Abstract
Three-dimensional (3D) printing of biomaterials provides an interesting alternative for the production of allograft tissues and organs to circumvent the incidences of donor scarcity and organ shortages. With the current deficit of readily available and viable organs for transplantation, the medical sector is faced with an increasing demand for organs and the shortfall in supply. Over the past decades, tissue engineering and regenerative medicine continue to provide alternative strategies for artificial tissues and organs. Current research shows that employing hydrogels as a cell-laden bioinks for the fabrication of 3D tissue constructs enables a lack of immunogenicity, since the hydrogel-based bioink is patient-specific and derived from biopolymers that demonstrate excellent biocompatibility and biodegradability, decreased organ rejection, increased organ viability and enhanced the supply in accordance to the demand. While sufficient evidence directs researchers to conclude the safe and efficacious process of seeding cells, biomolecules and biomaterials using 3D bioprinting, there are multiple limitations, which requires significant attention, such as cost, volumetric bioprinting, integrity and strength of biomaterials as well as multi-cellular and multi-material bioprinting. In this review, the focus is on the applications of hydrogels as bioinks employed in 3D bioprinting, and where applicable, considerations of note and challenges encountered. This review proposes to highlight the progress forged in this area, but also the limitations of hydrogel-based bioink investigations to date and the need for further multidisciplinary investigation and progression to the stage of clinical testing of human-scale tissue constructs.
Highlights
Three-dimensional (3D) bioprinting refers to the process of producing cell-laden models into functional tissue and organs for transplantation and drug testing
The selection of materials employing 3D bioprinting is significantly dependent on the biocompatibility with cellular growth and proliferation and its printing ability such as viscosity, extrudability, and mechanical stability
The fundamental understanding and integration of cellular microenvironment with material science are needed for the development of a novel bioink for the fabrication of 3D bioprinted tissue constructs
Summary
Three-dimensional (3D) bioprinting (biomimicry) refers to the process of producing cell-laden models into functional tissue and organs for transplantation and drug testing. This research field and future developments will extend from producing hydrogel-based bioinks with enhanced physicochemical attributes to incorporating microchannels to allow for effective nutrient diffusion for resident bioprinted cells (Vijayavenkataraman et al, 2018). Three-Dimensional Bioprinting Techniques for Fabricating Cell-Laden Hydrogel-Based Bioinks
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