Degenerative disc disease, associated to low back pain, afflicts more than 50% of humans, and represents a major healthcare problem, especially for the pathology initiation. Current treatments range from conservative strategies to more invasive surgical techniques, such as disc removal and vertebral fusion. In the Intervertebral Disease (IVD) the nucleus pulposus (NP) degeneration is a key factor for the pathology initiation. Several tissue engineering approaches aiming to restore the appropriate NP cell (NPCs) and matrix content, were attempted by using adult stromal cells either from bone marrow or adipose tissue, chondrocytes, notochordal cells and more recently also pluripotent stem cells. However, none was fully satisfactory since the NP acid and a-vascularized environment appeared averse to the implanted heterologous cells. Several studies demonstrated the efficacy of platelet derivatives such as platelet rich plasma (PRP) in promoting the regeneration of connective tissues. We investigated the efficacy of PRP on NPCs proliferation and differentiation with the goal to propose the direct stimulation of resident cells (stimulation of endogenous cells – less invasive surgical procedure) or the implantation of NPCs expanded in vitro in the presence of PRP as therapeutic agents in IVD degeneration.

NPCs were isolated from small fragments of NP explants, cultivated in medium supplemented with PRP or FCS (standard condition control) and characterized by FACS analysis for the expression of the typical mesenchymal stem cells markers CD34, CD44, CD45, CD73, CD90 and CD105. NPCs cultured in PL showed a phenotypic profile like the cells cultured in FCS. However, compared to NPCs expanded in the presence of FCS, NPCs expanded in PRP showed a much better proliferation and differentiation capacity. NPCs differentiation was evaluated by the cell ability to produce an organized metachromatic cartilaginous matrix, confirmed by the positive immunohistochemical staining for chondrogenic markers.

Large bone defect repair has always presented a difficult treatment problem. Marrow-derived osteogenic progenitor cells combined with hydroxyapatite (HA) were used for segmental bone reconstruction. The validity of this model has been shown for the repair of bone defects of critical size in large animal models. We used this cell-based therapeutic approach to treat three patients with large bone defects.

The patients were 41, 22 and 16 years old and had large tibial, ulnar and humeral diaphyseal gaps that ranged in size from 3.0 to 28.3 cm³. Marrow samples were harvested from the iliac crest and osteogenic progenitors isolated and expanded “ex vivo”. The expanded cells were then combined with a highly macroporous bioceramic scaffold whose size and shape reflected each individual bony defect. The cell/bioceramic composites were implanted at the lesion sites. External fixation was used to stabilise the grafts.

At present all patients have been followed up for 4–5 years. Already after the first month after surgery an initial integration at the bone/implant interface was evident. Bone formation in the implants, assessed by X-ray, progressed steadily in the follow-up period. Two patients achieved full functional recovery at 6 months after surgery, one patient at 12 months after surgery. The present report shows that large segmental bone reconstruction can be achieved in humans using osteoprogenitor cells. This technique can be improved by a more biodegradable and more biomechanically resistant scaffold use.