OBJECTIVES: The creation of a tissue-engineered auricle was initially successful in an immunocompromised nude mouse model. Subsequently, an immunocompetent porcine model successfully generated a helical construct. We wished to evaluate the novel technique of using a mold to create a complete, anatomically refined auricle in a large animal model. METHODS: Mixtures of autogenous chondrocytes and biodegradable polymers were used inside a perforated, auricle shaped hollow gold mold. Three biodegradable polymers (calcium alginate, pluronic F-127, and polyglycolic acid) were used to retain the seeded chondrocytes inside the mold. These molds, along with a control, were implanted subcutaneously in the abdominal area of 10 animals (pigs and sheep). The constructs were removed after 8 to 20 weeks and were assessed by gross morphology and histology. RESULTS: All the gold implants were well tolerated by the animals. The implants using calcium alginate (n = 3) generated constructs of the exact shape and size of a normal human ear; the histology demonstrated mostly normal cartilage with some persistent alginate. The implants with pluronic F-127 (n = 3) resulted in cartilage with essentially normal histology, although leakage outside the molds and external cartilage generation was noted. Polyglycolic acid implants (n = 3) produced no useful cartilage because of an inflammatory reaction with fibrosis. The empty control mold (n = 1) demonstrated only a very small amount of fibrous tissue inside. CONCLUSION: A tissue-engineered human sized auricle of normal anatomic definition can be generated in an immunocompetent large-animal model using a mold technique. Although further refinements will be necessary, the technique appears promising for potential use in patients with microtia.
OBJECTIVES: The creation of a tissue-engineered auricle was initially successful in an immunocompromised nude mouse model. Subsequently, an immunocompetent porcine model successfully generated a helical construct. We wished to evaluate the novel technique of using a mold to create a complete, anatomically refined auricle in a large animal model. METHODS: Mixtures of autogenous chondrocytes and biodegradable polymers were used inside a perforated, auricle shaped hollow gold mold. Three biodegradable polymers (calcium alginate, pluronic F-127, and polyglycolic acid) were used to retain the seeded chondrocytes inside the mold. These molds, along with a control, were implanted subcutaneously in the abdominal area of 10 animals (pigs and sheep). The constructs were removed after 8 to 20 weeks and were assessed by gross morphology and histology. RESULTS: All the gold implants were well tolerated by the animals. The implants using calcium alginate (n = 3) generated constructs of the exact shape and size of a normal human ear; the histology demonstrated mostly normal cartilage with some persistent alginate. The implants with pluronic F-127 (n = 3) resulted in cartilage with essentially normal histology, although leakage outside the molds and external cartilage generation was noted. Polyglycolic acid implants (n = 3) produced no useful cartilage because of an inflammatory reaction with fibrosis. The empty control mold (n = 1) demonstrated only a very small amount of fibrous tissue inside. CONCLUSION: A tissue-engineered human sized auricle of normal anatomic definition can be generated in an immunocompetent large-animal model using a mold technique. Although further refinements will be necessary, the technique appears promising for potential use in patients with microtia.
Authors: Irina Pomerantseva; David A Bichara; Alan Tseng; Michael J Cronce; Thomas M Cervantes; Anya M Kimura; Craig M Neville; Nick Roscioli; Joseph P Vacanti; Mark A Randolph; Cathryn A Sundback Journal: Tissue Eng Part A Date: 2015-12-15 Impact factor: 3.845
Authors: Benjamin Peter Cohen; Rachel C Hooper; Jennifer L Puetzer; Rachel Nordberg; Ope Asanbe; Karina A Hernandez; Jason A Spector; Lawrence J Bonassar Journal: Tissue Eng Part A Date: 2016-03-14 Impact factor: 3.845
Authors: Renata G Rosa; Paulo P Joazeiro; Juares Bianco; Manuela Kunz; Joanna F Weber; Stephen D Waldman Journal: PLoS One Date: 2014-08-15 Impact factor: 3.240
Authors: Julia R Brennan; Ashley Cornett; Brian Chang; Sarah J Crotts; Zahra Nourmohammadi; Isabelle Lombaert; Scott J Hollister; David A Zopf Journal: J Biomed Mater Res B Appl Biomater Date: 2020-08-24 Impact factor: 3.368