Preparation of CuO/ZnO Composite Nanospheres with Multi-enzyme Activity and Study of Their Antibacterial Properties

doi:10.6023/A25050176

Abstract

Bacterial infections pose a significant threat to human health. Clinically, the treatment of bacterial infections often relies on antibiotics. However, the emergence of “multi-drug resistant bacteria” due to antibiotic misuse has been a persistent challenge for the medical community, even leading humanity to a near “antibiotic-free” predicament. Metal-based nanozymes, with their high antibacterial activity and low resistance, have emerged as effective alternative strategies for treating bacterial infection wounds. However, single catalytic activity and limited antibacterial effects restrict its further development. In this study, a CuO/ZnO composite nanosphere was successfully prepared and used as nanozyme for the eradication of antibiotic-resistant bacteria. The CuO/ZnO composite nanosphere was characterized using transmission electron microscopy, scanning electron microscopy, X-ray diffraction, X-ray photoelectron spectroscopy, and nitrogen adsorption instruments, confirming its successful synthesis. The catalytic activity of the material was evaluated using two reactive oxygen probes, 3,3',5,5'-tetramethylbenzidine (TMB) and o-phenylenediamine (OPDA), revealing that the CuO/ZnO composite nanospheres possess both oxidase-like (OXD-like) and peroxidase-like (POD-like) activities. The catalytic activity of the composite nanospheres is significantly higher than that of individual CuO and ZnO nanospheres, validating the rationality of our synthesis strategy. The antibacterial performance of CuO/ZnO composite nanospheres at different concentrations was tested using the viable cell count method. The results indicated that the CuO/ZnO composite nanospheres at a concentration of 50 μg/mL, in the presence of H₂O₂, could generate reactive oxygen species through their multi-enzyme activity, effectively killing Escherichia coli (E. coli) and methicillin-resistant Staphylococcus aureus (MRSA), achieving a 100% inhibition rate. Subsequent studies on the antibacterial mechanism revealed that the high-efficiency bactericidal effect of CuO/ZnO composite nanospheres is primarily attributed to their disruption of bacterial cell membranes and leakage of intracellular proteins. Additionally, CCK-8 assays confirmed the good biocompatibility of CuO/ZnO composite nanosphere, with cell viability remaining above 80% even at a concentration of 100 μg/mL. In summary, this study provides new research perspectives for the application of metal-based nanozymes in the treatment of drug-resistant bacterial infections.

Key words: composite nanosphere, multi-enzyme activity, bacterial infection, reactive oxygen species, antibacterial mechanism

Cite this article

Shi Hanzhu, Gao Yaning, Chen Zhaoyu, Dai Chenwei, Zhou Xiuhong, Zhang Yingying. Preparation of CuO/ZnO Composite Nanospheres with Multi-enzyme Activity and Study of Their Antibacterial Properties[J]. Acta Chimica Sinica, 2025, 83(11): 1363-1371.

Export EndNote|Reference Manager|ProCite|BibTeX|RefWorks

share this article

Fig. & Tab. 7

Scheme 1. Schematic diagram of the synthesis and application of CuO/ZnO nanospheres

Figure 1. (A) Transmission electron microscopy (TEM) image, (B) scanning electron microscopy (SEM) image, (C) high-resolution SEM image and (D) high-resolution TEM image of CuO/ZnO nanospheres

Figure 2. (A) Fourier-transform infrared spectroscopy (FTIR) spectrum of CuO/ZnO nanospheres, (B) X-ray photoelectron spectroscopy (XPS) spectrum of CuO/ZnO nanospheres and (C, D) High-resolution XPS spectra of CuO/ZnO nanospheres [Cu 2p (C), Zn 2p (D)]

Figure 3. (A) Schematic representation of the OXD-like and POD-like enzymatic activities of CuO/ZnO nanospheres, enzyme-like catalytic activity of CuO/ZnO nanospheres obtained under different combinations (B), concentrations (C) and H2O2 concentrations (D) using TMB probe, and enzyme-like catalytic activity of CuO/ZnO nanospheres obtained under different combinations (E), concentrations (F) and H2O2 concentrations (G) using OPDA prob

Figure 4. (A) Number of colonies of E. coli (A) and MRSA (B) on plates and statistical graph of the lower bacterial survival rate of (C) E. coli and (D) MRSA after CuO/ZnO nanosphere treatment after treatment with CuO/ZnO nanospheres at different concentrations, with and without the presence of H2O

Figure 5. Scanning electron microscopy (SEM) images of E. coli (A) and MRSA (B) (arrows indicate bacterial damage sites) and protein leakage statistics of E. coli (C) and MRSA (D) after treatment with CuO/ZnO nanoparticles of different concentrations, with or without the presence of H2O2

Figure 6. Statistical results of cell survival after 24 h culture of different concentrations of CuO/ZnO nanospheres with (A) human umbilical vein endothelial cells (HUVECs) and (B) mouse fibroblasts (L929)

References 33

[1]	Deusenbery C.; Wang Y. Y.; Shukla A. ACS Infect. Dis. 2021, 7, 695.
[2]	Kang J.; Shi Z.-X.; Li J.-M. Acta Chim. Sinic. 2024, 82, 962 (in Chinese).
	(康健, 石梓煊, 李景梅, 化学学报, 2024, 82, 962.)
[3]	Vila J.; Moreno-Morales J.; Ballesté-Delpierre C. Clin. Microbiol. Infect. 2020, 26, 596.
[4]	Xie J. Y.; Zhou M.; Qian Y. X.; Cong Z. H.; Chen S.; Zhang W. J.; Jiang W. N.; Dai C. Z.; Shao N.; Ji Z. M.; Zou J. C.; Xiao X. M.; Liu L. Q.; Chen M. Z.; Li J.; Liu R. H. Nat. Commun. 2021, 12, 5898.
[5]	Liu C.; Wang W.-G.; Wang S.-F. Acta Chim. Sinic. 2024, 82, 1086 (in Chinese).
	(刘畅, 王文贵, 王守锋, 化学学报, 2024, 82, 1086.)
[6]	Zhu Z. X.; Huang C. J.; Liu L. Y.; Wang J. Y.; Gou X. J. Colloid Interface Sci. 2024, 661, 374.
[7]	Wang Y.; Yang Y. N.; Shi Y. R.; Song H.; Yu C. Z. Adv. Mate.. 2020, 32, 1904106.
[8]	Han Y.-C.; Wang Y.-L. Acta Chim. Sinic. 2023, 81, 1196 (in Chinese).
	(韩玉淳, 王毅琳, 化学学报, 2023, 81, 1196.)
[9]	Kong J.; Zhang J.-G.; Zhang S.-F.; Xi J.-Q.; Shen M. Acta Phys.- Chim. Sin. 2023, 39, 2212039 (in Chinese).
	(孔菁, 张金贵, 张素芬, 奚菊群, 沈明, 物理化学学报, 2023, 39, 2212039.)
[10]	Zhao X.-S.; Qiu H.-Y.; Shao Y.; Wang P.-J.; Yu S.-L.; Li H.; Zhou Y.-B.; Zhou Z.; Ma L.-F.; Tan C.-L. Acta Phys.-Chim. Sin. 2023, 39, 2211043 (in Chinese).
	(赵信硕, 邱海燕, 邵依, 王攀捷, 余石龙, 李海, 周郁斌, 周战, 马录芳, 谭超良, 物理化学学报, 2023, 39, 2211043.)
[11]	Zeng X. L.; Wang H. R.; Ma Y. T.; Xu X.; Lu X. X.; Hu Y. J.; Xie J. H.; Wang X.; Wang Y. S.; Guo X. L.; Zhao L.; Li J. C. ACS Appl. Mater. Interface. 2023, 15, 13941.
[12]	Dong H. J.; Du W.; Dong J.; Che R. C.; Kong F.; Cheng W. L.; Ma M.; Gu N.; Zhang Y. Nat. Commun. 2022, 13, 5365.
[13]	Wang C.; Zhang M. L.; Bai L. P.; Gai P. P.; Li F. Anal. Chem. 2023, 95, 7014.
[14]	Ren X. F.; Wang X. Z.; Yang J.; Zhang X. Y.; Du B. J.; Bai P. R.; Li L. P.; Zhang R. P. Adv. Healthcare Mater. 2023, 13, 2303537.
[15]	Song N. N.; Yu Y.; Zhang Y. N.; Wang Z. D.; Guo Z. J.; Zhang J. L.; Zhang C. B.; Liang M. M. Adv. Mater. 2024, 36, 2210455.
[16]	Yang K.; Ding M.; Xiu W.; Zhang Y.; Dong H.; Shan J.; Wang L. J. Colloid Interface Sci. 2024, 657, 611.
[17]	Chen Q.-W.; Zhang X.-Z. Acta Chim. Sinic. 2023, 81, 1043 (in Chinese).
	(陈其文, 张先正, 化学学报, 2023, 81, 1043.)
[18]	Liu Q. W.; Zhang A. M.; Wang R. H.; Zhang Q.; Cui D. X. Nano-Micro Lett. 2021, 13, 154.
[19]	Lanh L. T.; Hoa T. T.; Cuong N. D.; Khieu D. Q.; Quang D. T. J. Alloys Compd. 2015, 635, 265.
[20]	Shi Q. Y.; Zhao Y.; Liu M. H.; Shi F. Y.; Chen L. X.; Xu X. R.; Gao J.; Zhao H. B.; Lu F. P.; Qin Y. J.; Zhang Z.; Lian M. L.; Smal. 2023, 20, 2309366.
[21]	Wu H. B.; Wei M.; Hu S.; Cheng P.; Shi S. H.; Xia F.; Xu L. N.; Yin L. N.; Liang G.; Li F. Y.; Ling D. S. Adv. Sci. 2023, 10, 2301694.
[22]	Bai J. W.; Zhang X.; Zhao Z. W.; Sun S. H.; Cheng W. Y.; Yu H. X.; Chang X. Y.; Wang B. D. Smal. 2024, 20, 2400326.
[23]	Mei L. Q.; Zhu S.; Liu Y. P.; Yin W. Y.; Gu Z. J.; Zhao Y. L. Chem. Eng. J. 2021, 418, 129431.
[24]	Zhang W.; Lv Y.; Niu Q.; Zhu C.; Zhang H. G.; Fan K. L.; Wang X. W. Smal. 2025, 21, 2406356.
[25]	Karim M. N.; Singh M.; Weerathunge P.; Bian P.; Zheng R. K.; Dekiwadia C.; Ahmed T.; Walia S.; Gaspera E. D.; Singh S.; Ramanathan R.; Bansal V. ACS Appl. Nano Mater. 2018, 1, 1694.
[26]	Sun Y. W.; Zhang W.; Luo Z.; Zhu C.; Zhang Y. Q.; Shu Z.; Shen C.; Yao X.; Wang Y.; Wang X. W. Adv. Funct. Mater. 2024, 35, 2415778.
[27]	Fomina M.; Sizova E.; Nechitailo K. Arch. Microbiol. 2023, 205, 205.
[28]	Yu H.-C.; Huang X.-Y.; Li H.; Lei F.-H.; Tan X.-C.; Wei Y.-C.; Wu H.-Y. Acta Phys.-Chim. Sin. 2014, 30, 2085 (in Chinese).
	(余会成, 黄学艺, 李浩, 雷福厚, 谭学才, 韦贻春, 吴海鹰, 物理化学学报, 2014, 30, 2085.)
[29]	Shi H. Z.; Li L.; Zhang L. Y.; Wang T. T.; Wang C. G.; Zhu D. X.; Su Z. M. CrystEngCom. 2015, 17, 4768.
[30]	Wu K. L.; Zhu D. D.; Dai X. L.; Wang W. N.; Zhong X. Y.; Fang Z. B.; Peng C.; Wei X. W.; Qian H. S.; Chen X. L.; Wang X. W.; Zha Z. B.; Cheng L. Nano Toda. 2022, 43, 101380.
[31]	Tian H. T.; Yan J. Q.; Zhang W.; Li H. X.; Jiang S. W.; Qian H. S.; Chen X. L.; Dai X. L.; Wang X. W. Acta Biomater. 2023, 1, 449.
[32]	Fouda A.; Salem S. S.; Wassel A. R.; Hamza M. F.; Shaheen T. Heliyo. 2020, 6, 04896.
[33]	Ye M. Z.; Zhao Y.; Wang Y. Y.; Zhao M.; Yodsanit N.; Xie R. S.; Andes D.; Gong S. Q. Adv. Mater. 2021, 33, 2006772.

具有多酶活性CuO/ZnO复合纳米球的制备及其抗菌性能研究