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Copper oxide nanoparticles (CuO-NPs) have garnered significant attention due to their multifunctional properties and diverse application areas. The synthesized CuO-NPs were characterized using XRD, SEM, HRTEM, and FTIR. The photocatalytic properties of CuO-NPs were assessed using methylene blue dye degradation under UV light. Various parameters such as pH, initial concentration of MB, and catalyst dose were investigated to determine their effects on photocatalytic efficiency. Kinetic analysis revealed that the degradation process followed a pseudo-first-order model. The antimicrobial efficacy of CuO-NPs was evaluated against Gram-positive and Gram-negative bacteria, demonstrating significant activity and providing insights into the underlying antibacterial mechanisms. Additionally, the toxicity of CuO-NPs was tested on Culex pipiens larvae, showing increased mortality rates with higher nanoparticle concentrations. Copper oxide nanoparticles elucidated the larvicidal effect on Culex pipiens . The lethal concentration (LC 50 ) values were determined as 37.61 mg/L for 3rd instar larvae and 8.31 mg/L for 4th instar larvae. The study provides a comprehensive analysis of CuO-NPs’ potential in photocatalysis, antimicrobial applications, and insecticidal properties, contributing to the understanding of their multifunctional roles in various environmental and biological contexts.

Energy drinks are rapidly gaining prominence in the global beverage industry, with projected sales reaching $60 billion within the next five years. These beverages often contain high levels of caffeine and the amino acid taurine, among other ingredients. The increasing consumption of energy drinks by children has sparked concerns regarding potential caffeine toxicity. In the present study, an energy drink was administrated at doses of 5 ml/Kg or 10 ml/Kg body weight. The comet assay demonstrated a significant elevation in DNA damage, evidenced by increased % DNA in tail and olive tail moment in the energy drink groups. Additionally, there were notable elevation in malondialdehyde levels as an oxidative stress marker, while reduction in superoxide dismutase activity and glutathione levels as antioxidant markers in energy drink groups. Furthermore, acetylcholinesterase activity and dopamine levels were significantly decrease in the energy drink groups compared to the control group. The high-dose groups exhibited a more pronounced effect than the low-dose groups, indicating a dose-dependent adverse effect.

Drug delivery is the process or method of delivering a pharmacological product to have therapeutic effects on humans or animals. The use of nanoparticles to deliver medications to cells is driving the present surge in interest in improving human health. Green nanodrug delivery methods are based on chemical processes that are acceptable for the environment or that use natural biomaterials such as plant extracts and microorganisms. In this study, zinc oxide-superparamagnetic iron oxide-silver nanocomposite was synthesized via green synthesis method using Fusarium oxysporum  fungi mycelia then loaded with sorafenib drug. The synthesized nanocomposites were characterized by UV-visibile spectroscopy, FTIR, TEM and SEM techniques. Sorafenib is a cancer treatment and is also known by its brand name, Nexavar. Sorafenib is the only systemic medication available in the world to treat hepatocellular carcinoma. Sorafenib, like many other chemotherapeutics, has side effects that restrict its effectiveness, including toxicity, nausea, mucositis, hypertension, alopecia, and hand-foot skin reaction. In our study, 40 male albino rats were given a single dose of diethyl nitrosamine (DEN) 60 mg/kg b.wt., followed by carbon tetrachloride 2 ml/kg b.wt. twice a week for one month. The aim of our study is using the zinc oxide-superparamagnetic iron oxide-silver nanocomposite that was synthesized by Fusarium oxysporum  fungi mycelia as nanocarrier for enhancement the sorafenib anticancer effect.

Nanobiocatalysts (NBCs), which merge enzymes with nanomaterials, provide a potent method for improving enzyme durability, efficiency, and recyclability. This review highlights the use of eco-friendly synthesis methods to create sustainable nanomaterials for enzyme transport. We investigate different methods of immobilization, such as adsorption, ionic and covalent bonding, entrapment, and cross-linking, examining their pros and cons. The decreased environmental impact of green-synthesized nanomaterials from plants, bacteria, and fungi is emphasized. The review exhibits the various uses of NBCs in food industry, biofuel production, and bioremediation, showing how they can enhance effectiveness and eco-friendliness. Furthermore, we explore the potential impact of NBCs in biomedicine. In general, green nanobiocatalysts are a notable progression in enzyme technology, leading to environmentally-friendly and effective biocatalytic methods that have important impacts on industrial and biomedical fields.

This review presents an overview of one of the effective strategies for improving the anticancer impact of many drugs including sorafenib using a drug delivery system by employing nanoparticles that is produced through a biological system. The biological process has a lot of benefits, including being inexpensive and safe for the environment. Sorafenib is one of a multi-kinase inhibitor that inhibits molecularly targeted kinases. Because of its poor pharmacokinetic characteristics, such as fast elimination and limited water solubility, the bioavailability of Sorafenib is extremely low. More intelligent nano formulations of sorafenib have been developed to boost both the drug’s target ability and bioavailability. Researchers in a wide variety of sectors, including nanomedicine, have recently been interested in the topic of nanotechnology. It is possible for the body to develop resistance to widely used drugs available for treatment of liver cancer, including sorafenib. As a result, our goal of this research is to highlight the efficacy of nanomedicine-based drug delivery system to enhance drug’s cancer-fighting properties. Because of their magnetic properties, certain nanoparticle materials can be employed as a carrier for the medicine to the exact place where the cancer is located. This can lower the amount of the drug that is administered with no impact on the normal cells.

Nanobiocatalysts (NBCs) are a promising new class of biocatalysts that combine the advantages of enzymes and nanomaterials. Enzymes are biological catalysts that are highly selective and efficient, but they can be unstable in harsh environments. Nanomaterials, on the other hand, are small particles with unique properties that can improve the stability, activity, and selectivity of enzymes. The development of NBCs has been driven by the need for more sustainable and environmentally friendly bioprocessing methods. Enzymes are inherently green catalysts, but they can be expensive and difficult to recover and reuse. NBCs can address these challenges by providing a stable and reusable platform for enzymes. One of the key challenges in the development of NBCs is the immobilization of enzymes on nanomaterials. Enzyme immobilization is a process that attaches enzymes to a solid support, which can protect the enzymes from harsh environments and make them easier to recover and reuse. There are many different methods for immobilizing enzymes, and the choice of method depends on the specific enzyme and nanomaterial being used. This review explores the effective role of NBCs in pharmaceutical and biomedical fields.

Oral cancer represents one of the most prevalent malignancies worldwide, characterized by high morbidity and mortality rates primarily due to late diagnosis, limited therapeutic efficacy, systemic toxicity, and recurrence following conventional treatments. Traditional chemotherapeutic drugs, while effective to a certain extent, often suffer from poor bioavailability, nonspecific targeting, and multidrug resistance, highlighting the importance of innovative therapeutic strategies. Nanomedicine has emerged as a promising alternative, providing site-specific delivery, enhanced drug stability, and improved therapeutic outcomes. Among various nanoparticles (NPs), metal oxide nanoparticles (MONPs), such as zinc oxide, titanium dioxide, and copper oxide, have demonstrated potent anticancer activity due to their high surface area, tunable physicochemical properties, and ability to generate reactive oxygen species (ROS). Recent progress in green synthesis approaches, employing plant extracts, microbes, and biopolymers as reducing and stabilizing agents, has further advanced the development of biocompatible and eco-friendly NPs. These green-synthesized NPs minimize toxic byproducts and allow their functionalization with herbal compounds and conventional drugs, offering synergistic effects against oral cancer. This review highlights the limitations of traditional treatments, examines the role of nanomedicine, and discusses the application of green-synthesized MONPs as drug delivery platforms for oral cancer management. It also addresses challenges such as standardization, scalability, safety concerns, and regulatory barriers, while outlining future perspectives that integrate green nanotechnology with precision medicine. Collectively, green nanomedicine offers a sustainable and innovative paradigm with the potential to revolutionize oral cancer therapy.

Enzymes are highly selective and efficient biological catalysts that play a critical role in modern industrial biocatalysis. Their ability to operate under mild conditions and reduce environmental impact makes them ideal alternatives to conventional chemical catalysts. This review provides a comprehensive overview of advances in enzyme-based catalysis, focusing on enzyme classification, engineering strategies, and industrial applications. The six major enzyme classes—hydrolases, oxidoreductases, transferases, lyases, isomerases, and ligases—are discussed in the context of their catalytic roles across sectors such as pharmaceuticals, food processing, textiles, biofuels, and environmental remediation. Recent developments in protein engineering, including directed evolution, rational design, and computational modeling, have significantly enhanced enzyme performance, stability, and substrate specificity. Emerging tools such as machine learning and synthetic biology are accelerating the discovery and optimization of novel enzymes. Progress in enzyme immobilization techniques and reactor design has further improved process scalability, reusability, and operational robustness. Enzyme sourcing has expanded from traditional microbial and plant origins to extremophiles, metagenomic libraries, and recombinant systems. These advances support the integration of enzymes into green chemistry and circular economy frameworks. Despite challenges such as enzyme deactivation and cost barriers, innovative solutions continue to emerge. Enzymes are increasingly enabling cleaner, safer, and more efficient production pathways across industries, supporting the global shift toward sustainable and circular manufacturing.

Nanotechnology is revolutionizing medicine by enabling highly precise diagnostics, targeted therapies, and personalized healthcare solutions. This review explores the multifaceted applications of nanotechnology across medical fields such as oncology and infectious disease control. Engineered nanoparticles (NPs), such as liposomes, polymeric carriers, and carbon-based nanomaterials, enhance drug solubility, protect therapeutic agents from degradation, and enable site-specific delivery, thereby reducing toxicity to healthy tissues. In diagnostics, nanosensors and contrast agents provide ultra-sensitive detection of biomarkers, supporting early diagnosis and real-time monitoring. Nanotechnology also contributes to regenerative medicine, antimicrobial therapies, wearable devices, and theranostics, which integrate treatment and diagnosis into unified systems. Advanced innovations such as nanobots and smart nanosystems further extend these capabilities, enabling responsive drug delivery and minimally invasive interventions. Despite its immense potential, nanomedicine faces challenges, including biocompatibility, environmental safety, manufacturing scalability, and regulatory oversight. Addressing these issues is essential for clinical translation and public acceptance. In summary, nanotechnology offers transformative tools that are reshaping medical diagnostics, therapeutics, and disease prevention. Through continued research and interdisciplinary collaboration, it holds the potential to significantly enhance treatment outcomes, reduce healthcare costs, and usher in a new era of precise and personalized medicine.