Introduction. Nonunion is a common and costly fracture outcome. Intricate reciprocity between angiogenesis and osteogenesis means vascular cell-based therapy offers a novel approach to stimulating bone regeneration. Hypothesis. The current study compared early and late outgrowth endothelial progenitor cell subtypes (EPCs vs OECs) for fracture healing potential in vitro and in vivo. Methods. Primary cell cultures were isolated and characterized by endothelial assays, immunosorbent assays, and multi-color flow cytometry. Co-cultures of EPC subtypes with/without primary osteoblasts (pObs) were analyzed for tube length and connectivity. In vivo, EPCs or OECs (1×10. 6. ) seeded on a gelfoam scaffold were implanted in a rat model of nonunion. Radiography was used to monitor callus formation. Results. OECs expressed more BMP-2 and less VEGF than EPCs (p<0.05). Analysis of surface markers showed decreased CD34+/CD133+/Flk-1+, CD133+ and CD45+ populations in OECs while CD34+/CD31+/Flk-1+ cells increased. pObs significantly inhibited the strong tubulogenesis of OECs while enhancing connectivity and sprout length of EPCs. In vivo, 0/6 scaffold-control and 1/5 OEC rats achieved union at 10 weeks. In comparison, all EPC rats achieved full or partial union. Discussion and Conclusion. Despite favorable tubulogenic and osteoconductive profiles of OECs, EPCs display enhanced fracture healing in vivo. Differences in CXCR4 expression and cell-mediated effects may contribute to this result

Mesenchymal stem cells (MSCs) reside around blood vessels in all organs. This reservoir of progenitors can be ‘recruited’ in response to injury. The ability to manipulate stem cells therapeutically within injured tissue provides an attractive alternative to transplantation. Stem cells are regulated by neighbouring cells. We hypothesized that endothelial cells (ECs) influence MSC differentiation into bone and fat. MSCs were sorted from fat using fluorescent activated sorting. Their capacity to differentiate into bone, fat and cartilage was used to confirm MSC phenotype. MSCs and ECs were cultured in two-dimensions (standard culture dishes) and three-dimensions (vascular networks suspended in gel). Cocultures were exposed to osteogenic and adipogenic media. The role of EC-released factors on MSC differentiation was determined using a system in which cells share media but do not contact. Wnt pathway modulators were used to investigate the role of Wnt signalling. MSCs differentiated into bone, fat and cartilage. MSCs and ECs integrated in two- and three-dimensions. MSCs and ECs formed vessel-like structures in three-dimensions. When cultured with ECs, MSC differentiation to bone was accelerated while differentiation to fat was inhibited. This effect on osteogenesis was maintained when cells shared media but did not contact. Coculture with Wnt modulators confirmed that this effect is in part, mediated through Wnt signalling. Our data suggest that ECs influence MSC differentiation. Therapeutic targeting of EC-MSCs signalling may enable manipulation of MSCs in vivo avoiding the need for cell transplantation. This could enable trauma and orthopaedic patients who have healthy resident stem cells to self-repair

Perivascular stem cells (PSCs) from lipoaspirate demonstrate increased purity and immaturity with greater engraftment potential than standard mesenchymal stem cells (MSCs). MSCs from the infra-patellar fat pad (IFP) have previously demonstrated increased chondrogenic potential. This study investigated the availability and potential of PSCs harvested from the infra-patellar fat pad of the human knee for musculoskeletal regeneration. Tissue sections of IFP were stained with markers for PSCs, MSCs and endothelial cells to confirm their presence and location. Samples were obtained from patients undergoing TKR (n=13) or ACL reconstructions (n=10). Pericytes and adventitial cells made up 3.8% and 21.2% respectively of the stromal vascular fraction. The total number of pericytes and adventitial cells were 4.6±2.2×104 and 16.2±3.2×104 respectively. Cells were cultured both separately and combined. Cell identity was ascertained using fluorescence-activated cell sorting, immunocytochemistry and PCR. Cultured PSCs were differentiated using chondrogneic, osteogenic, adipogenic and myogenic medias. Differentiation was determined using Alcian Blue, Alizarin red, Oil Red O and myosin staining. This study demonstrates that the IPFP is a viable source of PSCs that can be harvested either arthroscopically or through an arthrotomy by orthopaedic surgeons for cell-based musculoskeletal regeneration. Their potential now needs to be compared to conventional MSCs

Perivascular stem cells (PSCs) from lipoaspirate demonstrate increased purity and immaturity with greater engraftment potential than standard mesenchymal stem cells (MSCs). MSCs from the infra-patellar fat pad (IFP) have previously demonstrated increased chondrogenic potential. This study investigated the availability and potential of PSCs harvested from the infra-patellar fat pad of the human knee for musculoskeletal regeneration. Sections of IFP were stained with markers for PSCs, MSCs and endothelial cells to confirm their presence and location. Samples were obtained from patients undergoing TKR (n=13) or ACL reconstructions (n=10). Pericytes and adventitial cells made up 3.8% and 21.2% respectively of the stromal vascular fraction. The total number of pericytes and adventitial cells were 4.6±2.2×10. 4. and 16.2±3.2×10. 4. respectively. Cells were cultured both separately and combined. Cell identity was ascertained using fluorescence-activated cell sorting and immunocytochemistry. Cultured PSCs were differentiated using chondrogneic, osteogenic, adipogenic and myogenic medias. Differentiation was determined using Alcian Blue, Alizarin red, Oil Red O and mysosin staining. This study demonstrates that the IFP is a viable source of PSCs that can be harvested either arthroscopically or through an arthrotomy by orthopaedic surgeons for cell-based musculoskeletal regeneration. Their potential now needs to be compared to conventional MSCs

We hypothesise that the Masquelet induced membrane used for the reconstruction of large bone defects were likely to involve mesenchymal stem cells (MSCs), given the excellent resultant skeletal repair. This study represents the first characterisation in humans of the induced membrane formed as a result of the Masquelet technique. Methods. Induced membranes and matching periosteum were harvested from 7 patients. Cytokines (BMP2, VEGF, SDF1) and cell lineage markers (CD31, CD271, CD146) were studied by immunohistochemisty. Flow cytometry was used to measure the cellularity and cellular composition. MSCs were enumerated using a colony forming unit fibroblast assay. In expanded cultures, a 96-gene array card was used to assess their transcriptional profile. Alkaline phophatase, alizarin red and calcium assays were employed to measure their in vitro osteogenic potential. Results. Membrane was more cellular(p=0.028), had more MSC phenotype(p=0.043) compared to matched periosteum. The molecular profiles were similar, except for 2-fold abundance of SDF-1 in membrane (p=0.043)compared to periosteum. Membrane and periosteum had a similar proportion of endothelial cells and CFU-F colonies; expanded MSCs from both sources were highly osteogenic. Discussion. These results indicate that the induced membrane possesses a rich source of MSC and therefore our findings support the view that the induced membrane plays an active role in bone regeneration

Exsanguination is the second most common cause of death in patients who suffer severe trauma. The management of haemodynamically unstable high-energy pelvic injuries remains controversial, as there are no universally accepted guidelines to direct surgeons on the ideal use of pelvic packing or early angio-embolisation. Additionally, the optimal resuscitation strategy, which prevents or halts the progression of the trauma-induced coagulopathy, remains unknown. Although early and aggressive use of blood products in these patients appears to improve survival, over-enthusiastic resuscitative measures may not be the safest strategy.

This paper provides an overview of the classification of pelvic injuries and the current evidence on best-practice management of high-energy pelvic fractures, including resuscitation, transfusion of blood components, monitoring of coagulopathy, and procedural interventions including pre-peritoneal pelvic packing, external fixation and angiographic embolisation.

Cite this article: Bone Joint J 2014; 96-B:1143–54.