is described in detail, followed by invaluable case studies of polymer biomaterial implants. Figure 1 Schematics for the degradation and analysis of synthetic polymeric biomaterials.
This review concerns the green part of this scheme. 4 Degradation methods Degradable polymeric materials contain moieties that are prone to chemical or enzymatic degradation (cf.
Table 1). The degradation of such materials can be divided as follows. The enzymatic degradation of polymers in vitro.
Authors. Smith, The amount of degradation is small, but could have significant sequelae should it be reproduced in vivo. Encyclopedia of Biomedical Polymers and Polymeric Biomaterials,CrossRef; 8 David K.
Dempsey, Cited by: Polymer degradation is a change in the properties—tensile strength, color, shape, etc.—of a polymer or polymer-based product under the influence of one or more environmental factors such as heat, light or chemicals such as acids, alkalis and some changes are usually undesirable, such as cracking and chemical disintegration of products or, more rarely, desirable, as in.
Polymeric Biomaterials: 2 Volume Set, Third Edition - CRC Press Book Biomaterials have had a major impact on the practice of contemporary medicine and patient care. Growing into a major interdisciplinary effort involving chemists, biologists, engineers, and physicians, biomaterials development has enabled the creation of high-quality devices.
Degradation studies of PP and PVDF monofilaments were carried out using a special chamber for several periods of time. One set of the samples was exposed to a % NaCl solution and to ultraviolet radiation at C and the other set involved the exposition in air under the same conditions of irradiation and temperature.
Scanning Electron Microscopy (SEM) analysis showed direct evidence of PP Cited by: 5. Polymeric biomaterials can also be incorporated with natural materials and inorganic nanoparticles to achieve novel, unique, and synergetic properties for better performance.
Biomimetic and intelligent polymeric systems have also been investigated to advance our material design by: 4.
This book provides readers with a comprehensive review of modelling polymers and polymeric medical devices as an alternative to practical experiments. Chapters in part one provide readers with an overview of the fundamentals of biodegradation.
Part two looks at a wide range of degradation theories for bioresorbable polymers and devices. A biomaterial is any substance that has been engineered to interact with biological systems for a medical purpose - either a therapeutic (treat, augment, repair or replace a tissue function of the body) or a diagnostic one.
As a science, biomaterials is about fifty years old. The study of biomaterials is called biomaterials science or biomaterials engineering. Corrosion and Degradation Phenomena in Biomaterials (Deadline: 30 July ) Block Copolymers for Drug Carriers/Vehicles (Deadline: 31 July ) Digital Image/Volume Correlation of Biological Tissues and Biomaterials (Deadline: 31 July ) Novel Biomaterials for Diseases Detection, Monitoring or Treatment (Deadline: 31 July ).
Biological degradation of synthetic polymer 1. A review on biological degradation of synthetic polymers Engr. Mizanur Rahman1 in Textile Engineering Department of Textile Engineering, Dhaka University of Engineering and Technology (DUET) Gazipur -Dhaka, Bangladesh Abstract Degradability of polymeric materials is a function of the structures of polymeric.
degradable polymeric biomaterials including but not limited to: material chemistry, molecular weight, hydrophobicity, sur-face charge, water adsorption, degradation, and erosion mech-anism.
Because of the wide-ranging use of polymeric biomate-rials, a single, ideal polymer or polymeric family does not exist. Structural Biomaterials: A Materials Science Perspective serves as a single point of reference to digest current research and develop a deeper understanding in the field of biomaterials engineering.
This book uses a materials-focused approach, allowing the reader to quickly access specific, detailed information on biomaterials characterization and selection.
DEGRADATION OF POLYMERIC BIOMATERIALS. Shalaby W. Shalaby*, Russell A. Johnson, and Meng Deng. 1 1. Bioengineering Department and Materials Science and Engineering Program, Rhodes Engineering Research Center, Clemson University, Clemson, SC (Received for publication Octoand in revised form Decem )Author: Shalaby W.
Shalaby, Russell A. Johnson, Meng Deng. Course Overview: Biomaterials is the study of materials and their use in medical implants, including metal, ceramics, polymers, composites, and biological biomaterials.
The course includes the. Published online: 29 Dec See all volumes and issues. Vol Vol. Author by: Buddy D. Ratner Languange: en Publisher by: Academic Press Format Available: PDF, ePub, Mobi Total Read: 10 Total Download: File Size: 49,7 Mb Description: The revised edition of this renowned and bestselling title is the most comprehensive single text on all aspects of biomaterials provides a balanced, insightful approach to both the learning of the science.
Biomaterials: A Nano Approach is written from a multi-disciplinary point of view that integrates aspects of materials science and engineering, nanotechnology, bioengineering, and biosciences.
The book fills a glaring void in the literature by providing a comprehensive discussion of biomaterials and a scientifically plausible extrapolation of. item 3 Degradation Phenomena on Polymeric Biomaterials (, Paperback) - Degradation Phenomena on Polymeric Biomaterials (, Paperback) $ Free shipping5/5(3).
The theoretical basis of surface engineering for improvement of biocontact properties of polymeric biomaterials as well as the current state-of-the-art of the surface engineering of polymeric biomaterials are presented.
The book also includes information on the most used conventional and advanced surface engineering methods. This is a useful book, with genuine 'handbook' characteristics. There's lots of good stuff here, and anyone interested in numerous aspects of polymer degradation and stabilization should have access to a copyPolymer News about the second editionCited by: the most promising polymeric biomaterials used today.
The polymeric biomaterials discussed in this review have been broadly classiﬁed into hydrolyti-cally degradable polymers and enzymatically de-gradable polymers placing emphasis on the mode of degradation for the corresponding polymers.
Hydrolytically degradable polymers as biomaterials. Commonly used traditional polymeric materials have many advantages, although their resistance to biological agents causes a negative impact on the environment.
Therefore, the use of (bio)degradable polymers with a minimal carbon footprint should become widespread due to the growing interest in sustainability, organic recycling, environmental.
This book contains 18 papers from the Next Generation Biomaterials and Surface Properties of Biomaterials symposia held during the Materials Science and Technology (MS&T'10) meeting, October, Houston, Texas.
Read More. Polymeric biomaterials for bone regeneration Chen Shi1, Zhangqin Yuan 2, Fengxuan Han, Caihong Zhu, Bin Li to acidic degradation products. Hydrophobic and lack of cellular adhesion Polycaprolactone (PCL) High crystallinity and good mechanical strength.
Slow degradation rate (years). Poor water. The Encyclopedia of Biomedical Polymers & Polymeric Biomaterials presents state-of-the-art research and development on the application of novel polymers in a vital area.
This groundbreaking work includes the insight of a large number of contributors from around the world who offer a broad-based perspective on a multitude of Range: $5, - $9, Doing Good: Efficacy. New biomaterials give us a wonderful opportunity to do good and improve the status might be possible to probe previously explored phenomena in a new way and reveal hidden new phenomena due to deployment of novel functional biomaterials (McIntyre et al., ).We might accelerate or enable healing that was not previously possible when we combine Cited by: 6.Language: English LCCN: MeSH: Biocompatible Materials*; Biodegradation, Environmental*; Polymers* Publication Type(s): Congresses Notes: "Proceedings of the 4th International Conference on Biomaterials, Denkendorf, September"--T.p.
verso. Includes bibliographical references and indexes. NLM ID: [Book].