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

Dhasmana, Archna; Singh, Akriti; S, Rawal

doi:10.1002/term.3019

Cited by 54 publications

(55 citation statements)

References 129 publications

(152 reference statements)

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“…A successful clinical application of a tissue‐engineered trachea, fabricated using collagen and polypropylene was first reported in 2005 (Omori et al., 2005). The outcomes of other clinically implanted materials, such as aortic allografts seeded with mesenchymal stem cells have been successful (Dhasmana et al., 2020; McPhail et al., 2020). However, the risks of repeated inflammation and graft rejection persist.…”

Section: Discussionmentioning

confidence: 99%

“…Our group developed and clinically applied a tracheal graft made of collagen and polypropylene (Omori et al., 2005). Tissue‐engineered tracheal grafts can regenerate ciliated cells (Dhasmana et al., 2020). Although the motility of the cilia in the regenerated epithelia has been confirmed in an animal study (T. Nakamura et al., 2000), the directions of the ciliary beating of the cells in the regenerated epithelium remain unclear.…”

Section: Introductionmentioning

confidence: 99%

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Airway ciliated cells regenerated on collagen sponge implants acquire planar polarities towards nearby edges of implanted areas

Nakamura

Katsuno

Tsuji

et al. 2021

J Tissue Eng Regen Med

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Summary Tissue‐engineered tracheae have been developed to replace defective tracheae. However, the direction of ciliated cells in the regenerated epithelium remains unclear. We investigated planar polarity formed in the regenerated airway epithelium after tracheal graft implantation. We partially resected the rat trachea and implanted a collagen scaffold. The direction of the basal foot was assessed by transmission electron microscopy. Immunofluorescence staining was performed to examine the biased distribution of Vangl1 and Frizzled6 proteins. The direction of mucociliary transport was analyzed by video microscopy. Our results showed that the basal feet of cilia in the proximal and distal regions of the implanted areas were respectively oriented toward the proximal and distal directions. The biased distribution of Vangl1 and Frizzled6, and the directions of mucociliary transport showed that planar polarities formed in the regenerated epithelium were oriented toward the proximal, distal, left, and right directions in the proximal, distal, left, and right regions of the implanted area. These polarities persisted until nine months after implantation. Hence, the results suggest that planar polarities formed in epithelia regenerated on tracheal grafts are directed toward the nearby edges of implanted areas and are preserved for a prolonged period. The polarities can, at least partially, contribute to clearing external materials from the implanted areas by transporting them to a normal region.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Airway ciliated cells regenerated on collagen sponge implants acquire planar polarities towards nearby edges of implanted areas

Nakamura

Katsuno

Tsuji

et al. 2021

J Tissue Eng Regen Med

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“…Regenerative medicine is an emerging interdisciplinary field of research and clinical applications focused on the repair, replacement, and regeneration of cells, tissues, or organs to restore damaged function from any cause, including congenital defects, diseases, and trauma [ 56 ]. This field includes therapeutic areas that were initially thought to be separate, such as cell therapy and tissue engineering (in vitro creation of tissues/organs for a subsequent transplantation as fully functional organs or tissue grafts) [ 57 , 58 ]. In particular, in cell therapy, the use of a biocompatible/bioabsorbable scaffold is not required, whereas in tissue engineering, a tridimensional biocompatible/bioabsorbable structure is necessary to support the regeneration of the damaged tissue [ 59 ].…”

Section: Main Bodymentioning

confidence: 99%

Current Strategies for Tracheal Replacement: A Review

Damiano

Palumbo

Fazzotta

et al. 2021

Life

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Airway cancers have been increasing in recent years. Tracheal resection is commonly performed during surgery and is burdened from post-operative complications severely affecting quality of life. Tracheal resection is usually carried out in primary tracheal tumors or other neoplasms of the neck region. Regenerative medicine for tracheal replacement using bio-prosthesis is under current research. In recent years, attempts were made to replace and transplant human cadaver trachea. An effective vascular supply is fundamental for a successful tracheal transplantation. The use of biological scaffolds derived from decellularized tissues has the advantage of a three-dimensional structure based on the native extracellular matrix promoting the perfusion, vascularization, and differentiation of the seeded cell typologies. By appropriately modulating some experimental parameters, it is possible to change the characteristics of the surface. The obtained membranes could theoretically be affixed to a decellularized tissue, but, in practice, it needs to ensure adhesion to the biological substrate and/or glue adhesion with biocompatible glues. It is also known that many of the biocompatible glues can be toxic or poorly tolerated and induce inflammatory phenomena or rejection. In tissue and organ transplants, decellularized tissues must not produce adverse immunological reactions and lead to rejection phenomena; at the same time, the transplant tissue must retain the mechanical properties of the original tissue. This review describes the attempts so far developed and the current lines of research in the field of tracheal replacement.

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“…Trachea is a fundamental cartilaginous construct for living beings that causes respiratory problems when damaged and causes cancer if disorders are not cured in time. Tracheal tissue engineering features and outcomes have recently been overviewed by Dashmana et al [154]. Human epithelial cells cocultured with articular chondrocytes within fibrin scaffolds have been proven to be highly efficient [155].…”

Section: Specific Applications In Tissue Regenerationmentioning

confidence: 99%

Biomimetic Hybrid Systems for Tissue Engineering

2020

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Tissue engineering approaches appear nowadays highly promising for the regeneration of injured/diseased tissues. Biomimetic scaffolds are continuously been developed to act as structural support for cell growth and proliferation as well as for the delivery of cells able to be differentiated, and also of bioactive molecules like growth factors and even signaling cues. The current research concerns materials employed to develop biological scaffolds with improved features as well as complex preparation techniques. In this work, hybrid systems based on natural polymers are discussed and the efforts focused to provide new polymers able to mimic proteins and DNA are extensively explained. Progress on the scaffold fabrication technique is mentioned, those processes based on solution and melt electrospinning or even on their combination being mainly discussed. Selection of the appropriate hybrid technology becomes vital to get optimal architecture to reasonably accomplish the final applications. Representative examples of the recent possibilities on tissue regeneration are finally given.

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

Cited by 54 publications

References 129 publications

Airway ciliated cells regenerated on collagen sponge implants acquire planar polarities towards nearby edges of implanted areas

Airway ciliated cells regenerated on collagen sponge implants acquire planar polarities towards nearby edges of implanted areas

Current Strategies for Tracheal Replacement: A Review

Biomimetic Hybrid Systems for Tissue Engineering

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