Enhanced Biocompatibility of Multi-Layered, 3D Bio-Printed Artificial Vessels Composed of Autologous Mesenchymal Stem Cells

Jang, Eui Hwa; Kim, Junghwan; Lee, Jun Hee; Kim, Dae-Hyun; Youn, Young‐Nam

doi:10.3390/polym12030538

Cited by 28 publications

(22 citation statements)

References 27 publications

(33 reference statements)

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“…While other researchers like Laura Niklason at Duke (later Yale) ( 285 , 286 ) also started their programs initially on the basis of bioreactor-based vital implants using degradable scaffolds ( 163 ), the group in Montreal went a step further. In an attempt to avoid all synthetic scaffolds and the associated problems of shrinkage and fibrosis, L'Heureux and Auger created polymer-free neo-vessels consisting of adventitial fibroblatsts, medial smooth muscle cells and an endothelium ( 287 – 291 ) Their extreme modern pendent are 3D printed pure stem-cell grafts ( 292 ). In clinical pilot trials with L'Heureux's AV-shunts graft dilatation was observed ( 288 ).…”

Section: A Protracted Evolutionmentioning

confidence: 99%

Progressive Reinvention or Destination Lost? Half a Century of Cardiovascular Tissue Engineering

Zilla

Deutsch

Bezuidenhout

et al. 2020

Front. Cardiovasc. Med.

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Section: A Protracted Evolutionmentioning

confidence: 99%

Progressive Reinvention or Destination Lost? Half a Century of Cardiovascular Tissue Engineering

Zilla

Deutsch

Bezuidenhout

et al. 2020

Front. Cardiovasc. Med.

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“…6 Data was obtained from parts printed using a Form 2, 100 µm, High Temp settings, and postcured with Form Cure at 80 • C for 120 min. 7 Data was obtained from parts printed using a Form 2, 100 µm, High Temp settings, and postcured with Form Cure at 60 • C for 60 min plus an additional thermal cure in a lab oven at 160 • C for 90 min.…”

Section: Structural Resinmentioning

confidence: 99%

A Review of Vat Photopolymerization Technology: Materials, Applications, Challenges, and Future Trends of 3D Printing

et al. 2021

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Additive manufacturing (3D printing) has significantly changed the prototyping process in terms of technology, construction, materials, and their multiphysical properties. Among the most popular 3D printing techniques is vat photopolymerization, in which ultraviolet (UV) light is deployed to form chains between molecules of liquid light-curable resin, crosslink them, and as a result, solidify the resin. In this manuscript, three photopolymerization technologies, namely, stereolithography (SLA), digital light processing (DLP), and continuous digital light processing (CDLP), are reviewed. Additionally, the after-cured mechanical properties of light-curable resin materials are listed, along with a number of case studies showing their applications in practice. The manuscript aims at providing an overview and future trend of the photopolymerization technology to inspire the readers to engage in further research in this field, especially regarding developing new materials and mathematical models for microrods and bionic structures.

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“…3D bioprinted vascular grafts, comprised of autologous mesenchymal stem cells printed onto conventional artificial grafts, were implanted into canine bilateral carotid and femoral arteries. Those that received the bioprinted grafts showed increased endothelialization and decreased inflammation relative to a control group that received artificial grafts alone ( 80 ). Microsteriolithography was utilized to generate an artificial limbus structure using rabbit limbal fibroblasts and endothelial cells.…”

Section: D Bioprinted Tissue and Organ Constructsmentioning

confidence: 99%

A Review of Recent Advances in 3D Bioprinting With an Eye on Future Regenerative Therapies in Veterinary Medicine

et al. 2021

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3D bioprinting is a rapidly evolving industry that has been utilized for a variety of biomedical applications. It differs from traditional 3D printing in that it utilizes bioinks comprised of cells and other biomaterials to allow for the generation of complex functional tissues. Bioprinting involves computational modeling, bioink preparation, bioink deposition, and subsequent maturation of printed products; it is an intricate process where bioink composition, bioprinting approach, and bioprinter type must be considered during construct development. This technology has already found success in human studies, where a variety of functional tissues have been generated for both in vitro and in vivo applications. Although the main driving force behind innovation in 3D bioprinting has been utility in human medicine, recent efforts investigating its veterinary application have begun to emerge. To date, 3D bioprinting has been utilized to create bone, cardiovascular, cartilage, corneal and neural constructs in animal species. Furthermore, the use of animal-derived cells and various animal models in human research have provided additional information regarding its capacity for veterinary translation. While these studies have produced some promising results, technological limitations as well as ethical and regulatory challenges have impeded clinical acceptance. This article reviews the current understanding of 3D bioprinting technology and its recent advancements with a focus on recent successes and future translation in veterinary medicine.

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Enhanced Biocompatibility of Multi-Layered, 3D Bio-Printed Artificial Vessels Composed of Autologous Mesenchymal Stem Cells

Cited by 28 publications

References 27 publications

Progressive Reinvention or Destination Lost? Half a Century of Cardiovascular Tissue Engineering

Progressive Reinvention or Destination Lost? Half a Century of Cardiovascular Tissue Engineering

A Review of Vat Photopolymerization Technology: Materials, Applications, Challenges, and Future Trends of 3D Printing

A Review of Recent Advances in 3D Bioprinting With an Eye on Future Regenerative Therapies in Veterinary Medicine

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