Abstract
This paper describes the plant-mediated preparation of silver nanoparticles with aqueous extract and infusion of Cistus incanus leaves. To evaluate aqueous extract and infusion antioxidant capacity and total phenolic content the DPPH and Folin–Ciocalteau methods were utilized. The antioxidant capacity and total phenolic content of extract and infusion were equal to 85.97 ± 6.54 mg gallic acid equivalents per gram of dry weight.; 10.76 ± 0.59 mg/mL and 12.65 ± 1.04 mg gallic acid equivalents per gram of dry weight.; 3.10 ± 0.14 mg/mL, respectively. The formed nanoparticles displayed the characteristic absorption band in the 380–450 nm wavelength range. The average size of particles was in the 68.8–71.2 nm range. Morphology and phase composition analysis revealed the formation of spherical nanoparticles with a face-centred cubic structure. Immune compatibility tests of nanoparticles and plant extracts showed no activation of the THP1-XBlue™ monocyte. Cytotoxicity tests performed with L929 mice fibroblasts showed that nanoparticles should be utilized at a concentration of 16 ppm. The minimum inhibitory concentrations determined with the microdilution method for nanoparticles prepared with plant infusion for S. aureus and S. epidermidis were 2 ppm and 16 ppm, respectively.
Highlights
The synthesis of nanoscale materials is an emerging area of science and technology and has focused researchers’ attention, owing to nanomaterials’ immense potential applications in various fields of life
Petkova et al compared the antioxidant activity and the total phenolic content (TPC) in infusions and microwave-assisted extracts from herbs showing that utilization of second extraction method leads to greater values of both extract parameters [50]
This paper describes inexpensive, environmental-friendly, and facile method of AgNPs preparation using Cistus incanus leaves aqueous extract and infusion at various concentrations
Summary
The synthesis of nanoscale materials is an emerging area of science and technology and has focused researchers’ attention, owing to nanomaterials’ immense potential applications in various fields of life. Nanosized materials may contribute solutions to technological and environmental demands in the fields of energy [1], water treatment [2] catalysis [3], and biomedical sciences [4,5,6]. There is a fundamental need to develop clean, environmentally benign, non-toxic, and safe approaches to the preparation of nanomaterials exploiting sustainable and cost-effective technologies. These essential challenges have led researchers to place a focus on biological systems, including bacteria [7], fungi [8], algae [9], and plants [10]
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