Abstract
Cold atmospheric plasma (CAP) devices generate an ionized gas with highly reactive species and electric fields at ambient air pressure and temperature. A flexible dielectric barrier discharge (DBD) was developed as an alternative antimicrobial treatment for chronic wounds. Treatment of Staphylococcus aureus in collagen-elastin matrices with CAP for 2 min resulted in a 4 log reduction. CAP treatment was less effective on S. aureus on dermal samples. CAP did not affect cellular activity or DNA integrity of human dermal samples when used for up to 2 min. Repeated daily CAP treatments for 2 min lowered cellular activity of dermal samples to 80% after 2 to 4 days, but this was not significant. Repeated treatment of ex vivo human burn wound models with CAP for 2 min did not affect re-epithelialization. Intact skin of 25 healthy volunteers was treated with CAP for 3× 20” to determine safety. Although participants reported moderate pain scores (numerical rating scale 3.3), all volunteers considered the procedure to be acceptable. Severe adverse events did not occur. CAP treatment resulted in a temporarily increased local skin temperature (≈3.4°C) and increased erythema. Lowering the plasma power resulted in a significantly lower erythema increase. Good log reduction (2.9) of bacterial load was reached in 14/15 volunteers artificially contaminated with Pseudomonas aeruginosa. This study demonstrated the in vitro and in vivo safety and efficacy in bacterial reduction of a flexible cold plasma device. Trial registration number NCT03007264, January 2, 2017Key Points• CAP strongly reduced bacterial numbers both in vitro and in vivo.• Re-epithelialization of burn wound models was not affected by repeated CAP.• CAP treatment of intact skin was well tolerated in volunteers.
Highlights
The presence of bacteria in a wound can result in delayed healing and a longer hospital stay
Appl Microbiol Biotechnol (2021) 105:2057–2070 plasma devices have been shown to be highly effective against a multitude of bacterial species including clinically relevant pathogens and multidrug-resistant bacterial strains, while buildup of resistance against cold atmospheric plasma (CAP) has not been observed (Daeschlein 2018; Zimmermann et al 2012)
These tests showed that the volume dielectric barrier discharge (DBD) pad inactivated bacteria effectively after short treatment times (< 2 min, data not shown)
Summary
The presence of bacteria in a wound can result in delayed healing and a longer hospital stay. Burn patients are more susceptible to opportunistic pathogens, such as Pseudomonas aeruginosa and Staphylococcus aureus (Dokter et al 2016). Because current therapies in burn care still have limited effects in eliminating bacteria, resistance to antibiotics is increasing, and antimicrobial therapies can hamper wound healing; additional measures are required. Cold atmospheric plasma (CAP) devices have been tested clinically as an alternative treatment to reduce bacterial load and support wound healing. Appl Microbiol Biotechnol (2021) 105:2057–2070 plasma devices have been shown to be highly effective against a multitude of bacterial species including clinically relevant pathogens and multidrug-resistant bacterial strains, while buildup of resistance against CAP has not been observed (Daeschlein 2018; Zimmermann et al 2012). Biological surfaces were more difficult to disinfect (Maisch et al 2012; Pavlovich et al 2013b)
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