699 An in-vitro keratinocyte model for the evaluation of skin damage induced by 5G radiation

Abstract

With the rapid spread of next-generation cellular communication technology, wireless bands between 3 – 100 GHz (5G), are increasingly in use in major population centers. The electromagnetic radiation involved remains non-ionizing, however it is of higher energy compared to existing cellular or wi-fi bands; and, this technology’s range is shorter – so that more emitter stations will be needed, placed closer to one another, and thus also closer to the user. This will result in higher net EM energy exposure. There is no clear consensus on the risks inherent in this exposure yet, but there is concern among the public and the scientific community, based on indications that this radiation can affect immune function, trigger inflammatory responses, and influence gene expression linked to protein folding, oxidative stress, tissue / ECM matrix turnover, and more. Further, some skin appendages have been shown to act as antennae for this radiation, which may lead to localized damage. To better understand the effects of this radiation on skin, we irradiated a normal human epidermal keratinocyte culture using a 6 GHz signal generator. Biological effects were evaluated by ELISA or immunostaining. After a remarkably short 1-h exposure time, clear effects were observable in several indicators of keratinocyte function, including: an increase in key inflammatory cytokine IL1-alpha; a reduction in collagenase inhibitor TIMP1; an increase in wound healing and epidermal differentiation facilitator ANGPLT4; and an increase in SA100A9, involved in immune recruitment during injury. These results indicate a clear influence of 5G irradiation on the keratinocytes, suggesting induced changes in skin homeostasis which may be consistent with a state of injury and damage response. In upcoming studies, we hope to be able to show these effects in more depth, and propose some possible solutions for daily users of 5G technology.