Millicent Ford Rauch scite author profile

Neural stem cells (NSCs) have the potential to replace the major cell types of the central nervous system (CNS) and may be important in therapies for injuries to and diseases of the CNS. However, for such treatments to be safe and successful, NSCs must survive and differentiate appropriately following transplantation. A number of polymer scaffolds have shown promise in improving the survival and promoting the differentiation of NSCs. To capitalize on the interaction between scaffolds and NSCs, we need to determine the fundamental material properties that influence NSC behavior. To investigate the role of material properties on NSCs, we synthesized a library of 52 hydrogels composed of poly(ethylene glycol) and poly(L-lysine) (PLL). This library of hydrogels allows independent variation of chemical and mechanical properties across a wide range of values. By culturing NSCs on this library, we have identified a subset of gels that promotes NSC migration and a further subset that promotes NSC differentiation. By combining the material properties of these subsets with the cell behavior, we determined that mechanical properties play a critical role in NSC behavior with elastic moduli promoting NSC migration and neuronal differentiation. Amine concentration is less critical, but PLL molecular weight also plays a role in NSC differentiation.

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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

Rauch

Hynes

Bertram

et al. 2008

Eur J of Neuroscience

100

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Angiogenesis precedes recovery following spinal cord injury (SCI), 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 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 plus ECs, or implant plus NPCs) to promote angiogenesis in a rat hemisection model of spinal cord injury. The coculture implant led to a four fold increase in functional vessels compared to the lesion control, implant alone, or implant plus NPCs groups and a 2 fold increase in functional vessels over the implant plus ECs group. Furthermore, half of the vessels in the coculture implant exhibited positive staining for the endothelial barrier antigen, a marker for formation of the blood spinal cord barrier (BSB). No other groups showed positive staining for the BSB in the injury epicenter. This work provides a novel method to induce angiogenesis following SCI and a foundation for studying its role in repair.

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Using Polymer Chemistry to Modulate the Delivery of Neurotrophic Factors from Degradable Microspheres: Delivery of BDNF

et al. 2009

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Co-culture of primary neural progenitor and endothelial cells in a macroporous gel promotes stable vascular networks in vivo

Rauch

Michaud

et al. 2008

Journal of Biomaterials Science, Polymer Edition

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Most tissues cannot survive without microvascular networks. In many cases, the host cannot vascularize implanted tissues, motivating the need for implantable vascular networks for tissue engineered grafts. However, engineering microvascular networks that are stable and functional for long times has proven challenging. The co-culture of neural progenitor cells with endothelial cells may lead to long term, functional microvascular networks. Ideally, these networks should be made from primary cells to avoid the potential safety concerns associated with immortalized or genetically-engineered cells. Thus, we have investigated and developed a paradigm for isolating and co-culturing primary rat endothelial cells and neural progenitor cells in biodegradable poly(ethylene glycol)/poly(L-lysine) macroporous hydrogels. The co-culture of these primary cells in the gels led to stabilization of vessels with no evidence of vessel regression even as far out as 6 weeks, the longest time point studied. Further more, the vessels contained host red blood cells, demonstrating they anastomosed with the host and were functional. Functional vessels were found throughout the implants, and no adverse effects such as clotting or thrombosis were observed. This work suggests that a co-culture of primary cells seeded in a macroporous hydrogel is a novel method to promote stable functional vascular networks which are critical for engineering complex tissues.

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Photopolymerized poly(ethylene glycol)/poly(L-lysine) hydrogels for the delivery of neural progenitor cells

Hynes

McGregor

Rauch

et al. 2007

Journal of Biomaterials Science, Polymer Edition

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Neural progenitor cells (NPCs) have shown promise in a number of models of disease and injury, but for these cells to be safe and effective, they must be directed to differentiate appropriately following transplantation. We have developed a photopolymerized hydrogel composed of macromers of poly(ethylene glycol) (PEG) bound to poly(L-lysine) (PLL) that supports NPC survival and directs differentiation. Green fluorescent protein (GFP) positive NPCs were encapsulated in these gels and demonstrated survival up to 17 days. When encapsulated in the gels at a photoinitiator concentration of 5.0 mg/ml, few NPCs (0.5 +/- 0.25%) demonstrated apoptosis. Furthermore, 55 +/- 6% of the NPCs cultured within the gels in epidermal growth factor (EGF) containing media differentiated into a mature neuronal cell type (neurofilament 200 positive) while the remainder 44 +/- 8% were undifferentiated (nestin positive). A small percentage, 1 +/- 0.4%, expressed the astrocytic marker glial acidic fibrilary protein. Photopolymerized PEG/PLL gels promote the survival and direct the differentiation of NPCs, making this system a promising delivery vehicle for NPCs in the treatment of injuries and diseases of the central nervous system.

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