Quantitative analysis of bone reactions to relative motions at implant-bone interfaces☆
References (39)
Deviatoric and hydrostatic mode interaction in hard and soft tissue
J. Biomechanics
(1990)- et al.
Post-loosening mechanical behavior of femoral resurfacing prostheses
Clin. Mater.
(1990) - et al.
The biologic interface between bone and cementless femoral endoprostheses
J. Arthroplasty
(1986) - et al.
Cracks emanating from a fluid filled void loaded in compression: application to the bone-implant interface
J. Biomech. Engng
(1987) - et al.
Hydroxyapatite coating provides a stronger fibrous anchorage of implants with controlled micromotion
Trans. orth. Res. Soc.
(1990) Analysis of implant failure in the Wagner resurfacing arthroplasty
- et al.
Reaction of bone to methacrylate
J. Bone Jt Surg.
(1974) The influence of force, motion and related quantities on the response of bone to implants
- et al.
The influence of functional use of endosseous dental implants on the tissue-implant interface. I. Histological aspects
J. Dental Res.
(1979) - et al.
Mechanical loading history and skeletal biology
J. Biomechanics
Histomorphology of the bone-to-cement interface: remodeling of the cortex and revascularization of the medullary canal in animal experiments
Prosthetic synovitis
Side effects of acrylic cement, implanted into bone
Acta orthop. scand.
The synoviallike membrane at the bone-cement interface in loose total hip replacements and its proposed role in bone lysis
J. Bone Jt Surg.
Modes of failure of cemented stem-type femoral components
Clin. Orthop.
The first 32 years of total hip arthroplasty: one surgeon's perspective
Clin. Orthop. Rel. Res.
Investigation of the bone-prosthesis interface following total joint replacement
Mechanical properties of the fibrous tissue found at the bone-cement interface following total joint replacement
J. Biomater. Res.
Cited by (58)
Laser processing of Ti composite coatings reinforced with hydroxyapatite and bioglass
2018, Additive ManufacturingCitation Excerpt :Poor wear resistance is another important concern of Ti and its alloys although not required for all implants. However, some areas of the implants, such as interface between hip stem neck and taper bore of the femoral head, experience considerable amount of micro-motions, where increase in the wear resistance of neck can significantly decrease the wear debris generation and improve in vivo life of the implants [8,9]. Generation of metal debris and metal ion release due to micro-motions could lead to implant loosening via osteolysis and metal sensitivity [10–13].
Finite element analysis of stresses generated in cortical bone during implantation of a novel Limb Prosthesis Osseointegrated Fixation System
2017, Biocybernetics and Biomedical EngineeringCitation Excerpt :The most commonly used involve an application of an interference fit between the cylindrical implant (with appropriate anchoring/anti-rotation elements and surface's roughness) and bone, e.g. the ITAP [15]. After around 6 months of osseointegration, a stable implant-bone connection is obtained [5,6,11,20]. Due to the fact that implants for direct skeletal attachment of limb prosthesis are a constantly developing and innovative method, numerous studies are carried out.
Non-linear 3D finite element analysis of full-arch implant-supported fixed dentures
2014, Materials Science and Engineering CCitation Excerpt :The bone-implant interface represents a great influence on stress in peri-implant bone [44]. It has been suggested that stress in the peri-implant bone and the implant apex is higher for free contact (contact elements) at the bone-implant interface in comparison with bond contact (100% union) [45]. The implants submitted to immediate loading presented a frictional component at the bone interface, and this contact transferred pressure, tangential and frictional forces [39].
Microstructure, mechanical and wear properties of laser surface melted Ti6Al4V alloy
2014, Journal of the Mechanical Behavior of Biomedical MaterialsCitation Excerpt :For example, the hip stem in the total hip prosthesis do not undergo any major articulation but significant amount of micro-motions can occur at two interfaces e.g., (i) femoral neck (Ti6Al4V alloy) and femoral head (CoCrMo alloy or Al2O3 or Zirconia toughened Al2O3) and (ii) hip stem and femur bone. These micro-motions can generate high wear debris, which can limit long-term stability of load-bearing implants (Fukunishi, 1995; Weinans et al., 1993). The severity of this problem may be magnified several times in younger and more active patients.
Comparison of different designs of implant-retained overdentures and fixed full-arch implant-supported prosthesis on stress distribution in edentulous mandible - A computed tomography-based three-dimensional finite element analysis
2013, Journal of BiomechanicsCitation Excerpt :The condition of the bone–implant interface has a burly influence on the stress intensities over the peri-implant area (O’Mahony et al., 2001). The stress at the periimplant bone and implant apex are greater for a free contact when compared to a fixed bond (Weinans et al., 1993). Before osseointegration, the implant–bone interface presents a frictional component which allows minor displacement.
Wear performance of laser processed tantalum coatings
2011, Materials Science and Engineering CCitation Excerpt :Although, HA coatings perform equally well in terms of biological fixation, the low fracture toughness, wear resistance and rough surface morphology of these coatings can generate high wear debris as a result of micro motions at the bone-implant interface during early stages of surgery. These particulate wear debris have been recognized as one of the major challenges for long-term viability of load bearing implants [15,16]. The above problem can be alleviated if HA coatings are replaced with bioactive Ta coatings, as the metallic Ta coatings have high fracture toughness and can be polished to achieve a smooth surface.
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Partly presented at the 34th Annual Meeting of the Orthopaedic Research Society, January 1988, Atlanta, Georgia.