Bioartificial tracheal grafts: can tissue engineering keep its promise?

References

• Grillo HC. Anatomy of the trachea. In: Surgery of the Trachea and Bronchi. Grillo HC (Ed.). BC Decker Inc, Hamilton, Canada, 39–59 (2004).
   Google Scholar
• Grillo HC. Development of tracheal surgery: a historical review. In: Surgery of the Trachea and Bronchi. Grillo HC (Ed.). BC Decker Inc, Hamilton, Canada, 1–35 (2004).
   Google Scholar
• Grillo HC. Development of tracheal surgery: a historical review. Part 1: Techniques of tracheal surgery. Ann. Thorac. Surg. 75,610–619 (2003).
   Google Scholar
• Grillo HC. Development of tracheal surgery: a historical review. Part 2: Treatment of tracheal diseases. Ann. Thorac. Surg. 75,1039–1047 (2003).
   Google Scholar
• Grillo HC, Wright CD, Vlahakes GJ, MacGillivray TE. Management of congenital tracheal stenosis by means of slide tracheoplasty or resection and reconstruction, with long-term follow-up of growth after slide tracheoplasty. j Thorac. Cardiovasc. Surg. 123,145–152 (2002).
   Google Scholar
• Wood DE. Airway stenting. Chest. Clin. North Am. 13,175–191 (2003).
   Google Scholar
• Grillo HC. Tracheal replacement. In: Surgery of the Trachea and Bronchi. Grillo HC (Ed.). BC Decker Inc, Hamilton, Canada, 839–854 (2004).
   Google Scholar
• Maccharini P. Trachea-guided generation: dela vu all over again? J Thorac. Cardiovasc. Surg. 128,14–16 (2004).
   Google Scholar
• Wykoff TVV. A preliminary report on segmental tracheal prosthetic replacement in dogs. Laryngoscope 83,1072–1077 (1973).
   Google Scholar
• Daniel RA. The regeneration of defects of the trachea and bronchi. An experimental study. J Thorac. Surg. 17,335–349 (1948).
   Google Scholar
• Shaw RR, Aslami A, Webb WR. Circumferential replacement of the trachea in experimental animals. Ann. Thorac. Surg. 5,30–35 (1968).
   Google Scholar
• Demos NJ, Mitnick H, McCally D et al. Tracheal regeneration in long-term survivors with silicone prosthesis. Ann. Thorac. Surg. 16,293–300 (1973).
   Google Scholar
• Bailey BJ, Kosoy J. Observations in the development of tracheal prostheses and tracheal transplantation. Laryngoscope 80, 1553–1565 (1970).
   Google Scholar
• Moncrief WH Jr, Salvatore JE. An improved tracheal prosthesis. Surg. Forum 9,350–352 (1958).
   Google Scholar
• McCall JVV, Whitaker CW. The use of prostheses in the larynx and trachea. Ann. Otol. Rhino]. Larngol. 71,397–403 (1962).
   Google Scholar
• Poticha SM, Lewis FJ. Experimental replacement of the trachea. J Thorac. Cardiovasc. Surg. 52,61–67 (1966).
   Google Scholar
• Kiriluk LB, Merendino KA. An experimental evaluation in the dog of bronchial transplantation, bronchial, tracheal and tracheobronchial resection with reconstruction. Ann. Surg. 137, 490–503 (1953).
   Google Scholar
• Mendak SH Jr, Jensik RJ, Haklin MF, Roseman DL. The evaluation of various bio-absorbable materials on the titanium fiber metal tracheal prosthesis. Ann. Thorac. Surg. 38,488–493 (1984).
   Google Scholar
• Sekine T, Nakamura T, Matsumoto K et al. Carinal reconstruction with a Y-shaped collagen-conjugated prosthesis. J Thorac. Cardiovasc. Surg. 119,1162–1168 (2000).
   Google Scholar
• Teramachi M, Okumura N, Nakamura T et al. Intrathoracic tracheal reconstruction with a collagen-conjugated prosthesis: evaluation of the efficiacy of omental wrapping. J Thorac. Cardiovasc. Surg. 113, 701–711 (1997).
   Google Scholar
• Cull DL, Lally KP, Mair EA eta]. Tracheal reconstruction with polytetrafluoroethylene graft in dogs. Ann. Thorac. Surg. 50, 899–901 (1990).
   Google Scholar
• Nelson RJ, Goldberg L, White RA eta]. Neovasculrity of a tracheal prosthesis/tissue complex. J Thorac. Cardiovasc. Surg. 86, 800–808 (1983).
   Google Scholar
• Jacobs J. Investigations into tracheal prosthetic reconstruction. Laryngoscope 98, 1239–1245 (1988).
   Google Scholar
• Atamuyk MY, Melrose DG. The treatment of circumferential defects of the trachea. Br. Surg. 52,59–65 (1965).
   Google Scholar
• Scherer MA, Ascherl R, Geissdorfer K eta]. Experimental biosynthetic reconstruction of the trachea. Arch. Otorhinolarynol. 243, 215–223 (1986).
   Google Scholar
• Pressman JJ, Simon MB. Tracheal stretching and metaplasia of the tracheal rings from cartilage to bone following the use of aortic homografts. Am. Surg. 25, 850–856 (1959).
   Google Scholar
• Swift EA, Grindlay JH, Clagett OT. The repair of tracheal defects with fascia and tantalum mesh. J Thorac. Surg. 24, 482–492 (1952).
   Google Scholar
• Martinod E, Seguin A, Pfeuty K eta]. Long-term evaluation of the replacement of the trachea with an autologous aortic graft. Ann. Thorac. Surg. 75,1572–1578 (2003).
   Google Scholar
• Daniel RA Jr, Taliaferro RM, Schaffarzick WR. Experimental studies on the repair of wounds and defects of the trachea and bronchi. Dis. Chest 17, 426–441 (1950).
   Google Scholar
• Keshishian JM, Blades B, Beattie EJ. Tracheal reconstruction. j Thorac. Surg. 32, 707–727 (1956).
   Google Scholar
• Michelson E, Solomon R, Maun I, Ramirez J. Experiments in tracheal reconstruction. J Thorac. Cardiovasc. Surg. 41,748–759 (1961).
   Google Scholar
• Bryant LR. Replacement of tracheobronchial defects with autogenous pericardium. J Thorac. Cardiovasc. Surg ,733–740 (1964).
   Google Scholar
• Cohen RC, Filler RM, Konuma K et al. A new model of tracheal stenosis and its repair with free periosteal grafts. J Thorac. Cardiovasc. Surg. 92,296-304 (1986).
   Google Scholar
• Farkas LG, Farmer AW, McCain WG, Wilson WD. Replacement of a tracheal defect in the dog by a preformed composite graft. Plast. Reconstr. Surg. 50,238–241 (1972).
   Google Scholar
• Sabas AA, Uez JB, Rojas 0 et al. Replacement of the trachea with dua mater. Experimental work. J Thorac. Cardiovasc. Surg. 74,761–765 (1977).
   Google Scholar
• Jones RE, Morgan RE Marcella KI et al. Tracheal reconstruction with autogenous jejunal microurgical transfer. Ann. Thorac. Surg. 41,636–638 (1986).
   Google Scholar
• Kimura K, Mukohara N, Tsugawa C et al. Tracheoplasty for congenital stenosis of the entire trachea. J Pediatr. Surg. 17, 869–871 (1982).
   Google Scholar
• Blair E. Study of the viable intercostal pedicle graft in tracheobronchial surgery. J Thorac. Surg. 36,869–878 (1958).
   Google Scholar
• Fonkalsrud EW, Plested WG, Mulder DG. Tracheobronchial reconstruction with autologous periosteum. j Thorac. Cardiovasc. Surg. 52,666–674 (1966).
   Google Scholar
• Nowakowski K. Beitrag zur tracheoplastik. Arch. Kiln. Chir. 90,847–861 (1909).
   Google Scholar
• Westaby S, Shepherd MP, Nohl-Oser HC. The use of diaphragmatic pedicle grafts for reonstructive procedures in the esophagus and tracheobronchial tree. Ann. Thorac. Surg. 33,486–490 (1982).
   Google Scholar
• Kato R, Onuki AS, Watanabe M et al. Tracheal reconstruction by esophageal interposition: an experimental study. Ann. Thorac. Surg. 49,951–954 (1990).
   Google Scholar
• Fuchs JR, Nasseri BA, Vacanti JP. Tissue engineering: a 21st century solution to surgical reconstruction. Ann. Thorac. Surg. 72,577–591 (2001).
   Google Scholar
• Palla S. Molecular biology, tissue engineering and the future of dentistry. J Orofac. Pain 15,273–274 (2001).
   Google Scholar
• Langer R, Vacanti JP. Tissue engineering. Science 260,920–926 (1993).
   Google Scholar
• Vacanti JP, Langer R. Tissue engineering: the design and fabrication of living replacement devices for surgical reconstruction and transplantation. Lancet 354 (Suppl.), S132—S134 (1999).
   Google Scholar
• Belsey R. Resection and reconstruction of the intrathoracic trachea. Br. J Surg. 38, 200–205 (1950).
   Google Scholar
• Fernandez FG, Jaramlllo A, Chen C et al. Airway epithelium is the primari target of allograft rejection in murine obliterative airway disease. Am. J Transplant: 4, 319–325 (2004).
   Google Scholar
• Lenot B, Macchiarini P, Dulmet E, Weiss M, Dartevelle P Tracheal allograft replacement. An unsuccessful method. Eur. Cardiothorac. Surg. 7, 648–652 (1993).
   Google Scholar
• Macchiarini P, Lenot P, Montpreville V et al. Heterotopic pig model for direct revascularization and venous drainage of tracheal allografts. j Thorac. Cardiovasc. Surg. 108,1066–1075 (1994).
   Google Scholar
• Abbott A. Biology's new dimension. Nature 424,870–872 (2003).
   Google Scholar
• Krieg T, Le Roy EC. Diseases of the extracellular matrix. J Mol. Med. 76, 224–225 (1998).
   Google Scholar
• Skalak R, Fox CF. Tissue engineering. Ann. Biotned. EngL 19,529–533 (1991).
   Google Scholar
• Wailes T, Puschmann C, Haverich A, Mertsching H. Acellular scaffold implantation — no alternative to tissue engineering. Int. J Art. Org. 26,225–234 (2003).
   Google Scholar
• Simon P, Kasimir MT, Seebacher G et al Early failure of the tissue-engineered porcine heart valve SYNERGRAFT in pediatric patients. Eur. j Cardiothorac. Surg. 23,1002–1006 (2003).
   Google Scholar
• Hoerstrup SP, Zund G, Schnell AM eta]. Optimized growth conditions for tissue engineering of human cardiovascular structures. Int. fArt. Org. 23,817–823 (2000).
   Google Scholar
• Wailes T, Herden T, Haverich A, Mertsching H. Influence of scaffold thickness and scaffold composition on bioartificial graft survival. Biornaterials 24, 1233–2139 (2003).
   Google Scholar
• Kim BS, Baez CE, Atala A. Biomaterials for tissue engineering. Wor]df Urol. 18,2–9 (2000).
   Google Scholar
• Schmidt CE, Baier JM. Acellular vascular tissue; natural biomaterials for tissue repair and tissue engineering. Biornaterials 21, 2215–2231 (2000).
   Google Scholar
• Weiss RA. Transgenic pigs and virus adaption. Nature 391,327–328 (1988).
   Google Scholar
• Patience C, Takeuchi Y, Weiss RA. Infection of human cells by an endogenous retrovirus of pigs. Nature Med. 3,282–286 (1997).
   Google Scholar
• Wilson CA, Wong S, Muller J eta]. Type C retrovirus released from porcine primary peripheral blood mononuclear cells infects human cells. J ViroL 72,3082–3087 (1998).
   Google Scholar
• Leyh RG, Wilhelmi M, Wailes T et al Acellularized porcine heart valve scaffolds for heart valve tissue engineering and the risk of cross-species transmission of porcine endogenous retrovirus. 1 Thorac. Cardiovasc. Surg. 126,1000–1004 (2003).
   Google Scholar
• Moza AK, Mertsching H, Herden T, Bader A, Haverich A. Heart valves from pigs and the porcine endogenous retrovirus: experimental and clinical data to assess the probability of porcine endogenous retrovirus infection in human subjects. J Thorac. Cardiovasc. Surg. 121,697–701 (2001).
   Google Scholar
• Rieder E, Kasimir MT, Silberhumer G et al. Decellularization protocols of porcine heart valves differ importantly in efficiency of cell removal and susceptibility of the matrix to recellularization with human vascular cells. Thorac. Cardiovasc. Surg. 127,399–405 (2004).
   Google Scholar
• Mertsching H, Brenning OH, Ciubotaru S, Kofidis T, Haverich A. BioVaM: a vascularized biological scaffold with arterial and venous pedicles. mt. J Art. Org. 25, 689 (2002).
   Google Scholar
• Schultheiss D, Gbouev Al, Cebotari S et al. Biological vascularized matrix (BioVaM) for bladder tissue engineering: matrix preparation, reseeding technique and short-term implantation in a porcine model. Urolog. In Press (2004).
   Google Scholar
• Hodde J. Naturally occurring scaffolds for soft tissue repair and regeneration. Tissue Eng. 8,295–308 (2002).
   Google Scholar
• Badylak S, Liang A, Record R, Tullis R, Hodde J. Endothelial cell adherence to small intestinal submucosa: an acellular bioscaffold. Biomaterials 20,2257–2263 (1999).
   Google Scholar
• Voytik-Harbin SL, Brightman AO, Kraine MR, Waisner B, Badylak SF. Identification of extractable growth factors from small intestinal submucosa. J Cell. Biochern. 67, 478–491 (1997).
   Google Scholar
• Lantz GC, Badylak SF, Hiles MC et al. Small intestinal submucosa as vascular graft. A review. J Invest. Surg. 6,297–310 (1993).
   Google Scholar
• Walles T, Giere B, Hofmann M et al. Experimental generation of a tissue-engineered functional and vascularized trachea. J Thorac. Cardiovasc. Surg. In Press (2004).
   Google Scholar
• Macchiarini P, Walles T, Biancosino C, Mertsching H. First human transplantation of a bioengineered airway tissue. J Thorac. Cardiovasc. Surg. In Press (2004).
   Google Scholar
• Stock UA, Vacanti JE Tissue engineering: current state and prospects. Ann. Rev. Med. 52,443–51 (2001).
   Google Scholar
• Vacanti JP, Langer R. Tissue engineering: the design and fabrication of living replacement devices for surgical reconstruction and transplantation. Lancet 354 (Suppl. 1), 32–34 (1999).
   Google Scholar
• Waldman SD, Grynpas MD, Pilliar RM, Kandel RA. The use of specific chondrocyte populations to modulate the properties of tissue-engineered cartilage. j Orthop. Res. 21,132–138 (2003).
   Google Scholar
• Alsberg E, Anderson KW, Albeiruti A, Rowley JA, Mooney DJ. Engineeing growing tissues. Proc. Natl Acad. Sci. USA 99,12025–12030 (2002).
   Google Scholar
• Altman GH, Horan RL, Martin I et al. Cell differentiation by mechanical stress. FASEB J 16,270–272 (2002).
   Google Scholar
• Mooney DJ, Mikos AG. Growing new organs. Sci. Am. 280,60–65 (1999).
   Google Scholar
• Iwasa J, Ochi M, Uchio Y et al. Effects of cell density on proliferation and matrix synthesis of chondrocytes embedded in atelocollagen gel. Art. Org. 27,249–255 (2003).
   Google Scholar
• Homicz MR, Schumacher BL, Sah RL, Watson D. Effects of serial expansion of septal chondrocytes on tissue-engineered neocartilage composition. Otolaryngol. Head Neck Surg.127,398-408 (2002).
   Google Scholar
• Yang L, Korom S, Welti M et al. Tissue- engineered cartilage generated from human trachea using DegraPol® scaffold. Eur. j Cardiothorac. Surg. 24,201–207 (2003).
   Google Scholar
• Nagel-Heyer S, Brink C, Goepfert T, Adamietz P, Pörtner R. Propagation of chondrocytes in bioreactors. Presented at the International Conference Strategies in Tissue Engineering, 14–16 June, 2004, Würzburg, Germany. Cytotherapy6,302 (2004).
   Google Scholar
• Meisel HJ, Oliviera A, William H, Timothy G. Disc repair with autologous chondrocytes: a pilot clinical study. Presented at the International Conference Strategies in Tissue Engineering, 14–16 June, 2004, Würzburg, Germany. Cytotherapy6, 271 (2004).
   Google Scholar
• De Ugarte DA, Puapong D, Roostaeian J et al. Surgisis patch tracheoplasty in a rodent model for tracheal stenosis. j Surg. Res. 112,65–69 (2003).
   Google Scholar
• Record RD, Hillegonds D, Simmons C et al. In vivo degradation of 14C-labeled small intestinal submucosa (SIS) when used for urinary bladder repair. Biornaterials 22, 2653–2659 (2001).
   Google Scholar
• Cheng ATL, Backer CL, Holinger LD et al. Histopathologic changes after pericardial patch tracheoplasty. Arch. Otolaryngol. Head Neck Surg. 123, 1069–1072 (1997).
   Google Scholar
• Idriss FS, DeLeon SY, Illbawi MN eta]. Tracheoplasty with pericardial patch for extensive tracheal stenosis in infants and children. J Thorac. Cardiovasc. Surg. 88, 527–526 (1984).
   Google Scholar
• Lee CJ, Moon KD, Choi H eta]. Tissue-engineered tracheal prosthesis with accelerated cultured homologues chondrocytes as an alternative of tracheal reconstruction. J Cardiovasc. Surg. 43, 275–279 (2002).
   Google Scholar
• Kojima K, Bonassar LJ, Roy AK, Vacanti CA, Cortiella J. Autologous tissue-engineered trachea with sheep nasal chondrocytes. j Thorac. Cardiovasc. Surg. 123,1177–1184 (2002).
   Google Scholar
• Vacanti CA, Paige KT, Kim WS eta]. Experimental tracheal replacement using tissue-engineered cartilage. J Pediatr. Surg. 29,201–205 (1994).
   Google Scholar
• Walles T, Giere B, Macchiarini P, Mertsching H. Expansion of chondrocytes in a three-dimensional matrix for tracheal tissue engineering. Ann. Thorac. Surg. 78, 444–448 (2004).
   Google Scholar
• Bucheler M, Haisch A. Tissue engineering in otorhinolaryngology. DNA Cell. Biol. 22, 549–564 (2003).
   Google Scholar
• Steinwachs MR, Kreuz PC. Combinations of different cartilage resurfacing techniques. Z Orthop. Ihm Grenzgeb. 141,625–628 (2003).
   Google Scholar
• Kafienah W, Jakob M, Demarteau 0 et al. Three-dimensional tissue engineering of hyaline cartilage: comparison of adult nasal and articular chondrocytes. Tissue Eng. 8, 817–826 (2002).
   Google Scholar
• Pittenger MF, Mackay AM, Beck SC et al. Multilineage potential of adult human mesenchymal stem cells. Science 284, 143–147 (1999).
   Google Scholar
• Noth U, Tuli R, Osyczka AM, Danielson KG, Tuan RS. In vitro engineered cartilage constructs produced by press-coating biodegradable polymer with human mesenchymal stem cells. Tissue Eng. 8, 131–144 (2002).
   Google Scholar
• Tsukada H, Osada H. Experimental study of a new tracheal prothesis: pored Dacron tube. J Thorac. Cardiovasc. Surg. 127, 877–884 (2004).
   Google Scholar
• Macchiarini E Candelier JJ, Coullin P et al. Use of embryonic human trachea grown in nude mice to repair congenital tracheal stenosis. Tranplant 70,1555–1559 (2000).
   Google Scholar
• Grillo HC. Tracheal replacement. J Thorac. Cardiovasc. Surg. 125,975 (2003).
   Google Scholar
• Buecheler M, Scheffler B, von Foerster U eta]. Growth of human respiratory epithelium on collagen foil. Laryngo. Rhino. Otol. 79,160–164 (2000).
   Google Scholar
• Doolin EJ, Strande LF, Sheng X, Hewitt CW. Engineering a composite neotrachea with surgical adhesives. J Pediatr. Surg. 37, 1034–1037 (2002).
   Google Scholar
• Rainer C, Wechselberger G, Bauer T et al. Transplantation of tracheal epithelial cells onto a prefabricated capsule pouch with fibrin glue as delivery vehicle. J Thorac. Cardiovasc. Surg. 121, 1187–1193 (2001).
   Google Scholar
• Kim J, Suh SW, Shin JY et al Replacement of a tracheal defect with a tissue-engineered prosthesis: early results from animal experiments. J Thorac. Cardiovasc. Surg. 128, 124–129 (2004).
   Google Scholar
• Gebotari S, Walles T, Sorrentino S, Haverich A, Mertsching H. Guided tissue regeneration of vascular grafts in the peritoneal cavity. Circ. Res. 90, E71 (2002).
   Google Scholar
• Atala A. Future perspectives in bladder reconstruction. Adv. Exp. Med. Biol. 539, 921–940 (2003).
   Google Scholar
• Schultheiss D, Gabouev A, Pilatz A et al. Use of bone marrow-derived mesenchymal stem cells for autologous tissue engineering of urinary bladder muscularis. Eur. Urol. Sapp]. 3, 159 (2004).
   Google Scholar
• Klepetko W Marta GM, Wisser W et al Heterotopic tracheal transplantation with omentum wrapping in the abdominal position preserves functional and structural integrity of a human tracheal allograft j Thorac. Cagliovac. Surg. 127, 862–867 (2004).
   Google Scholar
• Glatz F, Neumeister M, Suchy H et al. A tissue-engineering technique for vascularized laryngotracheal reconstruction. Arch. Otolaryngol. Head Neck Surg. 129, 201–206 (2003).
   Google Scholar