Mechanical Testing of Bone and the Bone-Implant Interface
Mechanical Testing of Bone and the Bone-Implant Interface

Author: Yuehuei H. An

Publisher: CRC Press

Published: 1999-11-29

Total Pages: 650

ISBN-13: 1420073567

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The mechanical properties of whole bones, bone tissue, and the bone-implant interfaces are as important as their morphological and structural aspects. Mechanical Testing of Bone and the Bone-Implant Interface helps you assess these properties by explaining how to do mechanical testing of bone and the bone-implant interface for bone-related research

Modelling and Characterization of Mechanically Regulated Tissue Formation Around Bone-interfacing Implants
Modelling and Characterization of Mechanically Regulated Tissue Formation Around Bone-interfacing Implants

Author: Craig Alexander Simmons

Publisher:

Published: 2000

Total Pages: 0

ISBN-13:

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In many cases, orthopaedic and dental implants can restore function to diseased or damaged joints and edentulous jaws. However, in several challenging clinical situations, it is difficult to achieve adequate fixation (osseointegration) between the implant and bone. Since osseointegration is necessary for clinical success, implant failure rates in these cases are unacceptably high. Understanding the factors that allow bone-interfacing implants to osseointegrate rapidly and reliably should lead to improvements in their use and design. With this being our goal, we investigated the influence of implant surface geometry and local tissue strains on peri-implant tissue formation. Using a rabbit model, we evaluated the histological and mechanical characteristics of the early healing tissues around nonfunctional implants with Ti6Al4V sintered porous surfaces and Ti plasma-sprayed surfaces. We found that the early healing tissues integrated with the three-dimensional interconnected structure of the sintered porous surface and mineralized more rapidly than the tissues around the irregular geometry of the plasma-sprayed surface. Consequently, the stiffness and strength of attachment was greater for the porous-surfaced implants. These results demonstrate that implant surface geometry influences early peri-implant tissue formation and, as a result, the early mechanical stability of implants. To investigate the relationship between implant surface geometry, the local mechanical environment, and peri-implant tissue formation, we developed a computational micromechanical model based on homogenization methods to describe the effective and local properties of the porous-surfaced and plasma-sprayed peri-implant regions. In validation tests, we showed that the model provided reasonably accurate initial predictions of the properties of the peri-implant regions. Using the computational model, we compared the local mechanical environments around porous-surfaced and plasma-sprayed implants. In cases with minimal implant loading, the model predicted local tissue strains that permitted localized ' and' appositional bone formation around porous-surfaced implants, but only appositional bone formation for plasma-sprayed implants. Based on the model predictions and experimental data from earlier studies, we proposed a quantitative model for the mechanical regulation of peri-implant tissue formation. The mechanoregulatory model is consistent with observations of tissue formation around porous-surfaced and plasma-sprayed implants, and provides initial criteria to evaluate the osseointegration potential of bone-interfacing implants.

Bone Response to Dental Implant Materials
Bone Response to Dental Implant Materials

Author: Adriano Piattelli

Publisher: Woodhead Publishing

Published: 2016-10-27

Total Pages: 286

ISBN-13: 0081002882

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Bone Response to Dental Implant Materials examines the oral environment and the challenges associated with dental biomaterials. Understanding different in vivo and in vitro responses is essential for engineers to successfully design and tailor implant materials which will withstand the different challenges of this unique environment. This comprehensive book reviews the fundamentals of bone responses in a variety of implant materials and presents strategies to tailor and control them. Presents a specific focus on the development and use of biomaterials in the oral environment Discusses the basic science of the dental interface and its clinical applications Contains important coverage on the monitoring and analysis of the dental implant interface

Interfaces in Medicine and Mechanics—2
Interfaces in Medicine and Mechanics—2

Author: K.R. Williams

Publisher: Springer

Published: 1991-02-28

Total Pages: 528

ISBN-13:

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The first Interfaces Conference was held at Swansea in April 1988 and represented the then state of the art of the science of implant surgery. The motivation for the initial venture was a supposed need for a closer interaction and dialogue between the clinician and scientist working in this area. As expressed in the Preface to the first Conference, we felt that the interface was represented graphically, scientifically and psychologically by the drawings of Edgar Rubins (1915), again widely used in the literature to the present Proceedings. The first Conference, we believe, achieved the aims of the organisers in bringing together scientists and clinicians towards an exchange of ideas by logically pursuing the sequence of events in clinical implant surgery. The present Conference, in collaboration with our Italian colleagues, has also attempted to achieve the same aims by examining the behaviour of implants constructed of a variety of materials in both hard and soft tissue. Many contributions in the conference employed the technique of finite element analysis, both for design and optimisation purposes, particularly in relation to bone remodelling. Indeed, this particular aspect of the Conference led to much debate and will require a major examination of the many levels of physical, chemical and biomechanical interactive behaviour of the implant and its environment. All this natural behaviour was presented and discussed, but difficulties and failures remain with such procedures and we feel it is only by continuing such meetings that we progress in this difficult area of clinical science.

Bone Tissue Engineering
Bone Tissue Engineering

Author: Jeffrey O. Hollinger

Publisher: CRC Press

Published: 2004-10-14

Total Pages: 500

ISBN-13: 1135501912

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Focusing on bone biology, Bone Tissue Engineering integrates basic sciences with tissue engineering. It includes contributions from world-renowned researchers and clinicians who discuss key topics such as different models and approaches to bone tissue engineering, as well as exciting clinical applications for patients. Divided into four sections, t

Swelling and Mechanical Characterization of a Porous Swelling Co-polymer for Orthopedic Applications
Swelling and Mechanical Characterization of a Porous Swelling Co-polymer for Orthopedic Applications

Author: Victoria McDonald

Publisher:

Published: 2021

Total Pages: 50

ISBN-13:

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Bone implants are a common part of orthopedic procedures used to correct a variety of conditions. The material used in these implants dictates the device's strength and efficacy. Researchers have spent decades looking for materials ideally suited to these applications that exhibit the necessary mechanical characteristics while enabling bone regrowth and healing. Self-anchoring materials have been identified as an excellent candidate for bone implants. These materials allow for gradual fixation, stimulation of bone growth, and desirable mechanical properties. The material described in this study is a swelling polymer that can be formulated into a porous matrix. This material is capable of controlled swelling when exposed to an aqueous media, like the fluids present in the human body. The porous matrix allows for the surrounding bone to integrate into the device, allowing for strong fixation and facilitation of the body's natural healing process. While it was anticipated that the porous material would not exhibit sufficient mechanical strength, the material was used to create a hybrid system of solid and porous components to maintain strength as well as osteointegration. The material was evaluated by quantifying the free swelling characteristics of the solid material, porous material, and hybrid system. This was done for two diameters for each type. Additionally, the mechanical properties for each material type were determined using standard compression testing. It was concluded that the solid samples exhibited similar properties to samples characterized in previous studies. As expected, the porous material did not exhibit sufficient strength, but when the two types were combined into the hybrid system, sufficient strength was observed. This indicates that the hybrid system would be a good candidate for additional evaluation as a self-fixating bone implant.

The Bone-biomaterial Interface
The Bone-biomaterial Interface

Author: John Edward Davies

Publisher:

Published: 1991

Total Pages: 524

ISBN-13:

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Based on the proceedings of the Bone-Biomaterial Interface Workshop held in Toronto, Canada, December 1990, addresses the questions which have arisen during this period of evolution from inert to active materials in orthopedic, dental, and maxillofacial implants with specific reference to the bone-biomaterial interface. The seven parts of the volume reflect the seven sessions of the workshop, dealing with materials issues, protein adsorption, cell and tissue reactions, mechanical influences on interfacial biology, retrieval analysis, and the industrial context. Annotation copyrighted by Book News, Inc., Portland, OR