Post-natal vasculogenesis, the process by which vascular committed bone marrow stem cells or endothelial precursor cells migrate, differentiate and incorporate into the nacent endothelium and thereby contribute to physiological and pathological neurovascularisation, has stimulated much interest. Its contribution to neovascularisation of tumours, wound healing and revascularisation associated with ischaemia of skeletal and cardiac muscles is well established. We evaluated the responses of endothelial precursor cells in bone marrow to musculoskeletal trauma in mice.

Bone marrow from six C57 Black 6 mice subjected to a standardised, closed fracture of the femur, was analysed for the combined expression of cell-surface markers stem cell antigen 1 (sca-1⁺) and stem cell factor receptor, CD117 (c-kit⁺) in order to identify the endothelial precursor cell population. Immunomagnetically-enriched sca-1⁺ mononuclear cell (MNC^sca-1+) populations were then cultured and examined for functional vascular endothelial differentiation. Bone marrow MNC^{sca-1+,c-kit+} counts increased almost twofold within 48 hours of the event, compared with baseline levels, before decreasing by 72 hours.

Sca-1⁺ mononuclear cell populations in culture from samples of bone marrow at 48 hours bound together Ulex Europus-1, and incorporated fluorescent 1,1′-dioctadecyl- 3,3,3,’3′-tetramethylindocarbocyanine perchlorate-labelled acetylated low-density lipoprotein intracellularily, both characteristics of mature endothelium.

Our findings suggest that a systemic provascular response of bone marrow is initiated by musculoskeletal trauma. Its therapeutic manipulation may have implications for the potential enhancement of neovascularisation and the healing of fractures.

Aims: Pharmocological modulation of skeletal muscle reperfusion injury after an ischaemic insult may improve limb salvage rates and prevent the associated systemic sequelae. Activated Protein c (APC) is an endogenous anti-coagulant with anti-inflammatory properties. The purpose of our study was to evaluate the effects of APC on skeletal muscle ischaemia reperfusion injury and to examine the direct effects of APC on neutrophil activation.

Methods: Adult male Sprague Dawley rats (n=30) were randomised into three groups: control group, I/R group treated with normal saline and I/R treated with APC. Bilateral hind-limb ischaemia was induced by rubber ban application proximal to the level of the greater trochanters for two hours. Treatment groups received either normal saline or APC prior to tourniquet release. Following twelve hours reperfusion, the tibialis anterior was dissected and muscle function assessed electrophysiologically by electrical field stimulation. The animals were then sacrificed and skeletal muscle harvested for evaluation. Skeletal muscle injury was assessed based on myeloperoxidase content, wet-to-dry ratio and histological analysis. The effect of APC on TNF-α stimulated human peripheral blood neutrophils was also examined by measuring CD 18 expression and reactive oxygen species (ROS) generation.

Results: APC significantly attenuated skeletal muscle reperfusion injury as shown by reduced myeloperoxidase content, wet-to-dry ratio and electrical properties of skeletal muscle. These findings were supported by our histological findings. Our in-vitro work demonstrated a reduction in CD 18 expression and ROS generation.

Conclusion: Activated Protein C may have a protective role in the setting of skeletal muscle ischaemia reperfusion injury and this is in part mediated by a direct inhibitory effect on neutrophil activation.