Decellularized Extracellular Matrix-based Bioinks for Engineering Tissue- and Organ-specific Microenvironments

Kim, Byoung Soo; Das, Sanjeev; Jang, Jinah; Cho, Dong‐Woo

doi:10.1021/acs.chemrev.9b00808

Cited by 273 publications

(277 citation statements)

References 396 publications

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“…Owing to these features, tubular structures were successfully printed and stably preserved in 3% VdECM bioink, thereby confirming that this material could be used as a pre‐gel suspension. In addition, several studies have demonstrated that various dECM‐based bioinks can respond to physical stimuli (e.g., shear stress), such as shear thinning behavior, [ 26 ] implying their feasibility as a supporting bath. Therefore, considering the outstanding biofunctionality of dECM bioinks, our findings suggest that the materials in this category might be promising alternatives for fabricating gel‐embedded 3D bioprinted tissue/organ models.…”

Section: Discussionmentioning

confidence: 99%

Construction of a Novel In Vitro Atherosclerotic Model from Geometry‐Tunable Artery Equivalents Engineered via In‐Bath Coaxial Cell Printing

Gao

Park

Kim

et al. 2020

Adv Funct Materials

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As the main precursor of cardiovascular diseases, atherosclerosis is a complex inflammatory disorder that preferentially occurs in stenotic, curved, and branched arterial regions. Although various in vitro models are established to understand its pathology, reconstructing the native atherosclerotic environment that involves both co‐cultured cells and local turbulent flow singling remains challenging. This study develops an arterial construct via in‐bath coaxial cell printing that not only facilitates the direct fabrication of three‐layered conduits with tunable geometry and dimensions but also maintains structural stability. Functional vascular tissues, which respond to various stimulations that induce endothelial dysfunction, are rapidly generated in the constructed models. The presence of multiple vascular tissues under stenotic and tortuous turbulent flows allows the recapitulation of hallmark events in early atherosclerosis under physiological conditions. Furthermore, the fabricated models are utilized to investigate the individual and synergistic functions of cell co‐culture and local turbulent flows in regulating atherosclerotic initiation, as well as the dose‐dependent therapeutic effect of atorvastatin. These outcomes suggest that the constructed atherosclerotic model via a novel fabrication strategy is a promising platform to elucidate the pathophysiology of atherosclerosis and seek effective drugs and therapies.

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Section: Discussionmentioning

confidence: 99%

Construction of a Novel In Vitro Atherosclerotic Model from Geometry‐Tunable Artery Equivalents Engineered via In‐Bath Coaxial Cell Printing

Gao

Park

Kim

et al. 2020

Adv Funct Materials

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“…Hydrogels for bioink are required to (1) flow under modest pressures, (2) solidify quickly, and (3) sustain adequate integrity after building up. 50 , 51 In the sol–gel transition process, fibers in solutions can be physically or chemically cross-linked by external stimuli, such as temperature, light source, or ion concentration. 52 The main strength of physical cross-linking is the absence of cytotoxic chemical agents.…”

Section: Advances In 3d Bioprintingmentioning

confidence: 99%

Application of 3D bioprinting in the prevention and the therapy for human diseases

Kim

Kwon

et al. 2021

Sig Transduct Target Ther

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Rapid development of vaccines and therapeutics is necessary to tackle the emergence of new pathogens and infectious diseases. To speed up the drug discovery process, the conventional development pipeline can be retooled by introducing advanced in vitro models as alternatives to conventional infectious disease models and by employing advanced technology for the production of medicine and cell/drug delivery systems. In this regard, layer-by-layer construction with a 3D bioprinting system or other technologies provides a beneficial method for developing highly biomimetic and reliable in vitro models for infectious disease research. In addition, the high flexibility and versatility of 3D bioprinting offer advantages in the effective production of vaccines, therapeutics, and relevant delivery systems. Herein, we discuss the potential of 3D bioprinting technologies for the control of infectious diseases. We also suggest that 3D bioprinting in infectious disease research and drug development could be a significant platform technology for the rapid and automated production of tissue/organ models and medicines in the near future.

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“…Due to the ability of 3D printing to create porous scaffolds with complex structure and the good perspective in the 3D fabrication of personalized grafts, [ 108 ] in the past few years, a large number of articles have explored this manufacturing process to produce tissue engineering grafts. [ 109,110 ] Combined with 3D printing, the use of nanostructured materials has also been employed due to its versatile functionalities: These materials improve drug solubility and stability and act as drug carriers. In addition, they can increase the surface area of materials or help in the process of cell adhesion, specifically in cell growth.…”

Section: D Printing and Nanotechnology Alliancementioning

confidence: 99%

3D Printing and Nanotechnology: A Multiscale Alliance in Personalized Medicine

Santos

Oliveira

et al. 2021

Adv Funct Materials

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3D printing and nanotechnology have been two important tools in the development of therapeutic approaches for personalized medicine. More recently, their alliance has been improved in an effort to build innovative, versatile, multifunctional, and/or smart medical and pharmaceutical products. Therefore, an extensive review about scientific studies that ally 3D printing and nanomaterials in the development of new approaches for pharmaceutical and medical applications for the treatment and prevention of diseases is presented here. The articles are classified into five categories according to their main application: Cell growth and tissue engineering, antimicrobial, drug delivery, stimulus‐response, and theranostics. Semisolid extrusion, inorganic nanoparticles, and cell growth and tissue engineering are the most reported 3D printing technique, type of nanomaterial, and application, respectively. The increase in papers dedicated to these areas is also notable, especially in the 2019 and 2020, when semisolid extrusion became the most used technique, overcoming fused deposition modelling. In fact, this review highlights that the possibility of an alliance between 3D printing and nanotechnology for the production of multiscale materials is undoubtedly a great opportunity for knowledge and innovation in the pharmaceutical and medical area.

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Decellularized Extracellular Matrix-based Bioinks for Engineering Tissue- and Organ-specific Microenvironments

Cited by 273 publications

References 396 publications

Construction of a Novel In Vitro Atherosclerotic Model from Geometry‐Tunable Artery Equivalents Engineered via In‐Bath Coaxial Cell Printing

Construction of a Novel In Vitro Atherosclerotic Model from Geometry‐Tunable Artery Equivalents Engineered via In‐Bath Coaxial Cell Printing

Application of 3D bioprinting in the prevention and the therapy for human diseases

3D Printing and Nanotechnology: A Multiscale Alliance in Personalized Medicine

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