Evaluation of Osteoconductive Scaffolds in the Canine Femoral Multi-Defect Model

Treatment of large segmental bone defects remains an unsolved clinical challenge, despite a wide array of existing bone graft materials. This project was designed to rapidly assess and compare promising biodegradable osteoconductive scaffolds for use in the systematic development of new bone regeneration methodologies that combine scaffolds, sources of osteogenic cells, and bioactive scaffold modifications. Promising biomaterials and scaffold fabrication methods were identified in laboratories at Rutgers, MIT, Integra Life Sciences, and Mayo Clinic. Scaffolds were fabricated from various materials, including poly(L-lactide-co-glycolide) (PLGA), poly(L-lactide-co-ɛ-caprolactone) (PLCL), tyrosine-derived polycarbonate (TyrPC), and poly(propylene fumarate) (PPF). Highly porous three-dimensional (3D) scaffolds were fabricated by 3D printing, laser stereolithography, or solvent casting followed by porogen leaching. The canine femoral multi-defect model was used to systematically compare scaffold performance and enable selection of the most promising substrate(s) on which to add cell sourcing options and bioactive surface modifications. Mineralized cancellous allograft (MCA) was used to provide a comparative reference to the current clinical standard for osteoconductive scaffolds. Percent bone volume within the defect was assessed 4 weeks after implantation using both MicroCT and limited histomorphometry. Bone formed at the periphery of all scaffolds with varying levels of radial ingrowth. MCA produced a rapid and advanced stage of bone formation and remodeling throughout the defect in 4 weeks, greatly exceeding the performance of all polymer scaffolds. Two scaffold constructs, TyrPC[subscript PL]/TCP and PPF4[subscript SLA]/HA[subscript PLGA Dip], proved to be significantly better than alternative PLGA and PLCL scaffolds, justifying further development. MCA remains the current standard for osteoconductive scaffolds.United States. Army Medical Research and Materiel Command (Armed Forces Institute of Regenerative Medicine)United States. Office of Naval ResearchUnited States. Air Force. Office of the Surgeon GeneralUnited States. NavyNational Institutes of Health (U.S.)United States. Veterans AdministrationCleveland Clinic Foundatio

GDNF Schwann cells in hydrogel scaffolds promote regional axon regeneration, remyelination and functional improvement after spinal cord transection in rats

Positively-charged oligo[poly(ethylene glycol)fumarate] (OPF+) is a biodegradable hydrogel used for spinal cord injury repair. We compared scaffolds containing primary Schwann cells (SCs) to scaffolds delivering SCs genetically modified to secrete high concentrations of glial cell-derived neurotrophic factor (GDNF). Multichannel OPF+ scaffolds loaded with SCs or GDNF-SCs were implanted into transected rat spinal cords for 4 weeks. GDNF-SCs promoted regeneration of more axons into OPF+ scaffolds (2773.0 +/- 396.0) than primary SC OPF+ scaffolds (1666.0 +/- 352.2) (p = 0.0491). This increase was most significant in central and ventral-midline channels of the scaffold. Axonal remyelination was quantitated by stereologic analysis. Increased myelination of regenerating axons was observed in the GDNF-SC group. Myelinating cell and axon complexes were formed by host SCs and not by implanted cells or host oligodendrocytes. Fast Blue retrograde tracing studies determined the rostral-caudal directionality of axonal growth. The number of neurons that projected axons rostrally through the GDNF-SC scaffolds was higher (7929 +/- 1670) than in animals with SC OPF+ scaffolds (1069 +/- 241.5) (pThis work was supported by the National Institutes of Health (EB002390) (A. J. W.), the Wilson, Morton and Mayo Foundations (A. J. W.) and the Health Research Board of Ireland (RP/2007/143) (N. M. and S. S. M.). We thank Thomas Ritter, National University of Ireland, Galway, for supplying source plasmids, James Tarara at Mayo Clinic for expertise in confocal microscopy, and Andrew Knight and Trent Chiang for the GDNF ELISA studies. We thank Ann Schmeichel and Shuya Zhang for expertise in immunohistochemistry, Jarred Nesbitt for expert animal care and Jane Meyer for her role in manuscript preparation.peer-reviewe

Fibroblast growth factor-2 and vascular endothelial growth factor mediated augmentation of angiogenesis and bone formation in vascularized bone allotransplants

We previously demonstrated recipient-derived neoangiogenesis to maintain viability of living bone allogeneic transplants without long-term immunosuppression. The effect of cytokine delivery to enhance this process is studied. Vascularized femur transplantation was performed from Dark Agouti to Piebald Virol Glaxo rats. Poly(d,l-lactide-co-glycolide) microspheres loaded with buffer (N = 11), basic fibroblast growth factor (FGF2) (N = 10), vascular endothelial growth factor (VEGF) (N = 11), or both (N = 11) were inserted intramedullarly alongside a recipient-derived arteriovenous bundle. FK-506 was administered for 2 weeks. At 18 weeks, bone blood flow, microangiography, histologic, histomorphometric, and alkaline phosphatase measurements were performed. Bone blood flow was greater in the combined group than control and VEGF groups (P = 0.04). Capillary density was greater in the FGF2 group than in the VEGF and combined groups (P  < 0.05). Bone viability, growth, and alkaline phosphatase activity did not vary significantly between groups. Neoangiogenesis in vascularized bone allotransplants is enhanced by angiogenic cytokine delivery, with results using FGF2 that are comparable to isotransplant from previous studies. Further studies are needed to achieve bone formation similar to isotransplants. © 2014 Wiley Periodicals, Inc. Microsurgery 34:301-307, 201

GDNF Schwann cells in hydrogel scaffolds promote regional axon regeneration, remyelination and functional improvement after spinal cord transection in rats

Positively-charged oligo[poly(ethylene glycol)fumarate] (OPF+) is a biodegradable hydrogel used for spinal cord injury repair. We compared scaffolds containing primary Schwann cells (SCs) to scaffolds delivering SCs genetically modified to secrete high concentrations of glial cell-derived neurotrophic factor (GDNF). Multichannel OPF+ scaffolds loaded with SCs or GDNF-SCs were implanted into transected rat spinal cords for 4 weeks. GDNF-SCs promoted regeneration of more axons into OPF+ scaffolds (2773.0 +/- 396.0) than primary SC OPF+ scaffolds (1666.0 +/- 352.2) (p = 0.0491). This increase was most significant in central and ventral-midline channels of the scaffold. Axonal remyelination was quantitated by stereologic analysis. Increased myelination of regenerating axons was observed in the GDNF-SC group. Myelinating cell and axon complexes were formed by host SCs and not by implanted cells or host oligodendrocytes. Fast Blue retrograde tracing studies determined the rostral-caudal directionality of axonal growth. The number of neurons that projected axons rostrally through the GDNF-SC scaffolds was higher (7929 +/- 1670) than in animals with SC OPF+ scaffolds (1069 +/- 241.5) (pThis work was supported by the National Institutes of Health (EB002390) (A. J. W.), the Wilson, Morton and Mayo Foundations (A. J. W.) and the Health Research Board of Ireland (RP/2007/143) (N. M. and S. S. M.). We thank Thomas Ritter, National University of Ireland, Galway, for supplying source plasmids, James Tarara at Mayo Clinic for expertise in confocal microscopy, and Andrew Knight and Trent Chiang for the GDNF ELISA studies. We thank Ann Schmeichel and Shuya Zhang for expertise in immunohistochemistry, Jarred Nesbitt for expert animal care and Jane Meyer for her role in manuscript preparation.peer-reviewe

In Vitro and In Vivo Correlation of BMP-2 Release Profiles from Complex Delivery Vehicles

Local sustained delivery of bioactive molecules from biomaterials is a promising strategy to enhance bone regeneration. To optimize delivery vehicles for bone formation, the design characteristics are tailored with consequential effect on BMP-2 release and bone regeneration. Complying with the 3R principles, the growth factor release is often investigated in vitro using several buffers to mimic the in vivo physiological environment. However, this remains an unmet need. Therefore, this study investigates the correlation between the in vitro and in vivo (IVIVC) BMP-2 release from complex delivery vehicles in several commonly used in vitro buffers: cell culture model, phosphate buffered saline, and a strong desorption buffer. The results from this study showed that the release environment affected the BMP-2 release profiles, creating distinct relationships between release versus time and differences in extent of release. According to the guidance set by the U.S. Food and Drug Administration (FDA), in vitro- in vivo correlation resulted in level A internal predictability for individual composites. Since the IVIVC was influenced by the BMP-2 loading method and composite surface chemistry, the external predictive value of the IVIVCs was limited. These results show that the IVIVCs can be used for predicting the release of an individual composite. However, the models cannot be used for predicting in vivo release for different composite formulations since they lack external predictability. Potential confounding effects of drug type, delivery vehicle formulations and application site should be added to the equation to develop one single IVIVC applicable for complex delivery vehicles. Altogether, these results imply that more sophisticated in vitro systems should be used in bone regeneration to accurately discriminate and predict in vivo BMP-2 release from different complex delivery vehicles

GDNF Schwann cells in hydrogel scaffolds promote regional axon regeneration, remyelination and functional improvement after spinal cord transection in rats

Positively-charged oligo[poly(ethylene glycol)fumarate] (OPF+) is a biodegradable hydrogel used for spinal cord injury repair. We compared scaffolds containing primary Schwann cells (SCs) to scaffolds delivering SCs genetically modified to secrete high concentrations of glial cell-derived neurotrophic factor (GDNF). Multichannel OPF+ scaffolds loaded with SCs or GDNF-SCs were implanted into transected rat spinal cords for 4 weeks. GDNF-SCs promoted regeneration of more axons into OPF+ scaffolds (2773.0 +/- 396.0) than primary SC OPF+ scaffolds (1666.0 +/- 352.2) (p = 0.0491). This increase was most significant in central and ventral-midline channels of the scaffold. Axonal remyelination was quantitated by stereologic analysis. Increased myelination of regenerating axons was observed in the GDNF-SC group. Myelinating cell and axon complexes were formed by host SCs and not by implanted cells or host oligodendrocytes. Fast Blue retrograde tracing studies determined the rostral-caudal directionality of axonal growth. The number of neurons that projected axons rostrally through the GDNF-SC scaffolds was higher (7929 +/- 1670) than in animals with SC OPF+ scaffolds (1069 +/- 241.5) (pThis work was supported by the National Institutes of Health (EB002390) (A. J. W.), the Wilson, Morton and Mayo Foundations (A. J. W.) and the Health Research Board of Ireland (RP/2007/143) (N. M. and S. S. M.). We thank Thomas Ritter, National University of Ireland, Galway, for supplying source plasmids, James Tarara at Mayo Clinic for expertise in confocal microscopy, and Andrew Knight and Trent Chiang for the GDNF ELISA studies. We thank Ann Schmeichel and Shuya Zhang for expertise in immunohistochemistry, Jarred Nesbitt for expert animal care and Jane Meyer for her role in manuscript preparation