Production of an Optimized Tissue-Engineered Pig Connective Tissue for the Reconstruction of the Urinary Tract

Nonurological autologous tissues are used for urethral reconstruction to correct urinary tract disorders but are still leading to complications. Other substitutes have been studied on small animal models without great success. For preclinical tests, we selected the porcine model for its similarity t...

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Bibliographic Details
Published in:Tissue engineering. Part A 2011-06, Vol.17 (11-12), p.1625-1633
Main Authors: Ouellet, Gabrielle, Dubé, Jean, Gauvin, Robert, Laterreur, Véronique, Bouhout, Sara, Bolduc, Stéphane
Format: Article
Language:English
Subjects:
Animals
Biomechanical Phenomena
Care and treatment
Cell Proliferation
Cells, Cultured
Connective Tissue - physiology
Connective tissues
Diagnosis
Elastic Modulus
Extracellular Matrix - metabolism
Fibroblasts - cytology
Fluorescent Antibody Technique
Hogs
Humans
Mouth Mucosa - cytology
Optimization techniques
Original Articles
Physiological aspects
Regenerative Medicine - methods
Skin - cytology
Sus scrofa
Temperature
Tensile Strength
Tissue engineering
Tissue Engineering - methods
Tissues
Urinary Tract - pathology
Urinary tract diseases
Urologic diseases
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Summary:Nonurological autologous tissues are used for urethral reconstruction to correct urinary tract disorders but are still leading to complications. Other substitutes have been studied on small animal models without great success. For preclinical tests, we selected the porcine model for its similarity to the human urinary tract. Up to now, porcine skin fibroblasts were not able to synthesize enough extracellular matrix under standard conditions to sustain the formation of an adequate tissue for transplantation purposes. Therefore, our goal was to optimize the harvesting site and culture conditions to obtain a thick and easy to handle porcine fibroblast tissue. The oral mucosa was found to be the ideal harvesting site, and a culture temperature of 39°C enabled the formation of a good porcine fibroblast sheet. We successfully superimpose three fibroblast sheets that merged into a thick and resistant tissue where physiological extracellular matrix was produced. Mechanical resistance evaluation by uniaxial traction on the three-layer fibroblast constructs also demonstrated its suitable properties. The production of this porcine connective tissue offers an interesting option in the field of urological tissue engineering. Autologous experiments on a larger animal model are now possible and accessible, allowing the performance of long-term in vivo studies.
ISSN:1937-3341
1937-335X
DOI:10.1089/ten.tea.2010.0324