Die Studien sprechen für sich

Hier haben wir für dich eine kleine Auswahl der wichtigsten wissenschaftlichen Veröffentlichungen zur Kaltplasma-Anwendung auf der Haut zusammengestellt.

Ausgewählte wissenschaftliche Veröffentlichungen

  • Heinlin, J. et al. Plasma Medicine: Possible Applications in Dermatology. J. Dtsch. Dermatol. Ges. J. Ger. Soc. Dermatol. JDDG 2010, 8 (12), 968–976.
    Zur Publikation
  • Isbary, G. et al. Atmospheric Plasma Devices for Medical Issues. Expert Rev. Med. Devices 2013, 10 (3), 367–377.
    Zur Publikation
  • Gerling, T. et al. Einführung in Atmosphärendruck-Plasmaquellen für plasmamedizinische Anwendungen. In Plasmamedizin; Metelmann, H.-R., von Woedtke, T., Weltmann, K.-D., Hrsg.; Springer Berlin Heidelberg: Berlin, Heidelberg, 2016; S. 3–15.
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  • Kogelheide, F., Offerhaus, B., Bibinov, N., Krajinski, P., Schücke, L., Schulze, J., Stapelmann, K., & Awakowicz, P. (2020). Characterisation of volume and surface dielectric barrier discharges in N2–O2 mixtures using optical emission spectroscopy. Plasma Processes and Polymers, 17(6), 1900126.
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  • Busco, G., Robert, E., Chettouh-Hammas, N., Pouvesle, J. M., & Grillon, C. (2020). The emerging potential of cold atmospheric plasma in skin biology. Free Radical Biology and Medicine, 161, 290–304.
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  • Offerhaus, B., Kogelheide, F., Jalat, D., Bibinov, N., Schulze, J., Stapelmann, K., & Awakowicz, P. (2019). Determination of NO densities in a surface dielectric barrier discharge using optical emission spectroscopy. Journal of Applied Physics, 126(19), 193301.
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  • Engelhardt, M., Kogelheide, F., Stapelmann, K., Bibinov, N., & Awakowicz, P. (2017). Micro-plasmoids in self organized filamentary dielectric barrier discharges. Plasma Processes and Polymers, 14(7), 1600095.
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  • Offerhaus, B., Lackmann, J.-W., Kogelheide, F., Bracht, V., Smith, R., Bibinov, N., Stapelmann, K., & Awakowicz, P. (2017). Spatially resolved measurements of the physical plasma parameters and the chemical modifications in a twin surface dielectric barrier discharge for gas flow purification. Plasma Processes and Polymers, 14(10), 1600255.
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  • Baldus, S., Kogelheide, F., Bibinov, N., Stapelmann, K., & Awakowicz, P. (2015). Phase resolved analysis of the homogeneity of a diffuse dielectric barrier discharge. Journal of Physics D: Applied Physics, 48(37), 375202.
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  • Heuer, K., Hoffmanns, M. A., Demir, E., Baldus, S., Volkmar, C. M., Röhle, M., Fuchs, P. C., Awakowicz, P., Suschek, C. V., & Opländer, C. (2015). The topical use of non-thermal dielectric barrier discharge (DBD): Nitric oxide related effects on human skin. Nitric Oxide, 44, 52–60.
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  • Kogelheide, F., Voigt, F., Hillebrand, B., Moeller, R., Fuchs, F., Gibson, A. R., Awakowicz, P., Stapelmann, K., & Fiebrandt, M. (2020). The role of humidity and UV-C emission in the inactivation of B. subtilis spores during atmospheric-pressure dielectric barrier discharge treatment. Journal of Physics D: Applied Physics, 53(29), 295201.
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  • Daeschlein, G., Scholz, S., Ahmed, R., von Woedtke, T., Haase, H., Niggemeier, M., Kindel, E., Brandenburg, R., Weltmann, K. D., & Jünger, M. (2012). Skin decontamination by low-temperature atmospheric pressure plasma jet and dielectric barrier discharge plasma. Journal of Hospital Infection, 81(3), 177–183.
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  • Bae, M., Lademann, J., Meinke, M. C., Meder, B., & Geilen, C. (2025). Therapeutic Use of Cold Atmospheric Plasma for the Treatment of Mild Acne Papulopustulosa—A Randomized, Controlled, Double‐Blind Pilot Study. Dermatologic Therapy, 2025(1), 4228323.
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  • Mariachiara, A., Anna, V., Alessandra, G., Edoardo, G. P., Stefania, B., Mariateresa, R., & Calzavara-Pinton, P. (2020). Cold atmospheric plasma (CAP) as a promising therapeutic option for mild to moderate acne vulgaris: Clinical and non-invasive evaluation of two cases. Clinical Plasma Medicine, 19, 100110.
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  • Śmiłowicz, D., Kogelheide, F., Schöne, A. L., Stapelmann, K., Awakowicz, P., & Metzler-Nolte, N. (2020). Catalytic oxidation of small organic molecules by cold plasma in solution in the presence of molecular iron complexes. Scientific Reports, 10(1), 21652.
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  • Lackmann, J.-W., Bruno, G., Jablonowski, H., Kogelheide, F., Offerhaus, B., Held, J., Schulz-von der Gathen, V., Stapelmann, K., von Woedtke, T., & Wende, K. (2019). Nitrosylation vs. oxidation – How to modulate cold physical plasmas for biological applications. PLOS ONE, 14(5), e0216606.
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  • Balzer, J., Demir, E., Kogelheide, F., Fuchs, P. C., Stapelmann, K., & Opländer, C. (2019). Cold atmospheric plasma (CAP) differently affects migration and differentiation of keratinocytes via hydrogen peroxide and nitric oxide-related products. Clinical Plasma Medicine, 13, 1–8.
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  • Śmiłowicz, D., Kogelheide, F., Stapelmann, K., Awakowicz, P., & Metzler-Nolte, N. (2019). Study on Chemical Modifications of Glutathione by Cold Atmospheric Pressure Plasma (CAP) Operated in Air in the Presence of Fe(II) and Fe(III) Complexes. Scientific Reports, 9(1), 18024.
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  • Lackmann, J.-W., Klinkhammer, C., Verlackt, C., Jablonowski, H., Kogelheide, F., Stapelmann, K., Bogaerts, A., Havenith, M., Weltmann, K.-D., & Wende, K. (2018). Modulating Plasma-Induced Thiol Chemistry in Liquids. Clinical Plasma Medicine, 9, 38–39.
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  • Chemical fingerprints of cold physical plasmas – an experimental and computational study using cysteine as tracer compound. Scientific Reports, 8(1), 7736.
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  • Klinkhammer, C., Verlackt, C., Śmiłowicz, D., Kogelheide, F., Bogaerts, A., Metzler-Nolte, N., Stapelmann, K., Havenith, M., & Lackmann, J.-W. (2017). Elucidation of Plasma-induced Chemical Modifications on Glutathione and Glutathione Disulphide. Scientific Reports, 7(1), 13828.
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  • Kogelheide, F., Kartaschew, K., Strack, M., Baldus, S., Metzler-Nolte, N., Havenith, M., Awakowicz, P., Stapelmann, K., & Lackmann, J.-W. (2016). FTIR spectroscopy of cysteine as a ready-to-use method for the investigation of plasma-induced chemical modifications of macromolecules. Journal of Physics D: Applied Physics, 49(8), 084004.
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  • Lackmann, J.-W., Baldus, S., Steinborn, E., Edengeiser, E., Kogelheide, F., Langklotz, S., Schneider, S., Leichert, L. I. O., Benedikt, J., Awakowicz, P., & Bandow, J. E. (2015). A dielectric barrier discharge terminally inactivates RNase A by oxidizing sulfur-containing amino acids and breaking structural disulfide bonds. Journal of Physics D: Applied Physics, 48(49), 494003.
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  • Rajasekaran, P., Opländer, C., Hoffmeister, D., Bibinov, N., Suschek, C. V., Wandke, D., & Awakowicz, P. (2011). Characterization of dielectric barrier discharge (DBD) on mouse and histological evaluation of the plasma‐treated tissue. Plasma Processes and Polymers, 8(3), 246–255.
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  • Marschewski, M., Hirschberg, J., Omairi, T., Höfft, O., Viöl, W., Emmert, S., & Maus‐Friedrichs, W. (2012). Electron spectroscopic analysis of the human lipid skin barrier: cold atmospheric plasma‐induced changes in lipid composition. Experimental Dermatology, 21(12), 921–925.
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  • Daeschlein, G., Scholz, S., Ahmed, R., Majumdar, A., von Woedtke, T., Haase, H., Niggemeier, M., Kindel, E., Brandenburg, R., Weltmann, K. D., & Jünger, M. (2012). Cold plasma is well‐tolerated and does not disturb skin barrier or reduce skin moisture. JDDG: Journal der Deutschen Dermatologischen Gesellschaft, 10(7), 509–515.
    Zur Publikation
Solltest du Fragen zu den Studien haben, schreibe uns gern unter beratung@pharmedix.de an.