Metal Ion Chelating Research Articles

Carboxymethyl cellulose assisted hydrothermal synthesis of litchi-like zinc ferrite nanoparticles for water remediation through visible photo-Fenton-like catalysis

The conventional methods for the synthesis of zinc ferrite (ZnFe2O4) basically require high temperature calcination oxidation step, which produces environmentally unfriendly high energy consumption and may produce harmful gases that pollute the atmosphere, as well as the calcination synthesis limits the application of ZnFe2O4 such as preparation of organic composite materials. To end this, by adding carboxymethyl cellulose (CMC) to the reaction system, homogeneous litchi-like ZnFe2O4/CMC nanoparticles were successfully synthesized without alkali and calcination in this paper. The rich carboxyl group of CMC is conducive to the chelation and fixation of metal ions in the reaction precursor, which greatly promotes the synthesis of ZnFe2O4. The synthesized particle size is ~100 nm, with obvious ZnFe2O4 diffraction peaks and good crystallinity. The photocatalytic performance of the synthesized photocatalyst was evaluated by visible light-Fenton-like method. With the activation of peroxymonosulfate (PMS), 80.27 % of tetracycline hydrochloride (TC) was degraded in just 18 min, suggesting that the synthesized catalyst had an excellent photocatalytic performance. After four cycles, the catalyst still could degrade 64.52 % TC. And the same behavior in XRD and FTIR spectra confirms the stability of the photocatalyst. In addition, it was determined that singlet oxygen (1O2) dominated the visible light catalytic degradation.

Enhancing Tannic Acid-Arginine Complex Loading in Ultraporous PA6 Nanofibers through NH3 Foaming for Efficient Heavy Metal Removal from Textile Wastewater.

Metal-containing dyes in the textile industry release heavy metal ions into wastewater, posing significant environmental risks and complicating treatment processes. Among various removal methods, chemical adsorption through functional groups that form stable complexes is one of the most effective. Tannic acid (TA), renowned for its strong chelation of metal ions via phenolic hydroxyl groups, faces challenges in operation and recycling in its powdered form. Electrospun polyamide 6 (PA6) nanofiber membranes, characterized by high surface area and structural stability, offer a promising platform. However, achieving an optimal TA loading remains a technical hurdle for industrial applications. To address this, we developed an arginine (l-Arg) bridging strategy to enhance the TA loading on PA6 nanofibers. Additionally, we implemented an NH3 escape foaming technique to increase membrane porosity by 20% and quadruple pore size, enhancing surface roughness and resulting in a 70% increase in TA loading. The optimized adsorbent demonstrated the effective removal of various heavy metal ions, achieving over 95% removal efficiency for five different metals. Even after five adsorption-desorption cycles, the membrane retained over 92% efficiency, translating to a treatment capacity of 12.5 tons of wastewater per kilogram of foaming fiber, underscoring its potential for practical wastewater treatment applications.

Transition metal ions-chelated COFs derived bifunctional oxygen catalysts for rechargeable Zn-air batteries

Improving energy conversion efficiency and battery cycle stability is an essential goal in energy conversion and storage, while a critical factor in achieving this goal is the design of effective bifunctional catalysts. The covalent organic framework is a new type of high molecular material that can be employed as an ideal template for quantitative chelate metal ions to synthesize highly efficient bifunctional catalysts with high dispersion metal active sites. In this work, the Fe2Ni1/NiFe2O4@NCG bifunctional catalysts are constructed by employing metal-chelated COFs and MA/GO mixture as primary precursors combined with a high-temperature pyrolysis strategy. COFs and MA serve as chelators and spacers to improve the dispersion of metal nanoparticles. The Fe2Ni1/NiFe2O4@NCG composite exhibits a large BET surface area and hierarchical structure with plentiful nanoparticles on the carbon layers. HRTEM proves the coexistence of FeNi and NiFe2O4. The optimal Fe2Ni1/NiFe2O4@NCG-800 composite shows satisfactory catalytic O2 performance, providing a half-wave potential of 0.857 V for ORR and an overpotential of 244 mV for OER. Meanwhile, DFT calculations prove that electron redistribution occurs at the interface between FeNi and NiFe2O4 after combination. The Fe2Ni1/NiFe2O4@NCG-based liquid and solid-state ZABs perform very well, exhibiting large specific capacities (796 mAh·g−1 for aqueous ZAB; 742 mAh·g−1 for solid-state ZAB) and stable charge-discharge cycle performance (300 h for aqueous ZAB; 180 h for solid-state ZAB).

Exploring the Antioxidant Potential of Fagopyrum esculentum Moench (Common Buckwheat) Leaf Extract

This study was conducted in 2022 at the Department of Molecular Biology and Genetic Engineering, College of Basic Sciences and Humanities, G.B. Pant University of Agriculture & Technology, Pantnagar, Uttarakhand, India. The objective was to assess the antioxidant potential of the hydromethanolic leaf extract of Fagopyrum esculentum Moench (common buckwheat) by evaluating its reducing power and metal ion chelation abilities. Leaves of Fagopyrum esculentum were collected from the Pithoragarh district in Uttarakhand and authenticated. A 50% hydromethanolic extract (FEE) was prepared from the powdered leaves. The antioxidant potential of FEE was assessed using reducing power and metal ion chelation tests. The hydromethanolic extract yielded 7.17%. FEE exhibited significant antioxidant activity in a concentration-dependent manner, demonstrating both electron-donating ability and metal ion chelation capacity with an IC50 value of 108.846 µg/ml. These results highlight the potential of F. esculentum leaf extract as a natural antioxidant for use in the pharmaceutical, cosmetic, and food industries. Further studies are recommended to investigate its effects In vivo.

Organotropic Engineering of Luminescent Gold Nanoclusters for In Vivo Imaging of Lung Orthotopic Tumors.

Gold nanoclusters (AuNCs) are emerging as promising functional probes for bioapplications. However, because of rapid renal clearance, it is a challenge to tailor their biofate and improve their disease-targeting ability in vivo. Herein, we report an efficient strategy to tailor their organotropic actions by rationally designing AuNC assemblies. The nanocluster assembly is established based on the moderate electrostatic interaction or strong coordination between AuNCs, enabled by solely chitosan (CS) or the coadded chelating metal ions (e.g., Gd3+). We show that AuNCs-CS is rapidly excreted into urine, while further coordination of Gd3+ confers assemblies with liver and lung accumulation capabilities, dependent on Gd3+ contents. The organotropic actions are unraveled to result from their tunable stability in vivo and binding capability to cells/proteins. We also demonstrate that lung-targeting assemblies can enable specific NIR-II luminescence imaging of lung orthotopic tumors, which cannot be realized by employing discrete AuNCs. We anticipate that these findings will offer insights into the design principles of metal nanocluster probes and related bioapplications.

Effect of drying conditions on the chemical compositions, molecular docking interactions and antioxidant activity of Hedychium spicatum Buch.-Ham. Rhizome essential oil

The fresh and dried rhizomes of Hedychium spicatum are used to treat various ailments. The present work aimed to determine the influence of drying conditions (shade; HSSH, sun; HSS, oven; HSSV30 HSSV50, blower; HSB) on the essential oil profile and antioxidant potential of H. spicatum rhizomes. The oil was extracted by hydrodistillation method. The GC-FID and GC-MS were used to identify compounds, while the antioxidant potential was measured by DPPH radical scavenging, metal ion chelating and H2O2 scavenging methods. To investigate the inhibitory potential, molecular docking simulations were conducted on major compounds targeting NADPH oxidase. Drying significantly enhanced the oil yield of H. spicatum. The dominant compounds identified across all the samples were 1,8-cineole (14.62–53.87%), α-cadinol (10.62–25.06%), elemol (6.56–20.03%), germacrene-4-ol (3.73–11.27%), and α-muurolol (3.32–7.74%). The content of 1,8-cineole increased significantly while the percentage of elemol, germacrene-4-ol, α-muurolol, and α-cadinol decreased significantly in the dried rhizome samples. Among all the drying conditions, HSOV30 exhibited the highest oil yield, antioxidant potential and highest content of 1,8-cineole and elemol (marker components). Docking studies indicated that α-muurolol and α-cadinol exhibited favorable binding affinities and significant hydrophobic interactions with the enzyme’s active site, suggesting their efficacy. Therefore, the selection of the appropriate drying condition to obtain essential oils is important not only in terms of higher yield but also, most importantly, in terms of the percentage of compounds that can bring the essential oils to their sustainable use. It is the first report on the effect of drying on H. spicatum rhizomes.

Evaluation of Different Swab Wetting Chemicals Affecting the Yield of DNA Obtained From Biological Evidence on Cartridge Casings

Cartridge casings made from transition metals can be examined ballistically and also serve as significant evidence by containing touch DNA. However, the success rate of profiles obtained from this type of evidence is generally low. To enhance the success of DNA profiling from suspects' biological evidence, using swabs moistened with chemicals can be beneficial. Swabs are typically moistened with water, whose hypotonic nature disrupts cell integrity, causing the release of DNA. However, water is not the only agent used for moistening swabs; various buffer solutions are also utilized. The ability of swabs to transfer touch DNA depends on the type of buffer solution used. Sodium dodecyl sulfate (SDS), a strong anionic detergent, denatures non-covalently linked secondary and tertiary structures to increase the release of bound DNA. Another buffer solution used for swab moistening is Te+4 buffer, which contains EDTA and Tris. EDTA chelates metal ions, inactivating enzymes that could potentially damage DNA, while Tris adjusts the pH to an optimal level. This study aims to compare the effectiveness of microfibre and cotton swabs moistened with SDS, Te+4 buffer, and water in recovering genetic material from blood and epithelial cells deposited on brass cartridge casings. The study also evaluates the impact of firing on the quality of DNA profiles. Among the profiles obtained, the swabs moistened with SDS produced the highest rate of complete profiles at 44%, while the lowest rate of complete profiles at 22% was observed with swabs moistened with Te+4 buffer. SDS is particularly advantageous over water when used on casings with epithelial cells. Microfibre swabs are more effective in eliminating degradative factors caused by firing, thus enhancing profiling success. Comparisons of the RFU values indicate that casings yield lower values compared to cartridges, supporting the negative impact of the high heat, pressure, and residues generated during firearm discharge.

Antioxidant peptides from silver carp steak by alkaline protease and flavor enzyme hydrolysis: Characterization of their structure and cytoprotective effects against H2O2-induced oxidative stress.

Silver carp steak is a rarely utilized silver carp processing byproduct. This study aimed to optimize a dual enzymatic method to extract antioxidant peptide components from silver carp steak and characterize their structure and in vitro antioxidant activity through ultrafiltration purification, response surface methodology, molecular docking, and radical scavenging activity analysis. The optimal extraction conditions for silver carp steak antioxidant peptides (SCSAP) were determined as 1:6 solid-liquid ratio, 1500 U/g alkaline protease addition, 4 h alkaline protease hydrolysis time, 1946 U/g flavor enzyme addition, and 2.5 h flavor enzyme hydrolysis time. The <3 kDa SCSAP component (SCSAP-3kDa) showed the strongest antioxidant activity, with its 1,1-diphenyl-2-trinitrophenyl hydrazine (DPPH) radical scavenging rate, ABTS radical scavenging rate, hydroxyl radical scavenging rate, metal ion chelating rate, and reducing capacity reaching 88.75%, 91.21%, 67.02%, 69.07%, and 0.985, respectively. Moreover, the three peptides (PF-7, GP-8, and YF-10) of 100 µg/mL could protect HepG2 cells from oxidative stress damage by reducing the oxidative damage level and activating Keap1-Nrf2-ARE pathways, enabling an increase of superoxide dismutases (SOD) activity, and a decrease of malondialdehyde (MDA) content and reactive oxygen species (ROS) level. The integrated results indicate the enormous potential of SCSAP-3kDa as a functional food ingredient in the food industry. PRACTICAL APPLICATION: This study selected the antioxidant capacity of silver carp steak peptides as the index and developed a facile dual enzymatic hydrolysis method to obtain three antioxidant peptides (PF-7, GP-8, and YF-10) with biological activity, providing a theoretical basis for bioavailability of antioxidant peptides from silver carp steak and contributing to their application in new functional foods.

Advancing Polyphenol-Based Nanomedicine for Inflammatory Bowel Disease: Challenges and Opportunities.

Oxidative stress, characterized by excessive production of reactive oxygen species (ROS), is a critical factor in the progression of inflammatory bowel disease (IBD) and presents a potential therapeutic target. Anti-oxidant therapy, aimed at mitigating excessive ROS, is emerging as a cornerstone in IBD treatment. Nanomaterials with robust anti-oxidant properties offer promise by inhibiting inflammation through ROS scavenging, enhancing IBD therapeutic efficacy. Recent focus in ROS scavenging has centered on metal oxide nanoenzymes and polyphenol-based nanomaterials. The primary challenges are the catalytic efficiency of nanoenzymes and the functional integration of these nanomaterials with therapeutic agents. Polyphenols, natural plant extracts, have garnered significant interest due to their potent anti-oxidant properties and unique catechol groups that interact with biomolecules such as proteins and nucleic acids. The strong metal ion chelating ability of catechols enriches the structure and functionality of nanomaterials, improving the physicochemical properties of nanocarriers and enabling innovative designs of multifunctional drug delivery systems (DDSs). Research on polyphenol-based DDSs has expanded to include agents like epigallocatechin gallate, curcumin, resveratrol, tannic acid, and polydopamine. These nanocarriers and anti-oxidants, which incorporate polyphenols, have demonstrated potential anti-oxidant properties in novel DDSs as therapeutic agents to reduce inflammation and as essential components of drug carriers. This review focuses on the design and application of natural polyphenol-based anti-oxidant nanomaterials for IBD treatment, offering a comprehensive discussion on the use of polyphenols in DDSs and the potential challenges posed by their diverse roles in innovative drug delivery strategies, including their impact on the physical and chemical properties of DDSs.

Evaluation of Anti-Alzheimer's Potential of Azo-Stilbene-Thioflavin-T derived Multifunctional Molecules: Synthesis, Metal and Aβ Species Binding and Cholinesterase Activity.

Inhibition of amyloid β (Aβ) aggregation and cholinesterase activity are two major therapeutic targets for Alzheimer's disease (AD). Multifunctional Molecules (MFMs) specifically designed to address other contributing factors, such as metal ion induced abnormalities, oxidative stress, toxic Ab aggregates etc. are very much required. Several multifunctional molecules have been developed using different molecular scaffolds. Reported herein is a new series of four MFMs based on ThT, Azo-stilbene and metal ion chelating pockets. The synthesis, characterization, and metal chelation ability for [Cu(II) and Zn(II)] are presented herein. Furthermore, we explored their multifunctionality w.r.t. to their (i) recognition of Aβ aggregates and monomeric form, (ii) utility in modulating the aggregation pathways of both metal-free and metal-bound amyloid-β, (iii) ex-vivo staining of amyloid plaques in 5xFAD mice brain sections, (iv) ability to scavenge free radicals and (v) ability to inhibit cholinesterase activity. Molecular docking studies were also performed with Aβ peptides and acetylcholinesterase enzyme to understand the observed inhibitory effect on activity. Overall, the studies presented here establish the multifunctional nature of these molecules and qualify them as promising candidates for furthermore investigation in the quest for finding Alzheimer's disease treatment.

Research Progress on Antioxidant Peptides from Fish By-Products: Purification, Identification, and Structure-Activity Relationship.

Background/Objectives: Excessive reactive oxygen species (ROS) can lead to oxidative stress, which has become an urgent problem requiring effective solutions. Due to the drawbacks of chemically synthesized antioxidants, there is a growing interest in natural antioxidants, particularly antioxidant peptides. Methods: By reviewing recent literature on antioxidant peptides, particularly those extracted from various parts of fish, summarize which fish by-products are more conducive to the extraction of antioxidant peptides and elaborate on their characteristics. Results: This article summarizes recent advancements in extracting antioxidant peptides from fish processing by-products, Briefly introduced the purification and identification process of antioxidant peptides, specifically focusing on the extraction of antioxidant peptides from various fish by-products. Additionally, this article comprehensively reviews the relationship between amino acid residues that compose antioxidant peptides and their potential mechanisms of action. It explores the impact of amino acid types, molecular weight, and structure-activity relationships on antioxidant efficacy. Conclusions: Different amino acid residues can contribute to the antioxidant activity of peptides by scavenging free radicals, chelating metal ions, and modulating enzyme activities. The smaller the molecular weight of the antioxidant peptide, the stronger its antioxidant activity. Additionally, the antioxidant activity of peptides is influenced by specific amino acids located at the C-terminus and N-terminus positions. Simultaneously, this review provides a more systematic analysis and a broader perspective based on existing research, concluded that fish viscera are more favorable for the extraction of antioxidant peptides, providing new insights for the practical application of fish by-products. This could increase the utilization of fish viscera and reduce the environmental pollution caused by their waste, offering valuable references for the study and application of antioxidant peptides from fish by-products.

The Impact of Biotechnologically Produced Lactobionic Acid on Laying Hens' Productivity and Egg Quality during Early Laying Period.

Lactobionic acid (Lba), an oligosaccharide aldonic acid, has demonstrated various health-promoting benefits and applications in diverse areas. Lba has been recognized for its multifunctional properties, such as metal ion chelation and calcium sequestration. This study aimed to evaluate the effects of supplementing the diet of early-laying hens with Lba (EXP group) on their performance and the physical-chemical properties, and nutritional quality of eggs. The 12-week study involved 700 Sonja breed hens per group, with the EXP group's diet enriched with 2% of biotechnologically produced Lba, while the control group (CON) received no Lba supplementation. Lba supplementation influenced both the hen's performance and egg quality, particularly in terms of egg production and fatty acid accumulation. Performance in the EXP group was significantly improved (p < 0.05), showing a 4.6-8.9% increase compared to the CON group at all experiment stages. Lba also promoted an increase in monounsaturated fatty acid (MUFA) content, particularly palmitoleic and vaccenic acids. Overall, Lba supplementation enhanced both the productivity of laying hens and the nutritional value of eggs during the early laying period.

Comparative analysis and mechanistic insights into polysorbate 80 stability differences in biopharmaceutical buffer systems

Polysorbate 80 (PS80) is a non-ionic surfactant extensively utilized in biopharmaceutical formulations for stabilizing proteins. However, PS80 degradation has become a widespread concern throughout the industry over the past decade. In this work, the impact of most frequently employed pH/buffer systems on the stability of PS80 was assessed. PS80 degraded fastest in histidine buffer, followed by acetate and succinate buffers, whereas it remained stable in citrate, phosphate and tris buffers. When there was PS80 degradation, the extent of degradation was found to be pH-dependent. The predominant degradation pathway was oxidation mainly triggered by metal ions. The varying stability of PS80 across different pH/buffer systems was attributed to the role of buffer agents, which can either promote or inhibit the oxidation process through their interactions with metal ions. Specifically, buffers except histidine exhibited metal ion chelation similar to ethylenediaminetetraacetic acid (EDTA), which can suppress the oxidation of PS80, although the effectiveness of chelation varies to different extents. Furthermore, the binding capacity appeared stronger at higher pH in acetate and succinate buffers. Conversely, histidine was reported to form pro-oxidant complexes with metal ions to accelerate PS80 degradation, especially at higher pH levels. Our work for the first time offers a comprehensive understanding of PS80 oxidation in biopharmaceutical buffer systems. This provides a strong foundation for buffer and excipient selection in parenteral formulations.

Antioxidant, antiacetylcholinesterase and apoptotic effects of essential oil of Isodon wightii (Bentham) H. Hara

Isodon wightii (Bentham) H. Hara is well known for aromatic essential oil. This is the first study aimed to evaluate antioxidant, antiacetylcholinesterase and apoptotic potential of I. wightii oil. DPPH scavenging, metal ion chelation and antiacetylcholinesterase activities were carried out for the extracted essential oil from the leaves of I. wightii. Cytotoxic effect on HeLa cells was studied by MTT assay and its apoptotic potential was determined by Acridine Orange/Ethidium Bromide and Hoechst33258 stains. A significant free radical scavenging and metal ion chelation were determined for oil. Acetylcholinesterase inhibition was recorded with IC50 value of 7.864 µg/mL. The cytotoxic effect of oil on HeLa cells was calculated with IC50 value of 13.264 µg/mL. High level of apoptosed cells were observed at 100 µg/mL oil treated cells. The results of the study emphasise the medicinal importance of I. wightii essential oil which could be a prominent plant based cancer therapeutic agent.

Facile and scalable method to synthesize MOFs/PET composite fibers for indoor VOCs adsorption

Volatile organic compounds (VOCs) that are emitted into indoor environments pose significant risks to human health, necessitating air purification to protect individuals from VOC-induced harm. Metal–organic frameworks (MOFs) are characterized by their extensive porosity and accessible metal sites and have attracted significant interest owing to their efficacy in VOC adsorption. However, the inherent difficulty in collecting powdered MOFs hinders their practical application. Thus, integrating MOFs with textiles presents an innovative solution for overcoming these challenges. In this study, MOFs/PET composite textiles (MOFs@STP-PET) were synthesized via an in-situ growth process on polyethylene terephthalate (PET) fiber substrates using thermal crosslinking coating and pre-soaked seed hot-solvent methodologies. The capacities of the composites to adsorb and mitigate VOCs, including benzene and formaldehyde, were evaluated. The presence of carboxyl groups (–COOH) on the polyacrylic acid coating facilitated the chelation of metal ions via electrostatic interactions, providing a foundation for MOF growth. Moreover, the obtained textiles exhibited good adsorption performance. Notably, the 10 % breakthrough time of ethylbenzene on the U6N@STP-PET textile increased to 267.9 min, resulting in a maximum adsorption capacity of 4.3 mg/g. Uniformly anchored MOFs on the fiber surface ensured a high specific surface area of 292.3 m2/g, further enhancing adsorption capabilities. In addition, the textile exhibited excellent mechanical properties, with a tensile strength of approximately 20 MPa. This straightforward, effective, and scalable approach paves the way for the development of novel VOC adsorption materials and holds promise for improving indoor air quality.

Evaluating the Root Extract of Reynoutria ciliinervis (Nakai) Moldenke: An Analysis of Active Constituents, Antioxidant Potential, and Investigation of Hepatoprotective Effects in Rats

Reynoutria ciliinervis (Nakai) Moldenke (R. ciliinervis) root, a traditional Chinese medicine, was found to exhibit remarkable pharmacological properties through a series of comprehensive investigations. Our study commenced with a qualitative phytochemical analysis that identified 12 bioactive compounds within the plant. Subsequently, utilizing ultraviolet-visible spectrophotometry, the methanol extract emerged as the optimal solvent extract, which was abundant in diverse classes of compounds such as carbohydrates, phenolics, steroids, alkaloids, phenolic acids, and tannins. In vitro antioxidant assays underscored the exceptional free radical scavenging, metal ion chelation, hydrogen peroxide scavenging, singlet oxygen quenching, and β-carotene bleaching capabilities of the methanol extract, significantly outperforming other solvent extracts. Further ultra high-performance liquid chromatography–electrospray ionization–quadrupole time of flight–mass spectrometry analysis revealed the presence of 45 compounds, predominantly anthraquinones and phenolics, in the methanol extract. The extract demonstrated robust stability under various conditions, including high temperatures, varying pH levels, and simulated gastrointestinal digestion as well as efficacy in inhibiting the oxidation in edible oils. Acute toxicity tests in mice confirmed the safety of the methanol extract and provided a valuable dosage reference for future studies. Importantly, high-dose methanol extract exhibited a significant pre-protective effect against D-galactosamine-induced liver injury in rats, as evidenced by reduced alanine aminotransferase, aspartate aminotransferase, γ-glutamyl transpeptidase, malondialdehyde levels, and elevated catalase and albumin levels. These findings suggest a potential role for the methanol extract of R. ciliinervis root in treating oxidative stress-related disorders, highlighting the plant’s immense medicinal potential. Our research offers a thorough evaluation of the bioactive components, antioxidant properties, stability, and liver-protecting effects of the methanol extract, setting the stage for deeper investigation and potential clinical applications.

Development of multi-herbal formulation with enhanced antimicrobial, antioxidant, cytotoxic, and antiaging properties

We developed a multi-herbal formulation (MCCSSTAMP) containing Mentha piperita, Allium sativum, Syzygium aromaticum, Curcuma longa, Syzygium cumini, Trigonella foenum-graecum, Coriandrum sativum, Murraya koenigii and Piper nigrum which was found to be versatile for the development of novel medicines and cosmetic products. The formulation was prepared using a hydro-alcoholic base and its phytochemical composition was analyzed. The initial phytochemical analysis revealed that MCCSSTAMP contained various phytochemicals, with the highest concentrations of phenolic content. The antimicrobial, anti-oxidant, cytotoxic, and anti-aging properties of the MCCSSTAMP were explored. The formulation showed potent anti-microbial efficacy against various microorganisms, including antibiotic-resistant strains. MCCSSTAMP also demonstrated potent anti-oxidant activity, effectively scavenging free radicals and chelating metal ions. Furthermore, it exhibited cytotoxic activity against carcinoma cell lines, comparable to a standard chemotherapeutic agent cisplatin. The formulation has a potential anti-aging agent and skin-whitening additive due to its significant inhibitory activity against enzymes involved in the aging process, such as hyaluronidase, elastase, and tyrosinase. Our study claims that the efficacy was attributed to the synergistic effect of combining multiple herbs in the formulation. Further, it acted as a viable source of nutritional supplements for the nutraceutical industry, as all of the plants used in the formulation are edible, making it a promising candidate for cancer treatment research and its application in cosmetic products to address hyperpigmentation and maintain skin integrity.

A Descriptive Review of the Antioxidant Effects and Mechanisms of Action of Berberine and Silymarin.

Oxidative stress is a key factor in the development of chronic diseases such as type 2 diabetes, cardiovascular diseases, and liver disorders. Antioxidant therapies that target oxidative damage show significant promise in preventing and treating these conditions. Berberine, an alkaloid derived from various plants in the Berberidaceae family, enhances cellular defenses against oxidative stress through several mechanisms. It activates the AMP-activated protein kinase (AMPK) pathway, which reduces mitochondrial reactive oxygen species (ROS) production and improves energy metabolism. Furthermore, it boosts the activity of key antioxidant enzymes like superoxide dismutase (SOD), catalase (CAT), and glutathione peroxidase (GPx), thus protecting cells from oxidative damage. These actions make berberine effective in managing diseases like type 2 diabetes, cardiovascular conditions, and neurodegenerative disorders. Silymarin, a flavonolignan complex derived from Silybum marianum, is particularly effective for liver protection. It activates the nuclear factor erythroid 2-related factor 2 (Nrf2) pathway, enhancing antioxidant enzyme expression and stabilizing mitochondrial membranes. Additionally, silymarin reduces the formation of ROS by chelating metal ions, and it also diminishes inflammation. This makes it beneficial for conditions like non-alcoholic fatty liver disease (NAFLD) and alcohol-related liver disorders. This review aims to highlight the distinct mechanisms by which berberine and silymarin exert their antioxidant effects.

Optimizing the Structure of a Pt Metal-Chelating Polymer to Reduce Nonspecific Binding for Mass Cytometry.

Mass cytometry is a bioanalytic tool based on atomic mass spectrometry for detecting biomarker expression on individual cells. Current reagents employ metal-chelating polymers binding isotopes of hard metal ions. Polymers bearing chelators for soft metal ions offer the promise for a large increase in multiplexing capabilities, but examples reported so far often have unacceptably high levels of nonspecific binding (NSB). We recently reported a new class of metal-chelating polymers with dipicolylamine (DPA) chelators that could bind Re and Pt. They also showed significant levels of NSB. Here, to reduce the NSB of the Pt-DPA polymer, we grafted water-soluble oligomers to the distal end of the dipicolylamine pendant group. Methoxy(polyethylene glycol) (DP = 24) was effective as was poly(sulfobetaine methacrylate) (DP = 29). Reacting the Pt-Cl bond of the metalated polymer with glutathione was remarkably effective at suppressing NSB. These results open the door to Pt-isotope-based metal-chelating polymers as new mass tags for mass cytometry.

Synthesis of Palladium Nanomaterials Using Plant Leaf Extract and their Enhanced Photocatalytic Activities against Organic Dyes

Aims and Objectives: This study aimed to carry out the green synthesis of palladium nanoparticles (Pd NPs) using the aqueous leaves extract of Eclipta alba. The appearance of a characteristic surface plasmon resonance peak at 410 nm confirmed the synthesis of Pd NPs. Method: The average particle sizes of 13 nm were observed by using the leaf concentrations of 10 mL with a certain amount of PdCl2 (0.001 M) at 25 ̊ C. The Pd NPs, as synthesized under the optimized conditions (10 mL extract + 60 ̊ C + 0.001 M PdCl2), were spherical in shape, small in size, and uniformly distributed, as depicted by HR-TEM images. Results: FTIR, XRD, DLS, and zeta potential further confirmed the formation of Pd NPs. The Pd NPs synthesized at optimized conditions exhibited strong catalytic activity in dye Eosin yellow, Rose Bengal, Tartrazine, and Ponceau S degradation by discoloration of dyes in 3 hrs. The removal of all dyes by the Pd NPs was optimized by varying specific operating parameters, such as initial dye concentration, solution pH, irradiation time, and temperature. Conclusion: This high activity of Pd NPs may be due to their small size, high dispersion, and surface- capping phytochemicals. result: Bio-fabrication of metallic Pd NPs using different plant extracts compared to other reducing agents is more scalable, rapid, and cost-effective for generating bulk nanoparticles. The phytochemical principles, such as phytoconstituents, reduce the PdCl2 to Pd NPs and are implicated in the capping and stability of the nanoparticles. Hence, the leaves of Eclipta alba have different polyols and are well known. Apart from this, hydroxyl groups in phenolic compounds may participate in the bio-reduction of PdCl2. Such compounds can chelate metal ions to form their quinones form, which is an intermediate palladium complex. Then, stabilization of the intermediate form and reduction of Pd2+ to Pd0 occurred due to free electrons or nascent hydrogen produced during the bio-reduction reaction. Finally, Pd-NPs were prepared due to the collision of neighboring Pd0 atoms. These significant conjugations exist in the keto-enol system within the quinone form of the compound.