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Autopericardial Patch Tracheoplasty for Tracheal Stenosis After Arterial Switch Operation (2005)

Takiguchi, Makoto ; Aoki, Mitsuru ; Shin'oka, Toshiharu ; [et al.]

350 Main Street , Malden , MA 02148-5020 , USA and 9600 Garsington Road , Oxford OX4 2XG , England . : Blackwell Science Inc

Journal of cardiac surgery 20 (2005), S. 0

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ISSN: 1540-8191

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Medicine

Notes: Abstract Though congenital tracheal stenosis in infants with congenital heart disease is uncommon, congestive heart failure is often deteriorated by respiratory symptoms. We report an infant having a diagnosis of congenital tracheal stenosis complicated with congenital heart disease who underwent pericardial patch tracheoplasty after the arterial switch operation for the transposition of the great arteries. External appearance of the trachea showed no stenosis and tracheal rings were well formed. Intraoperative bronchofiberscopy transilluminated the upper border of stenosis. The trachea was opened longitudinally to the extent of 30 mm to the point from 10 mm point proximal to the bifurcation. The incision was enlarged with the autologous pericardial patch using running absorbable suture. Then pericardial patch was anchored at several points to the posterior surface of the ascending aorta, innominate artery, and to the strap muscles of the neck. He is doing well now without any respiratory symptom.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1111/j.1540-8191.2005.200431.x

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Current status of tissue engineering for cardiovascular structures (2000)

Shin'oka, Toshiharu ; Imai, Yasuharu ; Watanabe, Manabu ; [et al.]

Springer

Journal of artificial organs 3 (2000), S. 102-106

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ISSN: 1619-0904

Keywords: Tissue engineering ; Bioprosthesis ; Biomaterial ; Cardiovascular surgery

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine , Technology

Notes: Abstract Various vascular and valvlular grafts are commonly used in the treatment of cardiovascular disease. Current prosthetic or bioprosthetic materials lack growth potential, and therefore, subsequent replacement further defeats the concept of primary repair early in pediatric cardiac patients. Tissue engineering is a new discipline that offers the potential to create replacement structures from autologous cells and biodegradable polymer scaffolds. Because tissue-engineering constructs contain living cells, they may have the potential for growth, self-repair, and self-remodeling. Cardiac valve leaflets and large conduits in the pulmonary ciruulation have been made with this tissue-engineering approach in lambs. Venous conduits were also created in dogs. Mixed cell populations of endothelial cells and fibroblasts were isolated from explanted peripheral arteries or vein. A synthetic biodegradable scaffold con-sisting of polyglactin and polyglycolic acid fibers was seeded in vitro with mixed cultured cells. After one week, these autologous cell/polymer constructs were reimplanted in animals. Each animal was then followed periodically by echocardiography and angiography. The animals were sacrificed, and the implanted tissues were examined histologically, biochemically, and biomechanically. A 4-hydroxyproline assay was performed to evaluate the collagen content. The implanted conduit diameters increased as the animals grew during the study period. Histologically, the biodegradable polymer scaffold was completely degraded. Collagen analysis of the constructs showed the development of an extracellular matrix. Immunohistochemical staining demonstrated elastin fiber in the matrix and factor VIII on the inner surface of the conduits. In conclusion, a tissue-engineering approach to constructing cardiovascular structures is feasible using cells of either arterial or venous origin. In these tissue-engineered autografts, transplanted autologous cells generated the proper matrix over the polymer scaffold under physiologic conditions.