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Silver nanoparticle synthesis by biogenic reduction method and investigation of antimicrobial, antibiofilm, anticancer activities

Year 2023, , 1 - 15, 31.12.2023
https://doi.org/10.59313/jsr-a.1277894

Abstract

It is very important to use the green synthesis approach that uses living things and plants. Using the biogenic reduction technique, silver nanoparticles were synthesized from the R. aculeatus plant for this research. Scanning electron microscopy (SEM), Fourier transform infrared spectroscopy, X-ray diffraction (XRD), and UV-vis spectroscopy was used to characterize the produced AgNPs (FT-IR). After the In this study, R. aculeatus plant extract and biogenically formed AgNPs were investigated for their potential antibacterial, antibiofilm and anticancer abilities. AgNPs were characterised using scanning electron microscopy (SEM), Fourier transform infrared spectroscopy (FT-IR), X-ray diffraction (XRD) and UV-vis spectroscopy (UV-VIS). According to the Debye Scherrer formula, the particle size was found to be 32.56 nm. Disc diffusion and microdilution methods were used to investigate the antibacterial activity. In the disc diffusion study, the best results were obtained from the extract and AgNP. In the tests using plant extracts, Staphylococcus aureus ATCC 25923 showed the lowest antibiofilm activity, while Bacillus subtilis and Enterobacter aerogenes ATCC 13048 showed the highest activity. Salmonella infantis was most affected by AgNP, while Escherichia coli CFAI ATCC 25922 was least affected. Biogenically synthesised AgNPs were also investigated in cytotoxic activity studies. It was found to have the lowest concentration value on MCF-7 and HUVEC cell lines at the determined concentrations. The extract did not have any cytotoxic effect on MCF-7 cell line. HUVEC cell line showed the lowest cytotoxic activity of 10-3 g/mL. The antibacterial, antibiofilm and anticancer properties of R. aculeatus plant extract and biogenically produced AgNPs have been the subject of an important study. Furthermore, the comparison of the effects of plant extract and AgNPs on breast cancer cell lines and healthy cell lines provides a rich scientific material.

References

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  • [4] Sarışen, Ö., and Çalşkan, D., (2005). Fitoterapi: bitkilerle tedaviye dikkat (!). STED- Sürekli Tıp Eğitimi Dergisi, 14, 182–187.
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  • [20] Artiukh, L., Povnitsa, O., Zahorodnia, S., Pop, C. V., and Rizun, N. (2022). Effect of coated silver nanoparticles on cancerous vs. healthy cells. Journal of Toxicology, 2022
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  • [23] Duncan, T. V., (2011). Applications of nanotechnology in food packaging and food safety: Barrier materials, antimicrobials and sensors. Journal of Colloid and Interface Science, 363, 1–24.
  • [24] Beykaya, M., and Çağlar, A., (2016). Bitkisel özütler kullanılarak gümüş-nanopartikül (agnp) sentezlenmesi ve antimikrobiyal etkinlikleri üzerine bir araştırma. Afyon Kocatepe University Journal of Sciences and Engineering, 16, 631–641.
  • [25] Rai, M., Yadav, A., and Gade, A., (2009). Silver nanoparticles as a new generation of antimicrobials. Biotechnology Advances, 27, 76–83.
  • [26] Naghizadeh, A., Mizwari, Z.M., Ghoreishi, S.M., Lashgari, S., Mortazavi-Derazkola, S., and Rezaie, B., (2021). Biogenic and eco-benign synthesis of silver nanoparticles using jujube core extract and its performance in catalytic and pharmaceutical applications: Removal of industrial contaminants and in-vitro antibacterial and anticancer activities. Environmental Technology & Innovation, 23, 101560.
  • [27] Bharadwaj, K.K., Rabha, B., Pati, S., Choudhury, B.K., Sarkar, T., Gogoi, S.K., Nayanjyoti, K., Debabrat, B., Zulhisyam, A.K., and Hisham A.E., (2021). Green synthesis of silver nanoparticles using diospyros malabarica fruit extract and assessments of their antimicrobial, anticancer and catalytic reduction of 4-nitrophenol (4-np). Nanomaterials, 11, 1999.
  • [28] Abdel-Rahman, L.H., Al-Farhan, B.S., Abou El-ezz, D., Abd–El Sayed, M.A., Zikry, M.M., and Abu-Dief, A.M., (2022). Green biogenic synthesis of silver nanoparticles using aqueous extract of moringa oleifera: access to a powerful antimicrobial, anticancer, pesticidal and catalytic agents. Journal of Inorganic and Organometallic Polymers and Materials, 32, 1422–1435.
  • [29] Rozhin, A., Batasheva, S., Kruychkova, M., Cherednichenko, Y., Rozhina, E., and Fakhrullin, R., (2021). Biogenic silver nanoparticles: synthesis and application as antibacterial and antifungal agents. Micromachines, 12.
  • [30] Meydan, I., Seckin, H., Burhan, H., Gür, T., Tanhaei, B., and Sen, F. (2022). Arum italicum mediated silver nanoparticles: Synthesis and investigation of some biochemical parameters. Environmental Research, 204, 112347.
  • [31] Karimi, F., Rezaei-savadkouhi, N., Uçar, M., Aygun, A., Elhouda Tiri, R.N., Meydan, I.,Aghapour, E., Seckin, H., Berikten, D., Gur, T., and Sen, F., (2022). Efficient green photocatalyst of silver-based palladium nanoparticles for methyle orange photodegradation, investigation of lipid peroxidation inhibition, antimicrobial, and antioxidant activity. Food and Chemical Toxicology, 169, 113406. [32] Kirby-Bauer disk diffusion susceptibility test protocol. (2009).
  • [33] Mosmann, T., (1983). Rapid colorimetric assay for cellular growth and survival: application to proliferation and cytotoxicity assays. Journal of Immunological Methods, 65, 55–63.
  • [34] Alley, M.C., Scudiero, D.A., Monks, A., Hursey, M.L., Czerwinski, M.J., Fine, D.L., Abbott, B.J., Mayo, J.G., Sjoemaker, R.H., and Boyd, M.R., (1988). Feasibility of drug screening with panels of human tumor cell lines using a microculture tetrazolium assay. Cancer Research, 48, 589–601.
  • [35] Razavi, M., (2017). Biomaterials for tissue engineering. bentham science publishers.
  • [36] Singhal, G., Bhavesh, R., Kasariya, K., Sharma, A.R., and Singh, R.P., (2011). Biosynthesis of silver nanoparticles using ocimum sanctum (tulsi) leaf extract and screening its antimicrobial activity. Journal of Nanoparticle Research, 13, 2981–2988.
  • [37] Saxena, A., Tripathi, R.M., Zafar, F., and Singh, P., (2012). Green synthesis of silver nanoparticles using aqueous solution of Ficus benghalensis leaf extract and characterization of their antibacterial activity. Materials Letters, 67, 91–94.
  • [38] Karakaya, F., (2021). Yeşil sentez yöntemiyle ruscus aculeatus l. bitkisi kullanılarak gümüş nanopartiküllerin sentezi ve antibiyofilm, antimikrobiyal, antikanser aktivitelerinin incelenmesi. Bartın Üniversitesi.
  • [39] Lu, X., Wang, J., Al-Qadiri, H.M., Ross, C.F., Powers, J.R., Tang, J., and A.Rasco, B., (2011). Determination of total phenolic content and antioxidant capacity of onion (Allium cepa) and shallot (Allium oschaninii) using infrared spectroscopy. Food Chemistry, 129, 637–644.
  • [40] Dıblan, S., Kadiroğlu, P., and Yurdaer Aydemir, L., (2018). FT-IR Spectroscopy Characterization and Chemometric Evaluatıon Of Legumes Extracted with Different Solvents. Food and Health, 4, 80–88.
  • [41] Del Bonis-O’Donnel, J.T., Beyene, A., Chio, L., Demirer, G., Yang, D., and Landry, M.P., (2017). Engineering molecular recognition with bio-mimetic polymers on single walled carbon nanotubes. Journal of Visualized Experiments, 119, 2017, 55030.
  • [42] Mellado-Mojica, E., Seeram, N.P., and López, M.G., (2016). Comparative analysis of maple syrups and natural sweeteners: Carbohydrates composition and classification (differentiation) by HPAEC-PAD and FTIR spectroscopy-chemometrics. Journal of Food Composition and Analysis, 52, 1–8.
  • [43] Se, K.W., Ghoshal, S.K., Wahab, R.A., Ibrahim, R.K.R., and Lani, M.N., (2018). A simple approach for rapid detection and quantification of adulterants in stingless bees (Heterotrigona itama) honey. Food Research International, 105, 453–460.
  • [44] Heydari, R. and Rashidipour, M., (2015). Green synthesis of silver nanoparticles using extract of oak fruit hull (jaft): Synthesis and in vitro cytotoxic effect on MCF-7 cells. International Journal of Breast Cancer, 2015.
  • [45] Suman, T.Y., Radhika Rajasree, S.R., Kanchana, A., and Elizabeth, S.B., (2013). Biosynthesis, characterization and cytotoxic effect of plant mediated silver nanoparticles using Morinda citrifolia root extract. Colloids and Surfaces B: Biointerfaces, 106, 74–78.
Year 2023, , 1 - 15, 31.12.2023
https://doi.org/10.59313/jsr-a.1277894

Abstract

References

  • [1] Patra, J.K., Das, G., Fraceto, L.F., Campos, E.V.R., Rodriguez-Torres, M.D.P., Acosta-Torres, L.S., Diaz-Torres, L.a., Grillo, R., Mallappa, K.S., Sharma, S., Habtemariam S., and Han-Seung, S., (2018). Nano based drug delivery systems: recent developments and future prospects. Journal of Nanobiotechnology,16, 1–33.
  • [2] Faydalıoğlu, E., and Sürüoğlu, M., (2014). Tıbbi ve aromatik bitkilerin antimikrobiyal, antoksidan aktivitelerinin tayini ve kullanım olanakları. Erzincan University Journal of Science and Technology, 6, 233–265.
  • [3] Öztürk, A., and Özbek, H., (2005). The anti-Inflammatory activity of eugenia caryophllata essential oil: An animal model of anti-inflammatory activity. Electronic Journal of General Medicine, 2, 159–163.
  • [4] Sarışen, Ö., and Çalşkan, D., (2005). Fitoterapi: bitkilerle tedaviye dikkat (!). STED- Sürekli Tıp Eğitimi Dergisi, 14, 182–187.
  • [5] Çelikboyun, P., (2015). Ruscus aculeatus L. ve punica granatum L. bitkilerinin ekstrelerinin ve boyanmış kumaş örneklerinin antimikrobiyal özelliklerinin belirlenmesi. Balıkesir Üniversitesi Fen Bilimleri Enstitüsü.
  • [6] Vieira, A., (2010). A comparison of traditional anti-inflammation and anti-infection medicinal plants with current evidence from biomedical research. Results from a regional study. Pharmacognosy Research, 2, 293.
  • [7] Luís, Â., Domingues, F., and Duarte, A.P. (2011). Bioactive compounds, RP-HPLC analysis of phenolics, and antioxidant activity of some portuguese shrub species extracts. Natural Product Communications, 6, 1863-72.
  • [8] Salgado, P., Márquez, K., Rubilar, O., Contreras, D., and Vidal, G., (2019). The effect of phenolic compounds on the green synthesis of iron nanoparticles (FexOy-NPs) with photocatalytic activity. Applied Nanoscience (Switzerland), 9, 371–385.
  • [9] Devi, H.S., Boda, M.A., Shah, M.A., Parveen, S., and Wani, A.H. (2019). Green synthesis of iron oxide nanoparticles using Platanus orientalis leaf extract for antifungal activity. Green Processing and Synthesis, 8, 38–45.
  • [10] Can, M., (2020). Green gold nanoparticles from plant-derived materials: An overview of the reaction synthesis types, conditions, and applications. Reviews in Chemical Engineering, 36, 859–877.
  • [11] Ying, S., Guan, Z., Ofoegbu, P.C., Clubb, P., Rico, C., He, F., and Hong, J., (2022). Green synthesis of nanoparticles: Current developments and limitations. Environmental Technology & Innovation. 26, 102336.
  • [12] Singh, A., Jain, D., Upadhyay, M.K., Khandelwal, N., and Verma, H.N., (2010). Green synthesis of silver nanoparticles using argemone mexicana leaf extract and evaluation of their antimicrobial activities. Article in Digest Journal of Nanomaterials and Biostructures, 5, 483–489.
  • [13] Gur, T., Meydan, I., Seckin, H., Bekmezci, M., and Sen, F. (2021). Green synthesis, characterization and bioactivity of biogenic zinc oxide nanoparticles. Environmental Research, 111897.
  • [14] Erduran, V., Bekmezci, M., Bayat, R., and Sen, F. (2022). Functionalized carbon material-based electrochemical sensors for day-to-day applications. Functionalized Nanomaterial-Based. Electrochemical Sensors, 97–111.
  • [15] Goksu, H., Bekmezci, M., Bayat, R., Altuner, E.E., and Şen, F. (2021). The synthesis and characterization of size-controlled bimetallic nanoparticles. Nanomaterials for Direct Alcohol Fuel Cells, 433–447.
  • [16] Akin, M., Bayat, R., Erduran, V., Bekmezci, M., Isik, I., and Şen, F. (2021). Carbon-based nanomaterials for alcohol fuel cells. Nanomaterials for Direct Alcohol Fuel Cells, 319–336.
  • [17] Dessale, M., Mengistu, G., and Mengist, H.M. (2022). Nanotechnology: a promising approach for cancer diagnosis, therapeutics and theragnosis. International Journal of Nanomedicine, 17, 3735.
  • [18] Takáč, P., Michalková, R., Čižmáriková, M., Bedlovičová, Z., Balážová, Ľ., and Takáčová, G. (2023). The role of silver nanoparticles in the diagnosis and treatment of cancer: are there any perspectives for the future?. Life, 13(2), 466.
  • [19] Sanati, M., Afshari, A.R., Kesharwani, P., Sukhorukov, V.N., and Sahebkar, A. (2022). Recent trends in the application of nanoparticles in cancer therapy: The involvement of oxidative stress. Journal of Controlled Release, 348, 287–304.
  • [20] Artiukh, L., Povnitsa, O., Zahorodnia, S., Pop, C. V., and Rizun, N. (2022). Effect of coated silver nanoparticles on cancerous vs. healthy cells. Journal of Toxicology, 2022
  • [21] Klaus-Joerger, T., Joerger, R., Olsson, E., and Granqvist, C.G., (2001). Bacteria as workers in the living factory: Metal-accumulating bacteria and their potential for materials science. Trends in Biotechnology, 19, 15–20.
  • [22] Ahmad, A., Mukherjee, P., Senapati, S., Mandal, D., Khan, M.I., Kumar, R., and Murali, S., (2003). Extracellular biosynthesis of silver nanoparticles using the fungus fusarium oxysporum. Colloids and Surfaces B: Biointerfaces, 28, 313–318.
  • [23] Duncan, T. V., (2011). Applications of nanotechnology in food packaging and food safety: Barrier materials, antimicrobials and sensors. Journal of Colloid and Interface Science, 363, 1–24.
  • [24] Beykaya, M., and Çağlar, A., (2016). Bitkisel özütler kullanılarak gümüş-nanopartikül (agnp) sentezlenmesi ve antimikrobiyal etkinlikleri üzerine bir araştırma. Afyon Kocatepe University Journal of Sciences and Engineering, 16, 631–641.
  • [25] Rai, M., Yadav, A., and Gade, A., (2009). Silver nanoparticles as a new generation of antimicrobials. Biotechnology Advances, 27, 76–83.
  • [26] Naghizadeh, A., Mizwari, Z.M., Ghoreishi, S.M., Lashgari, S., Mortazavi-Derazkola, S., and Rezaie, B., (2021). Biogenic and eco-benign synthesis of silver nanoparticles using jujube core extract and its performance in catalytic and pharmaceutical applications: Removal of industrial contaminants and in-vitro antibacterial and anticancer activities. Environmental Technology & Innovation, 23, 101560.
  • [27] Bharadwaj, K.K., Rabha, B., Pati, S., Choudhury, B.K., Sarkar, T., Gogoi, S.K., Nayanjyoti, K., Debabrat, B., Zulhisyam, A.K., and Hisham A.E., (2021). Green synthesis of silver nanoparticles using diospyros malabarica fruit extract and assessments of their antimicrobial, anticancer and catalytic reduction of 4-nitrophenol (4-np). Nanomaterials, 11, 1999.
  • [28] Abdel-Rahman, L.H., Al-Farhan, B.S., Abou El-ezz, D., Abd–El Sayed, M.A., Zikry, M.M., and Abu-Dief, A.M., (2022). Green biogenic synthesis of silver nanoparticles using aqueous extract of moringa oleifera: access to a powerful antimicrobial, anticancer, pesticidal and catalytic agents. Journal of Inorganic and Organometallic Polymers and Materials, 32, 1422–1435.
  • [29] Rozhin, A., Batasheva, S., Kruychkova, M., Cherednichenko, Y., Rozhina, E., and Fakhrullin, R., (2021). Biogenic silver nanoparticles: synthesis and application as antibacterial and antifungal agents. Micromachines, 12.
  • [30] Meydan, I., Seckin, H., Burhan, H., Gür, T., Tanhaei, B., and Sen, F. (2022). Arum italicum mediated silver nanoparticles: Synthesis and investigation of some biochemical parameters. Environmental Research, 204, 112347.
  • [31] Karimi, F., Rezaei-savadkouhi, N., Uçar, M., Aygun, A., Elhouda Tiri, R.N., Meydan, I.,Aghapour, E., Seckin, H., Berikten, D., Gur, T., and Sen, F., (2022). Efficient green photocatalyst of silver-based palladium nanoparticles for methyle orange photodegradation, investigation of lipid peroxidation inhibition, antimicrobial, and antioxidant activity. Food and Chemical Toxicology, 169, 113406. [32] Kirby-Bauer disk diffusion susceptibility test protocol. (2009).
  • [33] Mosmann, T., (1983). Rapid colorimetric assay for cellular growth and survival: application to proliferation and cytotoxicity assays. Journal of Immunological Methods, 65, 55–63.
  • [34] Alley, M.C., Scudiero, D.A., Monks, A., Hursey, M.L., Czerwinski, M.J., Fine, D.L., Abbott, B.J., Mayo, J.G., Sjoemaker, R.H., and Boyd, M.R., (1988). Feasibility of drug screening with panels of human tumor cell lines using a microculture tetrazolium assay. Cancer Research, 48, 589–601.
  • [35] Razavi, M., (2017). Biomaterials for tissue engineering. bentham science publishers.
  • [36] Singhal, G., Bhavesh, R., Kasariya, K., Sharma, A.R., and Singh, R.P., (2011). Biosynthesis of silver nanoparticles using ocimum sanctum (tulsi) leaf extract and screening its antimicrobial activity. Journal of Nanoparticle Research, 13, 2981–2988.
  • [37] Saxena, A., Tripathi, R.M., Zafar, F., and Singh, P., (2012). Green synthesis of silver nanoparticles using aqueous solution of Ficus benghalensis leaf extract and characterization of their antibacterial activity. Materials Letters, 67, 91–94.
  • [38] Karakaya, F., (2021). Yeşil sentez yöntemiyle ruscus aculeatus l. bitkisi kullanılarak gümüş nanopartiküllerin sentezi ve antibiyofilm, antimikrobiyal, antikanser aktivitelerinin incelenmesi. Bartın Üniversitesi.
  • [39] Lu, X., Wang, J., Al-Qadiri, H.M., Ross, C.F., Powers, J.R., Tang, J., and A.Rasco, B., (2011). Determination of total phenolic content and antioxidant capacity of onion (Allium cepa) and shallot (Allium oschaninii) using infrared spectroscopy. Food Chemistry, 129, 637–644.
  • [40] Dıblan, S., Kadiroğlu, P., and Yurdaer Aydemir, L., (2018). FT-IR Spectroscopy Characterization and Chemometric Evaluatıon Of Legumes Extracted with Different Solvents. Food and Health, 4, 80–88.
  • [41] Del Bonis-O’Donnel, J.T., Beyene, A., Chio, L., Demirer, G., Yang, D., and Landry, M.P., (2017). Engineering molecular recognition with bio-mimetic polymers on single walled carbon nanotubes. Journal of Visualized Experiments, 119, 2017, 55030.
  • [42] Mellado-Mojica, E., Seeram, N.P., and López, M.G., (2016). Comparative analysis of maple syrups and natural sweeteners: Carbohydrates composition and classification (differentiation) by HPAEC-PAD and FTIR spectroscopy-chemometrics. Journal of Food Composition and Analysis, 52, 1–8.
  • [43] Se, K.W., Ghoshal, S.K., Wahab, R.A., Ibrahim, R.K.R., and Lani, M.N., (2018). A simple approach for rapid detection and quantification of adulterants in stingless bees (Heterotrigona itama) honey. Food Research International, 105, 453–460.
  • [44] Heydari, R. and Rashidipour, M., (2015). Green synthesis of silver nanoparticles using extract of oak fruit hull (jaft): Synthesis and in vitro cytotoxic effect on MCF-7 cells. International Journal of Breast Cancer, 2015.
  • [45] Suman, T.Y., Radhika Rajasree, S.R., Kanchana, A., and Elizabeth, S.B., (2013). Biosynthesis, characterization and cytotoxic effect of plant mediated silver nanoparticles using Morinda citrifolia root extract. Colloids and Surfaces B: Biointerfaces, 106, 74–78.
There are 44 citations in total.

Details

Primary Language English
Subjects Nanochemistry
Journal Section Research Articles
Authors

Funda Karakaya This is me 0000-0003-4328-9062

Ali Savaş Bülbül 0000-0002-2200-7348

Muhammed Bekmezci 0000-0003-3965-6333

Fatih Şen 0000-0001-6843-9026

Publication Date December 31, 2023
Submission Date April 9, 2023
Published in Issue Year 2023

Cite

IEEE F. Karakaya, A. S. Bülbül, M. Bekmezci, and F. Şen, “Silver nanoparticle synthesis by biogenic reduction method and investigation of antimicrobial, antibiofilm, anticancer activities”, JSR-A, no. 055, pp. 1–15, December 2023, doi: 10.59313/jsr-a.1277894.