Three-dimensional bioprinting of multilayered constructs containing human mesenchymal stromal cells for osteochondral tissue regeneration in the rabbit knee joint

Shim, Jin Hyung; Jang, Ki-Mo; Hahn, Sei Kwang; Park, Ju Young; Jung, Hyuntae; Oh, Kyunghoon; Park, Kyeng Min; Yeom, Junseok; Park, Sun Hwa; Kim, Sung Won; Wang, Joon Ho; Kim, Kimoon; Cho, Dong‐Woo

doi:10.1088/1758-5090/8/1/014102

Cited by 215 publications

(166 citation statements)

References 50 publications

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“…Therefore, new studies focus on using alternative hydrogels such as decellularized extracellular matrix bioink to print cell‐laden constructs, which provides an optimized microenvironment for the growth of 3D tissue . Furthermore, researchers focus on fabricate 3D multilayered constructs consisting live cells and different ECM materials for heterogenous tissue regeneration …”

Section: Introductionmentioning

confidence: 99%

“…21 Furthermore, researchers focus on fabricate 3D multilayered constructs consisting live cells and different ECM materials for heterogenous tissue regeneration. 22 Extrusion-based bioprinting process can also be used for direct printing of cellular-aggregates. In extrusion-based bioprinting processes, biomaterial concentration, loaded cell viscosity, nozzle pressure, and nozzle diameter are determinant parameters for continuous deposition of cylindrical cell aggregates and hydrogel biomaterials.…”

Section: Introductionmentioning

confidence: 99%

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Three‐dimensional direct cell bioprinting for tissue engineering

et al. 2016

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Bioprinting is a relatively new technology where living cells with or without biomaterials are printed layer-by-layer in order to create three-dimensional (3D) living structures. In this article, novel bioprinting methodologies are developed to fabricate 3D biological structures directly from computer models using live multicellular aggregates. Multicellular aggregates made out of at least two cell types from fibroblast, endothelial and smooth muscle cells are prepared and optimized. A novel bioprinting approach is proposed in order to continuously extrude cylindrical multicellular aggregates through the bioprinter's glass microcapillaries. The multicellular aggregates are first aspirated into a capillary and then compressed to form a continuous cylindrical multicellular bioink. To overcome surface tension-driven droplet formation, the required compression ratio is calculated. Based on the developed bioprinting strategies, multicellular aggregates and their support structures are bioprinted to form 3D tissue constructs with predefined shapes. The effect of the bioprinting process was examined for fusion, cell viability at different compression ratios, and f-actin cytoskeletal organization. The results show that the bioprinted 3D constructs fuse rapidly and have high cell viability after printing. © 2016 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 2530-2544, 2017.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Three‐dimensional direct cell bioprinting for tissue engineering

et al. 2016

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“…Biofabricated osteochondral constructs have been already adopted in an in vivo study involving a MSC‐laden collagen and hyaluronic acid hydrogel construct reinforced by PCL. This artificial osteochondral plug was implanted in a rabbit knee and appeared to be mechanically stable and to integrate well with the native cartilage and the underlying bone . The success of this study was, at least in part, due to a perfectly fitting design of the prosthesis, as well as the good integration in both bone and cartilage region, achieved by stack crosslinking with the same cell‐friendly chemistry.…”

Section: Mimicking the Layered Structure Of Native Tissuementioning

confidence: 88%

“…A wide range of smaller osteochondral constructs have been successfully generated using AM alone or in combination with conventional techniques, including casting, freeze‐drying and solvent casting/particle leaching . Even though the generation of a long‐term functional solution in osteochondral tissue engineering remains challenging, in vivo approaches with 3D printed osteochondral plugs have already been reported …”

Section: Mimicking the Layered Structure Of Native Tissuementioning

confidence: 99%

From intricate to integrated: Biofabrication of articulating joints

Groen

Diloksumpan²,

Weeren³

et al. 2017

Journal Orthopaedic Research

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Articulating joints owe their function to the specialized architecture and the complex interplay between multiple tissues including cartilage, bone and synovium. Especially the cartilage component has limited self‐healing capacity and damage often leads to the onset of osteoarthritis, eventually resulting in failure of the joint as an organ. Although in its infancy, biofabrication has emerged as a promising technology to reproduce the intricate organization of the joint, thus enabling the introduction of novel surgical treatments, regenerative therapies, and new sets of tools to enhance our understanding of joint physiology and pathology. Herein, we address the current challenges to recapitulate the complexity of articulating joints and how biofabrication could overcome them. The combination of multiple materials, biological cues and cells in a layer‐by‐layer fashion, can assist in reproducing both the zonal organization of cartilage and the gradual transition from resilient cartilage toward the subchondral bone in biofabricated osteochondral grafts. In this way, optimal integration of engineered constructs with the natural surrounding tissues can be obtained. Mechanical characteristics, including the smoothness and low friction that are hallmarks of the articular surface, can be tuned with multi‐head or hybrid printers by controlling the spatial patterning of printed structures. Moreover, biofabrication can use digital medical images as blueprints for printing patient‐specific implants. Finally, the current rapid advances in biofabrication hold significant potential for developing joint‐on‐a‐chip models for personalized medicine and drug testing or even for the creation of implants that may be used to treat larger parts of the articulating joint. © 2017 The Authors. Journal of Orthopaedic Research Published by Wiley Periodicals, Inc. on behalf of the Orthopaedic Research Society. J Orthop Res 35:2089–2097, 2017.

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“…Without blood vessels, nerves, and lymphoid tissues, once there is injury to the articular cartilage, it has almost no effective ability to repair and rebuild itself [1]. Hydrogels are a kind of three-dimensional porous network with similar mechanical characteristics to those of articular cartilage [2,3,4]. As an ideal material substitute to repair articular cartilage, the physical and chemical properties of hydrogels such as their excellent biocompatibility have received extensive attention from researchers [5,6].…”

Section: Introductionmentioning

confidence: 99%

A Dual-Bonded Approach for Improving Hydrogel Implant Stability in Cartilage Defects

Liu

Zhou

et al. 2017

Materials

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Integration and stability of hydrogels and surrounding cartilage/bone tissue is crucial for both immediate functionality and long-term performance of the tissue. In this work, chondroitin sulphate (CS) a polysaccharide found in cartilage and other tissues was used to synthesize a tough hydrogel that was chemically functionalized with methacrylate and aldehyde groups, bonding to surrounding tissue via a dual-bonded approach. The hydrogel can not only chemically anchor onto implanted titanium at the subchondral bone, but also on cartilage tissue via the Schiff-base reaction. In vitro experiments confirmed that the strategy improved hydrogel implant stability with cartilage tissue, was favorable for chondrocyte attachment, and has the potential to quickly and effectively repair cartilage defects and maintain joint functionality for a long time.

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Three-dimensional bioprinting of multilayered constructs containing human mesenchymal stromal cells for osteochondral tissue regeneration in the rabbit knee joint

Cited by 215 publications

References 50 publications

Three‐dimensional direct cell bioprinting for tissue engineering

Three‐dimensional direct cell bioprinting for tissue engineering

From intricate to integrated: Biofabrication of articulating joints

A Dual-Bonded Approach for Improving Hydrogel Implant Stability in Cartilage Defects

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