Epidemiological studies have shown that accumulated mechanical stress is a risk factor for the development of osteoarthritis (OA). This debilitating progressive clinical condition affects a broad spectrum of patients and will ultimately lead to definitive arthroplasty surgery as the endpoint treatment option in many cases. The aim of this study is to establish a graded murine model of OA by medial meniscotibial destabilisation of the knee joint and in phase two, to investigate the migration and engraftment of radioisotope labeled mesenchymal stem cells (MSCs) at varying points of disease progression. The first phase of the study was to establish the murine model, an Irish first. All procedures were performed aseptically under general anaesthesia via a midline medial parapatellar approach on a murine fracture table. Microsurgical dissection was performed through necropsy analysed layers to the joint space and the meniscotibial ligament identified and transected. Validated histopathological analysis was performed at two, four, eight and twelve weeks postoperatively. The results showed a gradation of OA changes from mild unicondylar changes at two weeks, moderate unicompartmental change at four, severe unicompartmental change at eight and severe bicompartmental change at twelve weeks post-operatively. In vivo Bazooka-Single Photon Emission Computed Tomography (SPECT) (Phase 2) imaging studies are currently ongoing following the model establishment.

Introduction

Ischaemia reperfusion injury (IRI) is a very common metabolic insult in orthopaedics. It is often a subtle clinical event such as after brief tourniquet use, however severe injury, even multi-organ failure or death may result from prolonged tourniquet-use, crush injuries, vascular trauma or the release of compartment-syndrome. IRI is mediated by leukocyte infiltration and oxidatively-induced endothelial disruption. Antioxidants clearly attenuate or prevent this effect in animal models.

Background

70% of Breast Cancer patients develop metastatic bone deposits, predominantly spinal metasases. Adult Mesenchymal Stem Cells (MSCs) are multiprogenitor stem cells found within the bone marow which have the ability to self renew and differentiate into multiple cell types. MSCs home specifically to tumour sites, highlighting their potential as delivery vehicles for therapeutic agents. However studies show they may also increase tumour metastatic potential.

Over 80% of patients with advanced breast cancer will develop bone metastases for which there is no cure. Although thought to involve a complex cascade of cell-cell interactions, the factors controlling the development of bone metastases are still poorly understood. Osteoblasts may have an important role in mediating homing and proliferation of breast cancer cells to the bony environment.

This study aimed to examine the potential role osteoblasts have in the migration of circulating tumour cells to bone and the factors involved in this attraction.

Culture of osteoblasts and MDA-MB-231 breast cancer cells was performed. Breast cancer cell migration in response to osteoblasts was measured using Transwell Migration Inserts. Potential mediators of cell migration were detected using ChemiArray & ELISA assays. A luminometer based Vialight assay was used to measure breast cancer cell proliferation in response to factors secreted by osteoblasts.

There was a 3-4 fold increase of MDA-MB-231 migration in response to osteoblasts. ChemiArray analysis of osteoblast-conditioned medium revealed a range of secreted chemokines including IL-6 & 8, TIMP 1 & 2 and MCP-1. Initially, MCP-1 was quantified at 282 pg/ml, but rose to over 9000 pg/ml when osteoprogenitor cells were differentiated into mature osteoblasts. Inclusion of a monoclonal antibody to MCP-1 in osteoblast-conditioned medium resulted in a significant decrease in breast cancer cell migration to osteoblasts. There was no significant change in proliferation of MDA-MB 231 cells when exposed to osteoblast-conditioned medium.

Osteoblasts are capable of inducing breast cancer cell migration mediated at least in part by chemokine secretion. MCP-1 produced by the osteoblasts was shown to play a central role in mediating homing of the breast cancer cells. Increased understanding of the pathways involved in the development of bone metastases may provide new targets for therapeutic intervention.