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Orthopaedic Proceedings
Vol. 99-B, Issue SUPP_22 | Pages 98 - 98
1 Dec 2017
Diefenbeck M Bischoff S Lidén E Poh P van Griensven M Hettwer W
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Aim

A gentamicin-eluting biocomposite consisting of hydroxyapatite (HA) and calcium sulphate (CaS)*1 can provide effective dead space management and bone formation in chronic osteomyelitis. However, radiographic follow-up after implantation of this biomaterial has shown imaging features previously not described with other comparable bone graft substitutes. Last year we presented preliminary results with a follow-up of 6 months. Now we present the radiographic, µCT and histological one-year follow-up of the critical-size bone defect model in sheep. The aim of this study was to simulate the clinical situation in a large animal model to correlate different imaging techniques used in the clinic (Radiography, CT and MRI scans) with histological finding.

Methods

Standardised bone defects were created in ten Merino-wool sheep (age two to four years). Large drill holes (diameter 2.5cm, depth 2cm, volume approx. 10ml) were placed in the medial femoral condyles of both hind legs and filled with gentamicin-eluting biocomposite. Initially surgery was carried out on the right hind leg.

Three months later, an identical intervention was performed on the contralateral side. Animals were sacrificed at three and six weeks and 4.5, six and twelve months. Radiographs and MRI scans were taken immediately after sacrifice. Filled bone voids were harvested en-block and analysed using µCT, and histology.


Orthopaedic Proceedings
Vol. 97-B, Issue SUPP_16 | Pages 91 - 91
1 Dec 2015
Hettwer W Lidén E Kristensen S Petersen M
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Endoprosthetic reconstruction for pathologic acetabular fractures is associated with a high risk of periprosthetic joint infection. In this setting, bone defect reconstruction utilising co-delivery of a synthetic bone substitute with an antibiotic, is an attractive treatment option from both, therapeutic and prophylactic perspective. We wished to address some concerns that remain regarding the possible presence of potentially wear inducing particles in the periprosthetic joint space subsequent to this procedure.

We analysed a drain fluid sample from an endoprosthetic reconstruction of a pathologic acetabular fracture with implantation of a gentamicin eluting, biphasic bone graft substitute, consisting of 40% hydroxyapatite (HA) and 60% calcium sulphate (CERAMENT G), into the residual peri-acetabular bone defect. This sample was divided into two 1.5ml subsamples, to one of which 100mg HA particles were added as control before burning off all organic substance at very high temperature. These heat treated samples were then examined with scanning electron microscopy (SEM) and energy dispersive x-ray analysis (EDAX) and compared to a reference sample consisting of HA particles only.

On SEM, hydroxyapatite particles were readily recognisable in the control and reference samples, whereas only very few particles over 2μm were apparent in the ”pure” drain sample. EDAX revealed that very large amounts of salts were present in both drainage samples. The pure drainage sample however, contained markedly lower amounts of calcium and phosphate compared to reference and control samples. No HA particles as such, were seen in the pure sample, however their presence cannot be excluded with absolute certainty, as some particles might have been hidden within the large salt conglomerates.

We could not find clear evidence that the drain fluid really contained HA particles. More thorough investigations are needed and future analyses with prior removal of the high salt content would likely yield more conclusive results.