3D Bioprinting of Engineered Tissue Flaps with Hierarchical Vessel Networks (VesselNet) for Direct Host-To-Implant Perfusion.

Engineering hierarchical vasculatures is critical for creating implantable functional thick tissues. Current approaches focus on fabricating mesoscale vessels for implantation or hierarchical microvascular in vitro models, but a combined approach is yet to be achieved to create engineered tissue flaps. Here, millimetric vessel-like scaffolds and 3D bioprinted vascularized tissues interconnect, creating fully engineered hierarchical vascular constructs for implantation. Endothelial and support cells spontaneously form microvascular networks in bioprinted tissues using a human collagen bioink. Sacrificial molds are used to create polymeric vessel-like scaffolds and endothelial cells seeded in their lumen form native-like endothelia. Assembling endothelialized scaffolds within vascularizing hydrogels incites the bioprinted vasculature and endothelium to cooperatively create vessels, enabling tissue perfusion through the scaffold lumen. Using a cuffing microsurgery approach, the engineered tissue is directly anastomosed with a rat femoral artery, promoting a rich host vasculature within the implanted tissue. After two weeks in vivo, contrast microcomputer tomography imaging and lectin perfusion of explanted engineered tissues verify the host ingrowth vasculature's functionality. Furthermore, the hierarchical vessel network (VesselNet) supports in vitro functionality of cardiomyocytes. Finally, the proposed approach is expanded to mimic complex structures with native-like millimetric vessels. This work presents a novel strategy aiming to create fully-engineered patient-specific thick tissue flaps.

Prevascularized Scaffolds Bearing Human Dental Pulp Stem Cells for Treating Complete Spinal Cord Injury.

The regeneration of injured spinal cord is hampered by the lack of vascular supply and neurotrophic support. Transplanting tissue-engineered constructs with developed vascular networks and neurotrophic factors, and further understanding the pattern of vessel growth in the remodeled spinal cord tissue are greatly desired. To this end, highly vascularized scaffolds embedded with human dental pulp stem cells (DPSCs) are fabricated, which possess paracrine-mediated angiogenic and neuroregenerative potentials. The potent pro-angiogenic effect of the prevascularized scaffolds is first demonstrated in a rat femoral bundle model, showing robust vessel growth and blood perfusion induced within these scaffolds postimplantation, as evidenced by laser speckle contrast imaging and 3D microCT dual imaging modalities. More importantly, in a rat complete spinal cord transection model, the implantation of these scaffolds to the injured spinal cords can also promote revascularization, as well as axon regeneration, myelin deposition, and sensory recovery. Furthermore, 3D microCT imaging and novel morphometric analysis on the remodeled spinal cord tissue demonstrate substantial regenerated vessels, more significantly in the sensory tract regions, which correlates with behavioral recovery following prevascularization treatment. Taken together, prevascularized DPSC-embedded constructs bear angiogenic and neurotrophic potentials, capable of augmenting and modulating SCI repair.

Rapid prototyping fabrication of soft and oriented polyester scaffolds for axonal guidance.

Biodegradable polyesters have been extensively used for preparation of nerve guidance scaffolds, due to their high biocompatibility and defined degradation periods. However, conventional methods for fabrication of porous polyester scaffolds provide limited control over shape and micro-architecture. Here, a fabrication procedure based on 3D printing was developed to generate highly ordered and anatomically personalized, polyester scaffolds for soft tissue regeneration. Scaffolds composed of Poly-lactic-glycolic acid (PLGA) and poly-L-lactic acid (PLLA) were specifically customized for nerve injuries. This was obtained by using an oriented multi-layer printing pattern which established a linear structure in the fabricated scaffolds to match the aligned topography of nerve tissues. The oriented scaffold was shown to guide regenerating axons to linear conformations and support growth of induced pluripotent stem cell-derived neurons in vitro and in vivo in a model of spinal cord injury. The described scaffolds may advance the field of nerve regeneration. Furthermore, modifications could be integrated to generate soft implants for various types of tissues.

Enhanced Host Neovascularization of Prevascularized Engineered Muscle Following Transplantation into Immunocompetent versus Immunocompromised Mice.

: Engineering of functional tissue, by combining either autologous or allogeneic cells with biomaterials, holds promise for the treatment of various diseases and injuries. Prevascularization of the engineered tissue was shown to enhance and improve graft integration and neovascularization post-implantation in immunocompromised mice. However, the neovascularization and integration processes of transplanted engineered tissues have not been widely studied in immunocompetent models. Here, we fabricated a three-dimensional (3D) vascularized murine muscle construct that was transplanted into immunocompetent and immunocompromised mice. Intravital imaging demonstrated enhanced neovascularization in immunocompetent mice compared to immunocompromised mice, 18 days post-implantation, indicating the advantageous effect of an intact immune system on neovascularization. Moreover, construct prevascularization enhanced neovascularization, integration, and myogenesis in both animal models. These findings demonstrate the superiority of implantation into immunocompetent over immunocompromised mice and, therefore, suggest that using autologous cells might be beneficial compared to allogeneic cells and subsequent immunosuppression. Taken together, these observations have the potential to advance the field of regenerative medicine and tissue engineering, ultimately reducing the need for donor organs and tissues.

Mature vessel networks in engineered tissue promote graft-host anastomosis and prevent graft thrombosis.

Graft vascularization remains one of the most critical challenges facing tissue-engineering experts in their attempt to create thick transplantable tissues and organs. In vitro prevascularization of engineered tissues has been suggested to promote rapid anastomosis between the graft and host vasculatures; however, thrombotic events have been reported upon graft implantation. Here, we aimed to determine whether in vitro vessel maturation in transplantable grafts can accelerate vascular integration and graft perfusion and prevent thrombotic events in the grafts. To this end, endothelial cells and fibroblasts were cocultured on 3D scaffolds for 1, 7, or 14 d to form vasculature with different maturation degrees. Monitoring graft-host interactions postimplantation demonstrated that the 14-d in vitro-cultured grafts, bearing more mature and complex vessel networks as indicated by elongated and branched vessel structures, had increased graft-host vessel anastomosis; host vessel penetration into the graft increased approximately eightfold, and graft perfusion increased sixfold. The presence of developed vessel networks prevented clot accumulation in the grafts. Conversely, short-term cultured constructs demonstrated poor vascularization and increased thrombus formation. Elevated expression levels of coagulation factors, von Willebrand factor (vWF), and tissue factor (TF), were demonstrated in constructs bearing less mature vasculature. To conclude, these findings demonstrate the importance of establishing mature and complex vessel networks in engineered tissues before implantation to promote anastomosis with the host and accelerate graft perfusion.

Induced neuro-vascular interactions robustly enhance functional attributes of engineered neural implants.

Engineered neural implants have a myriad of potential basic science and clinical neural repair applications. Although there are implants that are currently undergoing their first clinical investigations, optimizing their long-term viability and efficacy remain an open challenge. Functional implants with pre-vascularization of various engineered tissues have proven to enhance post-implantation host integration, and well-known synergistic neural-vascular interplays suggest that this strategy could also be promising for neural tissue engineering. Here, we report the development of a novel bio-engineered neuro-vascular co-culture construct, and demonstrate that it exhibits enhanced neurotrophic factor expression, and more complex neuronal morphology. Crucially, by introducing genetically encoded calcium indicators (GECIs) into the co-culture, we are able to monitor functional activity of the neural network, and demonstrate greater activity levels and complexity as a result of the introduction of endothelial cells in the construct. The presence of this enhanced activity could putatively lead to superior integration outcomes. Indeed, leveraging on the ability to monitor the construct's development post-implantation with GECIs, we observe improved integration phenotypes in the spinal cord of mice relative to non-vascularized controls. Our approach provides a new experimental system with functional neural feedback for studying the interplay between vascular and neural development while advancing the optimization of neural implants towards potential clinical applications.