Tracheal Macrophages During Regeneration and Repair of Long‐Segment Airway Defects

Tan, Zheng Hong; Dharmadhikari, Sayali; Liu, Lumei; Wolter, Gabrielle L; Shontz, Kimberly M.; Reynolds, Susan D.; Johnson, Jed; Breuer, Christopher K.; Chiang, Tendy

doi:10.1002/lary.29698

Cited by 12 publications

(15 citation statements)

References 47 publications

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“…Several factors contributed to respiratory distress that required early euthanasia. First, the mouse model of orthotopic tracheal replacement has inherent challenges and is associated with perioperative morbidity 7 , 19 , 25 , 33 Additionally, a reduction in graft diameter leads to airway obstruction and respiratory symptoms. However, the specific histologic factors identified in the early euthanasia group were diverse, including both cartilaginous collapse and intraluminal stenosis.…”

Section: Discussionmentioning

confidence: 99%

“…48,49 The splint did not increase macrophage infiltration, change macrophage phenotype, or attenuate graft epithelialization and endothelialization, resulting in similar submucosal thickening to syngeneic controls. 19,25 The effect of our splint on submucosal thickness could be attributed to changes in the micromechanical environment, limiting cell infiltration. 24,50,51 Further study of inflammatory cell types and populations in the lamina propria and their roles in submucosal thickening will be characterized based on ongoing work using single-cell RNA sequencing.…”

Section: Discussionmentioning

confidence: 99%

“…Previous work has demonstrated host-derived myeloid cells as the major population infiltrating the lamina propria and mediating the chronic inflammatory response in tracheal grafts resulting in stenosis. 19 , 20 , 25 – 30 Immunohistochemistry (IHC) was performed to examine macrophage (pan, M1, and M2) distribution (CD68, CD206, iNOS respectively) using methods described previously as this is one of the most prevalent myeloid cell type seen in implanted tracheal grafts. 31 , 32 Immunofluorescent (IF) staining for epithelial (ACT, CCSP, K5/K14) and endothelial (CD31) biomarkers was completed using previously described methods.…”

Section: Methodsmentioning

confidence: 99%

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Tissue-engineered composite tracheal grafts create mechanically stable and biocompatible airway replacements

et al. 2022

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We tested composite tracheal grafts (CTG) composed of a partially decellularized tracheal graft (PDTG) combined with a 3-dimensional (3D)-printed airway splint for use in long-segment airway reconstruction. CTG is designed to recapitulate the 3D extracellular matrix of the trachea with stable mechanical properties imparted from the extraluminal airway splint. We performed segmental orthotopic tracheal replacement in a mouse microsurgical model. MicroCT was used to measure graft patency. Tracheal neotissue formation was quantified histologically. Airflow dynamic properties were analyzed using computational fluid dynamics. We found that CTG are easily implanted and did not result in vascular erosion, tracheal injury, or inflammation. Graft epithelialization and endothelialization were comparable with CTG to control. Tracheal collapse was absent with CTG. Composite tracheal scaffolds combine biocompatible synthetic support with PDTG, supporting the regeneration of host epithelium while maintaining graft structure.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Tissue-engineered composite tracheal grafts create mechanically stable and biocompatible airway replacements

et al. 2022

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“…Chemical treatments adopt detergents/chemicals to induce cellular bonds disruption up to cellular components removal. Considering tracheal tissue, the resort to chemicals alone (no enzymes) was attempted by Dang et al, 3 , 17 Kutten et al, 20 Liu et al, 22 Wood et al, 50 Hung et al, 51 and Tan et al 52 Specifically, the solutions consisted in detergents (sodium dodecyl sulfate (SDS) (ionic) and Triton X-100 (non-ionic)), hypertonic solutions (sodium chloride (NaCl)), acids (peracetic acid), bases (ammonium hydroxide (NH 4 OH)) and organic solvents (ethanol), alone or combined within more complex protocols. Regarding the physical treatments, agitation (broadly recommended by the Authors) was also eventually associated with sonication/ultrasonication, 3 , 17 , 51 freeze-drying, 51 freeze-thawing, 20 , 50 and vacuum.…”

Section: Introductionmentioning

confidence: 99%

“…The methods described, free from enzymes presence, allowed to set up only segmental, partially decellularized substitutes still showing chondrocytes within the lacunae; no repopulation of the samples was performed before graft positioning. 20 , 22 , 52 …”

Section: Introductionmentioning

confidence: 99%

Preclinical and clinical orthotopic transplantation of decellularized/engineered tracheal scaffolds: A systematic literature review

et al. 2023

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Severe tracheal injuries that cannot be managed by mobilization and end-to-end anastomosis represent an unmet clinical need and an urgent challenge to face in surgical practice; within this scenario, decellularized scaffolds (eventually bioengineered) are currently a tempting option among tissue engineered substitutes. The success of a decellularized trachea is expression of a balanced approach in cells removal while preserving the extracellular matrix (ECM) architecture/mechanical properties. Revising the literature, many Authors report about different methods for acellular tracheal ECMs development; however, only few of them verified the devices effectiveness by an orthotopic implant in animal models of disease. To support translational medicine in this field, here we provide a systematic review on studies recurring to decellularized/bioengineered tracheas implantation. After describing the specific methodological aspects, orthotopic implant results are verified. Furtherly, the only three clinical cases of compassionate use of tissue engineered tracheas are reported with a focus on outcomes.

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Partial decellularization eliminates immunogenicity in tracheal allografts

Tan

Liu

Dharmadhikari

et al. 2023

Bioengineering & Transla Med

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There is currently no suitable autologous tissue to bridge large tracheal defects. As a result, no standard of care exists for long‐segment tracheal reconstruction. Tissue engineering has the potential to create a scaffold from allografts or xenografts that can support neotissue regeneration identical to the native trachea. Recent advances in tissue engineering have led to the idea of partial decellularization that allows for the creation of tracheal scaffolds that supports tracheal epithelial formation while preserving mechanical properties. However, the ability of partial decellularization to eliminate graft immunogenicity remains unknown, and understanding the immunogenic properties of partially decellularized tracheal grafts (PDTG) is a critical step toward clinical translation. Here, we determined that tracheal allograft immunogenicity results in epithelial cell sloughing and replacement with dysplastic columnar epithelium and that partial decellularization creates grafts that are able to support an epithelium without histologic signs of rejection. Moreover, allograft implantation elicits CD8+ T‐cell infiltration, a mediator of rejection, while PDTG did not. Hence, we establish that partial decellularization eliminates allograft immunogenicity while creating a scaffold for implantation that can support spatially appropriate airway regeneration.

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Tracheal Macrophages During Regeneration and Repair of Long‐Segment Airway Defects

Cited by 12 publications

References 47 publications

Tissue-engineered composite tracheal grafts create mechanically stable and biocompatible airway replacements

Tissue-engineered composite tracheal grafts create mechanically stable and biocompatible airway replacements

Preclinical and clinical orthotopic transplantation of decellularized/engineered tracheal scaffolds: A systematic literature review

Partial decellularization eliminates immunogenicity in tracheal allografts

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