Poly-ether-ether-ketone (PEEK) is a biomaterial commonly used for spinal implants and screws. It is often desirable for orthopaedic implants to osseointegrate, but as PEEK is biologically inert this will not occur. The aim of this project was to determine if injection mould nanopatterning can be used to create a make PEEK bioactive and stimulate osteogenesis in vitro.

PEEK substrates were fabricated by injection mould nanopatterning to produce near-square (NSQ) nanopatterned PEEK and planar (FLAT) PEEK samples. Atomic force microscopy (AFM) and scanning electron microscopy were used to characterize the surface topography. Human bone marrow stromal cells (hBMSCs) were isolated from patients undergoing primary hip replacement operations and seeded onto the PEEK substrates. After 6 weeks the cells were stained using alizarin red S (ARS) stain (to detect calcium) and the von Kossa technique (to detect phosphate) and analyzed using CellProfiler image analysis software to determine: surface coverage; cell number; and expression of either calcium (ARS stain) or phosphate (von Kossa technique).

ARS stain showed calcium expression (quantified relative to the number of cells) was increased on NSQ PEEK compared to FLAT PEEK (not statistically significant) and the surface coverage was similar. Von Kossa staining revealed more surface coverage on FLAT PEEK (69.1% cf. 31.9%), cell number was increased on FLAT PEEK (9803 ± 4066 cf. 4068 ± 1884) and phosphate expression relative to cell number was also increased (seven-fold) on NSQ PEEK (P < 0.05) compared to FLAT PEEK.

Although hBMSCs may adhere to NSQ PEEK in smaller numbers, the cells expressed a relatively larger amount of calcium and phosphate. This indicates that the cells adopted a more osteoblastic phenotype and that nanopatterning PEEK induces hBMSC differentiation and stimulates osteogenesis. Injection mould nanopatterning therefore has the potential to improve osseointegration of PEEK implants in vivo.

Polyetheretherketone (PEEK) is a thermoplastic polymer that is predominant in spinal surgery as the material of choice for spinal fusion cages, and is also used for bone anchors, cruciate ligament interference screws, and femoral stems. It has the distinct advantage of having similar mechanical properties to bone, but its clinical application as implant material is limited by a lack of bioactivity. This project aims to create an PEEK surface capable of osseointegration using a surface modification technique known as oxygen plasma treatment.

PEEK surfaces were injection molded, washed and then treated in a plasma chamber for up to 10 min. Surfaces were characterised using atomic force microscopy (AFM), scanning electron microscopy (SEM), water contact angle measurements and X-ray photo-electron spectroscopy (XPS). Human bone marrow cells were cultured on the surfaces and assessed for calcium production (using alizarin red stain).

Water contact angle measurements show that after plasma treatment, the surfaces become very hydrophilic, before developing a meta-stable state at approx. 6 weeks. AFM and SEM showed destruction of the nano-pits at treatment durations longer than 2 mins. XPS detected a progressive increase in the atomic proportion of oxygen at the surface with increasing plasma treatment duration. There was significantly less alizarin uptake (and hence calcium production) on the untreated PEEK compared to the plasma treated PEEK surfaces (p < 0.05).

These results show that oxygen-plasma treatment can increase calcium production on PEEK surfaces and may improve long term osseointegration of PEEK implants.

Aim: In order to avoid complications of hip arthroplasty such as dislocation, impingement and eccentric liner wear accurate acetabular orientation is essential. The three-dimensional assessment of acetabular cup orientation using two-dimensional plain radiographs is inaccurate. The aim of this study was to develop a CT-based protocol to accurately measure postoperative acetabular cup inclination and anteversion establishing which bony reference points facilitate the most accurate estimation of these variables.

Methods: An all-polyethylene acetabular liner was implanted into a cadaveric acetabulum. A conventional pelvic CT scan was performed and reformatted images created in both functional and anterior pelvic planes. CT images were transferred to a Freedom-Plus Graphics software package enabling an identical, virtual, three dimensional model of the cadaveric pelvis to be created. Using a computer interface this model could be ‘palpated’, bony landmarks accurately identified and definitive acetabular cup orientation established. Using original CT scans, acetabular cup inclination and anteversion were measured on five occasions by eight radiographers using differing predetermined bony landmarks as reference points. The intra- and inter-observer variation in measurement of acetabular cup orientation using varying bony reference points was assessed in comparison to the previously elucidated definitive cup position. Statistical analysis using appropriate ANOVA models was performed in order to assess the significance of the results obtained.

Results: Virtually derived definitive acetabular cup orientation was measured showing cup inclination and anteversion as 41.0 and 22.5 degrees respectively. Mean CT-based measurement of cup inclination and anteversion by eight radiographers were 43.1 and 20.8 degrees respectively. No statistically significant difference was found in intra- and inter-observer recorded results. No statistically significant differences were found when using different bony landmarks for the measurement of inclination and anteversion (p= 0.255 and 0.324 respectively).

Conclusions: CT assessment of acetabular component inclination and anteversion is accurate, reliable and reproducible when measured using differing bony landmarks as reference points. We recommend measuring acetabular inclination and anteversion from the inferior acetabular wall/teardrop and posterior ischium respectively. The Perth CT hip protocol is easily reproducible in the clinical setting both in the routine assessment of hip arthroplasty patients and as research tool. In our unit its initial application will be to validate commercially available hip navigation systems.

A non-invasive method of electrical stimulation of healing in ununited fractures of the tibia by pulsed magnetic fileds has been evaluated. In a series of 17 patients all but two of the fractures united within 4 to 10 months, with an average time of just under six months. The method is sufficiently promising to merit further clinical investigation.