Characteristics of bone ingrowth and interface mechanics of a new porous tantalum biomaterial

Bobyn, J. D.; Stackpool, G. J.; Hacking, S. A.; Tänzer, Michael; Krygier, Jan

doi:10.1302/0301-620x.81b5.9283

Cited by 719 publications

(440 citation statements)

References 26 publications

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“…The diameter of sugar pellets was chosen according to previous research showing that the optimal size of pores for bone ingrowth is around 400 µm in order to allow formation of complete Haversian units inside the pores [14]. Table 1 …”

Section: Resultsmentioning

confidence: 99%

Manufacturing of biocompatible porous titanium scaffolds using a novel spherical sugar pellet space holder

et al. 2017

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This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. removed by dissolution in water before sintering. The morphology, pore structure and porosity were observed by optical microscopy, SEM and micro-CT. The porous titanium has highly spherical pore shapes, well-controlled pore sizes and high interconnectivity.The results suggest that porous titanium scaffolds generated using this manufacturing route have the potential for hard tissue engineering applications.

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Section: Resultsmentioning

confidence: 99%

Manufacturing of biocompatible porous titanium scaffolds using a novel spherical sugar pellet space holder

et al. 2017

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“…These coatings have included the addition of metal beads to a solid implant surface by a sintering or diffusion bonding process, thermal spraying of porous metal surfaces, sintering of metal cellular or mesh arrays onto the surface and the sintering of metallic foams to implant device surfaces (Bobyn et al 1999;Wen et al 2002). Figure 1 illustrates a commercial cellular structure composed of tantalum, developed by Zimmer Holdings, Inc. as Trabecular Metal.…”

Section: Introductionmentioning

confidence: 99%

Next-generation biomedical implants using additive manufacturing of complex, cellular and functional mesh arrays

Murr

Gaytan

Medina

et al. 2010

Phil. Trans. R. Soc. A.

478

290

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In this paper, we examine prospects for the manufacture of patient-specific biomedical implants replacing hard tissues (bone), particularly knee and hip stems and large bone (femoral) intramedullary rods, using additive manufacturing (AM) by electron beam melting (EBM). Of particular interest is the fabrication of complex functional (biocompatible) mesh arrays. Mesh elements or unit cells can be divided into different regions in order to use different cell designs in different areas of the component to produce various or continually varying (functionally graded) mesh densities. Numerous design elements have been used to fabricate prototypes by AM using EBM of Ti-6Al-4V powders, where the densities have been compared with the elastic (Young) moduli determined by resonant frequency and damping analysis. Density optimization at the bone-implant interface can allow for bone ingrowth and cementless implant components. Computerized tomography (CT) scans of metal (aluminium alloy) foam have also allowed for the building of Ti-6Al-4V foams by embedding the digital-layered scans in computer-aided design or software models for EBM. Variations in mesh complexity and especially strut (or truss) dimensions alter the cooling and solidification rate, which alters the a-phase (hexagonal close-packed) microstructure by creating mixtures of a/a (martensite) observed by optical and electron metallography. Microindentation hardness measurements are characteristic of these microstructures and microstructure mixtures (a/a ) and sizes.

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“…11,13) By manipulating and adjusting the size and ratio of titanium and nickel powder, we have been able to control the pore size and porosity in porous TiNi SMA implant (Kim & Kang, in preparation). Porosity of a material can influence mechanical properties such as strength, strain and superelasticity.…”

Section: Discussionmentioning

confidence: 99%

<I>In Vivo</I> Result of Porous TiNi Shape Memory Alloy: Bone Response and Growth

et al. 2002

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Porous titanium-nickel shape memory alloys (TiNi SMA) can be fabricated using special engineering technique. This material is a whole porous material with interconnected pores. This porous TiNi SMA retains the unique properties of solid TiNi SMA. Its porosity and pore size can be controlled. Its application to orthopaedic field is very expected especially in bone substitute and bone implant and so on. The purpose of this study was to evaluate bone tissue response and histocompatibility of porous TiNi SMA in vivo. Thirty block implants (5 mm × 5 mm × 7 mm) of porous TiNi SMA were prepared. Analysis of pore structure of the implant was performed using Hg-porosimetry and scanning electron microscope. Fifteen New Zealand white rabbits were used. Sterile porous TiNi SMA implant was implanted in the defects of proximal tibia metaphysis. Limbs of five rabbits were harvested respectively at 2, 4 and 6 weeks post implantation. Each specimen was embedded in PMMA. Embedded specimen was sectioned into 300 µm thickness with isomet-diamond saw. Quantitative histomorphometric analysis was performed within the each implant. The pore sizes of porous TiNi SMA were 323 ± 89 µm. Porosity was 55.3 ± 6.7%. No apparent adverse reactions such as inflammation and foreign body reaction were noted on or around all implanted porous TiNi SMA blocks. Bone ingrowth was found in the pore space of all implanted blocks. The percent bone ingrowth into the pore space of porous TiNi SMA increased over time. At six week post-implantation, bone ingrowth into pore in TiNi SMA block was very excellent (at 6 week, 78.3 ± 9.7%). This percent bone ingrowth was much higher than that of other porous materials. This in vivo response of porous TiNi SMA observed in this study opens to the possibility that porous TiNi SMA could be used as an ideal bone substitute.

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Characteristics of bone ingrowth and interface mechanics of a new porous tantalum biomaterial

Cited by 719 publications

References 26 publications

Manufacturing of biocompatible porous titanium scaffolds using a novel spherical sugar pellet space holder

Manufacturing of biocompatible porous titanium scaffolds using a novel spherical sugar pellet space holder

Next-generation biomedical implants using additive manufacturing of complex, cellular and functional mesh arrays

<I>In Vivo</I> Result of Porous TiNi Shape Memory Alloy: Bone Response and Growth

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