Stromal stem cells and platelet-rich plasma improve bone allograft integration.

Early vascular invasion is a key factor in bone allograft incorporation. It may reduce the complications related to slow and incomplete bone integration. Bone-marrow-derived stromal stem cells associated with platelet-rich plasma are potent angiogenic inducers proven to release vascular endothelial growth factor. Our goal was to test whether the combination of stromal stem cells and platelet-rich plasma is able to increase massive allograft integration in a large animal model with sacrifice at 4 months. A critical defect was made in the mid-diaphysis of the metatarsal bone of 10 sheep; the study group received an allograft plus stromal stem cells, platelet-rich plasma, and collagen (six animals) and the control group received only the allograft (four animals). Investigation was done with radiographs, mechanical tests and histomorphometric analysis, including new vascularization. Results showed substantial new bone formation in the allograft of the study group. Bone formation is correlated with better vascular invasion and remodeling of the graft in the study group. These results confirm the key role played by stromal stem cells and platelet-rich plasma in bone repair. Further studies are needed to better define the role stromal stem cells play when implanted alone.

Platelet-derived growth factors enhance proliferation of human stromal stem cells.

Studies on new procedures for bone reconstruction suggest that autologous cells seeded on a resorbable scaffold can improve the treatment of bone defects. It is important to develop culture conditions for ex vivo expansion of stromal stem cells (SSC) that do not compromise their self-renewing and differentiation capability. Bone marrow SSC and platelet gel (PG) obtained by platelet-rich plasma provide an invaluable source for autologous progenitor cells and growth factors for bone reconstruction. In this study the effect of platelet-rich plasma (PRP) released by PG on SSC proliferation and differentiation was investigated. MTT assay was used to investigate the effect of PRP on proliferation: results showed that PRP induced SSC proliferation. The effect was dose dependent and 10% PRP is sufficient to induce a marked cell proliferation. Untreated cells served as controls. Upon treatment with 10% PRP, cells entered logarithmic growth. Removal of PRP restored the characteristic proliferation rate. Because SSC can gradually lose their capability to differentiate along the chondrogenic and osteogenic lineage during subculture in vitro, we tested whether 10% PRP treatment affected SSC ability to mineralize. SSC were first exposed to 10% PRP for five passages, at passage 6 PRP was washed away and plated cells were treated with dexamethasone (DEX). DEX induced a three-fold increase in the number of alkaline phosphatase positive cells and induced mineralization that is consistent with the differentiation of osteochondroprogenitor cells. In conclusion, 10% PRP promotes SSC proliferation; cells expanded with 10% PRP can mineralize the extracellular matrix once PRP is withdrawn.

Recovery of stromal stem cells in bone sarcoma patients after chemotherapy: implication for cell-based therapy in bone defect reconstruction.

Bone sarcomas, such as osteosarcoma (OS) or Ewing sarcoma (ES), frequently arise in the intramedullary region of long bones. Patients affected by bone sarcomas are treated with preoperative aggressive chemotherapy immediately after diagnosis. After chemotherapy, patients undergo surgery that frequently entails the excision of wide bone segments. If a large segment of the bone is lost (defined as a critical defect) the patient undergoes bone reconstruction. Because bone marrow derived stromal stem cells (SSC) offer great promise for cell-based regenerative medicine in bone reconstruction, we investigated whether SSC could be isolated from chemotherapy-treated bone sarcoma patients. We also investigated whether chemotherapy modified SSC differentiation capability. We studied 9 SSC derived from OS and ES patients that had undergone chemotherapy and 5 SSC derived from bone sarcoma patients that had not undergone chemotherapy. SSC could be obtained from all the patients analyzed regardless of whether the patients received chemotherapy or not. Our results also showed that post-chemotherapy SSC can be cultured and expanded ex vivo, these cells retained the ability to differentiate toward the osteogenic lineage in vitro. In conclusion, our results support that SSC cells can be obtained from bone sarcoma patients that undergo chemotherapy and suggest that SSC can be used for cell-based bone reconstruction techniques in bone sarcoma patients treated with preoperative chemotherapy.