BACKGROUND: Vascular endothelial growth factor (VEGF)(165) induces formation of immature blood vessels with increased permeability. In this study, we used a cell-based gene-transfer model of fibroblasts to investigate the effects of a combined in vivo treatment consisting of the VEGF165 and basic fibroblast growth factor (bFGF) proteins on ischemic and non-ischemic tissues. MATERIALS AND METHODS: After controlled in vitro adenoviral transfection we transplanted fibroblasts into either healthy tissue, or into an ischemic skin flap model at different tissue locations and at different time points. Subsequent protein expression and angiogenic effects were measured using ELISA, PCR, immunohistology, planimetry, and microangiography. RESULTS: Transfected fibroblasts temporarily produced VEGF(165) and bFGF. After transdermal implantation we found an up-regulation of genes encoding for both factors in tissue samples. The combined transplantation of VEGF(165) and bFGF modified cells increased the number of sm-actin+/CD31+ blood vessels and reduced necrosis by 25%. The number of functional blood vessels increased over a period of 168 d even in healthy tissue. CONCLUSIONS: We achieved stable vessel growth in healthy tissue by inducing a temporary overexpression of VEGF(165) and bFGF and improved the survival of ischemic tissue. One possible mechanism for the latter observation is the stabilization of VEGF(165)-induced hyperpermeable vessels by a bFGF-mediated pericytial recruitment of smooth muscle cells.
BACKGROUND:Vascular endothelial growth factor (VEGF)(165) induces formation of immature blood vessels with increased permeability. In this study, we used a cell-based gene-transfer model of fibroblasts to investigate the effects of a combined in vivo treatment consisting of the VEGF165 and basic fibroblast growth factor (bFGF) proteins on ischemic and non-ischemic tissues. MATERIALS AND METHODS: After controlled in vitro adenoviral transfection we transplanted fibroblasts into either healthy tissue, or into an ischemic skin flap model at different tissue locations and at different time points. Subsequent protein expression and angiogenic effects were measured using ELISA, PCR, immunohistology, planimetry, and microangiography. RESULTS: Transfected fibroblasts temporarily produced VEGF(165) and bFGF. After transdermal implantation we found an up-regulation of genes encoding for both factors in tissue samples. The combined transplantation of VEGF(165) and bFGF modified cells increased the number of sm-actin+/CD31+ blood vessels and reduced necrosis by 25%. The number of functional blood vessels increased over a period of 168 d even in healthy tissue. CONCLUSIONS: We achieved stable vessel growth in healthy tissue by inducing a temporary overexpression of VEGF(165) and bFGF and improved the survival of ischemic tissue. One possible mechanism for the latter observation is the stabilization of VEGF(165)-induced hyperpermeable vessels by a bFGF-mediated pericytial recruitment of smooth muscle cells.
Authors: Paola Koenen; Timo A Spanholtz; Marc Maegele; Ewa Stürmer; Thomas Brockamp; Edmund Neugebauer; Oliver C Thamm Journal: Int Wound J Date: 2013-03-13 Impact factor: 3.315
Authors: Oliver C Thamm; Paola Koenen; Nicola Bader; Alina Schneider; Sebastian Wutzler; Edmund A M Neugebauer; Timo A Spanholtz Journal: Int Wound J Date: 2013-03-21 Impact factor: 3.315
Authors: Ziyang Zhang; Alex Slobodianski; Astrid Arnold; Jessica Nehlsen; Ursula Hopfner; Arndt F Schilling; Tatjana Perisic; Hans-Günther Machens Journal: Int J Med Sci Date: 2017-07-19 Impact factor: 3.738
Authors: Dilara Z Gatina; Ekaterina E Garanina; Margarita N Zhuravleva; Gulnaz E Synbulatova; Adelya F Mullakhmetova; Valeriya V Solovyeva; Andrey P Kiyasov; Catrin S Rutland; Albert A Rizvanov; Ilnur I Salafutdinov Journal: Int J Mol Sci Date: 2021-05-31 Impact factor: 5.923