Influences of Plasma Plume Length on Structural, Optical and Dye Degradation Properties of Citrate-Stabilized Silver Nanoparticles Synthesized by Plasma-Assisted Reduction
Abstract:Citrate-capped silver nanoparticles Ag@Cit NPs were synthesized by a simple plasma-assisted reduction method. Homogenous colloidal Ag@Cit NPs solutions were produced by treating a AgNO3-trisodium citrate-deionized water with an atmospheric-pressure argon plasma jet. The plasma-synthesized Ag@Cit NPs exhibited quasi-spherical shape with an average particle diameter of about 5.9−7.5 nm, and their absorption spectra showed surface plasmon resonance peaks at approximately 406 nm. The amount of Ag@Cit NPs increased… Show more
“…The frequency, electrical energy and power of the plasma were 85 kHz, 0.18 J/s and 1.8 W, respectively. The plasma generated energy, and dissipated power were calculated using the following equations 39 , 40 : Figure 1 Illustration depicting the configuration of a soft jet plasma ( A ), current–voltage characterization of the soft jet plasma ( B ), electrical properties of the soft plasma jet ( C ), optical emission spectra of the soft plasma jet ( D ). …”
Section: Resultsmentioning
confidence: 99%
“…The NO X spectrum was examined within the wavelength range of 200–280 nm, revealing the presence of OH radicals emitting at 309 nm. The emission attributed to the nitrogen second positive (N 2 SPS) was observed in the 311–380 nm region 40 . Furthermore, within the range of 390–410 nm, the First Negative System (FNS) of nitrogen (N 2 ) emission was observed.…”
The aim of this study was to evaluate the antimicrobial efficacy of an air gas soft jet CAP for its potential use in removing oral biofilms, given that plasma-based technologies have emerged as promising methods in periodontology. Two types of biofilms were developed, one by Streptococcus mutans UA 159 bacterial strain and the other by a complex mixture of saliva microorganisms isolated from a patient with periodontitis. This latter biofilm was characterized via Next Generation Sequencing to determine the main bacterial phyla. The CAP source was applied at a distance of 6 mm for different time points. A statistically significant reduction of both CFU count and XTT was already detected after 60 s of CAP treatment. CLSM analysis supported CAP effectiveness in killing the microorganisms inside the biofilm and in reducing the thickness of the biofilm matrix. Cytotoxicity tests demonstrated the possible use of CAP without important side effects towards human gingival fibroblasts cell line. The current study showed that CAP treatment was able to significantly reduce preformed biofilms developed by both S. mutans and microorganisms isolated by a saliva sample. Further studies should be conducted on biofilms developed by additional saliva donors to support the potential of this innovative strategy to counteract oral pathogens responsible for periodontal diseases.
“…The frequency, electrical energy and power of the plasma were 85 kHz, 0.18 J/s and 1.8 W, respectively. The plasma generated energy, and dissipated power were calculated using the following equations 39 , 40 : Figure 1 Illustration depicting the configuration of a soft jet plasma ( A ), current–voltage characterization of the soft jet plasma ( B ), electrical properties of the soft plasma jet ( C ), optical emission spectra of the soft plasma jet ( D ). …”
Section: Resultsmentioning
confidence: 99%
“…The NO X spectrum was examined within the wavelength range of 200–280 nm, revealing the presence of OH radicals emitting at 309 nm. The emission attributed to the nitrogen second positive (N 2 SPS) was observed in the 311–380 nm region 40 . Furthermore, within the range of 390–410 nm, the First Negative System (FNS) of nitrogen (N 2 ) emission was observed.…”
The aim of this study was to evaluate the antimicrobial efficacy of an air gas soft jet CAP for its potential use in removing oral biofilms, given that plasma-based technologies have emerged as promising methods in periodontology. Two types of biofilms were developed, one by Streptococcus mutans UA 159 bacterial strain and the other by a complex mixture of saliva microorganisms isolated from a patient with periodontitis. This latter biofilm was characterized via Next Generation Sequencing to determine the main bacterial phyla. The CAP source was applied at a distance of 6 mm for different time points. A statistically significant reduction of both CFU count and XTT was already detected after 60 s of CAP treatment. CLSM analysis supported CAP effectiveness in killing the microorganisms inside the biofilm and in reducing the thickness of the biofilm matrix. Cytotoxicity tests demonstrated the possible use of CAP without important side effects towards human gingival fibroblasts cell line. The current study showed that CAP treatment was able to significantly reduce preformed biofilms developed by both S. mutans and microorganisms isolated by a saliva sample. Further studies should be conducted on biofilms developed by additional saliva donors to support the potential of this innovative strategy to counteract oral pathogens responsible for periodontal diseases.
Objective: Cold atmospheric plasma (CAP) is a novel therapeutic approach for cancer treatment. It can be used to treat liquids - plasma-activated media (PAM) - which are then transferred to the target as an exogenous source of reactive oxygen and nitrogen species (RONS). The present study aimed at chemically characterizing different PAM and assessing their in vitro selectivity against head and neck cancer cell lines (HNC).
Materials and methods: PAM were obtained by exposing 2 and 5 mL of medium to CAP for 5, 10 and 20 minutes at a 6 mm working distance. Anions kinetics was evaluated by ion chromatography. In addition, inhibition of cell proliferation by MTS assay, apoptosis occurrence and cell cycle modifications by flow cytometry were assessed on primary human gingival fibroblasts (hGF) and the HNC cell lines HSC2, HSC4 and A253.
Results: All the 2 mL conditions showed a significant reduction in cell proliferation whereas for the 5 mL the effect was milder, but the time-dependence was more evident. In addition, hGF were unaffected by the 5 mL PAM, indicating a selectivity for cancer cells.
Conclusions: The media chemical composition modified by CAP exposure influenced cell proliferation by modulating cell cycle and inducing apoptosis in cancer cells, without affecting normal cells.
Clinical Relevance: The present investigation represents a starting point to favour the clinical translation of CAP as a precision medicine tool by proposing an innovative method, namely ion chromatography, to standardize the quantification of plasma-derived RONS and proving its selectivity in inactivating tumor cells over non-malignant cells. These strategies could be applied to identify the optimal parameter configuration to achieve the desired treatment/therapeutic outcome and to aid the definition of clinical protocols.
“…Through computational studies, we reveal that glycerol can undergo photodissociation of the O−H bonds for incident photon energies of >5 eV, forming various radicals, e.g., hydrogen radicals (H•, with a standard redox potential of −2.3 V), that then exhibit the ability to reduce silver ions (Ag + + H• → Ag 0 + H + ). 28,29 In this study, to differentiate among different plasma species such as electrons, ions, metastables, and UV photons, optical filters were introduced between the plasma and the droplet of the Ag/glycerol electrolyte solution, as depicted in panels a and b of Figure 1. The relevant experimental setup is described in section S1 of the Supporting Information.…”
mentioning
confidence: 99%
“…We find that photons with energies as low as 5 eV deliver an important contribution to NP production, resulting from the fragmentation of glycerol upon UV irradiation composed of these comparatively low-energy photons. Through computational studies, we reveal that glycerol can undergo photodissociation of the O–H bonds for incident photon energies of >5 eV, forming various radicals, e.g., hydrogen radicals (H•, with a standard redox potential of −2.3 V), that then exhibit the ability to reduce silver ions (Ag + + H• → Ag 0 + H + ). , …”
Low-temperature
plasmas in and in contact with liquids have emerged
as a catalyst-free approach for the selective, electrode-free, and
green synthesis of novel materials. For the synthesis of nanomaterials,
short-lived solvated electrons have been proposed to be the critical
reducing species, while the role of ultraviolet (UV) photons from
plasma is less explored. Here, we demonstrate that UV radiation contributes
∼70% of the integral plasma effect in synthesizing silver (Ag)
nanoparticles within a glycerol solution. We suggest that the UV radiation
causes C–H bond cleavage of the glycerol molecules, with an
experimentally and theoretically determined threshold photon energy
of only 5 eV. The photon-induced dissociation leads to the formation
of glycerol fragmentation radicals, causing the reduction of Ag+ ions to Ag neutrals, enabling nanoparticle formation in the
liquid phase.
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