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UHMWPE biomaterials for joint implan...

Fu, Jun.

UHMWPE biomaterials for joint implantsstructures, properties and clinical performance /

Record Type:	Electronic resources : Monograph/item
Title/Author:	UHMWPE biomaterials for joint implantsedited by Jun Fu, Zhong-Min Jin, Jin-Wu Wang.
Reminder of title:	structures, properties and clinical performance /
other author:	Fu, Jun.
Published:	Singapore :Springer Singapore :2019.
Description:	x, 339 p. :ill., digital ;24 cm.
Contained By:	Springer eBooks
Subject:	Artificial jointsMaterials.
Online resource:	https://doi.org/10.1007/978-981-13-6924-7
ISBN:	9789811369247$q(electronic bk.)

UHMWPE biomaterials for joint implantsstructures, properties and clinical performance /
UHMWPE biomaterials for joint implantsstructures, properties and clinical performance /[electronic resource] :edited by Jun Fu, Zhong-Min Jin, Jin-Wu Wang. - Singapore :Springer Singapore :2019. - x, 339 p. :ill., digital ;24 cm. - Springer series in biomaterials science and engineering,v.132195-0644 ;. - Springer series in biomaterials science and engineering ;2..

Clinical Applications of UHMWPE -- Highly Crosslinked UHMWPE -- Oxidation Mechanisms of UHMWPE -- Stablization of Highly Crosslinked UHMWPE -- Natural Polyphnol Stabilized Highly Crosslinked -- High Temperature Melted, Crosslinked, and Stabilized UHMWPE -- Effect of Biomolecules on Wear and Oxidation of UHMWPE Components -- Drug-loaded UHMWPE to Inhibit Wear Particle-induced Osteolysis--Processing, Characterizing and Biological Evaluation -- Biomechanics in Artificial Joints -- Tribology in Artificial Joints -- Perspective of Next Generation Polymer Materials for Joint Implants.

This book presents a comprehensive, state-of-the-art review of the latest progresses in UHMWPE biomaterials, which has been critical for the performance and longevity of joint implants. Oriented by clinical challenges to UHMWPE-based joint implants, it introduces the processing, crosslinking, structural manipulation, oxidation mechanism, stabilization, drug delivery, and wear, as well as clinical performance, biomechanics, and simulated studies of joint implant based on UHMWPE with low wear, which are aimed to tackle or minimize the adverse effect related to wear and wear debris. These contributions provide fundamentals of chemistry and physics of UHMWPEs to help understand the clinical performances of UHMWPE based joint implants. Perspectives to next generation UHMWPE to meet the unmet challenges in clinical use are included.

ISBN: 9789811369247$q(electronic bk.)

Standard No.: 10.1007/978-981-13-6924-7doiSubjects--Topical Terms:

666748
Artificial joints
--Materials.

LC Class. No.: RD686 / .U369 2019

Dewey Class. No.: 617.58

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505 0 $a Clinical Applications of UHMWPE -- Highly Crosslinked UHMWPE -- Oxidation Mechanisms of UHMWPE -- Stablization of Highly Crosslinked UHMWPE -- Natural Polyphnol Stabilized Highly Crosslinked -- High Temperature Melted, Crosslinked, and Stabilized UHMWPE -- Effect of Biomolecules on Wear and Oxidation of UHMWPE Components -- Drug-loaded UHMWPE to Inhibit Wear Particle-induced Osteolysis--Processing, Characterizing and Biological Evaluation -- Biomechanics in Artificial Joints -- Tribology in Artificial Joints -- Perspective of Next Generation Polymer Materials for Joint Implants.
520 $a This book presents a comprehensive, state-of-the-art review of the latest progresses in UHMWPE biomaterials, which has been critical for the performance and longevity of joint implants. Oriented by clinical challenges to UHMWPE-based joint implants, it introduces the processing, crosslinking, structural manipulation, oxidation mechanism, stabilization, drug delivery, and wear, as well as clinical performance, biomechanics, and simulated studies of joint implant based on UHMWPE with low wear, which are aimed to tackle or minimize the adverse effect related to wear and wear debris. These contributions provide fundamentals of chemistry and physics of UHMWPEs to help understand the clinical performances of UHMWPE based joint implants. Perspectives to next generation UHMWPE to meet the unmet challenges in clinical use are included.
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