The Potential of Silver Nanoparticles for Antiviral and Antibacterial Applications: A Mechanism of Action

Designing potent plasmonic Ag/TiO2 nanohetero-phase junction for visible light driven photo-catalysis and anti-bacterial effect

In this study, we have reported the impact of well-grown Ag nanoparticles on TiO2 nanofiber mat, focusing the efficiency in anti-bacterial properties with ROS generation. Herein, the nanoheterostructure sample was achieved using electrospinning technique, followed by a solvothermal approach. The core focus was based on the effect of growth of Ag nanoparticles by varying the solvothermal time as well as the molar weight of Ag precursor against both the anti-bacterial property with gram-negative (e.g. E. coli) and another gram-positive (e.g. E. faecalis) bacterium. Prior to the detailed anti-bacterial test, the morphological analysis and the heterojunction formation was thoroughly investigated which showed the clear growth of Ag nanoparticles upon altering the experimental parameters via HRTEM analysis. The investigation showed that superior antibacterial activity was exhibited for the higher Ag loaded heterojunction samples whereas there showed no effect in the absence of Ag nanoparticles for TiO2 nanofibers. This is basically due to the presence of higher superoxide radicals in the nanoheterojunction materials, which is proved by a systematic study using the NBT degradation test under dark and visible light environment. Moreover, this phenomenon can be elucidated by the surface plasmon resonance effect in Ag nanoparticles, which when illuminated under visible light generates electrons and is transferred to the conduction band of TiO2. This transfer promotes the generation of reactive oxygen species (ROS), resulting in the exceptional antibacterial properties observed in AgT-10 ˃ AgT-5 ˃ AgT-2.5 ˃ TiO2NF.

A promising agent against wild-type and antibiotic-resistant bacteria using biogenic silver nanoparticles from Marphysa moribidii extract

The antibiotic resistance (AR) crisis has intensified and overshadowed efforts to develop new antibiotics and treatments. Biogenic silver nanoparticles (AgNPs) synthesised using Marphysa moribidii extract offer a promising solution because of their broad-spectrum antibacterial activity and ease of synthesis. However, concerns regarding the physicochemical properties of AgNPs may vary, and the optimal dosage for bacterial inhibition must be determined. This study addresses these gaps by evaluating the physicochemical properties, antibacterial efficacy, and mechanisms of action of biogenic AgNPs against selected bacteria, including wild-type strains (Escherichia coli and Staphylococcus aureus) and antibiotic-resistant strains (ESBL-E. coli and MRSA). Silver nitrate reduction by bioactive compounds in polychaete extract, such as amino acids and fatty acids, resulted in the formation of stable spherical AgNPs. These nanoparticles exhibited surface plasmon resonance peak at 397 nm and zeta potential of -36.48 mV. The AgNPs effectively inhibited the growth of both wild-type and antibiotic-resistant bacteria at concentrations ranging from 0.05-0.40 μg/mL and 0.10-0.40 μg/mL, respectively. Bactericidal effects were observed against wild-type bacteria and bacteriostatic effects against antibiotic-resistant bacteria. Electron microscopies revealed membrane damage in wild-type and AR bacteria, whereas leakage assays confirmed increased membrane permeability. Furthermore, reactive oxygen species detection assay demonstrated that AgNPs induced oxidative stress, suggesting a multifaceted mechanism of action. These findings highlight the potential of M. moribidii-derived AgNPs as effective broad-spectrum antibacterial agents, particularly against AR bacteria, and pave the way for the development of standardised biogenic AgNPs synthesis methods for future applications.

Encapsulation of Ferula-derived bioactive compounds in nanoparticles: A promising therapeutic route for cancers and infectious diseases

The biomedical sector is constantly searching for new drugs that efficiently improve human health and well-being with minimum side effects. Bio-inspired nanomedicine has emerged as a feasible alternative to chemotherapeutic agents for diagnosis and therapy due to its safety, biocompatibility, affordability, and sustainability. Among biological sources available for green nanomedicine are plants offering the avoidance of the labor-intensive and time-consuming processes of cultivation and maintenance compared to microorganisms. With a long history of treating over a hundred health-related issues, Ferula-derived metabolites have received special consideration for combining with nanoparticles (NPs) since they have been reported to enhance the therapeutic efficiency of NPs, enable targeted drug delivery, and ensure controlled release, which make them elusive candidates for green nanotechnology. This review aimed to provide comprehensive information about the inhibitory effects of NPs carrying Ferula-originated bioactive compounds on several cancers and pathogenic bacteria. Plus, it explores the potential of these NPs in addressing different viral diseases, such as HIV, SARS-CoV2, and hepatitis. The anticancer, antibacterial, and antiviral mechanisms of action are also briefed. The valuable insights provided by this article may result in the development of designer Ferula-based NPs that satisfy the growing needs of the pharmaceutical industry for innovative and effective medications.

From adhesion to biofilms formation and resilience: Exploring the impact of silver nanoparticles-based biomaterials on Pseudomonas aeruginosa

Colonization of medical devices by microorganisms, often progressing to the formation of resilient biofilms, presents a common clinical issue. To address this challenge, there is growing interest in developing novel biomaterials with antimicrobial/antibiofilm properties as a promising preventive measure. This study explores nanocomposite biomaterials based on silver nanoparticles (AgNPs) deposited on thin silica (SiO2) layers for their potential effect on the adhesion, detachment, viability and biofilm formation of the opportunistic Pseudomonas aeruginosa. The AgNPs-based biointerface effect on biofilm development is investigated on the PAO1-Tn7-gfp strain by combining experiments under static and dynamic conditions. For the latter, a shear-stress flow chamber is used to mimic conditions encountered around certain medical devices. The findings reveal a rapid bactericidal effect of the AgNPs, noticeable within 30 min of exposure. Moreover, a delay in surface colonization is observed with a thin and unstructured biofilm, even after 72h of dynamic culture. A considerable fragility and sensitivity to hydrodynamic stresses is noticed for this loosely attached bacterial monolayer when compared with the thick and resilient biofilm formed on SiO2 surface. This study underlines the potential of AgNPs-based biomaterials in the conception of novel antimicrobial/antibiofilm surfaces with controlled release of the biocidal agent.

Silver Nanoparticles Derived from Probiotic Lactobacillus casei-a Novel Approach for Combating Bacterial Infections and Cancer

In the face of rising antibiotic resistance and the need for novel therapeutic approaches against cancer, the present study delves into the various facets of biosynthesized silver nanoparticles (AgNPs) derived from the probiotic strain Lactobacillus casei (AgNPs-LC), assessing their efficacy in combating bacterial infections, disrupting biofilm formation, interfering with quorum sensing mechanisms, and exhibiting anti-cancer properties. The results showed that the AgNPs-LC had a spherical shape with an average size of 15 nm. The biosynthesized AgNPs-LC showed a symmetrical absorption spectrum with a peak at 458 nm with a diameter of 5-20 nm. AgNPs-LC exhibited significant antibacterial activity against Gram-positive and Gram-negative bacteria and inhibited the biofilm formation (> 50% at sub-MIC) and quorum sensing-mediated virulence factors, such as the production of violacein in C. violaceum (> 80% at sub-MIC), pyocyanin in P. aeruginosa (> 70% at sub-MIC), and prodigiosin in S. marcescens (> 80% at sub-MIC). The exopolysaccharides (EPS) were also found to reduce in the presence of AgNPs-LC. Furthermore, the AgNPs-LC showed anti-cancer and anti-metastasis activity via inhibiting cell migration and invasion of human lung cancer (A-549) cells. Overall, the present study brings out the multifaceted therapeutic capabilities of AgNPs-LC which offer exciting prospects for the development of innovative biomedical and pharmaceutical interventions, making AgNPs-LC a versatile and promising candidate for a wide range of applications in healthcare and medicine. However, further research is essential to fully harness their therapeutic potential.

Advancements in silver-based nanocatalysts for organic transformations and other applications: a comprehensive review (2019-2024)

Over time, nanocomposites have revolutionized materials science, offering numerous applications in fields such as catalysis, environmental purification and treatment, biomedicine and various industries. Among these, silver-based nanocomposites are particularly notable for their remarkable stability, reusability, biocompatibility, and multifunctional medicinal properties. Hence, we present a comprehensive summary of recent developments (2019-2024) in silver-based nanomaterials, focusing on their applications across multiple domains, including catalytic organic transformations, biomedical uses, environmental remediation, and industrial sectors such as food packaging, agriculture and textiles. By highlighting recent advancements and emerging trends, we aim to provide a thorough understanding of the role of silver-based nanocomposites in contemporary science and technology, emphasizing their potential to drive innovation across diverse disciplines.

Comparative study on antibacterial activities and removal of iron ions from water using novel modified sand with silver through the hydrothermal technique

The hydrothermal-calcination technique was used to modify raw sand with silver (Ag) at different weight percentages: 2%, 5%, and 10% using silver nitrate. The raw and sand-coated Ag nanoparticle samples were analyzed using various techniques, including scanning electron microscopy (SEM), transmission electron microscopy (TEM), energy-dispersive X-ray spectroscopy (EDS), X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), Fourier transform infrared spectroscopy (FTIR), and Brunauer-Emmett-Teller (BET) analysis. The antibacterial properties of the raw and modified sand samples were evaluated using the zone of inhibition test and the minimum inhibitory concentration (MIC) method. This study aims to determine the efficiency of sand-coated Ag nanoparticles in removing iron ions and bacteria, specifically Escherichia coli (E. coli) and Staphylococcus aureus (S. aureus), compared to raw sand. The results showed that the Ag content in the modified sand increased proportionally with the silver nitrate concentration. The modification of raw sand with 2% Ag nanoparticles resulted in a significant increase in surface area (85.78%), adsorption pore diameter (138%), and micropore volume (65.65%). The sand modified with 2% Ag exhibited a 31.29% higher removal efficiency and 14.6 mg/g greater adsorption capacity for iron ions than raw sand. A feed pH level between 4 and 10 was found to be optimal for iron removal efficiency (99.95%) using a 1.5 g/L sand-coated with 2% Ag. The maximum adsorption capacity of iron ions obtained in this study was 64 mg/g using sand-coated 2%Ag (dose = 0.2 g/L) at 24 °C in 4 h. Studies utilizing zone of inhibition and MIC methods revealed that the modified sand exhibits strong antibacterial properties against both Gram-positive and Gram-negative strains. In contrast, the raw sand shows no antibacterial activity. All sand-coated Ag nanoparticle samples achieved 100% growth inhibition at 72 µg/mL.

Silver Nanoparticle-Mediated Antiviral Efficacy against Enveloped Viruses: A Comprehensive Review

Viral infections continue to pose a significant challenge to global health, with increasing resistance to conventional antiviral therapies highlighting the urgent need for alternative treatment strategies. Silver nanoparticles (AgNPs) have attracted attention as broad-spectrum antiviral agents due to their unique physicochemical properties and ability to target multiple stages of viral infection. This review provides a comprehensive analysis of the antiviral mechanisms of AgNPs, highlighting their efficacy against clinically relevant enveloped viruses such as influenza, herpes simplex, hepatitis B, and coronaviruses. How key nanoparticle characteristics, including size, shape, surface functionalization, and synthesis methods, influence their antiviral performance is examined. Studies indicate that AgNPs exert their effects through direct interactions with viral particles, inhibition of viral adhesion, and entry into host cells with disruption of viral replication. Furthermore, their potential applications in therapeutic formulations, antiviral coatings, and nanomedicine-based strategies are explored. Despite their promise, challenges regarding cytotoxicity, stability, and large-scale production must be addressed to ensure their safe and effective clinical use. This review highlights the transformative potential of AgNPs in antiviral therapy and highlights the need for further investigation to facilitate their clinical translation in the fight against emerging and drug-resistant viral infections.

Green synthesis of a lactoferrin-infused silver nanoparticle gel for enhanced wound healing

The study analyzed the benefits of nano-silver (AgNPs) in reducing side effects and enhancing efficacy, highlighting the advantages compared to silver ions. The study examined the production of AgNPs-lactoferrin complexes (AgNPs-LTF) using bovine lactoferrin (LTF) at 1, 2, and 4 mM concentrations. The objective was to create an AgNPs-LTF gel with Carbopol as the base and assess its effectiveness in enhancing wound healing in rats. UV-Vis, PL, FTIR, and XRD analyses confirmed the synthesis of AgNPs. Microscopic examinations (TEM and SEM) showed mainly spherical AgNPs in the AgNPs-LTF samples, with diameters between 11 and 27 nm. The AgNPs-LTF gel with biologically processed AgNPs demonstrated effective infection control and enhanced wound healing outcomes. In Sprague-Dawley rats, the 4 mM AgNPs-LTF gel demonstrated significant wound closure, achieving complete closure by day 10, exceeding the healing rates of both the LTF and control groups. The AgNPs-LTF complex demonstrated high robustness and exceeded the performance of native LTF, exhibiting similar toxicity levels to AgNPs. The study shows the effectiveness of AgNPs-LTF gel in wound treatment, indicating its potential as a viable treatment option.

A review on plant-mediated synthesis of AgNPs and their formulations for wound healing application

Wound healing is a sophisticated and dynamic process carried out by a myriad of cellular activities that work together in a coordinated manner to effectively repair damaged tissue. It involves a cascade process involving hemostasis, inflammation, granulation, maturation, and remodeling. However, in the case of chronic wounds, owing to the delayed wound healing process, various microbes invade the wound area and produce biofilms that hinder the healing process. Owing to rapid advancements in nanotechnology, several nanomaterials with diverse formulations have been investigated for wound healing. Among them, silver nanoparticles (AgNPs) have shown excellent properties, as they have unique physiochemical properties that address the problems associated with wound healing. The antibacterial and antioxidant properties of silver greatly enhance wound-care diagnostics. The use of medicinal plants for green synthesis of AgNPs has been widely researched, with these plants serving as both reducing and stabilizing agents in the nanoparticle formation process. This review focuses on different wound types, problems related to wounds, green-synthesized AgNPs using medicinal plants, and their limitations and advantages in wound dressing formulations. This study aims to provide the scientific community with a directional view in analyzing the role and importance of green-synthesized AgNPs in wound care.

Antibacterial properties of silver and gold nanoparticles synthesized using Cannabis sativa waste extract against Pseudomonas aeruginosa

AIMS

The study aimed to explore the sustainable synthesis of metal nanoparticles using a green and eco-friendly resource. Specifically, it investigated the utilization of Cannabis sativa waste extract for the production of gold and silver nanoparticles, focusing on their antimicrobial activity against gram-negative bacteria, particularly Pseudomonas aeruginosa strains, which are significant in nosocomial infections.

METHODS

Cannabis sativa waste extract was employed to synthesize gold and silver nanoparticles through a green synthesis approach. The produced nanoparticles were characterized using transmission electron microscopy (TEM), atomic absorption spectrometry (AAS), X-ray diffraction (XRD), and Fourier transform infrared spectroscopy (FTIR). The antimicrobial efficacy of the synthesized nanoparticles was assessed through their minimum inhibitory concentration (MIC), minimum bactericidal concentration (MBC), and minimal biofilm inhibitory concentration (MBIC) against Pseudomonas aeruginosa, utilizing a microcultivation device, solid medium cultivation, and a metabolic activity assay in a polystyrene microtiter plate, respectively.

RESULTS

The TEM analysis revealed the size and morphology of the nanoparticles, while AAS confirmed their concentration. XRD provided insights into the crystalline structure, and FTIR analysis identified the molecular structure of the nanoparticle's stabilizing layer. The synthesized nanoparticles showed significant antimicrobial activity against Pseudomonas aeruginosa, with determined MIC, MBC, and MBIC values of produced silver nanoparticles, showcasing their potential as effective antimicrobial agents.

CONCLUSIONS

This study successfully demonstrated the synthesis of silver and gold nanoparticles using Cannabis sativa waste extract and highlighted their potent antimicrobial properties. It underscores the potential of utilizing plant waste extracts in sustainable nanomaterial synthesis and contributes to the fields of green nanotechnology and waste valorization within the circular economy. The findings also offer valuable insights into developing natural waste source-based antimicrobial agents.

Silver and Zinc Oxide Nanoparticles for Effective Aquaculture Wastewater Treatment

This study explores the use of silver nanoparticles (Ag NPs) and zinc oxide nanoparticles (ZnO NPs), either singly or in combination, for the nanoremediation of aquaculture wastewater. Aquaculture wastewater was treated with varying doses of Ag NPs and ZnO NPs across the following six groups: Group 1 (0.05 mg Ag NPs/L), Group 2 (1 mg ZnO NPs/L), Group 3 (0.05 mg Ag NPs/L + 1 mg ZnO NPs/L), Group 4 (0.025 Ag NPs/L + 0.5 mg ZnO NPs/L), Group 5 (0.1 mg Ag NPs/L + 2 mg ZnO NPs/L), and a control group. Water quality, microbial loads and nanomaterial concentrations were assessed over ten days. Transmission electron microscopy (TEM) showed average particle sizes of 102.5 nm for Ag NPs and 110.27 nm for ZnO NPs. The removal efficiencies of NH4-N were over 98% across treatment groups. In addition, COD removal efficiencies were 33.33%, 68.82%, 49.59%, 61.49%, and 37.65%. The log-reductions in aerobic plate counts for the nanoparticle-treated wastewater were 1.191, 1.947, 1.133, 1.071, and 0.087, compared to a reduction of 0.911 in untreated wastewater. Silver concentrations ranged from 0.0079 to 0.0192 mg/L, while zinc concentrations ranged from 0.3040 to 0.9740 mg/L, indicating that ZnO-NPs represent a sustainable treatment method for aquaculture wastewater.

Ecotoxicity of fungal-synthesized silver nanoparticles: mechanisms, impacts, and sustainable mitigation strategies

The review investigates the ecotoxicological implications of fungal-synthesized silver nanoparticles (AgNPs), focusing on their behavior, transformations, and impacts across aquatic and terrestrial ecosystems. Advanced techniques, such as Single-Particle ICP-MS and Nanoparticle Tracking Analysis, reveal the persistence and biotransformation of AgNPs, including silver ion (Ag⁺) release and reactive oxygen species (ROS) generation. The review highlights species-specific bio-accumulation pathways in algae, soil microbes, invertebrates, and vertebrates, along with the limited biomagnification potential within trophic levels. Long-term exposure to AgNPs leads to reduced soil fertility, altered microbial communities, and inhibited plant growth, raising significant ecological concerns. Sustainable mitigation strategies, including bioremediation and advanced filtration systems, are proposed to reduce the environmental risks of AgNPs. This comprehensive analysis provides a framework for future ecological studies and regulatory measures, balancing the technological benefits of fungal-synthesized AgNPs with their environmental safety.

Enhancing Polyacrylonitrile Nanofibers Antiviral Activity Using Greenly Synthesized Silver Nanoparticles

Developing efficient antiviral protectives is a new approach against respiratory emerging viruses. This study aims to synthesize silver nanoparticles (Ag NPs) via a green technique using crocin to provide a virucidal effect and to enhance the protection of polyacrylonitrile (PAN) nanofibrous face masks or respirators against viruses. The influence of formulation and process variables on the particle size (PS) of Ag NPs was studied using d-optimal response surface design. The selected NPs were loaded into PAN nanofibers (NFs). MTT colorimetric assay was performed to determine the safety of the prepared NPs and NFs on Vero cells. Further, an immunofluorescent assay was performed to determine the composite's ability to inhibit the ACE2-SARS-CoV-2 spike protein interaction and prevent viral infection. The selected NPs possessed a small PS of 23.21 ± 0.86 nm, a PDI of 0.23 ± 0.019, and a ZP of -21.8 ± 1.82 mV. The optimum NF composite was fabricated with a PAN concentration of 8% w/v loaded with 0.25% w/w Ag NPs, with a feeding rate of 0.7 mL/h and an applied voltage of 23.5 kV. The resultant NFs displayed an acceptable morphology and a mean diameter of 378.88 ± 91.12 nm. In vitro cytotoxicity studies on Vero cells revealed the biocompatibility of crocin and Ag NPs. Moreover, Ag-PAN NFs were proven biologically safe. The immunofluorescent assay showed that Ag-PAN NFs demonstrated the least IC50 value of 10.99 µg/mL, indicating their potent effect on inhibiting SARS-CoV-2 infection. Ag-PAN NFs are a promising safe antiviral composite that has the potential to be used in face masks.

Development and characterization of gelatin microgel-stabilized silver nanoparticles loaded with curcumin: Evaluation of antibacterial, antioxidant, and antiproliferative activities

ObjectiveCurcumin is a polyphenol extracted from the roots of Curcuma longa L. It is a multifunctional biological substance that has notable antioxidant, anti-inflammatory, anti-cancer, and antibacterial properties, as reported in numerous previous papers. However, curcumin has limited bioavailability due to its low water solubility. Furthermore, pH, temperature, and light all have the potential to decrease curcumin's biopharmaceutical activities. Silver nanoparticles have excellent antibacterial characteristics and are used in various applications. The main objective of this work was to synthesize the gelatin microgel-stabilized silver nanoparticles loaded with curcumin (GelCurAg complex) to increase the biopharmaceutical activities of the complex.MethodsNumerous techniques, including UV-vis spectroscopy, FTIR spectroscopy, Zetasizer Nano instruments, TEM images, and XDR patterns, were used for investigating the characterization of the GelCurAg complex. The various methods, such as the DPPH antioxidant assay, cytotoxicity analysis, and the agar-well diffusion method, were used for the analysis of the biopharmaceutical activities of the GelCurAg complex.ResultsWe successfully synthesized and characterized the GelCurAg complex, consisting of gelatin, curcumin, and silver nanoparticle biofilms using polyvinylpyrrolidone. The average nanoparticle size was 50 nm. The GelCurAg complex improved water solubility and dispersion compared with the single curcumin component. The IC50 value for antioxidant activity was 4.87 μg/mL, and for antiproliferation on SK-MEL-28, it was 3.98 µg/mL. GelCurAg solution provided remarkable antibacterial activities against four bacterial strains: Bacillus cereus, Escherichia coli, Pseudomonas aeruginosa, and Staphylococcus aureus. The GelCurAg complex showed better antibacterial activities than the single curcumin component, with the antibacterial inhibition zone in the range of 0.9--1.6 cm.ConclusionsThe GelCurAg complex enhanced the solubility and dispersion of curcumin in water while increasing its antibacterial activity compared to curcumin. The GelCurAg complex has excellent biopharmaceutical properties to suggest its various applications in the future.

Silver Nanoparticles: A Versatile Tool Against Infectious and Non-Infectious Diseases

Silver nanoparticles possess remarkable properties that render them highly beneficial for medical applications in both infectious and non-infectious diseases. Among their most renowned attributes is their antimicrobial activity. They have demonstrated efficacy against a wide range of bacteria, fungi, protozoa, and viruses. Additionally, the antitumor and anti-diabetic properties of silver nanoparticles, along with their ability to promote wound healing and their application as biosensors, underscore their therapeutic potential for various non-infectious conditions. As silver nanoparticles are employed for medical purposes, their potential toxicity must be considered. While silver nanoparticles present a promising alternative in the therapeutic domain, further research is needed to elucidate their precise mechanisms of action, optimize their efficacy, and mitigate any potential health risks associated with their use.

Applications of heavy metal-based nanoparticles in cosmetics: a comprehensive review

The utilisation of heavy metal-based nanoparticles in cosmetic products has been steadily increasing because of their extraordinary physicochemical properties and benefits. In this thorough review, we will delve into the various types of nanoparticles, such as green nanoparticles, metallic nanoparticles, and carbon-based nanoparticles, with a special focus on heavy metal-based nanoparticles. These heavy metal-based nanoparticles exhibit exceptional physical and mechanical properties, making them suitable materials for cosmetic and personal care products. Silver nanoparticles effectively treat acne and have strong antimicrobial properties, while gold nanoparticles have anti-ageing and anti-inflammatory properties. ZnO and TiO2 nanoparticles are commonly used in sunscreens as ultraviolet (UV) filters to protect against ultraviolet-A (UVA) and ultraviolet-B (UVB) radiation. Certain metals like nickel, chromium, and cobalt are major allergens, frequently causing contact dermatitis and allergic reactions in sensitive individuals. Extensive use of materials such as cadmium, lead, mercury, and arsenic (metalloid) in cosmetics poses long-term health risks, including carcinogenicity, neurotoxicity, and organ damage. The utilisation of herbal extracts containing heavy metals in cosmetics further improves the effectiveness of personal care products due to their antioxidant properties. Consumer awareness and regulatory concerns, especially among those with metal allergies, are crucial for understanding the potential risks associated with heavy metal-containing cosmetics. Looking ahead, future research efforts should concentrate on the development of safer, non-toxic, natural nanomaterials and biocompatible alternatives to heavy metal-based nanoparticles.

In vitro study of silver nanoparticles-induced embryotoxicity using a rat whole embryo culture model

Recently, our in vivo experiment showed that silver nanoparticles (AgNPs) did not cause developmental toxicity. However, the putative influences of direct exposure of AgNPs on the embryo-fetuses could not be elucidated because the embryo-fetus was exposed to AgNPs through their dams. In this study, the potential impact of AgNPs on embryonic development during the critical phase of organogenesis was examined utilizing a rat whole embryo culture model. This system could separate the direct effects of AgNPs from those that are maternally mediated. To evaluate the embryotoxic potential of AgNPs, embryos were exposed to 1.67, 5, and 15 μg/mL of AgNPs for 48 h. At the conclusion of the culture period, embryonic growth and development were assessed, and morphological abnormalities were systematically evaluated. Also, apoptosis induced by AgNPs was evaluated by TUNEL and immunohistochemistry for caspase-3. At 15 μg/mL, a retardation in embryonic growth and differentiation, accompanied by a heightened frequency of morphological abnormalities, including abnormal axial rotation, open neural tube, absent optic vesicle, and growth retarded were observed in a dose-dependent manner. At this concentration, caspase-3-positive cells appeared in the treated embryonic tissues compared to controls. At 5 μg/mL, AgNPs also caused a decrease in the embryonic otic system, somite number, and total morphological score. No adverse effects on embryonic growth and development associated with the treatment were observed at 1.67 μg/mL. The findings demonstrated that the direct exposure of AgNPs to rat embryos induces developmental delays and morphological abnormalities, and that AgNPs can induce a direct developmental toxicity and caspase-dependent apoptosis in rat embryos.

Biodegradable antibacterial food packaging based on carboxymethyl cellulose from sugarcane bagasse/cassava starch/chitosan/gingerol extract stabilized silver nanoparticles (Gin-AgNPs) and vanillin as cross-linking agent

The increasing issue of plastic waste necessitates improved solutions, and biodegradable food packaging is a promising alternative to traditional plastic. In this study, we prepared packaging films using cassava starch (CV), chitosan (CT) and carboxymethyl cellulose (CMC), with glycerol as a plasticizer. However, these films require modifications to enhance their mechanical properties. Therefore, we modified the films by adding vanillin as the crosslinking agent and gingerol extract stabilized silver nanoparticles. The films were fabricated using the film-casting method and characterized by FTIR, XRD, SEM, TGA, mechanical property test, biodegradability test, anti-bacterial test and food packaging evaluation test. Among these films, CT/CV/V/CMC/Gin-AgNPs1 exhibited superior mechanical properties and demonstrated excellent anti-bacterial property both for gram-positive (S. aureus) and gram-negative (E. coli) bacteria and biodegradability, losing over 50% of its weight after 21 days of burial in soil and effectively preserved grapes at 4 °C for 21 days.

A mechanistic overview on green assisted formulation of nanocomposites and their multifunctional role in biomedical applications

The importance of nanocomposites constantly attains attention because of their unique properties all across the fields especially in medical perspectives. The study of green-synthesized nanocomposites has grown to be extremely fascinating in the field of research. Nanocomposites are more promising than mono-metallic nanoparticles because they exhibit synergistic effects. This review encapsulates the current development in the formulation of plant-mediated nanocomposites by using several plant species and the impact of secondary metabolites on their biocompatible functioning. Phyto-synthesis produces diverse nanomaterials with biocompatibility, environment-friendliness, and in vivo actions, characterized by varying sizes, shapes, and biochemical nature. This process is advantageous to conventional physical and chemical procedures. New studies have been conducted to determine the biomedical efficacy of nanocomposites against various diseases. Unfortunately, there has been inadequate investigation into green-assisted nanocomposites. Incorporating phytosynthesized nanocomposites in therapeutic interventions not only enhances healing processes but also augments the host's immune defenses against infections. This review highlights the phytosynthesis of nanocomposites and their various biomedical applications, including antibacterial, antidiabetic, antiviral, antioxidant, antifungal, anti-cancer, and other applications, as well as their toxicity. This review also explores the mechanistic action of nanocomposites to achieve their designated tasks. Biogenic nanocomposites for multimodal imaging have the potential to exchange the conventional methods and materials in biomedical research. Well-designed nanocomposites have the potential to be utilized in various biomedical fields as innovative theranostic agents with the subsequent objective of efficiently diagnosing and treating a variety of human disorders.

Advancements in Green Synthesis of Silver-Based Nanoparticles: Antimicrobial and Antifungal Properties in Various Films

Nanotechnology is an evolving field that presents extensive opportunities in antimicrobial and eco-friendly food packaging applications. Silver nanoparticles (AgNPs) are particularly valuable in this context due to their outstanding physicochemical properties and demonstrated biological and antimicrobial efficacy, rendering them highly effective in food packaging applications. Historically, nanoparticle synthesis has largely relied on synthetic chemicals and physical methods; however, growing awareness of their potential toxic impacts on human health and the environment has led researchers to reassess these conventional approaches. In response, green synthesis using plants or their metabolites to produce nanoparticles (NPs) has emerged as a focal point in recent research. This approach provides significant advantages, notably in reducing toxicity associated with traditionally synthesized nanoparticles. Silver, recognized for its non-toxic, safe profile as an inorganic antibacterial and antifungal agent, has been employed for centuries and exhibits remarkable potential in various biological applications in its nanoparticle form. Environmentally friendly synthesis techniques are increasingly prioritized within chemical sciences to reduce the harmful byproducts of reactions. Green synthesis methods also offer economic benefits due to their lower costs and the abundant availability of natural raw materials. In the past five years, concerted efforts have been made to develop new, sustainable, and cost-effective methodologies for nanoparticle synthesis. This review explains the green synthesis of silver nanoparticles from different sources along with their quantification techniques and application in food packaging.

Golden Therapeutic Approach to Combat Viral Diseases Using Gold Nanomaterials

Gold nanoparticles (AuNPs), due to their unique properties and surface modification abilities, have become a promising carrier for a range of biomedical applications. AuNPs have intrinsic antiviral characteristics because of their capacity to enhance drug distribution by making antiviral medications more stable and soluble, which assures that higher quantities reach the intended site. Through surface changes, AuNPs can bind directly to viral particles or infected cells, increasing therapeutic efficiency and reducing side effects. AuNPs efficiently damage cell membranes and hinder viral reproduction within a host cell. Furthermore, because of their large surface area-to-volume ratio, which enables many functional groups to connect, improving interaction with virus particles and ceasing their multiplication. By altering dimensions and morphology or conjugating it with additional antiviral drugs, AuNPs can array their synergistic antiviral activity. Thus, the development of AuNP conjugated therapy presents a promising avenue to address the demand for novel anti-viral therapeutics against infections resistant to several drugs.

A review on green synthesis of silver nanoparticles (SNPs) using plant extracts: a multifaceted approach in photocatalysis, environmental remediation, and biomedicine

A sustainable and viable alternative for conventional chemical and physical approaches is the green production of silver nanoparticles (SNPs) using plant extracts. This review centers on the diverse applications of plant-mediated SNPs in biomedicine, environmental remediation, and photocatalysis. Ocimum sanctum (tulsi), Curcuma longa (turmeric), and Azadirachta indica (neem) and many others are plant extracts that have been used as stabilizing and reducing agents because of their extensive phytochemical profiles. The resulting SNPs have outstanding qualities, such as better photocatalytic degradation of organic dyes like methylene blue, antibacterial efficacy towards multidrug-resistant pathogens, biocompatibility for possible therapeutic applications, and regulated magnitude (10-50 nm), enhanced rigidity, and tunable surface plasmon resonance. Significant effects of plant extract type, amount, and synthesis parameters on the physical and functional characteristics of SNPs are revealed by key findings. Along with highlighting important issues and potential paths forward, this review also underlines the necessity of scalable production, thorough toxicity evaluations, and investigating the incorporation of SNPs into commercial applications. This work highlights how plant-based SNPs can be used to address global environmental and biological concerns by straddling the division between sustainable chemistry and nanotechnology.

Antibacterial Efficacy Comparison of Electrolytic and Reductive Silver Nanoparticles Against Propionibacterium acnes

Background: The aim of this study was to develop an electrolysis system to produce silver nanoparticles free from toxic gases, as the most common reduction and electrolysis techniques produce nitrogen dioxide (NO2) as a byproduct, which is harmful to human health. The new electrolysis system used two identical silver plate electrodes, replacing silver and carbon rods, and used water as the electrolyte instead of silver nitrate (AgNO3) solution since AgNO3 is the source of NO2. Methods: The electrolytic silver nanoparticles (ESNs) produced by the new system were characterized and compared with reductive silver nanoparticles (RSNs). Using UV-Visible spectrophotometry, absorption peaks were found at 425 nm (ESN) and 437 nm (RSN). Using dynamic light scattering, the particle diameters were measured at 40.3 nm and 39.9 nm for ESNs at concentrations of 10 ppm and 30 ppm, respectively, and 74.0 nm and 74.6 nm for RSNs at concentrations of 10 ppm and 30 ppm, respectively. Antibacterial activity against Propionibacterium acnes (P. acnes) was assessed using the Kirby-Bauer method. Results: It was found that the efficacy of ESNs and RSNs was relatively lower than that of 5% chloramphenicol because it was measured in different concentration units (ESNs and RSNs in ppm and chloramphenicol in %). Using the calibration curve, the efficacy of 5% chloramphenicol was comparable to that of 0.005% ESN. It was also found that P. acnes developed a strong resistance to chloramphenicol and showed no resistance to ESNs. Conclusions: This finding underlines the tremendous potential of ESNs as a future antibiotic raw material.

In-Situ and Green Synthesis of Silk Fibroin-Silver Nanoparticles Composite Microfibers for Enhanced Antibacterial Applications

The antibacterial properties of modified silk fibroin microfibers (SF MFs) have been widely studied. Among various modifications, integration of silver nanoparticles (Ag NPs) and SF MFs has garnered significant attention due to the broad-spectrum antibacterial activities and long-term antibacterial effect of Ag nanomaterials. However, the traditional introduction of reducing agents or other additives during the synthesis of Ag-SF composite MFs potentially affects their structure and antibacterial properties. Facile, green and effective methods for the preparation of Ag-SF MFs with enhanced antibacterial properties are therefore highly desired. In this study, Ag NPs were uniformly in-situ deposited onto the optimized SF MFs by adjusting the pH and duration conditions under the guidance of green chemistry. The loaded Ag NPs have a good dispersibility and an average size of ~10 nm. The stability of SF MFs after the deposition of Ag NPs and the crystalline features of the loaded Ag NPs have been carefully investigated. Moreover, antibacterial experiments confirmed that Ag-SF MFs exhibited superior antibacterial activities. After co-incubating Ag-SF MFs with L929 cells, the cell viability reached 90 %, demonstrating the great biocompatibility of the modified fibers. This green in-situ synthetic method will promote the further medical use of Ag-SF MFs in antibacterial fields.

Synergistic antiviral potential of N-(2-hydroxy)propyl-3-trimethylammoniumchitosan-functionalized silver nanoparticles with oseltamivir against influenza A viruses

This study introduced a novel antiviral approach by combining three substances with different antiviral mechanisms: N-(2-hydroxy)propyl-3-trimethylammoniumchitosan (HTC), silver nanoparticles (AgNPs), and oseltamivir. First, positively surface-charged AgNPs were prepared using an environmentally friendly method. The surfaces of these AgNPs were capped with cationic quaternary chitosan HTC. It exhibits a positive zeta potential with extraordinary stability in aqueous solutions and facilitates substantial and rapid cellular uptake including entry into the cell nucleus. HTC-AgNPs display broad-spectrum antiviral activity against three influenza A viruses (H5N1, H3N2, and H1N1) at biocompatible concentrations. When blended with oseltamivir, HTC-AgNPs enhances the antiviral activity from that of oseltamivir alone by at least 20 times. After 24 h of combined treatment, the inhibition efficiency against influenza A virus can attain up to 99.9 %. We anticipate that this combination could reduce the effective dose of Tamiflu by 10-fold when used in clinic, thus shortening recovery period and lowering the medication costs. Moreover, the synergistic effects of the three active substances would reduce the likelihood of the emergence of drug-resistant viral strains. This would, in turn, enhance the effectiveness and safety of this medication.

Harnessing Nanoparticles to Overcome Antimicrobial Resistance: Promises and Challenges

The rise of antimicrobial resistance (AMR) has become a serious global health issue that kills millions of people each year globally. AMR developed in bacteria is difficult to treat and poses a challenge to clinicians. Bacteria develop resistance through a variety of processes, including biofilm growth, targeted area alterations, and therapeutic drug alteration, prolonging the period they remain within cells, where antibiotics are useless at therapeutic levels. This rise in resistance is linked to increased illness and death, highlighting the urgent need for effective solutions to combat this growing challenge. Nanoparticles (NPs) offer unique solutions for fighting AMR bacteria. Being smaller in size with a high surface area, enhancing interaction with bacteria makes the NPs strong antibacterial agents against various infections. In this review, we have discussed the epidemiology and mechanism of AMR development. Furthermore, the role of nanoparticles as antibacterial agents, and their role in drug delivery has been addressed. Additionally, the potential, challenges, toxicity, and future prospects of nanoparticles as antibacterial agents against AMR pathogens have been discussed. The research work discussed in this review links with Sustainable Development Goal 3 (SDG-3), which aims to ensure disease-free lives and promote well-being for all ages.

Green synthesis of silver nanoparticles from supercritical CO2 mediated Lagerstroemia speciosa extract: Characterization, antimicrobial and antibiofilm activity

In the current study, optimal supercritical fluid extract (SFE) of Lagerstroemia speciosa (LS) leaves at pressure 29.59 MPa (MPa), temperature 89.50 °C and extraction time 53.85 min was used to extract phenolic compounds for the synthesis of silver nanoparticles (AgNPs). The synthesis was studied for 0-20 h. Initially the synthesis of nanoparticles (SFELS-AgNPs) was confirmed using UV -spectroscopy. It demonstrated a maximum surface plasmon resonance at 430 nm. The crystallite dimension of nanoparticles was determined using X-ray diffraction (XRD) (13.47 nm), Transmission electron microscopy (TEM), zeta potential analysis and energy-dispersive X-ray analysis (EDAX) were used to analyze the morphology, surface charge and presence of differential elements in SFELS-AgNPs respectively. Developed nanoparticles revealed antimicrobial activity against 2 g-positive viz. Staphylococcus aureus and Bacillus cereus, and 3 g-negative bacteria viz. Klebsiella pneumonia, Pseudomonas aeruginosa and Escherichia coli. The nanoparticle showed a minimum inhibitory concentration (MIC) of 64 μg/ml whereas the minimum bactericidal concentration (MBC) 128 μg/ml against K. pneumonia. They significantly inhibited K. pneumonia biofilm formation which was confirmed using scanning electron microscopy (SEM). The results were encouraging compared to the standards drug Chloramphenicol and other controls. The generated nanoparticles have highly effective antimicrobial properties against pathogenic bacteria.

Nanotechnology: An avenue for combating fish parasites in aquaculture system

The intensification of aquaculture in recent years has led to the rise of infectious fish diseases caused by bacteria, viruses, and parasites. Parasitic diseases, in particular, are widespread and have significant economic impacts globally. Protozoan parasites like Ichthyophthirius multifiliis and Trichodina sp., myxozoans (cnidarians), monogeneans like Dactylogyrus sp. and Gyrodactylus sp., and crustacean parasites like Argulus sp. and Lernaea cyprinacea primarily cause these diseases. Despite advancements and new technologies aimed at understanding and treating these diseases, parasites remain a major health challenge in aquaculture. Traditional antiparasitic agents face limitations, including drug resistance and negative effects on non-target organisms. Recently, nanotechnology has emerged as a novel approach in aquaculture medicine, enabling the development of effective nanoparticles against pathogenic microbes. Silver nanoparticles (AgNPs) are particularly notable for their strong antimicrobial and antiparasitic properties due to their broad mechanisms of action. Although Argulus is a highly destructive crustacean parasite that financially burdens fish farmers, applying nanoparticles to manage this infection in aquaculture is still underexplored. Therefore, this review explores recent efforts to combat parasitic diseases with AgNPs and investigates their potential parasiticidal mechanisms of action, proposing them as a novel tool that could improve the management and control of argulosis diseases. The article underscores the benefits and challenges of this technology, emphasizing its significance in fostering improved health management for sustainable aquaculture.

Green-synthesized silver nanoparticles from Zataria multiflora as a promising strategy to target quorum sensing and biofilms in Pseudomonas aeruginosa

The global challenge to human health is significantly heightened by the resistance of harmful bacteria to antimicrobial treatments. Given the limited advancement in developing new antimicrobial medications, exploring innovative strategies is imperative to tackle the challenge of resistance to multiple drugs. Furthermore, there is a growing emphasis on the environmentally friendly synthesis of nanoparticles with potent medicinal attributes, specifically those targeting virulence, to combat the rise of multidrug resistance. Focusing on the inhibition of virulence factors and biofilms influenced by quorum sensing has become a promising and novel strategy in the development of anti-infective drugs. An aqueous extract of Zataria multiflora leaves was used to create green-synthesized silver nanoparticles, or AgNPs. X-ray diffraction (XRD), transmission electron microscopy (TEM), scanning electron microscopy (SEM), Fourier-transform infrared spectroscopy (FTIR), and UV-visible absorption spectroscopy were used to characterize the AgNPs. The impact of AgNPs on the virulence factors and biofilms of Pseudomonas aeruginosa PAO1, mediated by quorum sensing, was assessed at concentrations below the minimum inhibitory concentration (sub-MIC). Sub-MIC concentrations of Green-synthesized AgNPs inhibited various P. aeruginosa virulence factors, including bacterial motility (89 % inhibition), pyocyanin production (81.48 % inhibition), pyoverdin production (55.80 % inhibition), elastase activity (87.43 % inhibition), exoprotease activity (75.60 % inhibition), and rhamnolipid production (71.28 % inhibition). Additionally, these AgNPs demonstrated 80 % inhibition of P. aeruginosa biofilms. The in vitro efficacy of green-synthesized AgNPs against P. aeruginosa can be utilized for the creation of alternative therapeutic agents for managing bacterial infections, particularly for topical application in cases such as wound infections. Additionally, they can be used for surface coating to inhibit the attachment of bacteria to medical devices.

Enhanced antibacterial efficacy: rapid analysis of silver-decorated azithromycin-infused Soluplus® nanoparticles against E. coli and S. epidermidis biofilms

The escalating threat of antibiotic-resistant bacterial biofilms necessitates innovative antimicrobial strategies. This study introduces silver-decorated azithromycin-infused Soluplus® nanoparticles (Ag-AZI-Sol NPs) synthesized via a controlled emulsion diffusion method to ensure sustained release of antimicrobial silver ions for over six hours-a critical factor for continuous antibacterial efficacy. The efficacy of these nanoparticles was evaluated against biofilms formed by Escherichia coli (E. coli) and Staphylococcus epidermidis (S. epidermidis), pathogens that cause hospital-acquired infections. Concentrations of 5 and 10 μg mL-1 of Ag-AZI-Sol NPs induced significant morphological changes within the biofilms, disrupting the bacterial extracellular matrix as observed using scanning electron microscopy (SEM). This disruption peaked between two and six hours, coinciding with damage to bacterial cells by the silver ions. Antibacterial assay measurements confirmed a significant reduction in the growth rate among the Ag-AZI-Sol NP-treated bacteria compared with controls. Electrochemical analysis using laser-induced graphene (LIG) and chronoamperometry revealed a decline in current, indicating an effective antibacterial effect. This innovative biosensing technique makes use of the high conductivity and surface area of LIG to detect changes in bacterial activity quickly and sensitively. Our findings highlight the potent microbicidal properties of Ag-AZI-Sol NPs and suggest diverse applications from food processing to medical device coatings.

Exposure assessment and risks associated with wearing silver nanoparticle-coated textiles

Background

Silver (Ag) nanoparticles (NPs) are used increasingly in consumer and healthcare fabrics due to their antimicrobial properties. Abrasive leaching experiments have shown that AgNPs can be released during textile wear and cause a dermal exposure. Derived-no-effect-limit value for AgNPs ranges from 0.01 to 0.0375 mg/kg-body-weight, and thus, low exposures levels can cause relevant risk.

Methods

In this study AgNP release from textiles by artificial sweat immersion and mechanical stress was investigated. A mass balance model was used to calculate dermal Ag exposure and potential intake via percutaneous absorption and inadvertent (peri-)oral intake during wear of face mask, suit with a full body exposure and gloves. Mass flow analysis was performed for up to 8-h wear time and by using Ag penetration rate constants reported for fresh-, cryopreserved- and glycerolized skin grafts.

Results

Dermal intake risk characterization ratio (RCR) during 8-h wear time for glycerolized skin was up to 0.02 for face mask and 0.9 for full body wear in a worst-case condition. Wearing gloves for 1-h followed by single unintentional fingertip mouthing (contact area 11.5 cm 2) resulted in an RCR of 0.0002. RCR varied depending on the type of textile-product, exposure wear duration and skin type.

Conclusions

This study provides a comprehensive assessment of AgNPs release from textiles and their potential impact on human dermal exposure and was essential for understanding the safety implications for different exposure scenarios and mitigating potential risks.

Silver nanoparticles exhibit ecotoxicological effects via oxidative stress, inflammation, and reproductive toxicity in Asian clam (Corbicula fluminea)

Silver nanoparticles (AgNPs) are pervasive environmental pollutants capable of inducing toxicological impacts on benthic organisms. In this study, the effects of AgNPs on the antioxidant enzyme activities, tissue damage, inflammatory responses, and reproductive toxicity of Corbicula fluminea were investigated. C. fluminea was exposed to four concentrations of AgNPs (0, 5 mg/L, 10 mg/L, and 125 mg/L) for 48 h. The results showed that the higher concentrations of AgNPs caused severe tissue damage in multiple organs of C. fluminea, induced oxidative stress and an imbalance of the antioxidant enzyme activities (such as SOD, CAT, MDA), and increased the inflammatory immune response involving NFκB, TLR2/4, HSP70/90, IL1β, and TNFα. Notably, further transmission electron microscopy and cytological analyses revealed that AgNPs exposure induced apoptosis in the gonad tissues, resulting in significant loss and damage in the oocytes and spermatids. The present study demonstrates the ecotoxicological impacts of AgNPs on freshwater bivalves, particularly highlighting their reproductive toxicity on germ cells, signifying the potential toxic effects of heavy metal pollution on aquatic ecosystems.

Development of Targeted Drug Delivery System for the Treatment of SARS-CoV-2 Using Aptamer-Conjugated Gold Nanoparticles

Background: The SARS-CoV-2 pandemic has highlighted niclosamide (NIC) as a promising treatment for COVID-19. However, its clinical application is limited due to its poor water solubility, resulting in low bioavailability. Methods: To address this issue, we developed a AuNP-HA-NIC system, which combines gold nanoparticles with hyaluronic acid to enhance drug delivery. Our comprehensive characterization of the system revealed that hyaluronic acid with specific molecular weights, particularly those exposed to electron-beam irradiation between 2 and 20 kGy, produced the most stable nanoparticles for efficient drug loading and delivery. Results: Additionally, the AuNP-HA-NIC system exhibits a significant sensitivity to pH changes, which is a critical feature for targeted drug release. Under acidic conditions mimicking the stomach and small intestine, minimal drug release was observed, indicating the effective prevention of premature drug release in the gastrointestinal tract. Furthermore, the integration of a targeting aptamer established specific binding abilities towards the SARS-CoV-2 spike protein, distinguishing it from other coronaviruses. Conclusions: As research progresses, and with further in vivo testing and optimization, the AuNP-HA-NIC-aptamer system holds great promise as a game-changer in the field of antiviral therapeutics, particularly in the battle against COVID-19.

Effect of hyaluronic acid-stabilized silver nanoparticles on lettuce (Lactuca sativa L.) seed germination

Nanotechnology has brought significant advancements to agriculture through the development of engineered nanomaterials (ENPs). Silver nanoparticles (AgNPs) capped with polysaccharides have been applied in agricultural diagnostics, crop pest management, and seed priming. Hyaluronic acid (HA), a natural polysaccharide with bactericidal properties, has been considered a growth regulator for plant tissues and an inducer of systemic resistance against plant diseases. Additionally, HA has been employed as a stabilizing agent for AgNPs. This study investigated the synthesis and effects of hyaluronic acid-stabilized silver nanoparticles (HA-AgNPs) as a seed priming agent on lettuce (Lactuca sativa L.) seed germination. HA-AgNPs were characterized using several techniques, exhibiting spherical morphology and good colloidal stability. Germination assays conducted with 0.1, 0.04, and 0.02 g/L of HA-AgNPs showed a concentration-dependent reduction in seed germination. Conversely, lower concentrations of HA-AgNPs significantly increased germination rates, survival, tolerance indices, and seed water absorption compared to silver ions (Ag+). SEM/EDS indicated more significant potential for HA-AgNPs internalization compared to Ag+. Therefore, these findings are innovative and open new avenues for understanding the impact of Ag+ and HA-AgNPs on seed germination.

Silver Nanoparticles: Synthesis, Structure, Properties and Applications

Silver nanoparticles (Ag NPs) have accumulated significant interest due to their exceptional physicochemical properties and remarkable applications in biomedicine, electronics, and catalysis sensing. This comprehensive review provides an in-depth study of synthetic approaches such as biological synthesis, chemical synthesis, and physical synthesis with a detailed overview of their sub-methodologies, highlighting advantages and disadvantages. Additionally, structural properties affected by synthesis methods are discussed in detail by examining the dimensions and surface morphology. The review explores the distinctive properties of Ag NPs, including optical, electrical, catalytic, and antimicrobial properties, which render them beneficial for a range of applications. Furthermore, this review describes the diverse applications in several fields, such as medicine, environmental science, electronics, and optoelectronics. However, with numerous applications, several kinds of issues still exist. Future attempts need to address difficulties regarding synthetic techniques, environmental friendliness, and affordability. In order to ensure the secure utilization of Ag NPs, it is necessary to establish sustainability in synthetic techniques and eco-friendly production methods. This review aims to give a comprehensive overview of the synthesis, structural analysis, properties, and multifaceted applications of Ag NPs.

Silibinin-loaded chitosan-capped silver nanoparticles exhibit potent antimicrobial, antibiofilm, and anti-inflammatory activity against drug-resistant nosocomial pathogens

Nanoparticles capped with natural products can be a cost-effective alternative to treat drug-resistant nosocomial infections. Therefore, silibinin-loaded chitosan-capped silver nanoparticles (S-C@AgNPs) were synthesized to evaluate their antimicrobial and anti-inflammatory potential. The S-C@AgNPs plasmon peak was found at 430 nm and had a particle size distribution of about 130 nm with an average hydrodynamic diameter of 101.37 nm. The Scanning Electron Microscopy images showed the presence of sphere-shaped homogeneous nanoparticles. The Fourier Transform Infrared Spectroscopy analysis confirmed the loading of silibinin and chitosan on the AgNPs surface. The minimum inhibitory concentration of the S-C@AgNPs was reported between 3.12 μg/ml to 12.5 μg/ml and a minimum bactericidal concentration between 6.25 μg/ml to 25 μg/ml against drug-resistant nosocomial pathogens. Moreover, concentration-dependent significant inhibition of the biofilm formation was reported against P. aeruginosa (70.21%) and K. pneumoniae (71.02%) at 30 μg/ml, and the highest destruction of preformed biofilm was observed at 100 μg/ml against P. aeruginosa (89.74%) and K. pneumoniae (77.65%) as compared to individual bacterial control. Additionally, the fluorescence live/dead assay for bacterial biofilm confirmed that 100 µg/ml effectively inhibits the biofilm formed by these pathogens. S-C@AgNPs also showed anti-inflammatory activity, which is evident by the significant decrease in the proinflammatory cytokines and chemokines level in THP1 cells treated with LPS. This study concluded that S-C@AgNPs have potent antimicrobial, antibiofilm, and anti-inflammatory properties and could be a potential option for treating drug resistant nosocomial infections.

Advances in silver nanoparticles: a comprehensive review on their potential as antimicrobial agents and their mechanisms of action elucidated by proteomics

Nanoparticles play a crucial role in the field of nanotechnology, offering different properties due to their surface area attributed to their small size. Among them, silver nanoparticles (AgNPs) have attracted significant attention due to their antimicrobial properties, with applications that date back from ancient medicinal practices to contemporary commercial products containing ions or silver nanoparticles. AgNPs possess broad-spectrum biocidal potential against bacteria, fungi, viruses, and Mycobacterium, in addition to exhibiting synergistic effects when combined with certain antibiotics. The mechanisms underlying its antimicrobial action include the generation of oxygen-reactive species, damage to DNA, rupture of bacterial cell membranes and inhibition of protein synthesis. Recent studies have highlighted the effectiveness of AgNPs against various clinically relevant bacterial strains through their potential to combat antibiotic-resistant pathogens. This review investigates the proteomic mechanisms by which AgNPs exert their antimicrobial effects, with a special focus on their activity against planktonic bacteria and in biofilms. Furthermore, it discusses the biomedical applications of AgNPs and their potential non-preparation of antibiotic formulations, also addressing the issue of resistance to antibiotics.

Phytofabrication, characterization of silver nanoparticles using Hippophae rhamnoides berries extract and their biological activities

Introduction

Fabrication of plant-based metal nanoparticles has yielded promising results, establishing this approach as viable, sustainable, and non-toxic in the biomedical sector for targeted drug delivery, diagnostic imaging, biosensing, cancer therapy, and antimicrobial treatments.

Methods

The present work demonstrates the suitability of Hippophae rhamnoides berries for the instant green synthesis of silver nanoparticles to check their antioxidant, lipid peroxidation, and antimicrobial potential. The preliminary characterization of Hippophae rhamnoides-mediated AgNPs was validated by monitoring the color shift in the solution from pale yellow to reddish brown, which was further confirmed by UV-vis spectroscopy and the plasmon peaks were observed at 450 nm. Field Emission Scanning Electron Microscopy (FESEM) and X-ray diffraction (XRD) were used to evaluate the surface topography and structure of AgNPs. Herein, the antioxidant potential of synthesized AgNPs was investigated using DPPH free radical assay and the antimicrobial efficacy of similar was checked against E. coli and S. aureus by following MIC (minimum inhibitory concentration) and MBC (Minimum bactericidal concentration) assay. Along with the inhibitory percentage of lipid peroxidation was analysed by following TBARS (Thiobarbituric acid reactive species) assay.

Results & discussion

The results revealed that the AgNPs were spherical in shape with an average size distribution within the range of 23.5-28 nm and a crystalline structure. Negative zeta potential (-19.7 mV) revealed the physical stability of synthesized AgNPs as the repulsive force to prevent immediate aggregation. The bioactive functional moieties involved in reducing bulk AgNO3 into AgNPs were further validated by FTIR. TBARS was adapted to test lipid peroxidation, and Hippophae rhamnoides-mediated AgNPs showed a 79% inhibition in lipid peroxidation compared to Hippophae rhamnoides berries extract as 65%. Furthermore, the antibacterial tests showed 37 ± 0.01 mm and 35 ± 0.0132 mm, zones of inhibition against E. coli MTCC 1698 and S. aureus MTCC 3160 with MIC and MBC values of 1 mg/mL, respectively.

Disentangling the "tip-effects" enhanced antibacterial mechanism of Ag nanoparticles

Silver nanoparticles (Ag NPs) exhibit strong antibacterial activity and are widely used in industries such as medical, food and cosmetics. In this study, Ag nanospheres and Ag nanotriangles are selected as antibacterial agents to reveal the distinct mechanism of tip effects towards their antibacterial performance. A series of antibacterial experiments were implemented, including in situ monitoring as well as studying and determining the evolution of the inhibition zone, minimum inhibitory concentration (MIC)/minimum bactericidal concentration (MBC) values, growth kinetics, bactericidal curve, bacterial morphologies and intracellular reactive oxygen species (ROS). Ag nanotriangles can eradicate E. coli and S. aureus at extremely low concentrations in comparison to Ag nanospheres, in particular under sunlight irradiation. The destroyed bacterial cell walls were examined by scanning electron microscopy. Through the investigation of ROS production, the generation efficiency of ROS is improved by the merit of sunlight irradiation thanks to the localized surface plasmon resonance (LSPR) properties of Ag NPs. However, a more significant improvement in ROS generation efficiency occurred in the presence of Ag nanotriangles contributed by the pronounced "tip effects". This study sheds light on the structure-performance relationship for the rational design of antibacterial agents.

Biochemical properties of novel Carbon nanodot-stabilized silver nanoparticles enriched calcium hydroxide endodontic sealer

Calcium Hydroxide-based endodontic sealer loaded with antimicrobial agents have been commonly employed in conventional root canal treatment. These sealers are not effective against E. faecalis due to the persistent nature of this bacterium and its ability to evade the antibacterial action of calcium hydroxide. Therefore, endodontic sealer containing Carbon nanodots stabilized silver nanoparticles (CD-AgNPs) was proposed to combat E. faecalis. The therapeutic effect of CD-AgNPs was investigated and a new cytocompatible Calcium Hydroxide-based endodontic sealer enriched with CD-AgNPs was synthesized that exhibited a steady release of Ag+ ions and lower water solubility at 24 hours, and enhanced antibacterial potential against E. faecalis. CD-AgNPs was synthesized and characterized morphologically and compositionally by Scanning Electron Microscopy, Fourier Transform Infrared Spectroscopy (FTIR), and UV-Vis Spectroscopy, followed by optimization via minimum inhibitory concentration (MIC) determination against E. faecalis by broth microdilution technique and Cytotoxicity analysis against NIH3T3 cell lines via Alamar Blue assay. Calcium hydroxide in distilled water was taken as control (C), Calcium hydroxide with to CD-AgNPs (5mg/ml and 10mg/ml) yielded novel endodontic sealers (E1 and E2). Morphological and chemical analysis of the novel sealers were done by SEM and FTIR; followed by in vitro assessment for antibacterial potential against E. faecalis via agar disc diffusion method, release of Ag+ ions for 21 days by Atomic Absorption Spectrophotometry and water solubility by weight change for 21 days. CD-AgNPs were 15-20 nm spherical-shaped particles in uniformly distributed clusters and revealed presence of constituent elements in nano-assembly. FTIR spectra revealed absorption peaks that correspond to various functional groups. UV-Vis absorption spectra showed prominent peaks that correspond to Carbon nanodots and Silver nanoparticles. CD-AgNPs exhibited MIC value of 5mg/ml and cytocompatibility of 84.47% with NIH3T3 cell lines. Novel endodontic sealer cut-discs revealed irregular, hexagonal particles (100-120 nm) with aggregation and rough structure with the presence of constituent elements. FTIR spectra of novel endodontic sealers revealed absorption peaks that correspond to various functional groups. Novel endodontic sealers exhibited enhanced antibacterial potential where E-2 showed greatest inhibition zone against E. faecalis (6.3±2 mm), a steady but highest release of Ag+ ions was exhibited by E-1 (0.043±0.0001 mg/mL) and showed water solubility of <3% at 24 hours where E-2 showed minimal weight loss at all time intervals. Novel endodontic sealers were cytocompatible and showed enhanced antibacterial potential against E. faecalis, however, E2 outperformed in this study in all aspects.

Synthesis of Silver Nanoparticles Using Extracts from Different Parts of the Paullinia cupana Kunth Plant: Characterization and In Vitro Antimicrobial Activity

The green synthesis of silver nanoparticles (AgNPs) can be developed using safe and environmentally friendly routes, can replace potentially toxic chemical methods, and can increase the scale of production. This study aimed to synthesize AgNPs from aqueous extracts of guarana (Paullinia cupana) leaves and flowers, collected in different seasons of the year, as a source of active biomolecules capable of reducing silver ions (Ag+) and promoting the stabilization of colloidal silver (Ag0). The plant aqueous extracts were characterized regarding their metabolic composition by liquid chromatography coupled to high-resolution mass spectrometry (UHPLC-HRMS/MS), phenolic compound content, and antioxidant potential against free radicals. The synthesized AgNPs were characterized by UV/Vis spectrophotometry, dynamic light scattering (DLS), nanoparticle tracking analysis (NTA), transmission electron microscopy (TEM), and scanning electron microscopy coupled to energy-dispersive X-ray spectrometry (EDX). The results demonstrated that the chemical characterization indicated the presence of secondary metabolites of many classes of compounds in the studied aqueous extracts studied, but alkaloids and flavonoids were predominant, which are widely recognized for their antioxidant capabilities. It was possible to notice subtle changes in the properties of the nanostructures depending on parameters such as seasonality and the part of the plant used, with the AgNPs showing surface plasmon resonance bands between 410 and 420 nm using the leaf extract and between 440 and 460 nm when prepared using the flower extract. Overall, the average hydrodynamic diameters of the AgNPs were similar among the samples (61.98 to 101.6 nm). Polydispersity index remained in the range of 0.2 to 0.4, indicating that colloidal stability did not change with storage time. Zeta potential was above -30 mV after one month of analysis, which is adequate for biological applications. TEM images showed AgNPs with diameters between 40.72 to 48.85 nm and particles of different morphologies. EDX indicated silver content by weight between 24.06 and 28.81%. The synthesized AgNPs exhibited antimicrobial efficacy against various pathogenic microorganisms of clinical and environmental interest, with MIC values between 2.12 and 21.25 µg/mL, which is close to those described for MBC values. Therefore, our results revealed the potential use of a native species of plant from Brazilian biodiversity combined with nanotechnology to produce antimicrobial agents.

Compartmentalization into Outer and Inner Shells of Hollow Nanospheres for Antibiosis Based on Chemistry and Physical Damages

There is a substantially ascending demand for nonantibiotic strategies to overcome the resistance of bacterial infections. Here, the discovery of a distinctive antibacterial structure is reported. The novel structure of nanoparticle strategy is proposed for appreciable bacteria killing by the smart design of the delayed addition of crosslinkers into the reaction mixture. [2-(methacryloyloxy)ethyl]trimethylammonium chloride solution (MTCl), a water-soluble ionic liquid (IL), has narrow-size material distribution, good whiteness, and high weather resistance. The quaternary ammonium salt is utilized to efficiently permeate cell membranes through electrostatic interaction, accordingly, boasting a beneficiary of antibacterial properties. More importantly, it allows bacteria to attach the nanomaterials easily, especially the double-shelled nanosphere. In light of the introduction of 9-amino(9-deoxy)ep-quinine (QNNH2) on its inner shell, it blocks the nucleic acid and glucose metabolism in bacteria, which is betterment of the antibacterial activity of double-shelled structure nanoparticle compared to other structure of nanomaterials. This physical/chemical/biological triple antibacterial process eliminates the need for traditional antibiotics, and the fabrication strategies and material properties described here provide insights into the design of antibacterial nanomaterials based on chemical and physical effects.

Light microscopical and parasitological analyses revealed the beneficial effects of silver nanoparticles and various myrrh extracts against Trichinella spiralis infection in mice

Trichinella spiralis infection is a food-borne zoonotic disease caused by nematodes that dwell in the tissues, presenting a significant public health concern. This study aimed to evaluate the effectiveness of different treatments including silver nanoparticles (AgNPs), myrrh biosynthesized AgNPs "AgNPs synthesized using plant-based green technologies", myrrh extract, and myrrh essential oil, as alternative treatments against T. spiralis infection. Parasitological, histopathological, and cytotoxicity assessments were conducted to investigate the effects of various concentrations of these treatments in reducing the populations of adult worms and larvae during both the intestinal and muscular phases of T. spiralis-infected mice. The results showed that the highest antihelminthic efficacy against the intestinal phase of T. spiralis was achieved by myrrh extract (86.66%), followed closely by AgNPs (84.96%) and myrrh AgNPs (82.51%) at higher concentrations (800 mg/kg for myrrh extract, 40 μg/mL for AgNPs, and 40 μg/mL for myrrh AgNPs). While the group treated with myrrh essential oil showed the lowest percentage of adult reduction (78.14%). However, all treatments demonstrated comparable effects in reducing the larvae population in the muscle phase. Histopathological examination of the tissues revealed compelling evidence of the effectiveness of AgNPs, particularly when prepared with myrrh. Additionally, a comprehensive assessment of the cytotoxicity of AgNPs indicated low toxicity levels. This study supports that AgNPs synthesized using plant-based green technologies hold therapeutic potential for the treatment of T. spiralis infection. These findings present a promising avenue for the development of novel antiparasitic drugs that are both effective and safe. RESEARCH HIGHLIGHTS: Myrrh extract has the highest antihelminthic efficacy against the intestinal phase of T. spiralis. Histopathological examination of the tissues revealed compelling evidence of the effectiveness of AgNPs, particularly when prepared with myrrh. During intestinal phase of T. spiralis, varying levels of nanoparticle precipitation were detected in the liver, brain, lung, and intestine. During the muscular phase, the highest amount of AgNPs precipitation was detected in the liver, followed by the brain, and lung.

Bioinspired and Green Synthesis of Silver Nanoparticles for Medical Applications: A Green Perspective

Silver nanoparticles (AgNPs) possess unmatched chemical, biological, and physical properties that make them unique compounds as antimicrobial, antifungal, antiviral, and anticancer agents. With the increasing drug resistance, AgNPs serve as promising entities for targeted drug therapy against several bacterial, fungal, and viral components. In addition, AgNPs also serve as successful anticancer agents against several cancers, including breast, prostate, and lung cancers. Several works in recent years have been done towards the development of AgNPs by using plant extracts like flowers, leaves, bark, root, stem, and whole plant parts. The green method of AgNP synthesis thus has several advantages over chemical and physical methods, especially the low cost of synthesis, no toxic byproducts, eco-friendly production pathways, can be easily regenerated, and the bio-reducing potential of plant derived nanoparticles. Furthermore, AgNPs are biocompatible and do not harm normally functioning human or host cells. This review provides an exhaustive overview and potential of green synthesized AgNPs that can be used as antimicrobial, antifungal, antiviral, and anticancer agents. After a brief introduction, we discussed the recent studies on the development of AgNPs from different plant extracts, including leaf parts, seeds, flowers, stems, bark, root, and whole plants. In the following section, we highlighted the different therapeutic actions of AgNPs against various bacteria, fungi, viruses, and cancers, including breast, prostate, and lung cancers. We then highlighted the general mechanism of action of AgNPs. The advantages of the green synthesis method over chemical and physical methods were then discussed in the article. Finally, we concluded the review by providing future perspectives on this promising field in nanotechnology.

"Therapeutic advancements in nanomedicine: The multifaceted roles of silver nanoparticles"

Nanotechnology has the advantages of enhanced bioactivity, reduced toxicity, target specificity, and sustained release and NPs can penetrate cell membranes. The small size of silver nanoparticles, AgNPs, large surface area, and unique physicochemical properties contribute to cell lysis and increased permeability of cell membranes used in the field of biomedicine. Functional precursors integrate with phytochemicals to create distinctive therapeutic properties and the stability of the nanoparticles can be enhanced by Surface coatings and encapsulation methods, The current study explores the various synthesis methods and characterization techniques of silver nanoparticles (AgNPs) and highlights their intrinsic activity in therapeutic applications, Anti-cancer activity noted at a concentration range of 5-50 μg/ml and angiogenesis is mitigated at a dosage range of 10-50 μg/ml, Diabetes is controlled within the same concentration. Wound healing is improved at concentrations of 10-50 μg/ml and with a typical range of 10-08 μg/ml for bacteria with antimicrobial capabilities. Advancement of silver nanoparticles with a focus on the future use of AgNPs-coated wound dressings and medical devices to decrease the risk of infection. Chemotherapeutic drugs can be administered by AgNPs, which reduces adverse effects and an improvement in treatment outcomes. AgNPs have been found to improve cell proliferation and differentiation, making them beneficial for tissue engineering and regenerative medicine. Our study highlights emerging patterns and developments in the field of medicine, inferring potential future paths.

Evaluating the Effect of pH, Temperature and Concentration on Antioxidant and Antibacterial Potential of Spectroscopically, Spectrophotometrically and Microscopically Characterized Mentha Spicata Capped Silver Nanoparticles

The use of traditional plants has been tremendously increased due to their higher biological impact, minimal side effects, and comparatively low cost. Moreover, the emergence of antibacterial resistance is also shifting the scientific community to reconsider herbal remedies which provide relatively safer, cheap and biologically tolerable solutions. The present research was designed to fabricate the Mentha spicata conjugated silver nanoparticles (Me-AgNPs). Furthermore, the assessment of the bactericidal potential of Me-AgNPs against various bacterial strains was another motive behind this study. Fabricated NPs were characterized with the help of the UV-Visible spectrophotometric analysis, Fourier transform infrared spectroscopy (FTIR) and Scanning electron microscopy (SEM). Me-AgNPs showed a significant zone of inhibition (23 ± 0.2 mm) at 8 mg/mL against Staphylococcus aureus and a 4.0 ± 0.2 mm zone of growth inhibition at 2 mg/mL against Aeromonas veronii. The stability of Me-AgNPs was assessed at various pH (4, 7 and 11) and temperatures (25 °C, 4 °C, 37 °C, 75 °C). The significant zones of inhibition (11.3 ± 0.3 mm, 8.3 ± 0.3mm, 14.3 ± 0.3 mm, and 7.6 ± 0.2 mm) were observed at pH 11 against Escherichia coli, Staphylococcus aureus, Bacillus subtilis, and Klebsiella pneumoniae, respectively. Growth inhibition zones (14.0 ± 0.5 mm and 13.0 ± 0.5 mm) were also determined against B. subtilis and S. aureus at 25 °C. DPPH bioassay was conducted to find the antioxidant properties of Me-AgNPs. The highest (38.66 ± 0.2%) free radical scavenging activity was shown by Me-AgNPs at 4 mg/mL. Present study results concluded that biogenic Me-AgNPs have bactericidal as well as anti-oxidative potential. Moreover, these green synthesized Me-AgNPs could maintain their potency and stability at a wide range of pH and temperature.

Tripeptides Ghk and GhkCu-modified silver nanoparticles for enhanced antibacterial and wound healing activities

Bacterial skin infections represent a major healthcare concern that can delay healing and threaten human health. Silver nanoparticles (AgNPs) have been widely used for antimicrobial purposes; however, their high toxicity limits their applications. Therefore, there is an urgent need to develop simple and efficient therapeutic approaches for treating bacterial infections and promoting wound healing. Here, novel tripeptide (Ghk and GhkCu)-modified AgNPs were developed and subsequently evaluated their antibacterial efficacy against four pathogenic bacterial isolates, cytotoxic properties, and therapeutic effects as a topical treatment for infected wounds. Spherical GhkAgNPs and GhkCuAgNPs with average sizes of 45.92 nm and 56.82 nm exhibited potential antibacterial activity, with a MIC concentration of 8 μg/ml against S. aureus and E. coli. Both AgNPs showed superior bactericidal effects against S. aureus, with complete inhibition after 7 days of treatment. Cytotoxicity assays revealed IC50 (half maximal inhibitory concentrations) values ranging from 6.75 to 6.99 µg/ml in L929 cells. GhkAgNPs displayed accelerated cell migration and facilitated healing up to 92% after 12 h. Furthermore, topical applications of GhkAgNPs and GhkCuAgNPs to S. aureus-infected wounds demonstrated enhanced in vivo wound healing efficacy compared to control groups, as evidenced by increased regenerated epidermal thickness, improved collagen deposition, and downregulation of TNF-α expression. Hence concluded that these novel tripeptides Ghk and GhkCu-modified AgNPs exhibited potent antibacterial effects and significantly promoted wound healing properties.

Green Synthesis of Ganoderma Lucidum-Mediated Silver Nanoparticles and its Microbial Activity against Oral Pathogenic Microbes: An In Vitro Study

Nanotechnology is developing into a fast-expanding discipline with applications in science and technology, and nanostructures are a crucial research tool in many fields. Due to their remarkable electrical, optical, magnetic, catalytic, and pharmacological capabilities, metal and metal oxide nanoparticles (NPs) have drawn study interest. Natural elements (plants, microorganisms, fungi, etc.) are utilized in a chemical-free, environmentally benign way to synthesize metals and metal oxides. The optical, electrical, and antimicrobial qualities of silver nanoparticle (AgNP) make them a popular choice. More than 200 active ingredients, including water-soluble, organic-soluble, and volatile chemicals, are found in Ganoderma. The main components are polysaccharides, adenosine, and terpenoids, each of which has exceptional therapeutic properties. This article explains the synthesis of Ag NPs by Ganoderma lucidum and tests the antibacterial effectiveness for use in biological applications.