Synthesis and characterization of Se doped Fe3O4 nanoparticles for catalytic and biological properties

Fe/Se nanocomposite-loaded chitosan/alginate films for wound healing

Infectious wounds pose a major challenge to the healthcare sector, with numerous barriers, infections, dysregulated inflammation, and impaired cellular functions as well as complex healing mechanisms. To overcome these challenges, we report the fabrication of disulfide crosslinked chitosan/alginate (CAT)-based film loaded with iron oxide/selenium nanocomposite (SeIO) and ursodeoxycholic acid drug (UDC). Loading of SeIO and UDC in UDC/SeIO/CAT film leads to ⁓47 % increment in tensile strength as compared to CAT film. UDC/SeIO/CAT film shows the porosity of ∼70 % and swelling ratios of around 800 % at physiological pH 7.4, which can aid in the enhanced drug release and efficient wound healing. UDC/SeIO/CAT films exhibit a controlled degradation profile, and prolonged drug release of 92 % and 86 % at pH 7.4 and pH 8.5, respectively, over 110 h. It shows 99 % drug release at pH 5.5 over 74 h. Film displays 90 % antioxidant activity along with antibacterial activity of 86 % against E. coli and 89 % against S. aureus. Additionally, UDC/SeIO/CAT film is hemocompatible and exhibits good hemostatic behavior. It shows 130 % cell viability in murine fibroblast L929 cells, thus corroborating its cytocompatibility. Quantitative analysis of wound healing by scratch assay reveals 91 % decrease in wounded area on treatment with UDC/SeIO/CAT films.

Value addition to wastes: photo/sono-catalytic and antimicrobial performance of nickel ferrite derived using iron tailing and Raney nickel catalyst processing wastes

This research highlights a sustainable approach for the design and synthesis of a magnetic nickel ferrite (NiFe2O4) catalyst reutilizing industrial waste, specifically iron ore tailing and Raney nickel catalyst processing waste, by simple co-precipitation method. Transforming waste materials into high-performance catalysts, this study aligns with the principles of a circular economy, addressing both environmental waste and pollution. Structural characterization by X-ray diffraction (XRD) and microscopic (FESEM and TEM) revealed the formation of well crystalline nano ferrite with NiFe2O4 nanoparticles with cubic spinel structure. The ferromagnetic behavior with saturation magnetization of 43 emu/g and low band gap energy (1.81 eV) of the prepared catalyst supported its magnetic separation and activity under visible light. EDX and XPS analysis confirmed the purity of the sample with the existence of desired elements/ions. The prepared catalyst demonstrated significant photocatalytic and sonocatalytic activity under visible light and ultrasonic waves, respectively. The catalyst efficiently degraded the Reactive Red 35 (RR35), a model dye contaminant, in its aqueous solution (20-40 mg/L) within 2 h of the reaction. Besides its pollutant for dye removal, the catalyst also exhibits remarkable antibacterial activity, achieving a fivefold faster E. coli disinfection rate in comparison to traditional catalysts. Overall, the results established a lab-scale method for the synthesis of ferrite nanopowder from solid industrial wastes and provided inputs for developing a combined photo-sonocatalytic process for the degradation of different persistent organic contaminants including dyes.

Exploration of Metal-Doped Iron Oxide Nanoparticles as an Antimicrobial Agent: A Comprehensive Review

Over the past two decades, nanotechnology has captured significant interest, especially in the medical field, where the unique characteristics of nanoscale particles offer substantial advantages. The family of nanosized materials, specifically iron oxide nanoparticles (IONPs), has emerged as promising due to their magnetic properties, biocompatibility, and substantial surface area for therapeutic molecule attachment. The review explores various strategies to enhance the antibacterial properties of IONPs, such as metal doping, which modifies their physicochemical, biological, electrical, and optical properties. Metal-doped IONPs, including those with nickel, copper, zinc, selenium, molybdenum, gold, and others, have shown that they effectively eradicate viruses and bacteria. The mechanisms behind their enhanced antibacterial activity involve generating reactive oxygen species (ROS), inhibiting antibiotic-resistant genes, disrupting cell walls and DNA, dysfunction of efflux pumps, and internalizing nanoparticles. The review also addresses the potential toxicity of IONPs, highlighting factors such as their dimension, form, and outermost layers, which change how they affect the overall condition of cellular structures. Surface coatings using polymers and essential oils are among the strategies being investigated as potential ways to reduce toxicity. This review additionally looks into IONPs' drug delivery potential for antibiotics and antifungals. The integration of IONPs with various pharmaceutical compounds and their controlled release mechanisms are also detailed. The review concludes by offering a positive outlook on the potential enhancements and prospects of IONPs. Challenges in synthesis technologies, size tuning, and surface alteration are acknowledged, emphasizing the need for continued research to fully harness the capabilities of IONPs in biomedical applications.

Green synthesis of Zn-doped TIO2 nanoparticles from Zanthoxylum armatum

Green synthesis is an easy, safe, and environmentally beneficial nanoparticle creation method. It is a great challenge to simultaneously improve the capping and stabilizing agent carrier separation efficiency of photocatalysts. Herein, Zn-doped Titanium dioxide (TiO2) nanoparticles with high exposure of 360 nm using a UV/visible spectrophotometer were prepared via a one-step hydrothermal decomposition method. A detailed analysis reveals that the electronic structures were modulated by Zn doping; thus, the responsive wavelength was extended to 600 nm, which effectively improved the visible light absorption of TiO2. We have optimized the different parameters like concentration, time, and temperature. The peak for TiO2 is located at 600 cm-1 in FTIR. A scanning electron microscope revealed that TiO2 has a definite shape and morphology. The synthesized Zn-doped TiO2NPs were applied against various pathogens to study their anti-bacterial potentials. The anti-bacterial activity of Zn-doped TiO2 has shown robust against two gram-ve bacteria (Salmonella and Escherichia coli) and two gram + ve bacteria (Staphylococcus epidermidis and Staphylococcus aureus). Synthesized Zn-doped TiO2 has demonstrated strong antifungal efficacy against a variety of fungi. Moreover, doping TiO2 nanoparticles with metal oxide greatly improves their characteristics; as a result, doped metal oxide nanoparticles perform better than doped and un-doped metal oxide nanoparticles. Compared to pure TiO2, Zn-doped TiO2 nanoparticles exhibit considerable applications including antimicrobial treatment and water purification.

Solvent-thermal approach of MIL-100(Fe)/Cygnea/Fe3O4/TiO2 nanocomposite for the treatment of lead from oil refinery wastewater (ORW) under UVA light

The main purpose of this research endeavor is to reduce lead concentrations in the wastewater of an oil refinery through the utilization of a material composed of oyster shell waste (MIL-100(Fe)/Cygnea/Fe3O4/TiO2. Initially, iron oxide nanoparticles (Fe3O4) were synthesized via solvent-thermal synthesis. It was subsequently coated layer by layer with the organic-metallic framework MIL-100 (Fe) using the core-shell method. Additionally, the solvent-thermal method was utilized to integrate TiO2 nanoparticles into the magnetic organic-metallic framework's structure. Varieties of analytical analysis were utilized to investigate the physical and chemical properties of the synthetic final photocatalyst. Nitrogen adsorption and desorption technique (BET), scanning electron microscopy (SEM), scanning electron diffraction pattern (XRD), and transmission electron microscopy (TEM). Following the characterization of the final photocatalyst, the physical and chemical properties of the nanoparticles synthesized in each step, several primary factors that significantly affect the removal efficiency in the advanced oxidation system (AOPs) were examined. These variables consist of pH, photocatalyst dosage, lead concentration, and reaction temperature. The synthetic photocatalyst showed optimal performance in the removal of lead from petroleum wastewater under the following conditions: 35 °C temperature, pH of 3, 0.04 g/l photocatalyst dosage, and 100 mg/l wastewater concentration. Additionally, the photocatalyst maintained a significant level of reusability after undergoing five cycles. The findings of the study revealed that the photocatalyst dosage and pH were the most influential factors in the effectiveness of lead removal. According to optimal conditions, lead removal reached a maximum of 96%. The results of this investigation showed that the synthetic photocatalyst, when exposed to UVA light, exhibited an extraordinary capacity for lead removal.

Antitumor efficacy of synthesized Ag-Au nanocomposite loaded with PEG and ascorbic acid in human lung cancer stem cells

Lung cancer is the leading cause of mortality worldwide of which non-small cell lung carcinoma constitutes majority of the cases. High mortality is attributed to early metastasis, late diagnosis, ineffective treatment and tumor relapse. Chemotherapy and radiotherapy form the mainstay of its treatment. However, their associated side effects involving kidneys, nervous system, gastrointestinal tract, and liver further adds to dismal outcome. These disadvantages of conventional treatment can be circumvented by use of engineered nanoparticles for improved effectiveness with minimal side effects. In this study we have synthesized silver gold nanocomposite (Ag-Au NC) using polyethylene glycol and l-ascorbic acid as surfactant and reducing agent respectively. Synthesized nanocomposite was characterized by ultraviolet-visible absorption, dynamic light scattering, scanning and transmission electron microscopy. Compositional analysis was carried out by energy dispersive X-ray analysis and average pore diameter was estimated using Barrett-Joyner-Halenda method. In-silico molecular docking analysis of the synthesized NC against active regions of epidermal growth factor receptor revealed good binding energy. Subsequently, we investigated the effect of NC on growth and stem cell attributes of A549 lung cancer cells. Results showed that NC was effective in inhibiting A549 cell proliferation, induced DNA damage, G2/M phase arrest and apoptosis. Further, tumor cell migration and spheroid formation were also negatively affected. NC also enhanced reactive oxygen species generation and mitochondrial depolarization. In addition, the effect of NC on putative cancer stem cells in A549 cells was evaluated. We found that Ag-Au NC at IC50 targeted CD44, CD24, CD166, CD133 and CD326 positive cancer stem cells and induced apoptosis. CD166 positive cells were relatively resistance to apoptosis. Together our results demonstrate the anticancer efficacy of Ag-Au NC mediated by a mechanism involving cell cycle arrest and mitochondrial derangement.

The Promise of Metal-Doped Iron Oxide Nanoparticles as Antimicrobial Agent

Antibiotic resistance (AMR) is one of the pressing global public health concerns and projections indicate a potential 10 million fatalities by the year 2050. The decreasing effectiveness of commercially available antibiotics due to the drug resistance phenomenon has spurred research efforts to develop potent and safe antimicrobial agents. Iron oxide nanoparticles (IONPs), especially when doped with metals, have emerged as a promising avenue for combating microbial infections. Like IONPs, the antimicrobial activities of doped-IONPs are also linked to their surface charge, size, and shape. Doping metals on nanoparticles can alter the size and magnetic properties by reducing the energy band gap and combining electronic charges with spins. Furthermore, smaller metal-doped nanoparticles tend to exhibit enhanced antimicrobial activity due to their higher surface-to-volume ratio, facilitating greater interaction with bacterial cells. Moreover, metal doping can also lead to increased charge density in magnetic nanoparticles and thereby elevate reactive oxygen species (ROS) generation. These ROS play a vital role to disrupt bacterial cell membrane, proteins, or nucleic acids. In this review, we compared the antimicrobial activities of different doped-IONPs, elucidated their mechanism(s), and put forth opinions for improved biocompatibility.

Regulation of saturation magnetization of magnetite by doping with group III elements

Magnetic Fe3O4 nanoparticles show promising applications in nanomedicine. However, the saturation magnetization (MS) of Fe3O4 nanoparticles synthesized in laboratory is usually not high enough, which greatly limits their application in drug delivery and magnetic hyperthermia. Here, by accurate hybrid density functional computation, the doping behavior of group III elements (including Al, Ga, and In) and the effects on magnetic and electronic properties are well studied. The results show that the doping behavior depends on the concentration of dopants. Interestingly, appropriate Ga and In doping concentrations can significantly increase the MS of Fe3O4. In addition, the doping of group III elements (Al, Ga and In) into Fe3O4 would not induce any defect states in the band gap but slightly increases the band gap. Our results provide a simple and feasible scheme for increasing the MS of magnetite, which is significant for the applications of Fe3O4 nanoparticles in drug delivery and magnetic hyperthermia.

Self-cleaning cellulose acetate/crystalline nanocellulose/polyvinylidene fluoride/Mg0.975Ni0.025SiO3membrane for removal of diclofenac sodium and methylene blue dye in water

Recalcitrant pollutants present in wastewater, without an effective treatment, have several effects on aquatic ecosystems and human health due to their chemical structure and persistence. Therefore, it is crucial the development of efficient technologies to eliminate such pollutants in water. Nano-photocatalysts are considered a promising technology for water remediation; however, one common drawback is the difficulty of recovering it after water processing. One effective strategy to overcome such problem is its immobilization into substrates such as polymeric membranes. In this study, a polymeric membrane with embedded Mg0.975Ni0.025SiO3is proposed to remove model pollutants diclofenac sodium and methylene blue dye by synergetic adsorption and photocatalytic processes. Mg0.975Ni0.025SiO3was synthesized by the combustion method. The matrix polymeric blend consisting of a blend of cellulose acetate, crystalline nanocellulose and polyvinylidene fluoride was obtained by the phase inversion method. The composite membranes were characterized by FTIR, x-ray diffraction, and scanning electron microscopy. With pollutant solutions at pH 7, the pollutant adsorption capacity of the membranes reached up to 30% and 45% removal efficiencies for diclofenac sodium and methylene blue, respectively. Under simulated solar irradiation photocatalytic removal performances of 70% for diclofenac sodium pH 7, and of 97% for methylene blue dye at pH 13, were reached. The membrane photocatalytic activity allows the membrane to avoid pollutant accumulation on its surface, given a self-cleaning property that allows the reuse of at least three cycles under sunlight simulator irradiation. These results suggest the high potential of photocatalytic membranes using suitable and economical materials such as cellulosic compounds and magnesium silicates for water remediation.