Safety and efficacy of the Plasma Directed Electron Beam (PDEB ™) - implications for enhanced wound healing treatment in military operational medicine and beyond

Joseph A Bauer, Adrianne R Blocklin, Annette M Sysel, Thomas J Sheperak
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Abstract

Introduction: Wound healing presents a critical challenge in military operational medicine and combat casualty care, especially for soldiers in high-risk environments such as combat zones and training exercises. In these scenarios, wounds often result from bullets, shrapnel, burns, and blasts, affecting soft tissue, bone, and internal organs, and are frequently contaminated with hazardous substances like debris and bacteria. Limited resources in these environments make rapid and effective treatment difficult, often leading to delayed medical care and poorer healing outcomes. Emerging technologies like nonthermal plasma (NTP), also known as cold plasma, may provide superior wound healing treatment efficacy in these environments, owing to the ability to effectively kill pathogens, stimulate tissue regeneration, and minimize collateral damage compared to traditional methods. The Plasma Directed Electron Beam™ (PDEB™), an innovative advancement in nonthermal plasma research, shows promise in addressing these challenges. Materials and Methods: The antibiofilm efficacy of the PDEB™ was investigated on Acinetobacter baumannii and Streptococcus mutans. Cytotoxicity was assessed using primary human epithelial cells and TR146 cells, immortalized epithelial cells. Cell proliferation assays, immunoblotting, and lactate dehydrogenase (LDH) release were evaluated. Results: Our study demonstrates the effectiveness of the PDEB™ handheld in inhibiting the growth of bacterial pathogens implicated in biofilms. Acinetobacter baumannii and Streptococcus mutans showed zones of inhibition starting at lower power levels, achieving complete inhibition at 14 watts (W) and 7W respectively for 90-120 seconds. The safety of the PDEB™ was assessed through cell proliferation assays using human epithelial cells and semi-confluent TR146 cells, which were exposed to similar conditions as the bacterial assays. TR146 cells showed negligible differences in cleaved caspase 3 levels compared to controls. Cytotoxicity and apoptosis assays further confirmed the safety of PDEB™, as lactate dehydrogenase (LDH) release in epithelial cells and activated caspase 3 levels in cell extracts were comparable to untreated and helium-treated cells, indicating minimal cellular damage. Conclusion: The PDEB™ handheld, a first-generation device, has demonstrated significant efficacy in inhibiting the growth of bacteria. Concurrently, its application on human epithelial cells has shown encouraging safety profiles. These findings align with the effectiveness of traditional nonthermal plasma devices, positioning the PDEB™ as a viable and promising option for wound healing applications in Combat Casualty Care and Military Operational Medicine.
等离子体定向电子束(PDEB ™)的安全性和有效性--对军事作战医学及其他领域加强伤口愈合治疗的影响
简介伤口愈合是军事作战医学和战斗伤员救护中的一项重大挑战,尤其是对处于作战区和训练演习等高风险环境中的士兵而言。在这些场景中,伤口通常由子弹、弹片、烧伤和爆炸造成,影响软组织、骨骼和内脏,并经常受到碎片和细菌等有害物质的污染。在这些环境中,有限的资源使快速有效的治疗变得困难,往往导致医疗护理的延误和较差的愈合效果。与传统方法相比,非热等离子体 (NTP)(又称冷等离子体)等新兴技术能够有效杀灭病原体、刺激组织再生并最大限度地减少附带损伤,因此在这些环境中可能会提供更优越的伤口愈合治疗效果。等离子体定向电子束™(Plasma Directed Electron Beam™,PDEB™)是非热性等离子体研究领域的一项创新进展,有望解决这些难题。材料与方法:研究了 PDEB™ 对鲍曼不动杆菌和变异链球菌的抗生物膜功效。使用原代人类上皮细胞和 TR146 细胞(永生化上皮细胞)对细胞毒性进行了评估。对细胞增殖试验、免疫印迹和乳酸脱氢酶(LDH)释放进行了评估。结果:我们的研究证明了 PDEB™ 手持设备在抑制涉及生物膜的细菌病原体生长方面的有效性。鲍曼不动杆菌和变异链球菌从较低功率水平开始出现抑制区,分别在 14 瓦和 7 瓦时达到完全抑制,持续 90-120 秒。PDEB™ 的安全性是通过使用人类上皮细胞和半融合 TR146 细胞进行细胞增殖试验来评估的。与对照组相比,TR146 细胞中裂解的 caspase 3 水平的差异可以忽略不计。细胞毒性和细胞凋亡检测进一步证实了 PDEB™ 的安全性,因为上皮细胞中乳酸脱氢酶 (LDH) 的释放量和细胞提取物中活化的 caspase 3 水平与未处理细胞和氦处理细胞相当,表明细胞损伤极小。结论PDEB™ 手持设备是第一代设备,在抑制细菌生长方面效果显著。同时,它在人类上皮细胞上的应用也显示出令人鼓舞的安全性。这些研究结果与传统非热等离子设备的有效性相吻合,使 PDEB™ 成为战斗伤员护理和军事行动医学中伤口愈合应用的可行且有前途的选择。
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