Recent Advances in Bioink Design for 3D Bioprinting of Tissues and Organs

Ji, Shen; Guvendiren, Murat

doi:10.3389/fbioe.2017.00023

Cited by 369 publications

(277 citation statements)

References 91 publications

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“…138,140,141 However, the low resolution of available bioprinters and methods for bioprinting the vasculature (such as sacrificial hydrogel) make it impossible to print hepatic tissue with an integrated and perfusable vascular network with complex branching in a range of diameters from large vessels to capillaries. 142,143 The same holds true for the periportal to pericentral zonal distrubition. 142,143 The technology to transcend these challenges might be years away, but the potential of these biofabrication techniques is clear and compelling when considering whole-liver bioengineering.…”

Section: Future Directionsmentioning

confidence: 74%

“…142,143 The same holds true for the periportal to pericentral zonal distrubition. 142,143 The technology to transcend these challenges might be years away, but the potential of these biofabrication techniques is clear and compelling when considering whole-liver bioengineering. They allow not only the generation of organs on demand, but also a more exact and rapid 3D recreation of hepatic tissue with all of its refinements, and are only limited by our knowledge of what and where to print.…”

Section: Future Directionsmentioning

confidence: 74%

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Biotechnology Challenges to In Vitro Maturation of Hepatic Stem Cells

et al. 2018

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The incidence of liver disease is increasing globally. The only curative therapy for severe end-stage liver disease, liver transplantation, is limited by the shortage of organ donors. In vitro models of liver physiology have been developed and new technologies and approaches are progressing rapidly. Stem cells might be used as a source of liver tissue for development of models, therapies, and tissue-engineering applications. However, we have been unable to generate and maintain stable and mature adult liver cells ex vivo. We review factors that promote hepatocyte differentiation and maturation, including growth factors, transcription factors, microRNAs, small molecules, and the microenvironment. We discuss how the hepatic circulation, microbiome, and nutrition affect liver function, and the criteria for considering cells derived from stem cells to be fully mature hepatocytes. We explain the challenges to cell transplantation and consider future technologies for use in hepatic stem cell maturation, including 3-dimensional biofabrication and genome modification.

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Section: Future Directionsmentioning

confidence: 74%

Section: Future Directionsmentioning

confidence: 74%

Biotechnology Challenges to In Vitro Maturation of Hepatic Stem Cells

et al. 2018

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“…Fused deposition modelling (FDM) is an example of extrusion‐based printing used for synthetic thermoplastics and their composites. The technique is unsuitable for bioprinting as it involves melting thermoplastics at very high temperatures (Ji & Guvendiren, ). Therefore, a slightly modified FDM‐based printer has been developed by our group at the University of Bridgeport (Halim et al, ).…”

Section: D Bioprinting Technologiesmentioning

confidence: 99%

“…Inspite of the different printing methods used, there is a certain set of characteristics that need to be achieved in terms of both material (printability, flowability, and degradability) as well as biological (cytocompatibility and differentiation) requirements for appropriate ink preparation (Ji & Guvendiren, ). Different biocompatible materials ranging from naturally derived to chemically synthesized polymers, ceramics, bioactive glasses, and their modified derivatives are being extensively investigated as potential bioinks for bone.…”

Section: Bioinkmentioning

confidence: 99%

Advances in three‐dimensional bioprinting of bone: Progress and challenges

Midha

Dalela

Sybil

et al. 2019

J Tissue Eng Regen Med

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Several attempts have been made to engineer a viable three‐dimensional (3D) bone tissue equivalent using conventional tissue engineering strategies, but with limited clinical success. Using 3D bioprinting technology, scientists have developed functional prototypes of clinically relevant and mechanically robust bone with a functional bone marrow. Although the field is in its infancy, it has shown immense potential in the field of bone tissue engineering by re‐establishing the 3D dynamic micro‐environment of the native bone. Inspite of their in vitro success, maintaining the viability and differentiation potential of such cell‐laden constructs overtime, and their subsequent preclinical testing in terms of stability, mechanical loading, immune responses, and osseointegrative potential still needs to be explored. Progress is slow due to several challenges such as but not limited to the choice of ink used for cell encapsulation, optimal cell source, bioprinting method suitable for replicating the heterogeneous tissues and organs, and so on. Here, we summarize the recent advancements in bioprinting of bone, their limitations, challenges, and strategies for future improvisations. The generated knowledge will provide deep insights on our current understanding of the cellular interactions with the hydrogel matrices and help to unravel new methodologies for facilitating precisely regulated stem cell behaviour.

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“…To address this, dECM would be a suitable bioink as it is an excellent candidate for providing cells with the signals required to induce and maintain differentiation into tissue‐specific lineages (Agmon & Christman, ). Decellularized tissue or ECM‐based bioink formulations are developing fields due to their ease of printability and their inherent bioactivity (Ji & Guvendiren, ). dECM from cartilage (Pati et al, ), fat (Pati et al, ), heart (Das & Jang, ), skin (Ahn et al, ), and liver (Lee et al, ) has already been used for 3D bioprinting.…”

Section: Future Prospectsmentioning

confidence: 99%

Recent advances in three‐dimensional bioprinting of stem cells

Eswaramoorthy

Ramakrishna

Rath

2019

J Tissue Eng Regen Med

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In spite of being a new field, three‐dimensional (3D) bioprinting has undergone rapid growth in the recent years. Bioprinting methods offer a unique opportunity for stem cell distribution, positioning, and differentiation at the microscale to make the differentiated architecture of any tissue while maintaining precision and control over the cellular microenvironment. Bioprinting introduces a wide array of approaches to modify stem cell fate. This review discusses these methodologies of 3D bioprinting stem cells. Fabricating a fully operational tissue or organ construct with a long life will be the most significant challenge of 3D bioprinting. Once this is achieved, a whole human organ can be fabricated for the defect place at the site of surgery.

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Recent Advances in Bioink Design for 3D Bioprinting of Tissues and Organs

Cited by 369 publications

References 91 publications

Biotechnology Challenges to In Vitro Maturation of Hepatic Stem Cells

Biotechnology Challenges to In Vitro Maturation of Hepatic Stem Cells

Advances in three‐dimensional bioprinting of bone: Progress and challenges

Recent advances in three‐dimensional bioprinting of stem cells

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