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Orthopaedic Proceedings
Vol. 102-B, Issue SUPP_5 | Pages 42 - 42
1 Jul 2020
Lotfi N Hughes E McCulloch R Horner C Shepherd D Grover L Nightingale P Davis E
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Polymethylmethacetate (PMMA) is a bone cement used in over 725,000 primary hip arthroplasties in 2018. Cement integrity is affected by external factors, including temperature, mixing technique and moisture uptake, which can influence cement microstructure. Changes in the cement microstructure may ultimately threaten the survivorship of the implant.

The introduction of enhanced recovery and various local anaesthetic infiltration techniques have been adopted in an attempt to facilitate early mobilisation and reduce length of stay. Our study aims to investigate if the mechanical properties of PMMA are altered with exposure to Ropivacaine LA.

Cements were cured in three separate states (air, serum and serum with LA) and the mechanical properties tested at 24 hours and 28 days. Using Refobacin bone cement provided by ZimmerBIOMET, cylindrical molds (12×6mm) were constructed with a split-mold. The LA used was 2mg/ml Ropivacaine hydrochloride solution. Using pilot data, this study was powered to 80% and a sample size of 10 per group (n=60) was calculated.

Cement samples were subjected to compressive loading using a universal testing apparatus (Zwick/Roell). Yield-strength and modulus values were extracted from the respective stress versus strain curves. Significant differences were determined by one-way anova for each time point, and Bonferroni post-hoc testing to determine significance between actual groups.

At 24-hours there were no significant differences in strength or modulus between groups. At 28-day strength and modulus increased in all groups. Compared to the air group, both serum and LA groups show a significant decrease in compressive strength. The modulus for the LA group is significantly less stiff compared to the air group.

The results suggest that the initial exposure to LA has a significant impact on the physical properties of the PMMA. We propose increased awareness of the potential effects this may have on the longevity and survivorship of cemented implants.


Orthopaedic Proceedings
Vol. 100-B, Issue SUPP_4 | Pages 47 - 47
1 Apr 2018
Hughes E Williams R Cooke M Hall T Cox S Grover L
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Background

Bone is a hierarchically structured hard tissue that consists of approximately 70 wt% low-crystallinity hydroxyapatite. Intricate tubular channels, such as Haversian canals, Volkman's canals, and canaliculi are a preserved feature of bone microstructure. These structures provide pathways for vasculature and facilitate cell-to-cell communication processes, together supporting viability of cellular components and aiding in remodeling processes. Unfortunately, many commercial bone augmentation materials consist of highly crystalline phases that are absent of the structuring present within the native tissue they are replacing. This work reports on a the development of a novel bone augmentation material that is able to generate biologically analogous tubular calcium phosphate mineral structures from hydrogel-based spheres that can be packed into defects similar to those encountered in vivo.

Experimental

Calcium loaded spheres were made by adding 5 wt% agar powder to 1 M calcium nitrate solutions, before heating the mixture to 80–90 oC and feeding droplets of gel into a reservoir of liquid nitrogen. Deposition of tubular mineral was initiated by exposure to ammonium phosphate solutions at concentrations between 500 mM and 1 M, and was characterized by micro-XRF mapping, XRD and SEM techniques. For an ex vivo model, human bone tissue was collected from patients undergoing elective knee replacement surgery. The United Kingdom National Research Ethics Service (East of Scotland Research Ethics Service) provided ethical approval (11/ES/1044). The augmented defect of the model was characterised by micro-XRF mapping and micro-CT techniques.


Orthopaedic Proceedings
Vol. 99-B, Issue SUPP_8 | Pages 85 - 85
1 Apr 2017
Hughes E Williams R Chouhan G Jamshidi P Grover L
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Background

Calcium orthophosphates, such as hydroxyapatite (Ca5(PO4)3OH) (HA), have long been employed as bone graft materials. Recent work has suggested that calcium pyrophosphate (Ca2P2O7) (CaPy) may strongly stimulate bone deposition. In this study we compare calcium orthophosphate and pyrophosphate precipitates as suitable bone regeneration materials. As well as HA, two forms of pyrophosphate precipitate were compared in this work: amorphous calcium pyrophosphate (amCaPy) and star particle calcium pyrophosphate (stCaPy).

Methods

Briefly, 0.15M Na4P2O7·10H2O and 0.3M Ca2Cl·2H2O solutions of equivalent volume were combined and left to age before performing a series of filtration and re-suspension steps upon the precipitate. Drying yielded amCaPy powder. stAmPy was produced by the same procedure however the pH of the starting solutions were altered to pH7 before combination.