ABSTRACT
@#With the development of biomimetic technology, more and more in vitro models are used to simulate human physiological and pathological processes.These in vitro models can solve some scientific problems, such as studying drug effects in real-timely and visually.As an in vitro model, organ-on-a-chip provides novel means and methods for basic and applied science.The vascularized organ-on-a-chip, as a special kind of organ-on-a-chip, can better simulate the structure and function of human blood vessels.In this review, we summarized the structure and function of different vascularized organ-on-a-chip, analyzed the application of vascularized organ-on-a-chip in simulating physiological and pathological processes, and discussed the advantages and problems to be solved of vascularized organ-on-a-chip as a new in vitro model.Finally, the application of vascularized organ-on-a-chip is proposed.
ABSTRACT
3D bioprinting is an advanced manufacturing technology that utilizes biomaterials and bioactive components to manufacture artificial tissues and organs. It has been widely applied in multiple medical fields and possesses outstanding advantages in organ reconstruction. In recent years, 3D bioprinted organs have made an array of groundbreaking achievements. Nevertheless, it is still in the exploratory stage of research and development and still has bottleneck problems, which can not be applied in organ transplantation in vivo. In this article, the application of 3D printing technology in medicine, characteristics of 3D bioprinting technology, research hotspots and difficulties in bionic structure, functional reconstruction and immune response of 3D bioprinted organs, and the latest research progress on 3D bioprinting technology were illustrated, and the application prospect of 3D bioprinting technology in the field of organ reconstruction was elucidated, aiming to provide novel ideas for the research and clinical application of organ reconstruction and artificial organ reconstruction, and promote the development of organ transplantation and individualized medicine.
ABSTRACT
Objective: To propose a method for making organ-on-a-chip based on 3D printing, and study the relationship between cell growth on the chips and various factors. Methods: Through 3D printing technology and surface microstructure transfer method, ulcer-like and ridge-like mi-crostructures of the tumor surface and the intestinal villi were fabricated on a polydimethylsiloxane (PDMS) chip. Combined with fluorescence imaging, the effects of surface modification, shapes and heights of microstructures, and culture time on the surface coverage and density of Caco-2 cells on the chip were measured. Results:The PDMS chip was more likely to induce cell adhesion and growth rather than the 3D printing resin chip. On the surface of three-dimensional structure, cell surface coverage and cell density increased after the surface was treated with rat tail collagen (P0.05). Conclusion: The intestinal villi and tumor topological organ chips can be fabricated by 3D printing technology and surface microstructure transfer method. The surface modification and microstructure height affect the cell growth on the surface.
ABSTRACT
Traditional approaches to pathophysiology are advancing but still have many limitations that arise from real biologic systems and their associated physiological phenomena being too complicated. Microfluidics is a novel technology in the field of engineering, which provides new options that may overcome these hurdles. Microfluidics handles small volumes of fluids and may apply to various applications such as DNA analysis chips, other lab-on-a-chip analyses, micropropulsion, and microthermal technologies. Among them, organ-on-a-chip applications allow the fabrication of minimal functional units of a single organ or multiple organs. Relevant to the field of nephrology, renal tubular cells have been integrated with microfluidic devices for making kidneys-on-a-chip. Although still early in development, kidneys-on-a-chip are showing potential to provide a better understanding of the kidney to replace some traditional animal and human studies, particularly as more cell types are incorporated toward the development of a complete glomerulion-a-chip.