Division of Environmental Physics - User: veronika
Faculty of Mathematics, Physics and Informatics, Comenius University Bratislava

Effects of plasma activated water on wheat: Germination, growth parameters, photosynthetic pigments, soluble protein content and antioxidant enzymes activity

Kučerová K., Henselová M., Slováková Ľ., Hensel K.
Plasma Process. Polym. 16 (3), 1800131, 14 pp (2019)

download  

Abstract:

Cold atmospheric plasma operating in contact with water and biological media induce antimicrobial or antitumor effects and represent a great potential for applications in biomedicine and agriculture. The need of control and tunability of the chemical composition and biomedical effects of plasma activated water/media (PAW/PAM) is emerging. By comparing two non-thermal air plasma sources: streamer corona and transient spark, interacting with water in open and closed reactors and by enhancing the plasma-liquid interaction by water electrospray through these discharges, we demonstrate that the plasma gaseous products strongly depend on the discharge regime, its deposited power and gas flow conditions. Streamer corona leads dominantly to the formation of ozone and hydrogen peroxide, while more energetic transient spark leads to nitrogen oxides and hydrogen peroxide. The gaseous products then determine the chemical properties of the PAW and the dominant aqueous reactive oxygen and nitrogen species (RONS). Production of hydrogen peroxide depends on water evaporation and hydroxyl radical formation that is determined by the discharge power. Transient spark produces higher concentrations of gaseous and aqueous RONS and induces stronger antibacterial effects than streamer corona; however, the RONS production rates per Joule of deposited energy are comparable for both studied discharge regimes. The net production rate per Joule of gaseous nitrogen oxides strongly correlates with that of aqueous nitrites and nitrates. Antibacterial effects of the PAW tested on E. coli bacteria are determined by the aqueous RONS: in the lower power streamer corona mainly by the dissolved ozone and hydrogen peroxide, in the higher power transient spark by the combination of hydrogen peroxide, nitrite and acidic pH, while in transient spark in the closed reactor by acidified nitrites.

Citations:

1.)	V. Medvecká, S. Omasta, M. Klas, S. Mošovská, S. Kyzek, A. Zahoranova: Plasma activated water prepared by different plasma sources: physicochemical properties and decontamination effect on lentils sprouts, Plasma Sci. Technol. 24, 015503 (2022), citation no. X, WoS (2022) -------------
2.)	K. Kosumsupamala, P. Thana, N. Palee, Lamasai, C. Kuensaen, Ngamjarurojana, P. Yangkhamman, D. Boonyawan: Air to H2‑N2 Pulse Plasma Jet for In‑Vitro Plant Tissue Culture Process: Source Characteristics, Plasma Chem. Plasma Process. X, xxx (2022), citation no. 8, INDEX (2022) -------------
3.)	A. Asnavandi, G. Barzin, T. Davari Mahabadi, M. Entezari, L. Pishkar: Low Temperature Plasma Affects Physiological and Genetic Attributes of Foeniculum vulgare, Russian J. Plant Physiol. 69, 33 (2022), citation no. 33, INDEX (2022) -------------
4.)	R. Abbaszadeh, P. K. Nia, M. Fattahi, H. G. Marzdashti: The effects of three plasma-activated water generation systems on lettuce seed germination, Research in Agricultural Engineering 67, 131-137 (2001), citation Kucerova (2021) -------------
5.)	L. Wei, C. Wang, W. Liao: Hydrogen Sulfide Improves the Vase Life and Quality of Cut Roses and Chrysanthemums, Journal Plant Growth Regulation X, xxx (2021), citation Kucerova, WoS (2021) -------------
6.)	T. C. Huang, Y. T. Lai, P. H. Kuo, S. Y. Hsu, J. G. Duh: Activation of soy waste solution through plasma treatment, MRS Advances X, xxx (2021), citation no. 12, WoS (2021) -------------
7.)	J. Wang, D. Cui, L. Wang, M. Du, Y. Yin, R. Ma, H. Sun, Z. Jiao: Atmospheric pressure plasma treatment induces abscisic acid production, reduces stomatal aperture and improves seedling growth in Arabidopsis thaliana, Plant Biol. X, xxx (2021), citation no. X, WoS (2021) -------------
8.)	D. Guo, H. Liu, L. Zhou, J. Xie, C. He: Plasma‐activated water production and its application in agriculture, J. Sci. Food and Agricul. X, xxx (2021), citation no. 31, WoS (2021) -------------
9.)	M. Rashid, M. M. Rashid, M. A. Reza, M. R. Talukder: Combined Effects of Air Plasma Seed Treatment and Foliar Application of Plasma Activated Water on Enhanced Paddy Plant Growth and Yield, Plasma Chem. Plasma Process. X, xxx (2021), citation no. X, INDEX (2021) -------------
10.)	M. Selvamuthukumaran (ed): Non-Thermal Processing Technologies for the Grain Industry, CRC Press, 304 Pages (2021), ISBN 9780367608576 (2021) -------------
11.)	M. M. Rashid, M. Rashid, M. M. Hasan, M. R. Talukder: Rice plant growth and yield: foliar application of plasma activated water, Plasma Sci. Technol. 23 (7), 075503 (2021), citation no. 16, WoS (2021) -------------
12.)	T. Wang, Y. Zhao, Z. Xu, J. Wen, X. Su: Study on the optimum nutrient solution concentration for the growth of Mint (Mentha genus), African J. Agric. Research 17 (7), 1024-1030 (2021), citation Kucerova (2021) -------------
13.)	S. Theepharaksapan, Y. Lerkmahalikhit, P. Suwannapech, P. Boonnong, M. Limawatchanakarn, K. Matra: Impact of multi-air plasma jets on nitrogen concentration variance in effluent of membrane bioreactor pilot-plant, Engineer. Appl. Sci. Research 48 (6), 732-739 (2021), citation no. 13 (2021) -------------
14.)	J. Mravlje, M. Regvar, K. Vogel-Mikuš: Development of Cold Plasma Technologies for Surface Decontamination of Seed Fungal Pathogens: Present Status and Perspectives, J. Fungi 7, 650 (2021), citation no. 47, WoS (2021) -------------
15.)	D. Kostoláni, G. B. Ndiffo Yemeli, R. Švubová, S. Kyzek, Z. Machala: Physiological Responses of Young Pea and Barley Seedlings to Plasma-Activated Water, Plants 10, 1750 (2021), citation no. 26, WoS (2021) -------------
16.)	A. Ahmad, K. Sripong, A. Uthairatanakij, S Photchanachai, T. Pankasemsuk, P. Jitareerat: Decontamination of seed borne disease in pepper (Capsicum annuum L.) seed and the enhancement of seed quality by the emulated plasma technology, Scientia Horticulturae 291, 110568 (2021), citation Kucerova, WoS (2021) -------------
17.)	M. Bafoil, M. Yousfi, C. Dunand, N. Merbahi: Effects of Dielectric Barrier Ambient Air Plasma on Two Brassicaceae Seeds: Arabidopsis thaliana and Camelina sativa, Int. J. Mol. Sci. 22, 9923 (2021), citation no. 30, INDEX (2021) -------------
18.)	Y. Chi, S. Zhao, F. Li, S. Zuo, C. Du, L. Qiao, P. Wang: Utilization of Durvillaea antarctica (Chamisso) Hariot Extract as a Biostimulant to Enhance the Growth of Cucumber (Cucumis sativus L.) Seedlings, J. Plant Growth Regul. X, xxx (2021), citation Kucerova, INDEX (2021) -------------
19.)	V. Rathore, B. S. Tiwari, S. K. Nema: Treatment of Pea Seeds with Plasma Activated Water to Enhance Germination, Plant Growth, and Plant Composition, Plasma Chem. Plasma Process. X, xxx (2021), citation no. 25, INDEX (2021) -------------
20.)	H. A. Q. Than, T. H. Pham, D. K. V. Nguyen, T. H. Pham, A. Khacef: Non-thermal Plasma Activated Water for Increasing Germination and Plant Growth of Lactuca sativa L, Plasma Chem. Plasma Process. X, xxx (2021), citation no. 41, INDEX (2021) -------------
21.)	Y. Li , Z. Song, T. Zhang, W. Xu, C. Ding, H. Chen: Spectral Characteristics of Needle Array-Plate Dielectric Barrier Discharge Plasma and Its Activated Water, J. Spectrosc. X, xxx (2021), citation no. 9, INDEX (2021) -------------
22.)	M. Rashid, M. M. Rashid, M. S. Alam, M. R. Talukder: Stimulating Efects of Plasma Activated Water on Growth, Biochemical Activity, Nutritional Composition and Yield of Potato (Solanum tuberosum L.), Plasma Chem. Plasma Process. X, xxx (2021), citation no. 4, INDEX (2021) -------------
23.)	R. P. Guragain, H. B. Baniya, S. P. Pradhan, B. P. Pandey, D. P. Subedi: Influence of plasma-activated water (PAW) on the germination of radish, fenugreek, and pea seeds, AIP Advances 11, 125304 (2021), citation no. 62, INDEX (2021) -------------
24.)	S. Bazzi, J. Valizadeh, M. Valizadeh, A. Movafeghi: Effect of Green Synthesized Zinc Oxide Nanoparticles on the Physiological Parameters and Gum Production of the Saravan Landrace of Guar (Cyamopsis tetragonoloba L.), Int. J. Basic Sci. Med. 6 (3), 91-99 (2021), citation no. 40, INDEX (2021) -------------
25.)	U. G. M. Ekanayake, D. H. Seo, K. Firestein, A. P. O’Mullane, H. Shon, J. MacLeod, D. Golberg, Kostya (Ken) Ostrikov: Atmospheric pressure plasma seawater desalination: Clean energy, agriculture, and resource recovery nexus for a blue planet, Sustainable Materials and Technologies X, xxx (2020), citation no. 25, INDEX (2020) -------------
26.)	K. Gierczik, T. Vukušić, L. Kovács, A. Székely, G. Szalai, S. Milošević, G. Kocsy, K. Kutasi, G. Galiba: Plasma-activated water to improve the stress tolerance of barley, Plasma Proces. Polym. X, xxx-xxx (2020), citation no. 40, INDEX (2020) -------------
27.)	Z. Ahmed, M. F. Manzoor, N. Ahmad, X.A. Zeng, Z. Din, U. Roobab, A. Qayum, R. Siddique, A. Siddeeg, A. Rahaman: Impact of pulsed electric field treatments on the growth parameters of wheat seeds and nutritional properties of their wheat plantlets juice, Food Science & Nutrition 8 (5), 2490-2500 (2020), citation no. 19, WoS (2020) -------------
28.)	R. Han, H. Dai, I. Twardowska, J. Zhan, S. Wei: Aqueous extracts from the selected hyperaccumulators used as soil additives significantly improve accumulation capacity of Solanum nigrum L. for Cd and Pb, J. Hazardous Materials 394, 1225532 (2020), citation mo. 23, WoS (2020) -------------
29.)	L. Ma, J. Zhang, R. Ren, B. Fan, L. Hou, J. Li: Effects of different organic nutrient solution formulations and supplementation on tomato fruit quality and aromatic volatiles, Archives of Agronomy and Soil Science X, xxx (2020), citation Kucerova, INDEX (2020) -------------
30.)	M. Gao, Y. Xu, X. Chang, Y. Dong, Z. Song: Effects of foliar application of graphene oxide on cadmium uptake by lettuce, J. Hazardous Materials X, 122859 (2020), citation Kucerova, INDEX (2020) -------------
31.)	A. Zahoor, M. Manzoor, M. Muhammad Faisal, A. Nazir, Z. Xin et al.: Impact of pulsed electric field treatments on the growth parameters of wheat seeds and nutritional properties of their wheat plantlets juice, Food Science & Nutrition 8 (5) 2490-2500 (2020), INDEX (2020) -------------
32.)	E. M. Konchekov, N. G. Gusein-zade, L. V. Kolik, K. V. Artemev, A. V. Pulish: Using of direct piezo-discharge in generation of plasma-activated liquid media, IOP Conference Series: Materials Science and Engineering 848, 012037 (2020), citation no. 5, INDEX (2020) -------------
33.)	L. Song, Y. Pan, J. Gong, X. Li, M. Liu, B. Yang, Z. Zhan, T. Baoyin: Physiology of Leymus chinensis under seasonal grazing: Implications for the development of sustainable grazing in a temperate grassland of Inner Mongolia, J. Environ. Managem. 271, 110984 (2020), citation no. 41, WoS (2020) -------------
34.)	S. Taheri: Development and evaluation of a non-chemical method with microwave source for disinfection of legumes, PhD Thesis, The University of Melbourne, Melboure (AU), 240 p (2020), citation Kucerova (2020) -------------
35.)	P. Ranieri, N. Sponsel, J. Kizer, M. Rojas‐Pierce, R. Hernández, L. Gatiboni, A. Grunden, K. Stapelmann: Plasma agriculture: Review from the perspective of the plant and its ecosystem, Plasma Process. Polym. X, e2000162 (2020), citation no. 51, WoS (2020) -------------
36.)	Z. Chen, R.-G. Xu, P. Chen, Q. Wang: Potential Agricultural and Biomedical Applications of Cold Atmospheric Plasma-Activated Liquids With Self-Organized Patterns Formed at the Interface, IEEE Trans. Plasma Sci. X, xxx (2020), citation no. 93, INDEX (2020) -------------
37.)	G. B. Ndiffo Yemeli, R. Švubová, D. Kostolani, S. Kyzek, Z. Machala: The effect of water activated by nonthermal air plasmaon the growth of farm plants: Case of maize and barley, Plasma Process. Polym. X, xxx (2020), citation no. 41, INDEX (2020) -------------
38.)	N. C. Roy, C. Pattyn, A. Remy, N. Maira, F. Reniers: NOx synthesis by atmospheric‐pressure N2/O2 filamentary DBD plasma over water: Physicochemical mechanisms of plasma–liquid interactions, Plasma Process. Polym. X, xxx (2020), citation no. 16, WoS (2020) -------------
39.)	S. Herianto, C.-Y. Hou, C.-M. Lin, H.-L. Chen: Nonthermal plasma-activated water: A comprehensive review of this new tool for enhanced food safety and quality, Compr Rev Food Sci Food Saf. X, xxx (2020), citation Kucerova, INDEX (2020) -------------
40.)	V. Stoleru, R. Burlica, G. Mihalache, D. Dirlau, S. Padureanu, G.-C. Teliban, D. Astanei, A. Cojocaru, O. Beniuga, A. Patra: Plant growth promotion effect of plasma activated water on Lactuca sativa L. cultivated in two different volumes of substrate, Sci Rep. 10, 20920 (2020), citation no. 43, WoS (2020) -------------
41.)	P. Škarpa, D Klofáč, F. Krčma, J. Šimečková, Z. Kozáková: Effect of Plasma Activated Water Foliar Application on Selected Growth Parameters of Maize (Zea mays L.), Water 12, 3545 (2020), citation no. 38, INDEX (2020) -------------
42.)	S. Taheri, G. I. Brodie, D. Gupta, M. V. Jacob: Afterglow of atmospheric non-thermal plasma for disinfection of lentil seeds from Botrytis Grey Mould, Inovative Food Science and Emerging Technologies 66 (2020) 1024882, citation Kucerova, INDEX (2020) -------------
43.)	S. Cannazzaro, S. Traversari, S. Cacini, S. Di Lonardo, C. Pane, G. Burchi, D. Massa: Non-Thermal Plasma Treatment Influences Shoot Biomass, Flower Production and Nutrition of Gerbera Plants Depending on Substrate Composition and Fertigation Level, Plants 10, 689 (2021), citation no. 8, WoS (2020) -------------
44.)	A. Przekora, J. Pawlat, P. Terebun, D. Duday, C. Canal, S. Hermans, M. Audemar, C. Labay, J.-S. Thomann, G. Ginalska: The effect of low temperature atmospheric nitrogen plasma on MC3T3-E1 preosteoblast proliferation and differentiation in vitro, J. Phys. D. Appl. Phys. Phys. 52 (27), xxx (2019), citation no. 8, WoS (2019) -------------
45.)	V. Scholtz , B. Šerá, J. Khun, M. Šerý, J. Julák: Effects of Nonthermal Plasma on Wheat Grains and Products, J. Food Quality X, xxx-xxx (2019), citation no. 33, WoS (2019) -------------
46.)	V. Gamaleev, N. Iwata, M. Hori, M. Hiramatsu, M. Ito: Direct Treatment of Liquids Using Low-Current Arc in Ambient Air for Biomedical Applications, Appl. Sci. 9 (17), 3505 (2019), citation no. 6, WoS (2019) -------------
47.)	M. El Shaer, H. El Welily, A. Zaki, H. Arafa, A. ElSebaei, M. ElDaly, M. Mobashe: Germination of Wheat Seeds Exposed to Cold Atmospheric Plasma in Dry and Wet Plasma-Activated Water and Mist, Plasma Medicine 9 (3) 191–203 (2019), citation no. 19, INDEX (2019) -------------