Application and Research Progress of Extracellular Matrix in Long Segmental Tracheal Defect_Chinese Journal of Clinical Thoracic and Cardiovascular Surgery

Authors：

ZHANG Fangbiao , ZHANG Weidong , SHI Hongcan.

Department of Thoracic Surgery，Medical College of Yangzhou University，Yangzhou 225001，Jiangsu，P. R. China;

Corresponding author：

Keywords：

Extracellular matrix; 　Aorta; 　Trachea; 　Biological composite material

DOI：

10.7507/1007-4848.20130099

Video：

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Patients with pathological tracheal loss more than a certain length may need tracheal transplantation.Traditional natural tissue and autologous tissue have failed to produce satisfactory clinical outcomes to replace the trachea because of local infection，tracheal stenosis，tracheomalacia，immune rejection et al. In recent years，the emergence oftissue engineering trachea provides a new idea for tracheal transplantation. But scientists have not yet reached a consensus about how to choose ideal extracellular matrix to construct tissue engineering trachea. At present research and applicationof tissue engineering trachea，extracellular matrices mainly include allogenic trachea，allogenic aorta and biologicalcomposite materials. Each allogenic matrix or biological composite material has its own advantages and disadvantages. Therefore，this article mainly summarizes recent application and research progress of extracellular matrix in long segmental tracheal defect and its future perspective.

Citation： ZHANG Fangbiao,ZHANG Weidong,SHI Hongcan.. Application and Research Progress of Extracellular Matrix in Long Segmental Tracheal Defect. Chinese Journal of Clinical Thoracic and Cardiovascular Surgery, 2013, 20(3): 334-337. doi: 10.7507/1007-4848.20130099 Copy

1.	Kalathur M，Baiguera S，Macchiarini P. Translating tissue-engineered tracheal replacement from bench to bedside. Cell Mol Life Sci，2010，67 （24）：4185-4196.
2.	Jungebluth P，Alici E，Baiguera S，et al. Tracheobronchial transplantation with a stem-cell-seeded bioartificial nanocomposite：a proof-of-concept study. Lancet，2011，378 （9808）：1997-2004.
3.	Jungebluth P，Bader A，Baiguera S，et al. The concept of in vivo airway tissue engineering. Biomaterials，2012，33 （17）：4319-4326.
4.	Go T，Jungebluth P，Baiguero S，et al. Both epithelial cells and mesenchymal stem cell-derived chondrocytes contribute to the survival of tissue-engineered airway transplants in pigs. J Thorac Cardiovasc Surg，2010，139 （2）：437-443.
5.	Macchiarini P，Jungebluth P，Go T，et al. Clinical transplantation of a tissue-engineered airway. Lancet，2008，372 （9655）：2023-2030.
6.	Conconi MT，De Coppi P，Di Liddo R，et al. Tracheal matrices，obtained by a detergent-enzymatic method，support in vitro the adhesion of chondrocytes and tracheal epithelial cells. Transpl Int，2005，18 （6）：727-734.
7.	Shi HC，Xu H，Lu D，et al. Animal models of tracheal allotransplantation using vitrified cryopreservation. J Thorac Cardiovasc Surg，2009，138 （5）：1222-1226.
8.	Han Y，Lan N，Pang CJ，et al. Bone marrow-derived mesenchymal stem cells enhance cryopreserved trachea allograft epithelium regeneration and vascular endothelial growth factor expression. Transplantation，2011，92 （6）：620-626.
9.	Liu Y，Yang Y，Ding JY，et al. Ultrastructural changes in cryopreserved tracheal grafts of sprague-dawley rats. ASAIO J，2009，55 （5）：509-513.
10.	Haag J，Baiguera S，Jungebluth P，et al. Biomechanical and angiogenic properties of tissue-engineered rat trachea using genipin cross-linked decellularized tissue. Biomaterials，2012，33 （3）：780-789.
11.	Baiguera S，Jungebluth P，Burns A，et al. Tissue engineered human tracheas for in vivo implantation. Biomaterials，2010，31 （34）：8931-8938.
12.	Delaere P，Vrancks J，Verleden G，et al. Tracheal allotransplantation after withdrawal of immunosuppressive therapy. N Engl J Med，2010，194 （7）：1335-1337.
13.	Wurtz A，Porte H，Conti M，et al. Surgical technique and results of tracheal and carinal replacement with aortic allografts for salivary gland-type carcinoma. J Thorac Cardiovasc Surg，2010，140 （2）：387-393.
14.	Tsukada H，Ernst A，Gangadharan S，et al. Tracheal replacement with a silicone-stented，fresh aortic allograft in sheep. Ann Thorac Surg，2010，89 （1）：253-258.
15.	Makris D，Holder-Espinasse M，Wurtz A，et al. Tracheal replacement with cryopreserved allogenic aorta. Chest，2010，137 （1）：60-67.
16.	Kim DH，Choi CB，Yang WJ，et al. Tracheal replacement with fresh and cryopreserved aortic allograft in adult dog. J Surg Res，2012，175 （2）：199-206.
17.	Seguin A，Radu D，Holder-Espinasse M，et al. Tracheal replacement with cryopreserved，decellularized，or glutaraldehyde-treated aortic allografts. Ann Thorac Surg，2009，87 （3）：861-867.
18.	Wang YC，Wong LB，Mao H. Creation of a long-lifespan ciliated epithelial tissue structure using a 3D collagen scaffold. Biomaterials，2010，31 （5）：848-853.
19.	Alves da Silva ML，Crawford A，Mundy JM，et al. Chitosan/polyester-based scaffolds for cartilage tissue engineering：assessment of extracellular matrix formation. Acta Biomater，2010，6 （3）：1149-1157.
20.	Cui L，Wu YH，Cen L，et al. Repair of articular cartilage defect in non-weight bearing areas using adipose derived stem cells loaded polyglycolic acid mesh. Biomaterials，2009，30 （14）：2683-2693.
21.	Liu LQ，Wu W，Tuo XY，et al. Novel strategy to engineer trachea cartilage graft with marrow mesenchymal stem cell macroaggregate and hydrolyzable scaffold. Artif Organs，2010，34 （5）：426-433.
22.	Jungebluth P，Moll G，Baiguera S，et al. Tissue-engineered airway：a regenerative solution. Clin Pharmacol Ther，2012，91 （1）：81-93.
23.	Agarwal S，Wendorff JH，Greiner A. Progress in the field of electrospinning for tissue engineering applications. Adv Mater，2009，21 （32-33）：3343-3351.
24.	Li MY，Mondrinos MJ，Gandhi MR，et al. Electrospun protein fibers as matrices for tissue engineering. Biomaterials，2005，26 （30）：5999-6008.
25.	Chen ZG，Wang PW，Wei B，et al. Electrospun collagen-chitosan nanofiber：a biomimetic extracellular matrix for endothelial cell and smooth cell and smooth muscle cell. Acta Biomaterials，2010，6 （2）：372-382.
26.	Grafahrend D，Heffels KH，Beer MV，et al. Degradable polyester scaffolds with controlled surface chemistry combining minimal protein adsorption with specific bioactivation. Nat Mater，2011，10 （1）：67-73.
27.	Rnjak-Kovacina J，Weiss AS. Increasing the pore size of electrospun scaffolds. Tissue Eng Part B Rev，2011，17 （5）：365-372.
28.	Hinderer S，Schesny M，Bayrak A，et al. Engineering of fibrillar decorin matrices for a tissue-engineered trachea. Biomaterials，2012，33 （21）：5259-5266.
29.	Baiguera S，Del Gaudio C，Jaus MO，et al. Long-term changes to in vitro preserved bioengineered human trachea and their implications for decellularized tissues. Biomaterials，2012，33 （14）：3662-3672.

1. 　Kalathur M，Baiguera S，Macchiarini P. Translating tissue-engineered tracheal replacement from bench to bedside. Cell Mol Life Sci，2010，67 （24）：4185-4196.
2. 　Jungebluth P，Alici E，Baiguera S，et al. Tracheobronchial transplantation with a stem-cell-seeded bioartificial nanocomposite：a proof-of-concept study. Lancet，2011，378 （9808）：1997-2004.
3. 　Jungebluth P，Bader A，Baiguera S，et al. The concept of in vivo airway tissue engineering. Biomaterials，2012，33 （17）：4319-4326.
4. 　Go T，Jungebluth P，Baiguero S，et al. Both epithelial cells and mesenchymal stem cell-derived chondrocytes contribute to the survival of tissue-engineered airway transplants in pigs. J Thorac Cardiovasc Surg，2010，139 （2）：437-443.
5. 　Macchiarini P，Jungebluth P，Go T，et al. Clinical transplantation of a tissue-engineered airway. Lancet，2008，372 （9655）：2023-2030.
6. 　Conconi MT，De Coppi P，Di Liddo R，et al. Tracheal matrices，obtained by a detergent-enzymatic method，support in vitro the adhesion of chondrocytes and tracheal epithelial cells. Transpl Int，2005，18 （6）：727-734.
7. 　Shi HC，Xu H，Lu D，et al. Animal models of tracheal allotransplantation using vitrified cryopreservation. J Thorac Cardiovasc Surg，2009，138 （5）：1222-1226.
8. 　Han Y，Lan N，Pang CJ，et al. Bone marrow-derived mesenchymal stem cells enhance cryopreserved trachea allograft epithelium regeneration and vascular endothelial growth factor expression. Transplantation，2011，92 （6）：620-626.
9. 　Liu Y，Yang Y，Ding JY，et al. Ultrastructural changes in cryopreserved tracheal grafts of sprague-dawley rats. ASAIO J，2009，55 （5）：509-513.
10. 　Haag J，Baiguera S，Jungebluth P，et al. Biomechanical and angiogenic properties of tissue-engineered rat trachea using genipin cross-linked decellularized tissue. Biomaterials，2012，33 （3）：780-789.
11. 　Baiguera S，Jungebluth P，Burns A，et al. Tissue engineered human tracheas for in vivo implantation. Biomaterials，2010，31 （34）：8931-8938.
12. 　Delaere P，Vrancks J，Verleden G，et al. Tracheal allotransplantation after withdrawal of immunosuppressive therapy. N Engl J Med，2010，194 （7）：1335-1337.
13. 　Wurtz A，Porte H，Conti M，et al. Surgical technique and results of tracheal and carinal replacement with aortic allografts for salivary gland-type carcinoma. J Thorac Cardiovasc Surg，2010，140 （2）：387-393.
14. 　Tsukada H，Ernst A，Gangadharan S，et al. Tracheal replacement with a silicone-stented，fresh aortic allograft in sheep. Ann Thorac Surg，2010，89 （1）：253-258.
15. 　Makris D，Holder-Espinasse M，Wurtz A，et al. Tracheal replacement with cryopreserved allogenic aorta. Chest，2010，137 （1）：60-67.
16. 　Kim DH，Choi CB，Yang WJ，et al. Tracheal replacement with fresh and cryopreserved aortic allograft in adult dog. J Surg Res，2012，175 （2）：199-206.
17. 　Seguin A，Radu D，Holder-Espinasse M，et al. Tracheal replacement with cryopreserved，decellularized，or glutaraldehyde-treated aortic allografts. Ann Thorac Surg，2009，87 （3）：861-867.
18. 　Wang YC，Wong LB，Mao H. Creation of a long-lifespan ciliated epithelial tissue structure using a 3D collagen scaffold. Biomaterials，2010，31 （5）：848-853.
19. 　Alves da Silva ML，Crawford A，Mundy JM，et al. Chitosan/polyester-based scaffolds for cartilage tissue engineering：assessment of extracellular matrix formation. Acta Biomater，2010，6 （3）：1149-1157.
20. 　Cui L，Wu YH，Cen L，et al. Repair of articular cartilage defect in non-weight bearing areas using adipose derived stem cells loaded polyglycolic acid mesh. Biomaterials，2009，30 （14）：2683-2693.
21. 　Liu LQ，Wu W，Tuo XY，et al. Novel strategy to engineer trachea cartilage graft with marrow mesenchymal stem cell macroaggregate and hydrolyzable scaffold. Artif Organs，2010，34 （5）：426-433.
22. 　Jungebluth P，Moll G，Baiguera S，et al. Tissue-engineered airway：a regenerative solution. Clin Pharmacol Ther，2012，91 （1）：81-93.
23. 　Agarwal S，Wendorff JH，Greiner A. Progress in the field of electrospinning for tissue engineering applications. Adv Mater，2009，21 （32-33）：3343-3351.
24. 　Li MY，Mondrinos MJ，Gandhi MR，et al. Electrospun protein fibers as matrices for tissue engineering. Biomaterials，2005，26 （30）：5999-6008.
25. 　Chen ZG，Wang PW，Wei B，et al. Electrospun collagen-chitosan nanofiber：a biomimetic extracellular matrix for endothelial cell and smooth cell and smooth muscle cell. Acta Biomaterials，2010，6 （2）：372-382.
26. 　Grafahrend D，Heffels KH，Beer MV，et al. Degradable polyester scaffolds with controlled surface chemistry combining minimal protein adsorption with specific bioactivation. Nat Mater，2011，10 （1）：67-73.
27. 　Rnjak-Kovacina J，Weiss AS. Increasing the pore size of electrospun scaffolds. Tissue Eng Part B Rev，2011，17 （5）：365-372.
28. 　Hinderer S，Schesny M，Bayrak A，et al. Engineering of fibrillar decorin matrices for a tissue-engineered trachea. Biomaterials，2012，33 （21）：5259-5266.
29. 　Baiguera S，Del Gaudio C，Jaus MO，et al. Long-term changes to in vitro preserved bioengineered human trachea and their implications for decellularized tissues. Biomaterials，2012，33 （14）：3662-3672.

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