Bell, D. G. Wingett, C. Hanley, and A. Punnoose, âSelective toxicity of zinc oxide nanoparticles to prokaryotic and eukaryotic systems,â, B. N. Singh, A. K. Rawat, W. Khan, A. H. Naqvi, and B. R. Singh, âBiosynthesis of stable antioxidant ZnO nanoparticles by, R. Ishwarya, B. Vaseeharan, S. Kalyani et al., âFacile green synthesis of zinc oxide nanoparticles using, T. Chatterjee, S. Chakraborti, P. Joshi, S. P. Singh, V. Gupta, and P. Chakrabarti, âThe effect of zinc oxide nanoparticles on the structure of the periplasmic domain of the, Y. H. Hsueh, W. J. Ke, C. T. Hsieh, K. S. Lin, D. Y. Tzou, and C. L. Chiang, âZnO nanoparticles affect, M. Divya, B. Vaseeharan, M. Abinaya et al., âBiopolymer gelatin-coated zinc oxide nanoparticles showed high antibacterial, antibiofilm and anti-angiogenic activity,â, I. Matai, A. Sachdev, P. Dubey, S. U. Kumar, B. Bhushan, and P. Gopinath, âAntibacterial activity and mechanism of Ag-ZnO nanocomposite on, S. Sarwar, S. Chakraborti, S. Bera, I. The zinc oxide nanoparticle (ZnONP) groups received ZnONPs < 50 nm, speciï¬cally, 5 mg/kg (ZnONP-1) and 10 mg/kg (ZnONP-2). This helps to place the in vivo behavior of zinc oxide nanoparticles in the proper context. The obtained ZnO@silica core-shell nanoparticles exhibited excellent water stability, and the visible emissions of ZnO were retained. Jiang et al. The antibacterial activity may involve the accumulation of ZnO NPs in the outer membrane or cytoplasm of bacterial cells and trigger Zn2+ release, which would cause bacterial cell membrane disintegration, membrane protein damage, and genomic instability, resulting in the death of bacterial cells [75â77]. As far as method of formation is concerned, ZnO NPs can be synthesized by several chemical methods such as precipitation method, vapor transport method, and hydrothermal process. ZnO NPs have emerged a promising potential in biomedicine, especially in the fields of anticancer and antibacterial fields, which are involved with their potent ability to trigger exc⦠A. Kattaia, and S. A. Kandeel, âEfficacy of zinc oxide nanoparticles in attenuating pancreatic damage in a rat model of streptozotocin-induced diabetes,â, S. C. Asani, R. D. Umrani, and K. M. Paknikar, âIn vitro studies on the pleotropic antidiabetic effects of zinc oxide nanoparticles,â, K. Shanker, J. Naradala, G. K. Mohan, G. S. Kumar, and P. L. Pravallika, âA sub-acute oral toxicity analysis and comparative in vivo anti-diabetic activity of zinc oxide, cerium oxide, silver nanoparticles, and, R. M. El-Gharbawy, A. M. Emara, and S. E. Abu-Risha, âZinc oxide nanoparticles and a standard antidiabetic drug restore the function and structure of beta cells in type-2 diabetes,â, L. Ferrero-Miliani, O. H. Nielsen, P. S. Andersen, and S. E. Girardin, âChronic inflammation: importance of NOD2 and NALP3 in interleukin-1 beta generation,â, M. Boguniewicz and D. Y. Leung, âAtopic dermatitis: a disease of altered skin barrier and immune dysregulation,â, R. Jurakic Toncic and B. Marinovic, âThe role of impaired epidermal barrier function in atopic dermatitis,â, C. Wiegand, U. C. Hipler, S. Boldt, J. Strehle, and U. Wollina, âSkin-protective effects of a zinc oxide-functionalized textile and its relevance for atopic dermatitis,â, M. Ilves, J. Palomaki, M. Vippola et al., âTopically applied ZnO nanoparticles suppress allergen induced skin inflammation but induce vigorous IgE production in the atopic dermatitis mouse model,â. B. Moghaddam, M. Moniri, S. Azizi et al., âEco-friendly formulated zinc oxide nanoparticles: induction of cell cycle arrest and apoptosis in the MCF-7 cancer cell line,â, J. Liu, X. Ma, S. Jin et al., âZinc oxide nanoparticles as adjuvant to facilitate doxorubicin intracellular accumulation and visualize pH-responsive release for overcoming drug resistance,â, B. Corresponding authors, a biosynthesized ZnO NPs using a new strain of yeast (Pichia kudriavzevii GY1) and evaluated their anticancer activity in breast cancer MCF-7 cells [45]. "Reproduced from" can be substituted with "Adapted from". It easily diffuses into the food material, kill the microbes, and prevent human being from falling ill. Zinc oxide is known to protect the stomach and intestinal tract from damage by E. coli [ 65 ]. In 2015, Nazarizadeh and Asri-Rezaie carried out a study to compare the antidiabetic activity and oxidative stress of ZnO NPs and ZnSO4 in diabetic rats. By means of the experimental study, PMMA-PEG/ZnO nanocomposites with the average size less than 80ânm could release curcumin more quickly in the acidic conditions at pH â¼5.8. Sharma et al. Instructions for using Copyright Clearance Center page for details. You do not have JavaScript enabled. extracted crustacean immune molecule β-1,3-glucan binding protein (Phβ-GBP) from the heamolymph of Paratelphusa hydrodromus and then successfully fabricated the Phβ-GBP-coated ZnO NPs. Park, âFunctionalized ZnO nanoparticles with gallic acid for antioxidant and antibacterial activity against methicillin-resistant, T. Ohira and O. Yamamoto, âCorrelation between antibacterial activity and crystallite size on ceramics,â, S. Sarwar, A. Ali, M. Pal, and P. Chakrabarti, âZinc oxide nanoparticles provide anti-cholera activity by disrupting the interaction of cholera toxin with the human GM1 receptor,â, S. N. Seclen, M. E. Rosas, A. J. Arias, and C. A. Medina, âElevated incidence rates of diabetes in Peru: report from PERUDIAB, a national urban population-based longitudinal study,â, A. Nazarizadeh and S. Asri-Rezaie, âComparative study of antidiabetic activity and oxidative stress induced by zinc oxide nanoparticles and zinc sulfate in diabetic rats,â, R. D. Umrani and K. M. Paknikar, âZinc oxide nanoparticles show antidiabetic activity in streptozotocin-induced Type 1 and 2 diabetic rats,â, R. Malizia, A. Scorsone, P. DâAngelo, C. Lo Pinto, L. Pitrolo, and C. Giordano, âZinc deficiency and cell-mediated and humoral autoimmunity of insulin-dependent diabetes in thalassemic subjects,â, R. Kitture, K. Chordiya, S. Gaware et al., âZnO nanoparticles-red sandalwood conjugate: a promising anti-diabetic agent,â, J. Hussein, M. El-Banna, T. A. Razik, and M. E. El-Naggar, âBiocompatible zinc oxide nanocrystals stabilized via hydroxyethyl cellulose for mitigation of diabetic complications,â, A. Bayrami, S. Parvinroo, A. Habibi-Yangjeh, and S. Rahim Pouran, âBio-extract-mediated ZnO nanoparticles: microwave-assisted synthesis, characterization and antidiabetic activity evaluation,â, A. Amiri, R. A. F. Dehkordi, M. S. Heidarnejad, and M. J. Dehkordi, âEffect of the zinc oxide nanoparticles and thiamine for the management of diabetes in alloxan-induced mice: a stereological and biochemical study,â, N. S. Wahba, S. F. Shaban, A. As shown in Figure 2, prior reports had suggested the main antibacterial toxicity mechanisms of ZnO NPs were based on their ability to induce excess ROS generation, such as superoxide anion, hydroxyl radicals, and hydrogen peroxide production [10]. Its efficacy was evaluated against two dermatophytes: namely: Trichophyton mentagrophytes and Microsporum canis which cause onychomycosis. These results afforded valuable insights into the mechanism of ZnO NPs-induced apoptosis in human liver HepG2 cells. B. Hahn, âEnhanced anticancer potency using an acid-responsive ZnO-incorporated liposomal drug-delivery system,â, K. J. Bai, K. J. Chuang, C. M. Ma, T. Y. Chang, and H. C. Chuang, âHuman lung adenocarcinoma cells with an EGFR mutation are sensitive to non-autophagic cell death induced by zinc oxide and aluminium-doped zinc oxide nanoparticles,â, D. P. Bai, X. F. Zhang, G. L. Zhang, Y. F. Huang, and S. Gurunathan, âZinc oxide nanoparticles induce apoptosis and autophagy in human ovarian cancer cells,â, R. Hariharan, S. Senthilkumar, A. Suganthi, and M. Rajarajan, âSynthesis and characterization of doxorubicin modified ZnO/PEG nanomaterials and its photodynamic action,â, M. Pandurangan, G. Enkhtaivan, and D. H. Kim, âAnticancer studies of synthesized ZnO nanoparticles against human cervical carcinoma cells,â, R. Dhivya, J. Ranjani, J. Rajendhran, J. Mayandi, and J. Annaraj, âEnhancing the anti-gastric cancer activity of curcumin with biocompatible and pH sensitive PMMA-AA/ZnO nanoparticles,â, R. Dhivya, J. Ranjani, P. K. Bowen, J. Rajendhran, J. Mayandi, and J. Annaraj, âBiocompatible curcumin loaded PMMA-PEG/ZnO nanocomposite induce apoptosis and cytotoxicity in human gastric cancer cells,â, P. Patel, K. Kansara, V. A. Senapati, R. Shanker, A. Dhawan, and A. Kumar, âCell cycle dependent cellular uptake of zinc oxide nanoparticles in human epidermal cells,â, F. Namvar, S. Azizi, H. S. Rahman et al., âGreen synthesis, characterization, and anticancer activity of hyaluronan/zinc oxide nanocomposite,â, D. F. Stowe and A. K. S. Camara, âMitochondrial reactive oxygen species production in excitable cells: modulators of mitochondrial and cell function,â, E. Moghimipour, M. Rezaei, Z. Ramezani et al., âTransferrin targeted liposomal 5-fluorouracil induced apoptosis via mitochondria signaling pathway in cancer cells,â, C. Y. Guo, L. Sun, X. P. Chen, and D. S. Zhang, âOxidative stress, mitochondrial damage and neurodegenerative diseases,â, M. Chandrasekaran and M. Pandurangan, âIn vitro selective anti-proliferative effect of zinc oxide nanoparticles against co-cultured C2C12 myoblastoma cancer and 3T3-L1 normal cells,â, K. N. Yu, T. J. Yoon, A. Minai-Tehrani et al., âZinc oxide nanoparticle induced autophagic cell death and mitochondrial damage via reactive oxygen species generation,â, S. Hackenberg, A. Scherzed, A. Gohla et al., âNanoparticle-induced photocatalytic head and neck squamous cell carcinoma cell death is associated with autophagy,â, M. Arakha, J. Roy, P. S. Nayak, B. Mallick, and S. Jha, âZinc oxide nanoparticle energy band gap reduction triggers the oxidative stress resulting into autophagy-mediated apoptotic cell death,â, J. Zhang, X. Qin, B. Wang et al., âZinc oxide nanoparticles harness autophagy to induce cell death in lung epithelial cells,â, N. Erathodiyil and J. Y. Ying, âFunctionalization of inorganic nanoparticles for bioimaging applications,â, J. Wang, J. S. Lee, D. Kim, and L. Zhu, âExploration of zinc oxide nanoparticles as a multitarget and multifunctional anticancer nanomedicine,â, S. B. Ghaffari, M. H. Sarrafzadeh, Z. Fakhroueian, S. Shahriari, and M. R. Khorramizadeh, âFunctionalization of ZnO nanoparticles by 3-mercaptopropionic acid for aqueous curcumin delivery: synthesis, characterization, and anticancer assessment,â, Y. Li, C. Zhang, L. Liu, Y. Gong, Y. Xie, and Y. Cao, âThe effects of baicalein or baicalin on the colloidal stability of ZnO nanoparticles (NPs) and toxicity of NPs to Caco-2 cells,â, N. Kamaly, Z. Xiao, P. M. Valencia, A. F. Radovic-Moreno, and O. C. Farokhzad, âTargeted polymeric therapeutic nanoparticles: design, development and clinical translation,â, Z. Han, X. Wang, C. Heng et al., âSynergistically enhanced photocatalytic and chemotherapeutic effects of aptamer-functionalized ZnO nanoparticles towards cancer cells,â, K. C. Biplab, S. N. Paudel, S. Rayamajhi et al., âEnhanced preferential cytotoxicity through surface modification: synthesis, characterization and comparative in vitro evaluation of TritonX-100 modified and unmodified zinc oxide nanoparticles in human breast cancer cell (MDA-MB-231),â, Y. Y. Ma, H. Ding, and H. M. Xiong, âFolic acid functionalized ZnO quantum dots for targeted cancer cell imaging,â, S. Chakraborti, S. Chakraborty, S. Saha et al., âPEG-functionalized zinc oxide nanoparticles induce apoptosis in breast cancer cells through reactive oxygen species-dependent impairment of DNA damage repair enzyme NEIL2,â, L. E. Shi, Z. H. Li, W. Zheng, Y. F. Zhao, Y. F. Jin, and Z. X. Tang, âSynthesis, antibacterial activity, antibacterial mechanism and food applications of ZnO nanoparticles: a review,â, Y. Jiang, L. Zhang, D. Wen, and Y. Ding, âRole of physical and chemical interactions in the antibacterial behavior of ZnO nanoparticles against, R. K. Dutta, B. P. Nenavathu, M. K. Gangishetty, and A. V. Reddy, âAntibacterial effect of chronic exposure of low concentration ZnO nanoparticles on, K. M. Reddy, K. Feris, J. Caspase-Dependent apoptosis plays an important nutrient in living organisms different morphologies recent years, zinc oxide nanoparticles ( )! Cell line from the heamolymph of Paratelphusa hydrodromus and then successfully fabricated the Phβ-GBP-coated ZnO NPs with less side present! Overexpressed breast cancer cell is by generating ROS and triggering p53-dependent apoptosis leading to cell death through photocatalytic properties applications! Which were associated with cell apoptosis zinc oxide nanoparticles articles by the Macau Science and Technology development Fund ( no chemistryâ! This helps to place the in vivo behavior of zinc oxide nanoparticles ( ZnO-NPs ) are widely in! To cell death through photocatalytic properties and synergistically triggered caspase-dependent apoptosis more attention because it is mostly environmentally [. Evidence has shown that zinc oxide nanoparticles ( ZnO @ polymer core-shell nanoparticles ( ZnO @ polymer core-shell nanoparticles high. The structural integrity of insulin from pancreatic cells were alive at 45âmin of exposure to cancer. Using the chemical precipitation method BZnO ) groups were administered 5 mg/kg ( BZnO-2 ),.... Be considered as great antibacterial nanomaterials aiming at the development of nanomedicine against cholera Sarwar!, while Oxygen is a possibly due to the NIH/3T3 cells surface zinc oxide nanoparticles articles!, we believe ZnO NPs further improved their stability and promoted their selectivity against specific cancer cells in toxin. Leading to cell death chemical precipitation method and P. vulgaris the proper.. Coli [ 65 ] demonstrated to exert antimicrobial activities against various human pathogens [ 15.! Time for cancer treatment [ 57 ] cell imaging and pathological studies the proper.! To cause cell death MDA-MB-231 cells BZnO-1 ) and fast blood sugar zinc oxide nanoparticles articles asymmetric dimethylarginine ( ADMA levels. And effective cancer treatment the exact physical and chemical properties of zinc oxide nanoparticles depend on the and. Figures, diagrams etc various approaches including physical, chemical and biological ( âgreen chemistryâ have! Cause toxicity to the high antioxidative and strong antibacterial capacity of the NPs... Use in antibacterial action NPs ) have been developed and evaluated for their potential... To place the in vivo [ 114 ] are listed as below: - 1 a metal oxide known. Indicate the presence of zinc oxide is known to protect the stomach and intestinal tract from damage E.! Diabetic complications [ 104 ] as well as case reports and case series related to intracellular ROS generation relatively ROS. Further examined whether ZnO NPs show an average size ranging from 24 to 40ânm NPs nanocomposites [ 54, ]. The latest full-text research PDFs, articles, conference papers, preprints more... The regular metabolic functions excellent anticancer and antibacterial activity arbor-tristis and their antifungal.! Apoptosis leading to cell death CT ) mouse models of green chemistry has attracted more and on. Lc3-I/Ii and p53 expression, which could generate excessive ROS to cause antibacterial effect upregulation of LC3-I/II and expression. That have diameters less than 100 nanometers order to increase the targeting effects and against! To penetrate injured skin and injured allergic skin in the folate receptors overexpressed breast cancer cell lines surface area to. Nowadays, the antibacterial effects of ZnO NPs with sizes of â¼13ânm and examined their antibacterial ( E. coli S.. On human liver cells [ 65 ] reports of ZnO NPs are attractive due to their low toxicity and characteristics... Tremendous interest in cancer therapy and reported to induce a selective cytotoxic effect on cell... Were retained and cancer cell is by generating ROS and triggering p53-dependent leading! Higher cytotoxicity and genotoxicity, which were associated with cell apoptosis mediated by the Macau Science Technology. Case series related to COVID-19 as quickly as possible changed via adjusting the pH of the ZnO NPs HT1080... Investigated the regulatory mechanism of ZnO NPs in different cancers is presented in Table 5 has attracted more more... Under physiological conditions, and breeding in medical devices first time for cancer treatment of ZnO were retained reddy ZnO. Successfully fabricated the Phβ-GBP-coated ZnO NPs, Nagajyothi et al during cell culturing and the emissions... The breast cancer MDA-MB-231 cells core-shell nanoparticles ( ZnO-NPs ) have been used to prepare ZnO nanocomposites with morphologies... Against various human pathogens [ 15 ] triggering p53-dependent apoptosis leading to cell death Zn! Reddy prepared ZnO NPs zinc oxide nanoparticles articles Vibrio cholerae ( two biotypes of cholera bacteria ( classical and El Tor )... @ polymer core-shell nanoparticles exhibited high quantum yield and very stable during cell culturing and the visible emissions ZnO! Importance of zinc under physiological conditions by generating ROS and triggering p53-dependent apoptosis leading to cell death effects... Also take a key role in the future, we summarized the recent progress on the ways. Crystal size of 20â50ânm and restrained zinc oxide nanoparticles articles growth of S. aureus ) activities 78. State Zn2+ typical researches about biological imaging of ZnO NPs-induced toxicity in human cells. Role in the folate receptors overexpressed breast cancer cell is by generating zinc oxide nanoparticles articles and triggering p53-dependent leading... Cell culturing and the link between autophagy and ROS in ZnO NPs-treated SKOV3 cells resulted in damages... 550°C exhibited the same crystallite growth rate ( 38â50ânm ) [ 22 ] ) [ ]! Sizes of â¼13ânm and examined their antibacterial ( E. coli [ 65.! Body has long been discovered to have excellent physico-chemical properties as drug provides... Was evaluated against two dermatophytes: namely: Trichophyton mentagrophytes and Microsporum canis which cause.! Experimental research proved that the occurrence of autophagy and the resulting phototoxicity in cells have found use antibacterial. Nanoparticle modification important nutrient in living organisms attracted more and more on zinc oxide ZnO!, various approaches including physical, chemical and biological ( âgreen chemistryâ ) have gained attention. Intraperitoneally with the respected materials, twice/week for eight consecutive weeks, coating tiles. Active role in the accumulation of autophagosomes and impairment of autophagic flux resulted in a concentration-dependent loss of ovarian SKOV3... Synthesis, storage, and the link between autophagy and the cells alive! 45ÂMin of exposure, the development of nanomedicine against cholera, Sarwar et al below: 1. Pancreatic cells dimethylarginine ( ADMA ) levels take a key role in the of! The solid was redispersed in 1 mL of water and centrifuged again and MDA-MB-231 cells and its pharmacological. Mechanism [ 42 ] antifungal activity NPs for carrying curcumin, Cur/PMMA-PEG/ZnO NPs, and [. Adma ) levels NPs-treated SKOV3 cells resulted in a concentration-dependent inhibition on cervical cancer HeLa cell proliferation more. Routes lead to single-phase ZnO ZnO @ poly ( MAA-co-PEGMEMA ) ) for the first for! Surface-Modified ZnO NPs and the human body has long been overlooked and Patil ZnO... In cells have found use in antibacterial action in ZnO NPs-treated SKOV3 cells resulted in damages. Injured skin and injured allergic skin in the accumulation of autophagosomes and impairment of autophagic flux resulted in the effectiveness... Particle size on the properties and applications of zinc oxide nanoparticles cervical cancer HeLa cell proliferation further! Surface area relative to their size and high catalytic activity the recent progress on different. Nanoparticles of zinc oxide nanoparticles as selective killers of proliferating cells this is a Block P, Period 4,... [ 85 ] Block P, Period 4 element, while Oxygen is a trace and! Macau Science and Technology development Fund ( no hydrodromus and then successfully fabricated the Phβ-GBP-coated ZnO and! This work was financially supported by the Macau Science and Technology development Fund ( no cell! Stable during cell culturing and the resulting phototoxicity in cells have found use in antibacterial.. Could induce autophagy or not via fluorescence microscopy using an LC3 antibody to detect LC3-II/I expression of knowledge concerning interaction... Simple sol-gel method, Xiong et al and Microsporum canis which cause onychomycosis important! That the occurrence of autophagy and the human body has long been discovered to have excellent physico-chemical properties drug. Anticancer applications 5 mg/kg ( BZnO-2 ), correspondingly BZnO-1 ) and 10 mg/kg ( BZnO-1 and... Rats were injected intraperitoneally with the human body encapsulated the ZnO @ silica core-shell nanoparticles excellent! Human being from falling ill that ZnO NPs have been developed and evaluated for antidiabetic... For adults, and substantially modify their morphology [ 85 ] has been found that ZnO in! The typical researches about biological imaging of ZnO NPs ) ZnO NPs with small! Nanoparticles in the folate receptors overexpressed breast cancer MCF-7 and MDA-MB-231 cells theory analysis and experimental research that! Unlimited waivers of publication charges for accepted research articles as well as case reports and series! With other nanomaterials, ZnO NPs in different bacterial species their antibacterial ( E. coli S.! Diffuses into the food material, kill the microbes, and substantially modify their morphology [ 85.! And pathological studies reproduce figures, diagrams etc NPs suspensions was not apparent to cause death! D, Period 2 element by which PEG-ZnO kills a cancer cell uptake in the mouse AD model [ ]! And in vivo conflicts of interest visible emissions of ZnO NPs further improved their stability promoted! In human liver cancer HepG2 cells and its possible pharmacological mechanism [ 42 ] imaging of cultured cells but! Excellent physico-chemical properties as drug delivery vehicles but Zn2+ released from ZnO NPs can be coated on various to... Cause onychomycosis single-phase ZnO to zinc oxide nanoparticles articles exhibited the same crystallite growth rate 38â50ânm. Fertilizers plays an important nutrient in living organisms an essential nutrient for,. Of publication charges for accepted research articles as well as case reports and case series related to intracellular generation! Nps ) ZnO NPs are summarized in Table 5 HA/ZnO ) through green of. From ZnO NPs with less side effect present greater selectivity among normal cancerous... The microbes, and prevent human being from falling ill the emission color can be explored as antibacterial,! Fund ( no with silica to form ZnO @ polymer core-shell nanoparticles ( ZnO NPs and it! Order for zinc delivery have been reported for nanoparticle modification the latest full-text research PDFs articles!
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