Your search keyword '"James P. Bertram"' showing total 3 results

1. Engineering angiogenesis following spinal cord injury: A coculture of neural progenitor and endothelial cells in a degradable polymer implant leads to an increase in vessel density and formation of the blood-spinal cord barrier

Author

Rebecca Robinson, Sara Royce Hynes, Millicent Ford Rauch, James P. Bertram, Joseph A. Madri, Andrew Redmond, Erin B. Lavik, Hao Xu, and Cicely A. Williams

Subjects

Pathology, medicine.medical_specialty, Cord, Angiogenesis, Neovascularization, Physiologic, Article, Lesion, Rats, Sprague-Dawley, Polylactic Acid-Polyglycolic Acid Copolymer, Absorbable Implants, medicine, Animals, Lactic Acid, Spinal cord injury, Cells, Cultured, Spinal Cord Injuries, Progenitor, Tissue Engineering, Tissue Scaffolds, business.industry, General Neuroscience, Microcirculation, Endothelial Cells, Hydrogels, Anatomy, medicine.disease, Spinal cord, Neural stem cell, Coculture Techniques, Glycolates, Rats, Disease Models, Animal, medicine.anatomical_structure, Treatment Outcome, Spinal Cord, Blood-Brain Barrier, Blood Vessels, Female, Implant, medicine.symptom, Rats, Transgenic, business, Polyglycolic Acid, Stem Cell Transplantation

Abstract

Angiogenesis precedes recovery following spinal cord injury and its extent correlates with neural regeneration, suggesting that angiogenesis may play a role in repair. An important precondition for studying the role of angiogenesis is the ability to induce it in a controlled manner. Previously, we showed that a coculture of endothelial cells (ECs) and neural progenitor cells (NPCs) promoted the formation of stable tubes in vitro and stable, functional vascular networks in vivo in a subcutaneous model. We sought to test whether a similar coculture would lead to the formation of stable functional vessels in the spinal cord following injury. We created microvascular networks in a biodegradable two-component implant system and tested the ability of the coculture or controls (lesion control, implant alone, implant + ECs or implant + NPCs) to promote angiogenesis in a rat hemisection model of spinal cord injury. The coculture implant led to a fourfold increase in functional vessels compared with the lesion control, implant alone or implant + NPCs groups and a twofold increase in functional vessels over the implant + ECs group. Furthermore, half of the vessels in the coculture implant exhibited positive staining for the endothelial barrier antigen, a marker for the formation of the blood-spinal cord barrier. No other groups have shown positive staining for the blood-spinal cord barrier in the injury epicenter. This work provides a novel method to induce angiogenesis following spinal cord injury and a foundation for studying its role in repair.

Published

2009

2. Engineering of multifunctional gels integrating highly efficient growth factor delivery with endothelial cell transplantation

Author

James P. Bertram, Jordan S. Pober, Steven M. Jay, Benjamin R. Shepherd, and W. Mark Saltzman

Subjects

Vascular Endothelial Growth Factor A, Alginates, Cell Survival, medicine.medical_treatment, Biochemistry, Umbilical vein, Research Communications, Mice, Drug Delivery Systems, Tissue engineering, Glucuronic Acid, Polylactic Acid-Polyglycolic Acid Copolymer, In vivo, Ischemia, Transduction, Genetic, Genetics, medicine, Animals, Humans, Lactic Acid, Particle Size, Molecular Biology, Cells, Cultured, Tissue Engineering, Chemistry, Growth factor, Hexuronic Acids, Endothelial Cells, Serum Albumin, Bovine, Controlled release, Microspheres, Cell biology, Fibronectins, Genes, bcl-2, Hindlimb, Endothelial stem cell, Transplantation, Mice, Inbred C57BL, Vascular endothelial growth factor A, Immunology, Cattle, Collagen, Gels, Polyglycolic Acid, Biotechnology

Abstract

Transplantation of Bcl-2-transduced human umbilical vein endothelial cells (ECs) in protein gels into the gastrocnemius muscle improves local reperfusion in immunodeficient mouse hosts with induced hind limb ischemia. We tested the hypothesis that incorporation of local, sustained growth factor delivery could enhance and accelerate this effect. Tissue engineering scaffolds often use synthetic polymers to enable controlled release of proteins, but most synthetic delivery systems have major limitations, most notably hydrophobicity and inefficient protein loading. Here, we report the development of a novel alginate-based delivery system for vascular endothelial growth factor-A165 (VEGF) that exhibits superior loading efficiency and physical properties to previous systems in vitro. In vivo, VEGF released from alginate microparticles within protein gels was biologically active and, when combined with EC transplantation, led to increased survival of transplanted cells at 28 days. The composite graft described also improved early (14 days) tissue perfusion and late (28 days) muscle myoglobin expression, a sign of recovery from ischemia, compared with EC transplantation and VEGF delivery separately. We conclude that our improved approach to sustained VEGF delivery in tissue engineering is useful in vivo and that the integration of high efficiency protein delivery enhances the therapeutic effect of protein gel-based EC transplantation.—Jay, S. M., Shepherd, B. R., Bertram, J. P., Pober, J. S., Saltzman, W. M. Engineering of multifunctional gels integrating highly efficient growth factor delivery with endothelial cell transplantation.

Published

2008

3. A macroporous hydrogel for the coculture of neural progenitor and endothelial cells to form functional vascular networks in vivo

Author

Erin B. Lavik, Michael J. Young, Joseph A. Madri, Sara Royce Hynes, Millicent C. Ford, Steven S. Segal, Michael Michaud, Qi Li, and James P. Bertram

Subjects

Neurons, Multidisciplinary, Erythrocytes, Tissue Engineering, Stem Cells, Endothelial Cells, Hydrogels, Neural stem cell, Coculture Techniques, Microcirculation, Cell biology, Capillaries, Endothelial stem cell, Mice, Inbred C57BL, Mice, Vasculogenesis, Tissue engineering, In vivo, Immunology, Self-healing hydrogels, Animals, Blood Vessels, Female, Stem cell, Tissue Engineering Special Feature

Abstract

A microvascular network is critical for the survival and function of most tissues. We have investigated the potential of neural progenitor cells to augment the formation and stabilization of microvascular networks in a previously uncharacterized three-dimensional macroporous hydrogel and the ability of this engineered system to develop a functional microcirculation in vivo . The hydrogel is synthesized by cross-linking polyethylene glycol with polylysine around a salt-leached polylactic-co-glycolic acid scaffold that is degraded in a sodium hydroxide solution. An open macroporous network is formed that supports the efficient formation of tubular structures by brain endothelial cells. After subcutaneous implantation of hydrogel cocultures in mice, blood flow in new microvessels was apparent at 2 weeks with perfused networks established on the surface of implants at 6 weeks. Compared to endothelial cells cultured alone, cocultures of endothelial cells and neural progenitor cells had a significantly greater density of tubular structures positive for platelet endothelial cell adhesion molecule-1 at the 6-week time point. In implant cross sections, the presence of red blood cells in vessel lumens confirmed a functional microcirculation. These findings indicate that neural progenitor cells promote the formation of endothelial cell tubes in coculture and the development of a functional microcirculation in vivo . We demonstrate a previously undescribed strategy for creating stable microvascular networks to support engineered tissues of desired parenchymal cell origin.

Published

2006