We review new trends of agricultural applications of atmospheric‐pressure plasmas for decontaminating agricultural products and enhancing seed germination and growth of plants and beneficial microorganisms. We classify the decontamination techniques into three kinds of treatments, which are gas‐phase, in‐liquid, and plasma‐activated liquid treatments, and introduce recent studies mainly after 2010, discussing the inactivation mechanism of microorganisms in each treatment. Likewise, we categorize the enhancement techniques into the same three kinds of treatments, and introduce the growth enhancements in detail, discussing the mechanisms and future prospects.
This paper reports on the correlation between gas flow and plasma behaviour in the outflow of a micro-atmospheric pressure plasma jet operating in helium using both 2D optical imaging and Schlieren photography. Schlieren photography shows that the helium outflow changes from laminar to turbulent conditions after distances between 20 and 50 mm from the nozzle. Above a flow rate of 1.4 slm, the length of the laminar region decreases with increasing flow rate. However, by contrast the visible plasma plume increases in length with increasing flow rate until its extension just exceeds that of the laminar region. At this point, the plasma becomes turbulent and its length decreases. Exposing polystyrene (PS) samples to the plasma jet significantly alters the water contact angle in a defined area, with the hydrophobic PS surface becoming more hydrophilic. This modification occurs both with and without direct contact of the visible glow on the surface. The radius of the treated area is much larger than the width of the visible jet but much smaller than the area of the turbulence on the surface. The treated area reduces with increasing nozzle–substrate distance.
Cold atmospheric plasmas have attracted significant worldwide attention for their potential beneficial effects in cancer therapy. In order to further improve the effectiveness of plasma in cancer therapy, it is important to understand the generation and transport of plasma reactive species into tissue fluids, tissues and cells, and moreover the rates and depths of delivery, particularly across physical barriers such as skin. In this study, helium (He) plasma jet treatment of a 3D cancer tumour, grown on the back of a live mouse, induced apoptosis within the tumour to a depth of 2.8 mm. The He plasma jet was shown to deliver reactive oxygen species through the unbroken skin barrier before penetrating through the entire depth of the tumour. The depth and rate of transport of He plasma jet generated H 2 O 2 , NO 3 − and NO 2 − , as well as aqueous oxygen [O 2 (aq)], was then tracked in an agarose tissue model. This provided an approximation of the H 2 O 2 , NO 3 − , NO 2 − and O 2 (aq) concentrations that might have been generated during the He plasma jet treatment of the 3D tumour. It is proposed that the He plasma jet can induce apoptosis within a tumour by the 'deep' delivery of H 2 O 2 , NO 3 − and NO 2 − coupled with O 2 (aq); the latter raising oxygen tension in hypoxic tissue.
NK cells are innate lymphocytes capable of eliciting an innate immune response to pathogens. NK cells develop and become mature in the bone marrow (BM) before they migrate out to peripheral organs. Although the developmental program leading to mature NK cells has been studied in the context of several transcription factors, the stage-specific role of GATA3 in NK cell development has been incompletely understood. Using NKp46-Cre-Gata3fl/fl mice in which Gata3 deficiency was induced as early as the immature stage of NK cell differentiation, we demonstrated that GATA3 is required for the NK cell maturation beyond the CD27 single-positive stage and is indispensable for the maintenance of liver-resident NK cells. The frequencies of NK cells from NKp46-Cre-Gata3fl/fl mice were found higher in the BM but lower in peripheral organs compared with control littermates, indicating that GATA3 controls the maturation program required for BM egress. Despite the defect in maturation, upon murine CMV infection, NK cells from NKp46-Cre-Gata3fl/fl mice expanded vigorously, achieving NK cell frequencies surpassing those in controls and therefore provided comparable protection. The heightened proliferation of NK cells from NKp46-Cre-Gata3fl/fl mice was cell intrinsic and associated with enhanced upregulation of CD25 expression. Taken together, our results demonstrate that GATA3 is a critical regulator for NK cell terminal maturation and egress out of the BM and that immature NK cells present in the periphery of NKp46-Cre-Gata3fl/fl mice can rapidly expand and provide a reservoir of NK cells capable of mounting an efficient cytotoxic response upon virus infection.
We demonstrated the efficacy of using a simple experimental approach, involving UV absorption spectroscopy, to monitor the transport of reactive oxygen and nitrogen species (RONS) through an agarose film (as surrogate for real tissue) into deionized (DI) water. The experiment involved placing a 4 mm thick agarose film over a quartz cuvette filled with DI water. The agarose film was exposed to a non-thermal, He atmospheric-pressure plasma jet (APPJ) and the UV absorption of the DI water was recorded in real-time. Our results indicate an accumulation of RONS within the agarose film during APPJ exposure and a subsequent time-lapsed release of RONS into the DI water. Curve fitting of the UV spectra suggested the APPJ transported and / or generated at least four RONS (NaNO 2 , HNO 3 , H 2 O 2 and O 2 ) through the 4 mm thick agarose film. Our approach of analyzing the delivery depth of RONS through synthetic tissue targets might find use in the future development of APPJ medical therapies and for improving our understanding of APPJ interactions with soft tissue.
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