• Combining MucilAir™ and Vitrocell Powder Chamber for the In Vitro Evaluation of Nasal Ointments in the Context of Aerosolized Pollen.

      Metz, Julia; Knoth, Katharina; Groß, Henrik; Lehr, Claus-Michael; Stäbler, Carolin; Bock, Udo; Hittinger, Marius; HIPS, Helmholtz-Institute für pharmazeutische Forschung Saarland, Universitätscampus E8.1, 66123 Saarbrücken, Germany. (2018-05-10)
      Hay fever is notoriously triggered when nasal mucosa is exposed to allergenic pollen. One possibility to overcome this pollen exposure may be the application of an ointment with physical protective effects. In this context, we have investigated Bepanthen Eye and Nose Ointment and the ointment basis petrolatum as reference while using contemporary in vitro techniques. Pollen from false ragweed () was used as an allergy-causing model deposited as aerosol using the Vitrocell Powder Chamber (VPC) on Transwell inserts, while being coated with either Bepanthen Eye and Nose Ointment and petrolatum. No pollen penetration into ointments was observed upon confocal scanning laser microscopy during an incubation period of 2 h at 37 °C. The cellular response was further investigated by integrating the MucilAir™ cell system in the VPC and by applying pollen to Bepanthen Eye and Nose Ointment covered cell cultures. For comparison, MucilAir™ were stimulated by lipopolysaccharides (LPS). No increased cytokine release of IL-6, TNF-α, or IL-8 was found after 4 h of pollen exposure, which demonstrates the safety of such ointments. Since nasal ointments act as a physical barrier against pollen, such preparations might support the prevention and management of hay fever.
    • Development and evaluation of a quality control system based on transdermal electrical resistance for skin barrier function in vitro.

      Knoth, Katharina; Zäh, Ralf-Kilian; Veldung, Barbara; Burgio, Dominic; Wiegand, Birgit; Smola, Hans; Bock, Udo; Lehr, Claus-Michael; Hittinger, Marius; Groß, Henrik; et al. (Wiley & Sons, 2021-01-06)
      Background: In vitro skin permeation experiments are highly relevant for pharmaceutical, cosmetic, agricultural developments, and regulatory evaluation. A key requirement is the skin barrier integrity, that is accompanied by an intact stratum corneum (SC) which implements high skin quality. A variety of integrity tests are currently available, for example, measurement of transepidermal water loss, monitoring the permeation of tritiated water and the measurement of transdermal electrical resistance (TER). Materials and methods: We aimed for a non-destructive examination of barrier integrity as quality control system, based on TER. Therefore, the in-house developed instrument SkinTER measures electrical resistance on excised human skin samples in a non-invasive and easy-to-use pattern. In this proof of concept study, we compared three human in vitro skin models with focus on their TER and permeation properties. The skin integrity was impaired to mimic conditions of skin during age, lifestyle (eg, shaving) or diseases (eg, obesity, psoriasis, and atopic dermatitis). The OECD permeation marker caffeine was correlated to the corresponding TER value. Results: A correlation between both was obtained by having a Pearson coefficient of -0.830. Hereby, a minimum TER value for intact skin samples of ~1.77 kΩ*cm2 was suggested. Intact samples are significantly different (α = ≤0.05) to their impaired counterparts in flux and TER values. Conclusion: The new SkinTER instrument gives a quick and non-invasive feedback on skin quality before a permeation experiment.