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Orthopaedic Proceedings
Vol. 101-B, Issue SUPP_5 | Pages 97 - 97
1 Apr 2019
Justin D Nguyen YS Walsh W Pelletier M Friedrich CR Baker E Jin SH Pratt C
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Recent clinical data suggest improvement in the fixation of tibia trays for total knee arthroplasty when the trays are additive manufactured with highly porous bone ingrowth structures. Currently, press-fit TKA is less common than press-fit THA. This is partly because the loads on the relatively flat, porous, bony apposition area of a tibial tray are more demanding than those same porous materials surrounding a hip stem. Even the most advanced additive manufactured (AM) highly porous structures have bone ingrowth limitations clinically as aseptic loosening still remains more common in press-fit TKA vs. THA implants.

Osseointegration and antibacterial properties have been shown in vitro and in vivo to improve when implants have modified surfaces that have biomimetic nanostructures designed to mimic and interact with biological structures on the nano-scale. Pre-clinical evaluations show that TiO2 nanotubes (TNT), produced by anodization, on Ti6Al4V surfaces positively enhance the rate at which osseointegration occurs and TNT nano-texturization enhances the antibacterial properties of the implant surface.2

In this in vivo sheep study, identical Direct Metal laser Sintered (DMLS) highly porous Ti6Al4V specimens with and without TNT surface treatment are compared to sintered bead specimens with plasma sprayed hydroxyapatite-coated surface treatment. Identical DMLS specimens made from CoCrMo were also implanted in sheep tibia bi-cortically (3 per tibia) and in the cancellous bone of the distal femur and proximal tibia (1 per site). Animals were injected with fluorochrome labels at weeks 1, 2 and 3 after surgery to assess the rate of bone integration. The cortical specimens were mechanically tested and processed for PMMA histology and histomorphometry after 4 or 12 weeks. The cancellous samples were also processed for PMMA histology and histomorphometry. The three types of bone labels were visualized under UV light to examine the rate of new bony integration.

At 4 weeks, a 42% increase in average pull-out shear strength between nanotube treated specimens and non-nanotube treated specimens was shown. A 21% increase in average pull-out shear strength between nanotube treated specimens and hydroxyapatite-coated specimens was shown. At 12 weeks, all specimens had statistically similar pull-out values. Bone labels demonstrated new bone formation into the porous domains on the materials as early as 2 weeks.

A separate in vivo study on 8 rabbits infected with methicillin-resistant Staphylococcus aureus showed bacterial colonization reduction on the surface of the implants treated with TNT. In vitro and in vivo evidence suggests that nanoscale surfaces have an antibacterial effect due to surface energy changes that reduce the ability of bacteria to adhere.

These in vivo studies show that TNT on highly porous AM specimens made from Ti6Al4V enhances new bone integration and also reduce microbial attachment.


Orthopaedic Proceedings
Vol. 100-B, Issue SUPP_6 | Pages 5 - 5
1 Apr 2018
Justin D Friedrich C Bhosle S Baker E Jin S Pratt C
Full Access

Titanium knee, shoulder and hip implants are typically grit-blasted, thermal plasma spray coated, or sintered to provide ingrowth surface features having texture with pore sizes on the order of hundreds of micrometers. This provides macro and micro-mechanical locking upon bone remodeling. However, at the nanoscale and cellular level, these surfaces appear smooth. In vitro and in vivo research shows surfaces with nanoscale features result in enhanced osseointegration, greater bone-implant contact area and pullout force, and the potential to be bactericidal via a simple hybrid anodization surface modification process. Prior processes for creating nanotube nano-textured surfaces via electrochemical anodization relied on hydrofluoric acid electrolyte and platinum cathodes. This novel process uses ammonium fluoride electrolytes and graphite cathodes which are more cost effective and easier to handle during processing. Hybrid electrolytes with differing concentrations of ethylene glycol, water, and ammonium fluoride provide a variety of nanotube morphologies and sizes. Nano-tubular surfaces on knee tibial and femoral implants, hip stems and acetabular cups, bone screws and other 3D printed parts have been enhanced by this method of nano-texturing in as little as 30 minutes.

In vivo work in a Sprague Dawley rat model showed bone-implant contact area up to 2.9-times greater, and uniaxial pullout forces up to 6.9-times greater, than implanted smooth titanium controls at 4 and 12-week time points. In these tests, 1.25mm Kirschner wires were implanted in the rat femora to simulate an intramedullary nail. Histomorphometry in the mid-shaft and distal regions showed greater trabecular thickness and bone tissue mineral density than controls. Axial pullout tests often resulted in bone failure before the bone-implant interface.

In vitro evidence suggests that nanoscale surfaces may have an antibacterial effect due to surface energy changes that reduce the ability of bacteria to adhere. However, it is recognized that silver is highly antibacterial in appropriate concentrations. It is also recognized that nanosilver, approximately 10–20nm, is especially effective. Ammonium fluoride anodization is modified using a hybrid electrolyte that includes silver fluoride. By substituting some of the ammonium fluoride with silver fluoride, to maintain a constant total fluorine mass, nanosilver is integrated within and among the nanotubes in the same single process that forms the nanotubes.

This hybrid process in nano-texturing titanium implants can be integrated into current manufacturing production at low cost.


Orthopaedic Proceedings
Vol. 99-B, Issue SUPP_4 | Pages 38 - 38
1 Feb 2017
Justin D Pratt C Jin S Shivaram A Bose S Bandyopadhyay A
Full Access

Introduction

Titanium (Ti) alloys are used as porous bone ingrowth materials on non-cemented knee arthroplasty tibial tray implants. Nano-surface mechanism that increase the osseointegration rate between Ti alloys, and surrounding tissue has been recognized to improve the interface to ultimately allow patients to weight bear on non-cemented arthroplasty implants sooner. Bioactive TiO2 nanotube arrays has been shown to accelerate osseointegration. Ideally, these surfaces would both increase the adhesion of bone to the implant and help to reduction of infection to substitute for antibiotic bone cement. This study examines a combination treatment of both TiO2 nanotubes combined with silver nano-deposition, that simultaneously enhances osseointegration while improving infection resistance, by testing ex vivo implantation stability in an equine cadaver bone followed by in vitro and in vivo analysis to understand the biocompatibility and early stage osseointegration.

Methods

100nm diameter and 300nm length TiO2 nanotubes were formed on a CP titanium surface using anodization method at 20V for 45mins using 1% HF electrolyte. Silver deposition on TiO2 nanotubes were performed using 0.1M AgNO3 solution at 3V for 45s. Figure 1 shows SEM images showing (a) TiO2 nanotubes of 300nm length and (b) nanotubes with silver coating). Ti anodized samples with and without silver nanotubes implanted into an equine cadaver bone in an ex vivo manner to study the stability of nanotubes and the adherence of silver deposition. Silver release study was performed for a period of 14 days in a similar ex vivo manner. Dimensions for implantation samples: 2.5 mm diam. × 15 mm. For cell culture, circular disc samples 12.5mm in diameter and 3 mm in thickness were used to study the bone cell-material interactions using human fetal osteoblast (hFOB) cells. To evaluate the cell proliferation, MTT (3-(4, 5-dimethylthiazol-2-yl)-2, 5-diphenyl tetrazolium bromide) assay was used. The in vitro cell-materials interaction study was performed for a period of 4 and 7 days. In vivo study was performed using rat distal femur model for a period of 12 weeks with dense Ti samples as control (Sample dimensions: 3mm diam. × 5mm). At the end of 12 weeks, the samples were analyzed for early stage osseointegration using histological analysis and SEM imaging.


Orthopaedic Proceedings
Vol. 98-B, Issue SUPP_8 | Pages 71 - 71
1 May 2016
Justin D Jin S Frandsen C Brammer K Bjursten L Oh S Pratt C
Full Access

Introduction

Recent advances in nano-surface modification technologies are improving osseointegration response between implant materials and surrounding tissue. Living cells have been shown to sense and respond to cues on the nanoscale which in turn direct stem cell differentiation. One commercially practical surface treatment technique of particular promise is the modification of titanium implant surfaces via electrochemical anodization to form arrays of vertically aligned, laterally spaced titanium oxide (TiO2) nanotubes on areas of implants where enhanced implant–to-bone fixation is desired. Foundational work has demonstrated that the TiO2 nanotube surface architecture significantly accelerates osteoblast cell growth, improves bone-forming functionality, and even directs mesenchymal stem cell fate. The initial in vitro osteoblast cell response to such TiO2 nanotube surface treatments and corresponding in vivo rabbit tissue response are evaluated.

Methods

Arrays of 30, 50, 70, 100nm diameter TiO2 nanotubes formed onto titanium surfaces were compared to grit blasted titanium controls in vitro (Figure 1). SEM micrographs of bovine cartilage chondrocytes (BCCs) on the nanotube surfaces were evaluated after 2 hours, 24 hours, and 5 days of culture. Additionally 20 samples each of various nanotube diameters and the non-nanotube treated titanium controls were evaluated after exposure to human mesenchymal stem cell (hMSC) after 2 hours and 24 hours.

The left tibia and right tibia of four rabbits were implanted with disk shaped titanium implants (5.0 mm dia. × 1.5 mm) with and without TiO2 nanotubes. The front side of each implant faced the rabbit tibia bone and the back side of the implant had screw holes for post-in vivo tensile testing. After 4 weeks, the bones with implants were retrieved for mechanical testing and histology analysis.

Comparative osteogenic behavior on metal oxide nanotube surfaces applied to other implant material surface chemistries including ZrO2, Ta, and Ta2O5 were also evaluated along with TiO2 nanotubes formed on a thin films of titanium on the surface of zirconia and CoCr alloy orthopedic implants.