3D Bioprinted Artificial Trachea with Epithelial Cells and Chondrogenic-Differentiated Bone Marrow-Derived Mesenchymal Stem Cells

Bae, Seunghee; Lee, Kang-Woog; Park, Jae-Hyun; Lee, JunHee; Jung, Cho‐Rok; Yu, Junjie; Kim, Hwi-Yool; Kim, Dae-Hyun

doi:10.3390/ijms19061624

Cited by 87 publications

(44 citation statements)

References 29 publications

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“…Scaffold seeded with chondrocytes enhanced biomechanical strength of cell‐scaffold construct, but chondrocytes, after implantation, became nonviable. On the other hand, the scaffold, seeded with epithelial cells, showed cell viability and better tracheal tissue regeneration in vivo (Bae et al, ; Go et al, ).…”

Section: Tracheal Tissue Engineeringmentioning

confidence: 99%

Biomedical grafts for tracheal tissue repairing and regeneration “Tracheal tissue engineering: an overview”

Dhasmana

Singh

2020

J Tissue Eng Regen Med

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Airway system is a vital part of the living being body. Trachea is the upper respiratory portion that connects nostril and lungs and has multiple functions such as breathing and entrapment of dust/pathogen particles. Tracheal reconstruction by artificial prosthesis, stents, and grafts are performed clinically for the repairing of damaged tissue. Although these (above-mentioned) methods repair the damaged parts, they have limited applicability like small area wounds and lack of functional tissue regeneration. Tissue engineering helps to overcome the abovementioned problems by modifying the traditional used stents and grafts, not only repair but also regenerate the damaged area to functional tissue. Bioengineered tracheal replacements are biocompatible, nontoxic, porous, and having 3D biomimetic ultrastructure with good mechanical strength, which results in faster and better tissue regeneration. Till date, the bioengineered tracheal replacements studies have been going on preclinical and clinical levels. Besides that, still many researchers are working at advance level to make extracellular matrix-based acellular, 3D printed, cell-seeded grafts including living cells to overcome the demand of tissue or organ and making the ready to use tracheal reconstructs for clinical application. Thus, in this review, we summarized the tracheal tissue engineering aspects and their outcomes. K E Y W O R D S biocompatible, chondrocytes, ECM, in vivo, tissue engineering, trachea

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Section: Tracheal Tissue Engineeringmentioning

confidence: 99%

Biomedical grafts for tracheal tissue repairing and regeneration “Tracheal tissue engineering: an overview”

Dhasmana

Singh

2020

J Tissue Eng Regen Med

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“…The rotating rod is provided as temporary support to the printed biomaterial for keeping a 3D shape and is removed when the printed structure is considered to be self-supporting. Sang-Woo Bae et al printed the artificial tracheal structure with a synthetic polymer (i.e., PCL) and cell-laden bioink (epithelial cells and bone-marrow stem cells) by sequential extruding on the rotating rod [119]. Qing Gao et al fabricated a hydrogel-based vascular structure with multilevel fluidic channels using a combination with co-axial bioprinting [31].…”

Section: Recent Design Approaches For Engineering Tubular Structuresmentioning

confidence: 99%

3D Bioprinting Strategies for the Regeneration of Functional Tubular Tissues and Organs

et al. 2020

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It is difficult to fabricate tubular-shaped tissues and organs (e.g., trachea, blood vessel, and esophagus tissue) with traditional biofabrication techniques (e.g., electrospinning, cell-sheet engineering, and mold-casting) because these have complicated multiple processes. In addition, the tubular-shaped tissues and organs have their own design with target-specific mechanical and biological properties. Therefore, the customized geometrical and physiological environment is required as one of the most critical factors for functional tissue regeneration. 3D bioprinting technology has been receiving attention for the fabrication of patient-tailored and complex-shaped free-form architecture with high reproducibility and versatility. Printable biocomposite inks that can facilitate to build tissue constructs with polymeric frameworks and biochemical microenvironmental cues are also being actively developed for the reconstruction of functional tissue. In this review, we delineated the state-of-the-art of 3D bioprinting techniques specifically for tubular tissue and organ regeneration. In addition, this review described biocomposite inks, such as natural and synthetic polymers. Several described engineering approaches using 3D bioprinting techniques and biocomposite inks may offer beneficial characteristics for the physiological mimicry of human tubular tissues and organs.

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“…Recently, Bae et al used a similar approach co-culturing chondrogenic-differentiated bMSC and respiratory epithelial cells in one scaffold. Neocartilage formation, neo-epithelization and neovascularization could be observed (Bae et al, 2018). Chang et al 3D-printed a 10x10mm half-pipe-shaped PCL scaffold coated with rabbit MSC seeded in human-derived fibrin and then implanted for 8 weeks.…”

Section: Cellular Types Biologic Components and Hydrogelsmentioning

confidence: 99%

3D-bioprinted tracheal reconstruction: an overview

Frejo

Grande

2019

Bioelectron Med

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Congenital tracheomalacia and tracheal stenosis are commonly seen in premature infants. In adulthood, are typically related with chronic obstructive pulmonary disease, and can occur secondarily from tracheostomy, prolong intubation, trauma, infection and tumors. Both conditions are life-threatening when not managed properly. There are still some surgical limitations for certain pathologies, however tissue engineering is a promising approach to treat massive airway dysfunctions. 3D-bioprinting have contributed to current preclinical and clinical efforts in airway reconstruction. Several strategies have been used to overcome the difficulty of airway reconstruction such as scaffold materials, construct designs, cellular types, biologic components, hydrogels and animal models used in tracheal reconstruction. Nevertheless, additional long-term in vivo studies need to be performed to assess the efficacy and safety of tissue-engineered tracheal grafts in terms of mechanical properties, behavior and, the possibility of further stenosis development.

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3D Bioprinted Artificial Trachea with Epithelial Cells and Chondrogenic-Differentiated Bone Marrow-Derived Mesenchymal Stem Cells

Cited by 87 publications

References 29 publications

Biomedical grafts for tracheal tissue repairing and regeneration “Tracheal tissue engineering: an overview”

Biomedical grafts for tracheal tissue repairing and regeneration “Tracheal tissue engineering: an overview”

3D Bioprinting Strategies for the Regeneration of Functional Tubular Tissues and Organs

3D-bioprinted tracheal reconstruction: an overview

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