Clinic Application of Tissue Engineered Bronchus for Lung Cancer Treatment

Overview

Journal J Thorac Dis

Publisher AME Publishing Company

Specialty Pulmonary Medicine

Date 2017 Feb 17

PMID 28203403

Citations 10

Authors

Qiang Tan

Ruijun Liu

Xiaoke Chen

Jingxiang Wu

Yinggen Pan

Shun Lu

Walter Weder

Qingquan Luo

Affiliations

Soon will be listed here.

Abstract

Background: Delayed revascularization process and substitute infection remain to be key challenges in tissue engineered (TE) airway reconstruction. We propose an " bioreactor" design, defined as an implanted TE substitutes perfused with an intra-scaffold medium flow created by an extracorporeal portable pump system for organ regeneration. The perfusate keeps pre-seeded cells alive before revascularization. Meanwhile the antibiotic inside the perfusate controls topical infection.

Methods: A stage IIIA squamous lung cancer patient received a 5-cm TE airway substitute, bridging left basal segment bronchus to carina, with the bioreactor design to avoid left pneumonectomy. Continuous intra-scaffold Ringer's-gentamicin perfusion lasted for 1 month, together with orthotopic peripheral total nucleated cells (TNCs) injection twice a week.

Results: The patient recovered uneventfully. Bronchoscopy follow-up confirmed complete revascularization and reepithelialization four months postoperatively. Perfusate waste test demonstrated various revascularization growth factors secreted by TNCs. The patient received two cycles of chemotherapy and 30 Gy radiotherapy thereafter without complications related to the TE substitute.

Conclusions: bioreactor design combines the traditionally separated 3D cell-scaffold culture system and the regenerative processes associated with TE substitutes, while treating the recipients as bioreactors for their own TE prostheses. This design can be applied clinically. We also proved for the first time that TE airway substitute is able to tolerate chemo-radiotherapy and suitable to be used in cancer treatment.

Citing Articles

Advances in lung bioengineering: Where we are, where we need to go, and how to get there.

Hsiung T, James L, Chang S, Geraci T, Angel L, Chan J Front Transplant. 2024; 2:1147595.

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Current Advances in the Use of Tissue Engineering for Cancer Metastasis Therapeutics.

Katti P, Jasuja H Polymers (Basel). 2024; 16(5).

PMID: 38475301 PMC: 10934711. DOI: 10.3390/polym16050617.

Evaluation of a decellularized bronchial patch transplant in a porcine model.

Taniguchi D, Kamata S, Rostami S, Tuin S, Marin-Araujo A, Guthrie K Sci Rep. 2023; 13(1):21773.

PMID: 38066170 PMC: 10709302. DOI: 10.1038/s41598-023-48643-y.

Application of tissue engineering techniques in tracheal repair: a bibliometric study.

Xu X, Shen Z, Shan Y, Sun F, Lu Y, Zhu J Bioengineered. 2023; 14(1):2274150.

PMID: 37927226 PMC: 10629433. DOI: 10.1080/21655979.2023.2274150.

Epidemiology and Long-Term Outcomes in Thoracic Transplantation.

Abraham A, Singh M, Abraham M, Ahuja S J Cardiovasc Dev Dis. 2023; 10(9).

PMID: 37754826 PMC: 10531612. DOI: 10.3390/jcdd10090397.

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