BACKGROUND: Definitive and high-quality coverage of large and, in particular, massive skin defects remains a significant challenge in burn as well as plastic and reconstructive surgery because of donor site shortage. A novel and promising approach to overcome these problems is tissue engineering of skin. Clearly, before eventual clinical application, engineered skin substitutes of human origin must be grafted and then evaluated in animal models. For the various tests to be conducted it is indispensable to be able to identify human cells as such in culture and also to distinguish between graft and recipient tissue after transplantation. Here we describe a tool to identify human cells in vitro and in vivo. METHODS: In situ hybridization allows for the detection and localization of specific DNA or RNA sequences in morphologically preserved cells in culture or tissue sections, respectively. We used digoxigenin-labeled DNA probes corresponding to human-specific Alu repeats in order to identify human keratinocytes grown in culture together with rat cells, and also to label split and full thickness skin grafts of human origin after transplantation on immuno-incompetent rats. RESULTS: Digoxigenin-labeled DNA probing resulted in an intensive nuclear staining of human cells, both in culture and after transplantation onto recipient animals, while recipient animal cells (rat cells) did not stain. CONCLUSION: In situ hybridization using primate-specific Alu probes reliably allows distinguishing between cells of human and non-human origin both in culture as well as in histological sections. This method is an essential tool for those preclinical experiments (performed on non-primate animals) that must be conducted before novel tissue engineered skin substitutes might be introduced into clinical practice.
BACKGROUND: Definitive and high-quality coverage of large and, in particular, massive skin defects remains a significant challenge in burn as well as plastic and reconstructive surgery because of donor site shortage. A novel and promising approach to overcome these problems is tissue engineering of skin. Clearly, before eventual clinical application, engineered skin substitutes of human origin must be grafted and then evaluated in animal models. For the various tests to be conducted it is indispensable to be able to identify human cells as such in culture and also to distinguish between graft and recipient tissue after transplantation. Here we describe a tool to identify human cells in vitro and in vivo. METHODS: In situ hybridization allows for the detection and localization of specific DNA or RNA sequences in morphologically preserved cells in culture or tissue sections, respectively. We used digoxigenin-labeled DNA probes corresponding to human-specific Alu repeats in order to identify human keratinocytes grown in culture together with rat cells, and also to label split and full thickness skin grafts of human origin after transplantation on immuno-incompetent rats. RESULTS:Digoxigenin-labeled DNA probing resulted in an intensive nuclear staining of human cells, both in culture and after transplantation onto recipient animals, while recipient animal cells (rat cells) did not stain. CONCLUSION: In situ hybridization using primate-specific Alu probes reliably allows distinguishing between cells of human and non-human origin both in culture as well as in histological sections. This method is an essential tool for those preclinical experiments (performed on non-primate animals) that must be conducted before novel tissue engineered skin substitutes might be introduced into clinical practice.
Authors: Irene Montaño; Clemens Schiestl; Jörg Schneider; Luca Pontiggia; Joachim Luginbühl; Thomas Biedermann; Sophie Böttcher-Haberzeth; Erik Braziulis; Martin Meuli; Ernst Reichmann Journal: Tissue Eng Part A Date: 2010-01 Impact factor: 3.845
Authors: Thomas Biedermann; Luca Pontiggia; Sophie Böttcher-Haberzeth; Sasha Tharakan; Erik Braziulis; Clemens Schiestl; Martin Meuli; Ernst Reichmann Journal: J Invest Dermatol Date: 2010-04-08 Impact factor: 8.551
Authors: Luca Pontiggia; Thomas Biedermann; Martin Meuli; Daniel Widmer; Sophie Böttcher-Haberzeth; Clemens Schiestl; Jörg Schneider; Erik Braziulis; Irene Montaño; Claudia Meuli-Simmen; Ernst Reichmann Journal: J Invest Dermatol Date: 2008-08-21 Impact factor: 8.551