3D printing of self-standing and vascular supportive multi-material hydrogel structures for organ engineering

Three dimensional printable formulation of self-standing and vascular-supportive structures using multi-materials suitable for organ engineering is of great importance and highly challengeable, but, it could advance the 3D printing scenario from printable shape to functional unit of human body. In this study, the authors report a 3D printable formulation of such self-standing and vascular-supportive structures using an in-house formulated multi-material combination of albumen/alginate/gelatin (A-SA-Gel)-based hydrogel. The rheological properties and relaxation behavior of hydrogels were analyzed prior to the printing process. The suitability of the hydrogel in 3D printing of various customizable and self-standing structures, including a human ear model, was examined by extrusion-based 3D printing. The structural, mechanical, and physicochemical properties of the printed scaffolds were studied systematically. Results supported the 3D printability of the formulated hydrogel with self-standing structures, which are customizable to a specific need. In vitro cell experiment showed that the formulated hydrogel has excellent biocompatibility and vascular supportive behavior with the extent of endothelial sprout formation when tested with human umbilical vein endothelial cells. In conclusion, the present study demonstrated the suitability of the extrusion-based 3D printing technique for manufacturing complex shapes and structures using multi-materials with high fidelity, which have great potential in organ engineering.

Whole Heart Engineering: Advances and Challenges

Bioengineering a solid organ for organ replacement is a growing endeavor in regenerative medicine. Our approach – recellularization of a decellularized cadaveric organ scaffold with human cells – is currently the most promising approach to building a complex solid vascularized organ to be utilized in vivo, which remains the major unmet need and a key challenge. The 2008 publication of perfusion-based decellularization and partial recellularization of a rat heart revolutionized the tissue engineering field by showing that it was feasible to rebuild an organ using a decellularized extracellular matrix scaffold. Toward the goal of clinical translation of bioengineered tissues and organs, there is increasing recognition of the underlying need to better integrate basic science domains and industry. From the perspective of a research group focusing on whole heart engineering, we discuss the current approaches and advances in whole organ engineering research as they relate to this multidisciplinary field’s 3 major pillars: organ scaffolds, large numbers of cells, and biomimetic bioreactor systems. The success of whole organ engineering will require optimization of protocols to produce biologically-active scaffolds for multiple organ systems, and further technological innovation both to produce the massive quantities of high-quality cells needed for recellularization and to engineer a bioreactor with physiologic stimuli to recapitulate organ function. Also discussed are the challenges to building an implantable vascularized solid organ.

Abstract 14125: An in vitro Pulmonary Vascular Platform From Endothelialized Whole Lung Scaffolds

Introduction: The development of an in vitro system is critical to studying human diseases including the novel coronavirus disease-19 (COVID-19), and is typically centered on recapitulating native physiology. In the case of the pulmonary vasculature, the endothelium is critical for establishing the fluid-tight barrier in the alveolar compartment, and displays significant phenotypic and functional heterogeneity along vascular tree. Objective: Here, we developed an experimental platform that could mimic physiological functions and cellular phenotypes of pulmonary vasculature, during homeostatic and diseased states. Methods and Results: Lymphatic low pulmonary microvascular endothelial cells (Lymph low PMECs) were isolated from Prox1-GFP rodent lungs from regions of having low amounts of lymphatic tissue. Single-cell RNA-sequencing (scRNAseq) data revealed that these cells were becoming phenotypically homogenous over several passages while losing some markers of native differentiation during passaging. Intriguingly, after culturing in decellularized lung scaffolds, the phenotype of the lymph low PMEC changed back toward native lung endothelium. Vascular barrier function was partially restored in engineered lungs repopulated with endothelium, while small capillaries with patent lumens were appreciable. To evaluate the ability of the engineered endothelium to modulate permeability in response to exogenous stimuli, lipopolysaccharide (LPS) was introduced into repopulated lungs to simulate acute lung injury. After LPS treatment, the pro-inflammatory signal was significantly increased and the vascular barrier was severely impaired in the repopulated lung. Conclusions: Taken together, these results show a novel platform that recapitulates some pulmonary microvascular functions and phenotypes at a whole organ level. This development may help pave the way for using the whole organ engineering approach to model vascular diseases.

Whole Organ Engineering: Approaches, Challenges, and Future Directions

End-stage organ failure remains a leading cause of morbidity and mortality across the globe. The only curative treatment option currently available for patients diagnosed with end-stage organ failure is organ transplantation. However, due to a critical shortage of organs, only a fraction of these patients are able to receive a viable organ transplantation. Those patients fortunate enough to receive a transplant must then be subjected to a lifelong regimen of immunosuppressant drugs. The concept of whole organ engineering offers a promising alternative to organ transplantation that overcomes these limitations. Organ engineering is a discipline that merges developmental biology, anatomy, physiology, and cellular interactions with enabling technologies such as advanced biomaterials and biofabrication to create bioartificial organs that recapitulate native organs in vivo. There have been numerous developments in bioengineering of whole organs over the past two decades. Key technological advancements include (1) methods of whole organ decellularization and recellularization, (2) three-dimensional bioprinting, (3) advanced stem cell technologies, and (4) the ability to genetically modify tissues and cells. These advancements give hope that organ engineering will become a commercial reality in the next decade. In this review article, we describe the foundational principles of whole organ engineering, discuss key technological advances, and provide an overview of current limitations and future directions.

Polymer microcapsules and microbeads as cell carriers for in vivo biomedical applications

This Review discusses the polymer cell microcarriers for in vivo biomedical applications, focusing on the materials and methods employed in their fabrication and their use as cell delivery vehicles for cell therapies, tissue regeneration and bioartificial organ engineering.