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The requirements for new technologies to serve as anticancer agents go far beyond their toxicity potential. Novel applications also need to be safe on a molecular and patient level. In a broader sense, this also relates to cancer metastasis and inflammation. In a previous study, the toxicity of an atmospheric pressure argon plasma jet in four human pancreatic cancer cell lines was confirmed and plasma treatment did not promote metastasis in vitro and in ovo. Here, these results are extended by additional types of analysis and new models to validate and define on a molecular level the changes related to metastatic processes in pancreatic cancer cells following plasma treatment in vitro and in ovo. In solid tumors that were grown on the chorion-allantois membrane of fertilized chicken eggs (TUM-CAM), plasma treatment induced modest to profound apoptosis in the tissues. This, however, was not associated with a change in the expression levels of adhesion molecules, as shown using immunofluorescence of ultrathin tissue sections. Culturing of the cells detached from these solid tumors for 6d revealed a similar or smaller total growth area and expression of ZEB1, a transcription factor associated with cancer metastasis, in the plasma-treated pancreatic cancer tissues. Analysis of in vitro and in ovo supernatants of 13 different cytokines and chemokines revealed cell line-specific effects of the plasma treatment but a noticeable increase of, e.g., growth-promoting interleukin 10 was not observed. Moreover, markers of epithelial-to-mesenchymal transition (EMT), a metastasis-promoting cellular program, were investigated. Plasma-treated pancreatic cancer cells did not present an EMT-profile. Finally, a realistic 3D tumor spheroid co-culture model with pancreatic stellate cells was employed, and the invasive properties in a gel-like cellular matrix were investigated. Tumor outgrowth and spread was similar or decreased in the plasma conditions. Altogether, these results provide valuable insights into the effect of plasma treatment on metastasis-related properties of cancer cells and did not suggest EMT-promoting effects of this novel cancer therapy.
Cold physical plasma (CPP) technology is of high promise for various medical applications.
The interplay of specific components of physical plasma with living cells, tissues and organs on a structural and functional level is of paramount interest with the aim to induce therapeutic effects in a controlled and replicable fashion.
In contrast to other medical disciplines such as dermatology and oromaxillofacial surgery, research reports on CPP application in orthopaedics are scarce.
The present implementation of CPP in orthopaedics involves surface modifications of orthopaedic materials and biomaterials to optimize osseointegration. In addition, the influence of CPP on musculoskeletal cells and tissues is a focus of research, including possible adverse reactions and side effects. Its bactericidal aspects make CPP an attractive supplement to current treatment regimens in case of microbial inflammations such as periprosthetic joint infections. Attributed anticancerogenic and pro-apoptotic effects underline the clinical relevance of CPP as an additive in treating malignant bone lesions.
The present review outlines ongoing research in orthopaedics involving CPP; it distinguishes considerations for safe application and the need for more evidence-based research to facilitate robust clinical implementation.
Multiple evidence in animal models and in humans suggest a beneficial role of cold physical
plasma in wound treatment. Yet, risk assessment studies are important to further foster therapeutic
advancement and acceptance of cold plasma in clinics. Accordingly, we investigated the long-term
side effects of repetitive plasma treatment over 14 consecutive days in a rodent full-thickness ear
wound model. Subsequently, animals were housed for 350 days and sacrificed thereafter. In blood,
systemic changes of the pro-inflammatory cytokines interleukin 1β and tumor necrosis factor α
were absent. Similarly, tumor marker levels of α-fetoprotein and calcitonin remained unchanged.
Using quantitative PCR, the expression levels of several cytokines and tumor markers in liver,
lung, and skin were found to be similar in the control and treatment group as well. Likewise,
histological and immunohistochemical analysis failed to detect abnormal morphological changes
and the presence of tumor markers such as carcinoembryonic antigen, α-fetoprotein, or the neighbor
of Punc 11. Absence of neoplastic lesions was confirmed by non-invasive imaging methods such as
anatomical magnetic resonance imaging and positron emission tomography-computed tomography.
Our results suggest that the beneficial effects of cold plasma in wound healing come without apparent
side effects including tumor formation or chronic inflammation.
On the aqueous phase chemistry of atmospheric-pressure plasma jets for biomedical applications
(2021)
Cold atmospheric-pressure plasmas are candidate biomedical tools proposed for various applications, such as biological decontamination, cancer regression, and promotion of wound healing. Plasmas, which are in the fourth state of matter, can be generated using inert gases (e.g., argon, helium, ambient air) and different source concepts. Together with the applied parameters, the source design defines the chemical-physical characteristics of the resulting plasma, leading in turn to variable biochemical effects on biological matter. The medical effectiveness of cold plasmas has been proven in vitro and in vivo, also in clinical trials for wound healing in patients using two certified plasmas sources, the kINPen MED and the PlasmaDerm. However, molecular mechanisms leading to those effects are unclear. In the same way, it must be studied if the modulation of plasma properties could improve the specificity of biological effects. These findings are needed to define the concept of plasma dose to be optimized in targeting peculiar pathologic conditions. The present thesis consisting of five peer-reviewed publications has investigated these aspects of plasma research.
In the gaseous phase of cold plasmas, various components with biological activity are produced, such as radiation (e.g., vacuum UV, UV) and reactive species (e.g., •O, 1O2, •OH, •NO, •NO2, O3). As most gaseous species are short-lived, liquid compartments surrounding cells and molecular structures could mediate their transformation and/or the production of other aqueous species. For this reason, plasma-induced aqueous chemistry has been mainly investigated in this thesis. The reaction pathways of reactive oxygen and nitrogen species in liquid were analyzed by monitoring the oxidative modifications induced on tyrosine and cysteine, which are biological structures essential in cellular protein functioning. Liquid chromatography and mass spectrometry-based strategies have been elaborated to elucidate structural changes and characterize the oxidative pattern occurring on the tracers after treatment with plasmas.
As a first result, it could be shown that the oxidative pattern induced on tyrosine or cysteine variated qualitatively and quantitatively with the applied conditions, reflecting the action of differently produced/deposited species in liquid. Biologically relevant structures were identified and in part quantified (e.g., cystine, sulfonic acid, sulfinic acid, S-sulfonate, S-nitrosocysteine, nitrotyrosine, nitrosotyrosine). By using isotopically labeled oxygen or nitrogen in the gas plasma, or labeled oxygen in the target liquid, the incorporation of gaseous or aqueous species in the tracer’s structures was monitored via mass spectrometry. With this strategy, the reaction mechanisms involving gaseous oxygen and nitrogen species at the liquid interface were clarified, as well as the de novo production of reactive species in liquid. Short-lived gaseous oxygen species such as atomic and singlet oxygen (•O, 1O2), predominantly formed in conditions with oxygen in the plasma gas, were able to modify the cysteine structures in highly oxidized derivatives, such as cysteine sulfonic acid. Due to their half-life, however, their activity occurred mainly at the interface. Vacuum UV radiation and •O also led to the formation in liquid of hydroxyl radicals (•OH) and hydrogen peroxide (H2O2), due to water photolysis and homolysis. Water-derived species were responsible for the formation of reversible modifications, such as cysteine S-sulfonate, cystine, and cystine sulfoxides. Nitrosative modifications (e.g., S-nitrosocysteine, nitrosotyrosine, nitrotyrosine) could be observed only in conditions with both nitrogen and oxygen in the plasma gas, and further optimization occurred in presence of water molecules in the gas. In this case, the formation and action of peroxynitrite (ONOO-) in generating nitrotyrosine was proven by using a scavenger molecule for ONOO-.
Finally, the cysteine product pattern was applied as a tool to characterize and compare the overall chemistry generated in liquid by different plasma sources and applied parameters. These findings aim to support and contribute to the definition of plasma dose for plasma medicine, through the standardization, control, tuning, and optimization of plasma parameters and plasma liquid chemistry. These results may be applied in the future to improve the specificity and selectivity of the biological effects generated by the described atmospheric-pressure plasma jets.
Molecular Mechanisms of the Efficacy of Cold Atmospheric Pressure Plasma (CAP) in Cancer Treatment
(2020)
Cold medical gas plasmas are under pre-clinical investigation concerning their hemostatic activity and could be applied for intra-operative bleeding control in the future. The technological leap innovation was their generation at body temperature, thereby causing no thermal harm to the tissue and ensuring tissue integrity. This directly contrasts with current techniques such as electrocautery, which induces hemostasis by carbonizing the tissue using a heated electrode. However, the necrotized tissue is prone to fall, raising the risk of post-operative complications such as secondary bleedings or infection. In recent years, various studies have reported on the ability of medical gas plasmas to induce blood coagulation, including several suggestions concerning their mode of action. As non-invasive and gentle hemostatic agents, medical gas plasmas could be particularly eligible for vulnerable tissues, e.g., colorectal surgery and neurosurgery. Further, their usage could be beneficial regarding the prevention of post-operative bleedings due to the absence or sloughing of eschar. However, no clinical trials or individual healing attempts for medical gas plasmas have been reported to pave the way for clinical approvement until now, despite promising results in experimental animal models. In this light, the present mini-review aims to emphasize the potential of medical gas plasmas to serve as a hemostatic agent in clinical procedures. Providing a detailed overview of the current state of knowledge, feasible application fields are discussed, and possible obstacles are addressed.
Medical gas plasmas are of emerging interest in pre-clinical oncological research. Similar to an array of first-line chemotherapeutics and physics-based therapies already approved for clinical application, plasmas target the tumor redox state by generating a variety of highly reactive species eligible for local tumor treatments. Considering internal tumors with limited accessibility, medical gas plasmas help to enrich liquids with stable, low-dose oxidants ideal for intratumoral injection and lavage. Pre-clinical investigation of such liquids in numerous tumor entities and models in vitro and in vivo provided evidence of their clinical relevance, broadening the range of patients that could benefit from medical gas plasma therapy in the future. Likewise, the application of such liquids might be promising for recurrent BRAF(V600E) papillary thyroid carcinomas, resistant to adjuvant administration of radioiodine. From a redox biology point of view, studying redox-based approaches in thyroid carcinomas is particularly interesting, as they evolve in a highly oxidative environment requiring the capability to cope with large amounts of ROS/RNS. Knowledge on their behavior under different redox conditions is scarce. The present study aimed to clarify resistance, proliferative activity, and the oxidative stress response of human papillary thyroid cancer cells K1 after exposure to plasma-oxidized DMEM (oxDMEM). Cellular responses were also evaluated when treated with different dosages of hydrogen peroxide and the RNS donor sodium nitroprusside (SNP). Our findings outline plasma-oxidized liquids as a promising approach targeting BRAF(V600E) papillary thyroid carcinomas and extend current knowledge on the susceptibility of cells to undergo ROS/RNS-induced cell death.