BACKGROUND AND OBJECTIVES: Complete blanching of port wine stain (PWS) birthmarks after laser therapy is rarely achieved for most patients. We postulate that the low therapeutic efficacy or treatment failure is caused by regeneration and revascularization of photocoagulated blood vessels due to angiogenesis associated with the skin's normal wound healing response. Rapamycin (RPM), an antiangiogenic agent, has been demonstrated to inhibit growth of pathological blood vessels. Our objectives were to (1) investigate whether topical RPM can inhibit reperfusion of photocoagulated blood vessels in an animal model and (2) determine the effective RPM concentration required to achieve this objective. STUDY DESIGN/ MATERIALS AND METHODS: For both laser-only and combined laser and RPM treated animals, blood vessels in the dorsal window chambers implanted on golden Syrian hamsters were photocoagulated with laser pulses. Structural and flow dynamics of blood vessels were documented with color digital photography and laser speckle imaging to evaluate photocoagulation and reperfusion. For the combined treatment group, topical RPM was applied to the epidermal side of the window daily for 14 days after laser exposure. RESULTS: In the laser-only group, 23 out of 24 photocoagulated blood vessels reperfused within 5-14 days. In the combined treatment group with different RPM formulae and concentrations, the overall reperfusion rate of 36% was much lower as compared to the laser-only group. We also found that the reperfusion rate was not linearly proportional to the RPM concentration. CONCLUSIONS: With topical RPM application, the frequency of vessel reperfusion was considerably reduced, which implies that combined light and topical antiangiogenic therapy might be a promising approach to improve the treatment efficacy of PWS birthmarks.
BACKGROUND AND OBJECTIVES: Complete blanching of port wine stain (PWS) birthmarks after laser therapy is rarely achieved for most patients. We postulate that the low therapeutic efficacy or treatment failure is caused by regeneration and revascularization of photocoagulated blood vessels due to angiogenesis associated with the skin's normal wound healing response. Rapamycin (RPM), an antiangiogenic agent, has been demonstrated to inhibit growth of pathological blood vessels. Our objectives were to (1) investigate whether topical RPM can inhibit reperfusion of photocoagulated blood vessels in an animal model and (2) determine the effective RPM concentration required to achieve this objective. STUDY DESIGN/ MATERIALS AND METHODS: For both laser-only and combined laser and RPM treated animals, blood vessels in the dorsal window chambers implanted on golden Syrian hamsters were photocoagulated with laser pulses. Structural and flow dynamics of blood vessels were documented with color digital photography and laser speckle imaging to evaluate photocoagulation and reperfusion. For the combined treatment group, topical RPM was applied to the epidermal side of the window daily for 14 days after laser exposure. RESULTS: In the laser-only group, 23 out of 24 photocoagulated blood vessels reperfused within 5-14 days. In the combined treatment group with different RPM formulae and concentrations, the overall reperfusion rate of 36% was much lower as compared to the laser-only group. We also found that the reperfusion rate was not linearly proportional to the RPM concentration. CONCLUSIONS: With topical RPM application, the frequency of vessel reperfusion was considerably reduced, which implies that combined light and topical antiangiogenic therapy might be a promising approach to improve the treatment efficacy of PWS birthmarks.
Authors: Markus Guba; Gudrun E Koehl; Evelyn Neppl; Axel Doenecke; Markus Steinbauer; Hans J Schlitt; Karl-Walter Jauch; Edward K Geissler Journal: Transpl Int Date: 2005-01 Impact factor: 3.782
Authors: Michal Heger; Johan F Beek; Nicanor I Moldovan; Chantal M A M van der Horst; Martin J C van Gemert Journal: Thromb Haemost Date: 2005-02 Impact factor: 5.249
Authors: Young Sam Kwon; Hyun Sook Hong; Jae Chan Kim; Jun Seop Shin; Youngsook Son Journal: Invest Ophthalmol Vis Sci Date: 2005-02 Impact factor: 4.799
Authors: Nadine S Dejneka; Akiko M Kuroki; Joshua Fosnot; Waixing Tang; Michael J Tolentino; Jean Bennett Journal: Mol Vis Date: 2004-12-22 Impact factor: 2.367
Authors: U Kozlowska; U Blume-Peytavi; V Kodelja; C Sommer; S Goerdt; S Majewski; S Jablonska; C E Orfanos Journal: Arch Dermatol Res Date: 1998-12 Impact factor: 3.017
Authors: S Lachgar; H Moukadiri; F Jonca; M Charveron; N Bouhaddioui; Y Gall; J L Bonafe; J Plouët Journal: J Invest Dermatol Date: 1996-01 Impact factor: 8.551
Authors: Jennifer K Chen; Pedram Ghasri; Guillermo Aguilar; Anne Margreet van Drooge; Albert Wolkerstorfer; Kristen M Kelly; Michal Heger Journal: J Am Acad Dermatol Date: 2012-02-03 Impact factor: 11.527
Authors: Vivian T Laquer; Belinda M Dao; Janelle M Pavlis; Amy N Nguyen; Tina S Chen; Ronald M Harris; Elizabeth L Rugg; Kristen M Kelly Journal: Lasers Surg Med Date: 2012-02-02 Impact factor: 4.025
Authors: Wangcun Jia; Nadia Tran; Victor Sun; Marko Marinček; Boris Majaron; Bernard Choi; J Stuart Nelson Journal: Lasers Surg Med Date: 2012-01-24 Impact factor: 4.025
Authors: J C Ramírez-San-Juan; Y C Huang; N Salazar-Hermenegildo; R Ramos-García; J Muñoz-Lopez; B Choi Journal: Phys Med Biol Date: 2010-11-03 Impact factor: 3.609
Authors: Bruce Yang; Owen Yang; John Guzman; Paul Nguyen; Christian Crouzet; Kathryn E Osann; Kristen M Kelly; J Stuart Nelson; Bernard Choi Journal: Lasers Surg Med Date: 2015-06-03 Impact factor: 4.025