高抗菌性光催化材料的制备及LED光驱动其抗菌性能研究

doi:10.6023/A24050161

摘要/Abstract

本工作采用简易的水热合成法合成了一种具有高抗菌性能的Mn-ZnO复合无机光催化材料. 通过X射线衍射、扫描电子显微镜、X射线能谱、紫外-可见漫反射吸收光谱等方法对其进行了表征, 证实了材料的成功制备同时表明Mn的引入提高了电子-空穴对的分离效率; 光催化抗菌实验结果表明锰掺杂量为质量分数1%的Mn-ZnO复合材料对细菌的光催化抗菌性能显著高于单一的ZnO纳米材料. 在LED光的驱动下, Mn-ZnO复合材料的浓度仅需125 mg/L时, 其对大肠杆菌(E. coli)、金黄色葡萄球菌(S. aureus)和枯草芽孢杆菌(Bacillus subtilis)的抗菌效率在较短时间内即可分别达到98.33%、100%和100%. 这说明Mn-ZnO复合光催化材料对细菌的杀伤效果十分高效且具有广谱抗菌性, 只需要很短的时间且极低的浓度就可以将多种病原微生物快速杀灭. 而3-(4,5-二甲基噻唑-2)-2,5-二苯基四氮唑溴盐法(MTT)实验证明所合成的这种高抗菌性复合光催化材料在实验浓度下具有良好的生物相容性. 本研究提供了一种廉价、绿色、简单易制备的方法合成了高抗菌性能的光催化材料, 该材料也有望投入到污水处理当中, 在实际抗菌领域拥有广阔的应用前景.

关键词: 锰掺杂, 氧化锌, LED光, 光催化, 抗菌, 复合材料

In this study, a Mn-ZnO composite inorganic photocatalytic material with high antimicrobial properties was successfully synthesised using a facile hydrothermal synthesis method. The material was characterised by X-ray diffraction, scanning electron microscopy, energy dispersive X-ray spectra and ultraviolet-visible diffuse reflection spectra, which confirmed the successful preparation of the material and showed that the introduction of Mn improved the separation efficiency of electron-hole pairs. In order to determine the optimum molar ratio of composites selected for subsequent experiments, this experiment was carried out by comparing the photocatalytic efficiencies of Mn-ZnO composite photocatalytic materials with doping molar ratios of 1%, 3% and 5%. The results demonstrated that the photocatalytic antimicrobial performance of the composites against bacteria was significantly higher than that of single ZnO nanomaterials at 1% Mn doping. In subsequent studies, a 35 W LED light was employed as the excitation light source, and the gradient dilution method and plate colony counting method were used to evaluate the photocatalytic antimicrobial performance of Mn-ZnO composite photocatalytic materials at different concentration gradients (125 mg/L, 250 mg/L, 375 mg/L, 500 mg/L, 1000 mg/L) against three bacterial species, namely, E. coli, S. aureus and Bacillus subtilis. In comparison to the pure ZnO control group, the composites demonstrated antimicrobial effects of 98.33%, 100% and 100% respectively, in a shorter period of time under light conditions with only 125 mg/L. These results indicate that the Mn-ZnO composite photocatalytic materials were more effective against E. coli, S. aureus and Bacillus subtilis than the pure ZnO. This suggests that the Mn-ZnO composite photocatalytic material exhibits high efficiency and broad-spectrum antimicrobial properties, capable of rapidly destroying a multitude of pathogenic microorganisms at a low concentration. Furthermore, 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) experiments demonstrated that this highly antimicrobial composite photocatalytic material, which was synthesised by our research group, has good biocompatibility at the experimental concentration. Therefore, this study provides a cheap, environmentally friendly and facile method to prepare photocatalytic materials with high antimicrobial properties. This new class of functional materials may be used in the field of wastewater treatment in the future and has a promising future in practical antimicrobial applications.

Key words: manganese doping, zinc oxide, LED lamp, photocatalysis, antimicrobial, composites

引用此文

康健, 石梓煊, 李景梅. 高抗菌性光催化材料的制备及LED光驱动其抗菌性能研究[J]. 化学学报, 2024, 82(9): 962-970.

Jian Kang, Zixuan Shi, Jingmei Li. Preparation of Highly Antimicrobial Composites and Study of Photocatalytic Antimicrobial Properties Driven by LED Light[J]. Acta Chimica Sinica, 2024, 82(9): 962-970.

导出引用 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

分享此文

图/表 8

图1. Mn-ZnO复合光催化材料的X-射线衍射分析图(XRD)和扫描电镜图(SEM): (a) Mn-ZnO复合材料和纯ZnO的XRD图谱; (b), (c) Mn-ZnO复合材料的SEM扫描图像

Figure 1. X-ray diffraction analysis (XRD) and scanning electron microscopy (SEM) images of Mn-ZnO composite photocatalytic materials: (a) XRD patterns of Mn-ZnO composites and pure ZnO; (b) and (c) SEM images of the Mn-ZnO composites

图2. Mn-ZnO复合光催化材料的元素分析图(EDS)以及相应的元素映射图: (a) Mn-ZnO的SEM图像; (b)元素占比的峰面积图; (c~f) Mn-ZnO、Zn、Mn、O的EDS图谱(图片标尺: 5 μm)

Figure 2. Elemental analysis diagram (EDS) of Mn-ZnO composite photocatalytic materials and the corresponding elemental mappings: (a) SEM images of Mn-ZnO; (b) elemental occupancy peak area maps; (c~f) EDS profiles of Mn-ZnO, Zn, Mn, O (scale bar: 5 μm)

图3. Mn-ZnO复合光催化材料和ZnO的UV-vis DRS图谱

Figure 3. UV-vis DRS spectra of Mn-doped ZnO composite photocatalytic materials and ZnO

图4. 不同锰掺杂量的ZnO纳米材料对大肠杆菌的抗菌效率图

Figure 4. Antibacterial efficacy of ZnO nanomaterials with varying Mn doping levels against E. coli.

图5. Mn-ZnO在LED灯光照条件下的光催化抗菌效率图及抗菌平板图: (a), (b)大肠杆菌; (c), (d)金黄色葡萄球菌; (e), (f)枯草芽孢杆菌

Figure 5. Photocatalytic antimicrobial efficiency plots and antimicrobial plateplots of Mn-ZnO under LED light illumination conditions: (a), (b) E. coli; (c), (d) S. aureus; (e), (f) Bacillus subtilis

图6. Mn-ZnO在3 h、6 h时对不同细菌的光催化抗菌效率图. (a)大肠杆菌; (b)金黄色葡萄球菌; (c)枯草芽孢杆菌

Figure 6. Photocatalytic antimicrobial efficiency of Mn-ZnO against different bacteria at 3 h and 6 h. (a) E. coli; (b) S. aureus; (c) Bacillus subtilis

图7. 加入不同清除剂对大肠杆菌抗菌效果的影响

Figure 7. Effect of adding different scavengers on the antimicrobial effect of E. coli

图8. MTT检测所制备样品与L929细胞共同培养24 h的细胞存活率

Figure 8. MTT assay for cell viability of the prepared samples co-cultured with L929 cells for 24 h ns indicates no significant difference; * indicates a significant difference

参考文献 58

[1]	Huang L. Biol. Chem. Eng. 2019, 5, 135 (in Chinese).
	(黄亮, 生物化工, 2019, 5, 135.)
[2]	Wen G. Q. J. China Prescr. Drug 2022, 20, 186 (in Chinese).
	(温国琴, 中国处方药, 2022, 20, 186.)
[3]	Vincent J. L.; Sakr Y.; Singer M.; Martin-Loeches I.; Machado F. R.; Marshall J. C.; Finfer S.; Pelosi P.; Brazzi L.; Aditianingsih D.; Timsit J. F.; Du B.; Wittebole X.; Máca J.; Kannan S.; Gorordo-Delsol L. A.; De Waele J. J.; Mehta Y.; Bonten M. J. M.; Khanna A. K.; Kollef M.; Human M.; Angus D. C. JAMA 2020, 323, 1478.
[4]	Lv X. N. Chin. J. Anim. Husbandry Vet. Med. 2018, 5, 51 (in Chinese).
	(吕新年, 畜牧兽医科技信息, 2018, 5, 51.)
[5]	Chen C. L.; Zhai S. Q.; Fu L. Z. Livest. Poult. Industry 2018, 29, 47 (in Chinese).
	(陈春林, 翟少钦, 付利芝, 畜禽业, 2018, 29, 47.)
[6]	Liu T.; Xiao Y. Y. Chin. J. Infect. Control 2023, 22, 995 (in Chinese).
	(刘婷, 肖园园, 中国感染控制杂志, 2023, 22, 995.)
[7]	Prasetya H.; Agustina L.; Rinovian A.; Muttaqin F. IOP Conf. Ser. Earth Environ. Sci. 2022, 986, 12002.
[8]	Song J.; Ashtar M.; Yang Y.; Liu Y.; Chen M.; Cao D. J. Semiconduct. 2023, 44, 111701.
[9]	Zhang L.; Hou S.; Wang T.; Liu S.; Gao X.; Wang C.; Wang G. Small 2022, 18, 2202252.
[10]	Adak M. K.; Mondal D.; Mahato U.; Basak H. K.; Mandal S.; Das A.; Chakraborty B.; Dhak D. Int. J. Hydrogen Energy 2023, 48, 39910.
[11]	Zhu H. W.; Pan Y. S.; Wang Y. Q.; Xiang Y. L.; Han R.; Huang R. J. Nano Res. 2024, 82, 55.
[12]	Kanmani S.; Dileepan A. B. J. Environ. Manage. 2023, 345, 118794.
[13]	Zhao J. J. Shanxi Chem. Industry 2020, 40, 24 (in Chinese).
	(赵巾巾, 山西化工, 2020, 40, 24.)
[14]	Gomez-Gonzalez M. A.; Koronfel M. A.; Goode A. E.; Al-Ejji M.; Voulvoulis N.; Parker J. E.; Quinn P. D.; Scott T. B.; Xie F.; Yallop M. L.; Porter A. E.; Ryan M. P. ACS Nano 2019, 13, 11049. doi: 10.1021/acsnano.9b02866 pmid: 31525960
[15]	Li S.; Sun J.; Guan J. Chin. J. Catal. 2021, 42, 511.
[16]	Ran B.; Ran L.; Wang Z.; Liao J.; Li D.; Chen K.; Cai W.; Hou J.; Peng X. Chem. Rev. 2023, 123, 12371.
[17]	Zhang Q.; Du R.; Tan C.; Chen P.; Yu G.; Deng S. J. Hazard. Mater. 2021, 403, 123582.
[18]	Li B.; Meng X.; Yue Y.; Gao F. J. Wuhan Univ. Technol. Mater. Sci. Ed. 2024, 39, 309.
[19]	Gao Y.; Zhai X.; Zhang Y.; Guan F.; Liu N.; Wang X.; Zhang J.; Hou B.; Duan J. Nano Mater. Sci. 2023, 5, 177.
[20]	Khavar A. H. C.; Khazaee Z.; Mahjoub A. Environ. Sci. Pollut. Res. 2023, 30, 18461.
[21]	Chen Y.; Tang X.; Gao X.; Zhang B.; Luo Y.; Yao X. Ceram. Int. 2019, 45, 15505.
[22]	Baig F.; Zaheer Z.; Khan Z.; Qasim F. Opt. Quantum Electron. 2024, 56, 715.
[23]	Ambujam K.; Sridevi A.; Meivel S.; Chinnusamy T. J. Mater. Sci. Mater. Electron. 2024, 35, 578.
[24]	Fomekong R. L.; Yontchoum P. K.; Ntep T. J. M.; Kamta H. M. T.; Tsobnang P. K. Adv. Energy Sustain. Res. 2024, 5, 2300232.
[25]	Mondal S.; Jamal M.; Ayon S. A.; Anik M. J. F.; Billah M. M. J. Rare Earths 2023, 42, 859.
[26]	Asif N.; Fatima S.; Aziz M. N.; Zaki A.; Fatma T. Bioorg. Chem. 2021, 113, 104999.
[27]	Ponnamma D.; Cabibihan J. J.; Rajan M.; Pethaiah S. S.; Deshmukh K.; Gogoi J. P.; Pasha S. K.; Ahamed M. B.; Krishnegowda J.; Chandrashekar B. N.; Polu A. R.; Cheng C. Mater. Sci. Eng. C 2019, 98, 1210.
[28]	Putri A. E.; Roza L.; Budi S.; Umar A. A.; Fauzia V. Appl. Surf. Sci. 2021, 536, 147847.
[29]	Tata P.; Ganesan R.; Dutta J. R. J. Photochem. Photobiol. B Biol. 2024, 250, 112815.
[30]	Van Embden J.; Gross S.; Kittilstved K. R.; Della Gaspera E. Chem. Rev. 2022, 123, 271.
[31]	Liang S.; Zhang D.; Pu X.; Yao X.; Han R.; Yin J.; Ren X. Sep. Purif. Technol. 2019, 210, 786.
[32]	Liu W.; Zhou M.; Fu H. J. Environ. Chem. Eng. 2023, 11, 110926.
[33]	Liu X.; Yan C.; Wang Y.; Zhang P.; Yan S.; Zhuang J.; Zhu X.; Yang F. Fuel 2023, 349, 128758.
[34]	Lage V. M. A.; Rodríguez-Fernández C.; Vieira F. S.; Da Silva R. T.; Bernardi M. I. B.; De Lima Jr M. M.; Cantarero A.; De Carvalho H. B. Acta Mater. 2023, 259, 119258.
[35]	Aguilar N.; Rozas S.; Escamilla E.; Rumbo C.; Martel S.; Barros R.; Marcos P. A.; Bol A.; Aparicio S. Surf. Interfaces 2024, 46, 103965.
[36]	Vrithias N. R.; Katsara K.; Papoutsakis L.; Papadakis V. M.; Viskadourakis Z.; Remediakis I. N.; Kenanakis G. Materials 2023, 16, 5672.
[37]	Iqbal T.; Afzal M.; Al-Asbahi B. A.; Afsheen S.; Maryam I.; Mushtaq A.; Kausar S.; Ashraf A. Mater. Sci. Semicond. Process. 2024, 173, 108152.
[38]	Senol S.; Yalcin B.; Ozugurlu E.; Arda L. Mater. Res. Express 2020, 7, 015079.
[39]	Aadnan I.; Zegaoui O.; El Mragui A.; Daou I.; Moussout H.; Esteves Da Silva J. C. Catalysts 2022, 12, 1382.
[40]	Vallejo W.; Cantillo A.; Díaz-Uribe C. Heliyon 2023, 9, e20809
[41]	Guo H.; Liu F. H.; Fu X.; Li X. L.; Peng X. Y.; Feng S. L. J. Synth. Cryst. 2020, 49, 1699 (in Chinese).
	(郭慧, 刘方华, 付翔, 李香兰, 彭小英, 冯胜雷, 人工晶体学报, 2020, 49, 1699.)
[42]	Pan H.; Hu Y.; Wu X. W.; Su Q. H. J. Synth. Cryst. 2018, 47, 2498 (in Chinese).
	(潘会, 胡轶, 兀晓文, 苏巧红, 人工晶体学报, 2018, 47, 2498.)
[43]	Güneri E.; Henry J.; Göde F.; Özpozan N. K. J. Cent. South Univ. 2023, 30, 691.
[44]	Janani F. Z.; Khiar H.; Taoufik N.; Sadiq M.; Favier L.; Ezzat A. O.; Elhalil A.; Barka N. Environ. Sci. Pollut. Res. 2024, 31, 25373.
[45]	Tian B.; Tian R.; Liu S.; Wang Y.; Gai S.; Xie Y.; Yang D.; He F.; Yang P.; Lin J. Adv. Mater. 2023, 35, 2304262.
[46]	Aryee A. A.; Dovi E.; Han R.; Li Z.; Qu L. J. Colloid Interface Sci. 2021, 598, 69.
[47]	Singh N.; Shah K.; Pramanik B. K. Environ. Res. 2023, 233, 116484.
[48]	Raza A.; Shoeb M.; Mashkoor F.; Rahaman S.; Mobin M.; Jeong C.; Ansari M. Y.; Ahmad A. Mater. Chem. Phys. 2022, 286, 126173.
[49]	Xie Q.; Liu X.; Liu H. Superlattices Microstruct. 2020, 139, 106391.
[50]	Ramesh A.; Gavaskar D.; Nagaraju P.; Duvvuri S.; Vanjari S. R. K.; Subrahmanyam C. Appl. Surf. Sci. Adv. 2022, 12, 100349.
[51]	Kononenko V.; Repar N.; Marušič N.; Drašler B.; Romih T.; Hočevar S.; Drobne D. Toxicol. Vitro 2017, 40, 256.
[52]	Perumal P.; Sathakkathulla N. A.; Kumaran K.; Ravikumar R.; Selvaraj J. J.; Nagendran V.; Gurusamy M. Sci. Rep. 2024, 14, 2204.
[53]	Gupta J.; Hassan P.; Barick K. Mater. Today Proc. 2021, 42, 926.
[54]	Basnet P.; Samanta D.; Chanu T. I.; Chatterjee S. J. Alloys Compd. 2021, 867, 158870.
[55]	Wang X.; Liu B.; Ma S.; Zhang Y.; Wang L.; Zhu G.; Huang W.; Wang S. Nat. Commun. 2024, 15, 2600. doi: 10.1038/s41467-024-47022-z pmid: 38521830
[56]	Godoy-Gallardo M.; Eckhard U.; Delgado L. M.; De Roo Puente Y. J. D.; Hoyos-Nogués M.; Gil F. J.; Perez R. A. Bioact. Mater. 2021, 6, 4470. doi: 10.1016/j.bioactmat.2021.04.033 pmid: 34027235
[57]	Li J.; Yuan H.; Zhang Q.; Luo K.; Liu Y.; Hu W.; Xu M.; Xu S. Phys. Chem. Chem. Phys. 2020, 22, 27272.
[58]	Chen J.; Shan M.; Zhu H.; Zhang S.; Li J.; Li L. Environ. Sci. Pollut. Res. 2023, 30, 55498.