[1] A Mahmud, R Lee, D Munfus-Mccray et al. Actinomucor elegans as an emerging cause of Mucormycosis. Journal of Clinical Microbiology, 50, 1092-1095(2012).

[2] J Dorin, M D’Aveni, A Debourgogne et al. Update on Actinomucor elegans, a mucormycete infrequently detected in human specimens: how combined microbiological tools contribute efficiently to a more accurate medical care. International Journal of Medical Microbiology, 307, 435-442(2017).

[3] P A Kubica, W M Rehrauer, A K Sterkel. An unusual case of Actinomucor elegans: a challenging diagnosis. The American Journal of Case Reports, 21, e921562(2020).

[4] W Schostakowitsch. Actinomucor repens n. gen. n. sp. Plant Biology, 16, 155-158(2013).

[5] C R Benjamin, C W Hesseltine. The genus actinomucor. Mycologia, 49, 240(1957).

[6] S C Jong, G F Yuan. Actinomucor taiwanensis sp. nov., formanufacture of fermented soybean food. Mycotaxon, 23, 261-4(1985).

[7] G Davel, P Featherston, A Fernández et al. Maxillary sinusitis caused by Actinomucor elegans. Journal of Clinical Microbiology, 39, 740-742(2001).

[8] Z U Khan, S Ahmad, E Mokaddas et al. Actinomucor elegans var. kuwaitiensis isolated from the wound of a diabetic patient. Antonie Van Leeuwenhoek, 94, 343-352(2008).

[9] C C Tully, A M Romanelli, D A Sutton et al. Fatal Actinomucor elegans var. kuwaitiensis infection following combat trauma. Journal of Clinical Microbiology, 47, 3394-3399(2009).

[10] M M Roden, T E Zaoutis, W L Buchanan et al. Epidemiology and outcome of zygomycosis: a review of 929 reported cases. Clinical Infectious Diseases: an Official Publication of the Infectious Diseases Society of America, 41, 634-653(2005).

[11] D P Kontoyiannis, R E Lewis. Invasive zygomycosis: update on pathogenesis, clinical manifestations, and management. Infectious Disease Clinics of North America, 20, 581-607(2006).

[12] D Farmakiotis, D P Kontoyiannis. Mucormycoses. Infectious Disease Clinics of North America, 30, 143-163(2016).

[13] G Chamilos, R E Lewis, D P Kontoyiannis. Delaying amphotericin B-based frontline therapy significantly increases mortality among patients with hematologic malignancy who have zygomycosis. Clinical Infectious Diseases: an Official Publication of the Infectious Diseases Society of America, 47, 503-509(2008).

[14] Xinglong JIN, Xiaoyan WANG, Hongxia REN et al. Degradation of acid orange 7 and toxicity change to luminescent bacteria during contact glow discharge electrolysis treatment. Acta Scientiarum Naturalium Universitatis Nankaiensis (Natural Science Edition), 50, 79-85(2017).

[15] Xiaoyan WANG, Xinglong JIN, Hongxia REN. Degradation of acid orange 7 using contact glow discharge electrolysis combined with persulfate. Acta Scientiarum Naturalium Universitatis Nankaiensis (Natural Science Edition), 54, 17-22(2021).

[16] Yu CHENG, Leilei JIA, Yunwen LIU et al. Antibacterial finishing treatment of denim fabric based on plasma technology. Journal of Radiation Research and Radiation Processing, 40, 020401(2022).

[17] L Wang, P L Liu, T X Chen. Glow discharge plasma induced dechlorination and decomposition of dichloromethane in an aqueous solution. Plasma Chemistry and Plasma Processing, 36, 615-626(2016).

[18] Zhaojie LI, Li XU, Wei LIU et al. Sterilization of several food contact materials by low temperature plasma by glow discharge. Journal of Inspection and Quarantine, 26, 24-26(2016).

[19] Yafu LIU, Tengfei FU, Chencheng LIU et al. Bactericidal efficacy and kinetics of cold plasma against staphylococcus aureus and pseudomonas aeruginosa. Modern Food Science and Technology, 37, 127-135(2021).

[20] Huixiu ZHANG. Study on metabolites of rhizoctonia solani in potato, 42(2017).

[21] Yan SUN. Degradation of T-2 toxin and patulin by glow discharge plasma(2016).

[22] Mingyuan DU, Haitao LONG, Lipeng TIAN et al. Fungicidal effect of glow discharge plasma on fusarium sulphureum. Food Science, 41, 89-96(2020).

[23] Zhian LIU, Feibo ZHOU, Judong ZHAO et al. Study on sterilization rate of heterotrophic bacteria in power plant cooling water by changing low frequency square-wave pulsed magnetic fields direction. Journal of Inner Mongolia Normal University (Natural Science Edition), 42, 658-662(2013).

[24] Lu YAN. Citric acid inhibits against trichothecium roseum in vitro and its partial mechanism(2015).

[25] Lingang HU, Jianpeng LI, Yongcai LI et al. Control of exogenous H2O2 on dry rot of potato tuber and possible mechanism of action. Scientia Agricultura Sinica, 46, 4745-4752(2013).

[26] Jing HU, Yilin REN, Zhenming LU. Optimization of liquid fermentation conditions of coriolus versicolor extracellular polysaccharide. Edible Fungi, 38, 17-18(2016).

[27] Guojing GUAN, Guilin LIANG, Jixin LI et al. Effects of temperature on growth, sporification, and germination of flue-cured tobacco leaf spot causing C. cassiicola in Guizhou Province. Acta Tabacaria Sinica, 12, 27-31(2006).

[28] Hongmei ZOU. Effect of microwave, ethanol treatment on enzymatic browning of fresh-cut potatoes(2019).

[29] Hui LU. Study on inhibition mechanism of new agricultural antibiotic 702 on plant pathogenic fungi(2012).

[30] Zhixing Gai, Rikui WANG, Mingyang HE et al. Antifungal acitivity of potassium cinnamate against the main postharvest fungal pathogens of citrus fruits. Food and Fermentation Industries, 42, 109-113(2016).

[31] Rui ZHANG. The inhibition and mechanism on growth of fusarium sulphureum caused fusarium rot of muskmelon(2021).

[32] M Yahyazadeh, R Omidbaigi, R Zare et al. Effect of some essential oils on mycelial growth of Penicillium digitatum Sacc. World Journal of Microbiology and Biotechnology, 24, 1445-1450(2008).

[33] Zhaojie LI, Xiaojing LIU, Lijun YANG et al. Sterilization of several foods by glow discharge low temperature plasma and its effects on food quality. Journal of Anhui Agricultural Sciences, 43, 310-315(2015).

[34] Zheng ZHANG, Yongjie YUE. Study on bactericidal effects and mechanisms of dielectric barrier discharge (DBD) air plasma on Staphylococcus aureus. Chinese Journal of Disinfection, 32, 853-856(2015).

[35] Xiaoguang YU, Jiang NI, Shuling BIAN et al. Effects of tyrosine and mifepristone on membrane fluidity and mitochon-drial membrane potential of granulosa cell in rats. Basic Medical Sciences and Clinics, 19, 69-72(1999).

[36] Yuxing CHEN, Lianshuang FU, Xiaonan WANG et al. Effect of freezing stress on membrane permeability and MDA content in the re-growth plant of winter wheat cultivars. Journal of Northeast Agricultural University, 41, 10-16(2010).

[37] J W Zhao, W Lin, X H Ma et al. The protein kinase Hal5p is the high-copy suppressor of lithium-sensitive mutations of genes involved in the sporulation and meiosis as well as the ergosterol biosynthesis in Saccharomyces cerevisiae. Genomics, 95, 290-298(2010).

[38] Longhui CAO, Xiaojun LI, Wenhong ZHAO et al. Research progress on ergosterol. China Brewing, 33, 9-12(2014).

[39] M L Rodrigues. The multifunctional fungal ergosterol. mBio, 9, e01755-e01718(2018).

[40] Xingmei XI, Guangming ZENG, Hongyan YU et al. The techniques of isolation and determination of ergosterol as the indicator of fungal biomass. Microbiology, 33, 128-132(2006).

[41] E N Kobzev, G V Kireev, Y A Rakitskii et al. Effect of cold plasma on the E. coli cell wall and plasma membrane. Applied Biochemistry and Microbiology, 49, 144-149(2013).

[42] Y H Huang, X P Ye, C J Doona et al. An investigation of inactivation mechanisms of Bacillus amyloliquefaciens spores in non-thermal plasma of ambient air. Journal of the Science of Food and Agriculture, 99, 368-378(2019).

[43] Mingyuan DU. Study on fungicidal effect and mechanism of fusarium sulphureum induced by glow discharge plasma(2020).

[44] M Moisan, J Barbeau, S Moreau et al. Low-temperature sterilization using gas plasmas: a review of the experiments and an analysis of the inactivation mechanisms. International Journal of Pharmaceutics, 226, 1-21(2001).

[45] M K Boudam, M Moisan, B Saoudi et al. Bacterial spore inactivation by atmospheric-pressure plasmas in the presence or absence of UV photons as obtained with the same gas mixture. Journal of Physics D: Applied Physics, 39, 3494-3507(2006).

[46] W K Ching, A J Colussi, M R Hoffmann. Soluble sunscreens fully protect E. coli from disinfection by electrohydraulic discharges. Environmental Science & Technology, 37, 4901-4904(2003).