Co-culture Model for Cutaneous Wound Healing to Assess a Porous Fiber-Based Drug Delivery System

In vitro tissue-engineered cell culture models are an essential instrument to investigate physiological and pathophysiological wound healing mechanisms and to evaluate new beneficial wound dressing materials and therapeutics to identify possible drug targets and to improve regeneration processes in...

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Veröffentlicht in:Tissue engineering. Part C, Methods Methods, 2020-09, Vol.26 (9), p.475-484
Hauptverfasser: Dohle, Eva, Scherrieble, Andreas, Doser, Michael, Al-Maawi, Sarah, Hoss, Martin, Dauner, Martin, Sader, Robert, Kirkpatrick, Charles James, Ghanaati, Shahram
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Sprache:eng
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Zusammenfassung:In vitro tissue-engineered cell culture models are an essential instrument to investigate physiological and pathophysiological wound healing mechanisms and to evaluate new beneficial wound dressing materials and therapeutics to identify possible drug targets and to improve regeneration processes in nonhealing and chronic wounds. In this study, the authors established an in vitro model for cutaneous wound healing, based on primary human dermal microvascular endothelial cells (HDMEC) and primary human dermal fibroblasts (HDF) to study wound healing-associated processes. Co-cultivation of HDMEC and HDF results in the formation of microvessel-like structures in long-term co-cultures. The proposed in vitro co-culture model can be easily modified by adding macrophages to simulate the process of inflammation, thus allowing in vitro investigation of pathophysiological wound healing processes present in nonhealing wounds. Furthermore, the beneficial in vitro wound healing model was used to evaluate a porous fiber-based drug delivery dressing material consisting of melt-spun porous fibers that were filled with a hydrogel carrier (gellan gum) containing vascular endothelial growth factor (VEGF). Angiogenic capability was chosen as functional parameter for improved wound healing, and release of deposited VEGF from the dressing material was evaluated up to 7 days of cultivation. The experiments demonstrated that the porous fiber-based drug delivery dressing material for dermal wound healing with incorporated VEGF strongly enhances the process of angiogenesis in the in vitro co-culture model through a release of VEGF over 7 days of cultivation. In conclusion, tissue-engineered human skin equivalents could contribute significantly to the understanding and improvement of drug releasing dressing materials in the context of treating chronic wounds.
ISSN:1937-3384
1937-3392
DOI:10.1089/ten.tec.2020.0145