Spherical Morphology Research Articles

Small Organic Molecule‐Assisted Mesoscopic Self‐Assembly of SnO2 Nanoparticles: An Efficient Catalyst for the Synthesis of β‐Nitroaldol

AbstractOver the past few decades, huge number of mesoporous materials have been synthesized by using supramolecular assembly of ionic/non‐ionic surfactants as structure‐directing agents (SDAs). Here, we report a facile synthetic strategy to fabricate self‐assembled SnO2 nanoparticles with well‐defined nanocrystalline spherical morphology and mesoporosity using sodium salicylate as a SDA and stabilizing agent. The mesophases of the materials were investigated by powder X‐ray diffraction, TEM and N2 sorption studies. TEM results show that the mesopores are formed by the assembly of ultrasmall SnO2 NPs with broad range of interparticle voids and N2 sorption studies agreed well with this TEM data. This synthesis strategy facilitated the generation of SnO2 NPs with increased surface area and pores of nanoscale dimensions with a large number of exposed surface‐active sites. The photoinduced electron transfer in these materials was investigated by the fluorescence quenching study with pyranine, which suggested the presence of surface Lewis basicity. The materials showed excellent catalytic activity for the synthesis of β‐nitroaldol through the reaction of benzaldehyde and nitromethane. The heterogeneous nature of the catalyst could be attributed to the high surface area, presence of numerous surface active sites, and structural robustness of the self‐assembled SnO2 nanostructure. The catalysts exhibited negligible loss in activity after several catalytic cycles.

Green synthesis of almond peel-mediated lignin nanoparticles as a potential photocatalytic agent with cytotoxicity response

In this study, we innovatively explored the utilization of almond peel to synthesize lignin-NPs through a singular and cost-effective hydrothermal process. The research delved into a comprehensive analysis of the structural and optical characteristics of the synthesized lignin-NPs through a suite of techniques including FT-IR, XRD, TEM, EDX/FESEM, UV–Vis, and Photoluminescence (PL). UV–Vis spectra showed the maximum wavelength at 280 nm, confirming the NPs’ synthesis. According to PL spectroscopy, lignin-NPs emitted fluorescent light at 551 nm. Also, FTIR and XRD patterns confirmed nanoparticle synthesis with crystallinestructure. The TEM and FESEM images showed spherical morphology with an average size of 9.97 nm. The stability of nanoparticles was assessed utilizing zeta potential analysis (−23 mV) and DLS showing a PDI around 0.2. The cytotoxic effect of lignin-NPs was investigated on Huh-7 and normal L929 cell lines using the MTT assay and the result showed that no significant toxicity was observed on normal L929 cells after 48 h, but IC50 value for cancer Huh-7 cells was about 597.2 µg/mL. A photocatalytic test revealed that lignin-NPs degrade Methylene Blue (90 %, MB), Eriochrome Black T (89 %, EBT), and Rhodamine B (85 %, RhB) pigments under UVA light after 60 min.

Efficient construction of self-assembled starch colloidosomes for controlled-release of pesticides

Biodegradable colloidosomes have attracted increasing attention for their applications to enhance the efficacy and reduce wastage of pesticides in agriculture. In this study, we present a continuous and highly efficient method for production of starch colloidosomes. The starch particles with an average particle size of 230.2 nm and good dispersibility were prepared using surface modification technology, and then used as environment-friendly shell materials to form self-assembled starch colloidosomes using spray drying technology. The influences of inlet temperature, feed rate and air flow rate on the morphologies of colloidosomes were also studied. This strategy enables the construction of starch colloidosomes with uniform spherical morphology and controllable pore sizes under different pH, and can be used for pesticide encapsulation. After loading pyraclostrobin (PYR), the regular spherical colloidosomes not only achieve a small mean diameter of 2.35 µm, but also realize a high encapsulation efficiency of 82 %. The release performance of PYR has an obvious pH response and follows the segmented Ritger-Pepapes model of sustained-release. The colloidosomes were used to prevent the photodegradation of pesticides. The PYR loaded colloidosomes exhibit excellent UV resistance with a retention rate of 72.7 %. In addition, the loading of Fe3O4 nanoparticles and the embedding of carbon dots were also explored.

Exploring the Processing Potential of Polylactic Acid, Polyhydroxyalkanoate, and Poly(butylene succinate-co-adipate) Binary and Ternary Blends.

Biodegradable and bio-based polymers, including polyhydroxyalkanoate (PHA), polylactic acid (PLA), and poly(butylene succinate-co-adipate) (PBSA), stand out as sustainable alternatives to traditional petroleum-based plastics for a wide range of consumer applications. Studying binary and ternary blends is essential to exploring the synergistic combinations and efficiencies of three distinct biopolyesters. A comprehensive evaluation of melt-extruded binary and ternary polymer blends of PHA, PLA, and PBSA was conducted. Scanning electron microscopy (SEM) analyses revealed a heterogeneous morphology characteristic of immiscible blends, with a predominant spherical inclusion morphology observed in the majority of the blends. An increased PBSA concentration led to an elevation in melt viscosity and elasticity across both ternary and binary blends. An increased PHA content reduced the viscosity, along with both storage and loss moduli in the blends. Moreover, a rise in PHA concentration within the blends led to increased crystallinity, albeit with a noticeable reduction in the crystallization temperature of PHA. PLA retained amorphous structure in the blends. The resultant bio-based blends manifested enhanced rheological and calorimetric traits, divergent from their pure polymer counterparts, highlighting the potential for optimizing material properties through strategic formulation adjustments.

Synergistic effects of Co-Mn co-doping on the structural and optical properties of TiO2 nanospheres: Dual functions for DSSC photoanodes and degradation photocatalyst

Synthesizing direct solar irradiance-responsive nanomaterial capable of serving as an efficient photoanode for dye-sensitized solar cells (DSSCs) and active photocatalysts for organic pollutant elimination poses a formidable challenge. This study focused on the synthesis of cobalt and manganese co-doped titanium dioxide (TiO2) nanoparticles via sol-gel technique, enhancing their efficacy in both the DSSCs and methylene blue (MB) dye degradation. X-ray diffraction and Raman analysis confirm the existence of a tetragonal crystal structure with the anatase phase of TiO2, while XPS analysis verifies the successful integration of cobalt and manganese ions into the host lattices. BET analysis has confirmed that Co, Mn co-doped TiO2 exhibits a higher pore volume and specific surface area compared to the undoped TiO2 material. FESEM and HR-TEM reveals spherical shape morphology and EDS mapping confirms the purity of synthesized nanoparticles. Moreover, Co-Mn co-doped TiO2 nanoparticles exhibits a shift in the optical absorption edge towards the visible spectrum in UV-DRS analysis. PL analysis suggests a diminished electron-hole recombination within the doped and co-doped sample. Electrochemical impedance spectroscopy demonstrates improved charge transfer properties. DSSCs employing the co-doped TiO2 exhibit significantly enhanced power conversion efficiency (4.99 %) compared to bare TiO2 (2.03 %), cobalt-doped (2.61 %), and manganese-doped TiO2 (3.97 %). Additionally, it demonstrates exceptional photocatalytic activity, with 87.83 % (Co-Mn co-doped TiO2) degradation efficiency with a lesser time extent for the methylene blue dye degradation. These findings underscore the potential of Co-Mn co-doped TiO2 for addressing dual challenges in renewable energy (DSSC) and environmental remediation (Pollutant removal).

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.

Green Synthesis and Chemical Characterization of Silver Nanoparticles by Tribulus terrestris for the Treatment of Myocardial Infarction.

Silver nanoparticles (AgNPs) are commonly utilized in the medical sector, particularly in cardiovascular applications. Nevertheless, there is a studies scarcity examining the impact of AgNPs on myocardial infarction protection. A green formulation of AgNPs was documented in the research. Different spectroscopic methods were utilized to examine the AgNPs, and their potential for treating myocardial infarction was explored. The NPs exhibited a spherical morphology upon formation. Isoproterenol (85mg/kg) was administered to induce myocardial infarction in mice. The mice were categorized into four distinct groups (n = 15): (1) untreated; (2) normal; (3,4) AgNPs + isoproterenol at various doses (5 and 50µg/kg). The activation of PPAR-Υ/NF-κB and subsequent cytokine release induced by lipopolysaccharide were quantified using real-time PCR and western blot techniques. Subsequent to the administration of AgNPs at different doses, the evaluation of cardiac function was conducted through biochemical, histochemical, and electrocardiogram (ECG) analysis. AgNPs significantly inhibit the levels of myocardial injury markers, reduce the incidence of mortality, and improve the condition of ventricular wall infarction. In addition, the administration of AgNPs effectively prevents the characteristic ST segment depression when compared to animals with myocardial infarction. The positive effects of AgNPs could potentially be attributed to the restoration of normal gene expression in PPAR-Υ/NF-κB/ΙκB-α/ΙΚΚα/β and PPAR-Υ phosphorylation pathways. Additionally, the application of AgNPs led to a reduction in the levels of pro-inflammatory cytokines in the hearts of mice suffering from myocardial infarction. The expression suppression of inflammation cytokines and cell death was significantly reduced by AgNPs. Recent findings suggest that AgNPs possess cardioprotective properties on isoproterenol-induced myocardial infarction, possibly by the inhibition of NF-κB signaling and activation of PPAR-γ. To summarize, the present study introduces a contemporary therapeutic approach for treating myocardial infarction in clinical settings.

Targeted polymeric primaquine nanoparticles: optimization, evaluation, and in-vivo liver uptake for improved malaria treatment

Primaquine (PQ) is a widely used antimalarial drug, but its high dosage requirements can lead to significant tissue damage and adverse gastrointestinal and hematological effects. Recent studies have shown that nanoformulations can enhance the bioavailability of pharmaceuticals, thereby increasing efficacy, reducing dosing frequency, and minimizing toxicity. In this study, PQ-loaded PLGA nanoparticles (PQ-NPs) were prepared using a modified double emulsion solvent evaporation technique (w/o/w). The PQ-NPs exhibited a mean particle size of 228 ± 2.6 nm, a zeta potential of +27.4 mV, and an encapsulation efficiency of 81.3 ± 3.5%. Scanning electron microscopy (SEM) confirmed their spherical morphology, and the in vitro release profile demonstrated continuous drug release over 72 h. Differential scanning calorimetry (DSC) thermograms indicated that the drug was present in the nanoparticles, with improved physical stability. Fourier-transform infrared spectroscopy (FTIR) analysis showed no interactions between the various substances in the NPs. In vivo studies in Swiss albino mice infected with Plasmodium berghei revealed that the nanoformulated PQ was 20% more effective than the standard oral dose. Biodistribution studies indicated that 80% of the NPs accumulated in the liver, highlighting their potential for targeted drug delivery. This research demonstrates the successful development of a nanomedicine delivery system for antimalarial drugs, offering a promising strategy to enhance treatment efficacy while reducing adverse effects.

Hybrid manufacturing process for the synthesis of doped TiO2 nanoparticles and optimization to determine an efficient photocatalyst

The hybrid sol-gel method was used to synthesize the transition metals (Cu and Ag) doped TiO2 nanoparticles for achieving enhanced visible light response photocatalysts. Different characterization techniques such as UV–Visible, FESEM, EDS, and TEM were carried out to characterize prepared nanocomposites. The synthesized Cu/TiO2 and Ag/TiO2 photocatalysts exhibit redshifts with improved light absorption capacity compared with pure TiO2. Scanning electron microscopic images show almost spherical morphology with relatively uniform sizes. Photocatalytic degradation of Methylene Blue (MB) and hydrogen production were carried out to estimate the photocatalytic efficiency of synthesized photocatalysts. As a result of increased charge separation efficiency and higher visible light absorption for photoexcitation, the photocatalytic response of the modified photocatalyst was elevated. In this study, the significant factors like initial pH, nitrate concentration, and dopant were identified. These factors were investigated in terms of hydrogen generation as a response to the successful optimization for the determination of the most efficient photocatalyst. In addition, in this work, density functional theory was used to simulate metals (Cu/Ag) doped TiO2 to learn more about the impact of doping on the structural, electrical, and photocatalytic properties of TiO2. Ag/TiO2 nanocomposite prepared via nitrate precursor concentration of 0.9 M and operated at an initial pH value of 4 exhibits maximum hydrogen generation capacity.

Investigation of the Electrochemical Behavior of CuO-NiO-Co3O4 Nanocomposites for Enhanced Supercapacitor Applications.

In the present study, composites incorporating NiO-Co3O4 (NC) and CuO-NiO-Co3O4 (CNC) as active electrode materials were produced through the hydrothermal method and their performance was investigated systematically. The composition, formation, and nanocomposite structure of the fabricated material were characterized by XRD, FTIR, and UV-Vis. The FE-SEM analysis revealed the presence of rod and spherical mixed morphologies. The prepared NC and CNC samples were utilized as supercapacitor electrodes, demonstrating specific capacitances of 262 Fg-1 at a current density of 1 Ag-1. Interestingly, the CNC composite displayed a notable long-term cyclic stability 84.9%, which was observed even after 5000 charge-discharge cycles. The exceptional electrochemical properties observed can be accredited to the harmonious effects of copper oxide addition, the hollow structure, and various metal oxides. This approach holds promise for the development of supercapacitor electrodes. These findings collectively indicate that the hydrothermally synthesized NC and CNC nanocomposites exhibit potential as high-performance electrodes for supercapacitor applications.

Synthesis of Chi-sphere silver nanocomposite and nanocomposites of silver, gold, and S@G using a chitosan biopolymer extracted from potato peels and their antimicrobial application

Chitin and chitosan have been proven to have numerous applications in biomedical, pharmaceutical, and industrial fields. In the present study, chitin structural polymer was extracted from potato peel wastes by the use of chemical methods and chitosan biopolymer was generated through the deacetylation of the isolated potato peel chitin. On a dry weight basis, the yield of chitin content of the potato peel wastes is 49.80±1.2 % and the yield of deacetylated potato peel chitin (potato peel chitosan) is 47.60±1.8 %. It was characterized by FTIR and 1H NMR studies. Consequently, the potato peel chitosan was employed in the synthesis of Chitosan-Silver-Nanocomposite-Sphere (Chi-SNC-Sphere), and other metal nanocomposite of silver (C.g-CSNCs), gold (C.g-CGNCs), and bimetallic (C.g-CS@GNCs). The physicochemical features of the resulting products were characterized using UV-Vis, FT-IR, PXRD, FESEM, TEM, and EDAX. The FESEM unveiled a smooth, spherical, and nonporous surface morphology of the synthesized Chi-SNCs-Sphere, while the remaining three have surfaces that appeared in the form of flakes. As per TEM images, particles were visible in black-spherical (C.g-CSNC) and black-multi-shapes (C.g-CSNC, C.g-CS@GNC) nanostructures. Their sizes were confined within the range of 1–10 nm, with average values of 4.36 nm±0.40–5.85 nm±0.42. On the basis of BET analysis, C.g.CSNCs C.g-CS@GNC and C.g.CGNCs under identical conditions possess the surface area of 69.92 m2g−1, 52.35 m2g−1, and 49.75 m2g−1 respectively. The nanomaterials were found stable as revealed by the study of zeta potential which is found in the range of +41.3–56.2. The results of the bioassay for antibacterial activity against P. aeruginosa and S. aureus uncovered that the Chi-SNCs-Sphere, C.g-CSNCs, and C.g-CS@GNCs demonstrated superior activities than C.g-CGNCs. According to statistical analysis results of one-way ANOVA of antibacterial results against S. aureus, the P-value F- calculated F-critical was 0.99,1.5 and 3.4 and for P. aeruginosa; P-value, F-calculated, F-critical was 0.80, 0.22 and 5.94 respectively. Minimum inhibitory concentration (MIC) was found most significant for C.g-CSNC (20 µg/mL) due to its higher surface area. These activities could be attributed to the synergistic effect of the metal nanoparticles, potato peel chitosan, and the plant extract that was used for the reduction, stabilization, and biofunctionalization.

Polygonum bistorta Linn. as a green source for synthesis of biocompatible selenium nanoparticles with potent antimicrobial and antioxidant properties.

Here, we report for the first time, green-synthesized selenium nanoparticles (SeNPs) using pharmacologically potent herb of Polygonum bistorta Linn. for multiple biomedical applications. In the study, a facile and an eco-friendly approach is utilized for synthesis of SeNPs using an aqueous roots extract of P. bistorta Linn. followed by extensive characterization via Fourier transform infrared spectroscopy, X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM) and Energy Dispersive X-Ray (EDX) analysis. The XRD and FTIR data determine the phase composition and successful capping of plant extract onto the surface of NPs while SEM and TEM micrographic examination reveals the elliptical and spherical morphology of the particles with a mean size of 69 ± 23nm. After comprehensive characterization, the NPs are investigated for antifungal, antibacterial, antileishmanial, antioxidant, and biocompatibility properties. The study reveals that Polygonum bistorta Linn. synthesized SeNPs exhibit significant antibacterial and antifungal activities with Staphylococcus aureus and Fusarium oxysporum inducing the highest zone of inhibition of 14 ± 1.0mm and 20 ± 1.2mm, respectively at the concentration of 40mg/mL. The NPs are also found to have antiparasitic potential against promastigote and amastigote forms of Leishmania tropica. Furthermore, the NPs are discovered to have excellent potential in neutralizing harmful free radicals thus exhibiting considerable antioxidant potential. Most importantly, Polygonum bistorta Linn. synthesized SeNPs showed substantial compatibility against blood cells in vitro studies, which signifies the nontoxic nature of the NPs. The study thus concludes that medicinally important Polygonum bistorta Linn. roots can be utilized as an eco-friendly, sustainable, and green source for the synthesis of pharmacologically potent selenium nanoparticles.

Multifunctional Nanosystem for Dual Anti-Inflammatory and Antibacterial Photodynamic Therapy in Infectious Diabetic Wounds.

Infectious diabetic wounds present a substantial challenge, characterized by inflammation, infection, and delayed wound healing, leading to elevated morbidity and mortality rates. In this work, we developed a multifunctional lipid nanoemulsion containing quercetin, chlorine e6, and rosemary oil (QCRLNEs) for dual anti-inflammatory and antibacterial photodynamic therapy (APDT) for treating infectious diabetic wounds. The QCRLNEs exhibited spherical morphology with a size of 51 nm with enhanced encapsulation efficiency, skin permeation, and localized delivery at the infected wound site. QCRLNEs with NIR irradiation have shown excellent wound closure and antimicrobial properties in vitro, mitigating the nonselective cytotoxic behavior of PDT. Also, excellent biocompatibility and anti-inflammatory and wound healing responses were observed in zebrafish models. The infected wound healing properties in S. aureus-infected diabetic rat models indicated re-epithelization and collagen deposition with no signs of inflammation. This multifaceted approach using QCRLNEs with NIR irradiation holds great promise for effectively combating oxidative stress and bacterial infections commonly associated with infected diabetic wounds, facilitating enhanced wound healing and improved clinical outcomes.

Highly functionalized pH-triggered supramolecular nanovalve for targeted cancer chemotherapy

Chemotherapeutic drug delivery systems are commonly limited by their short half-lives, poor bioavailability, and unsuccessful targetability. Herein, pH-responsive hybrid NPs consist of benzimidazole-coated mesoporous silica nanoparticles (BZ-MSN) loaded with naturally occurring flavonoid quercetin (QUE-BZ-MSN). The NPs were further capped with beta-cyclodextrin (BCD) to obtain our desired BCD-QUE-BZMSN, with a zeta potential around 7.05 ± 2.37 mV and diameter about 115.2 ± 19.02 nm. The abundance of BZ onto the nanoparticles facilitates targeted quercetin chemotherapy against model lung and liver cancer cell lines. FTIR, EDX, and NMR analyses revealed evidence of possible surface functionalizations. Powder XRD analysis showed that our designed BCD-QUE-BZMSN formulation is amorphous in nature. The UV and SEM showed that our designed BCD-QUE-BZMSN has high drug entrapment efficiency and a nearly spherical morphology. In vitro, drug release assessments show controlled pH-dependent release profiles that could enhance the targeted chemotherapeutic response against mildly acidic regions in cancer cell lines. The obtained BCD-QUE-BZMSN nanovalve achieved significantly higher cytotoxic efficacy as compared to QUE alone, which was evaluated by in vitro cellular uptake against liver and lung cancer cell lines, and the cellular morphological ablation was further confirmed via inverted microscopy. The outcomes of the study imply that our designed BCD-QUE-BZMSN nanovalve is a potential carrier for cancer chemotherapeutics.

CRYSTALLO-CO-AGGLOMERATION OF SIMVASTATIN: IMPROVING DISSOLUTION AND MICROMERITIC PROPERTIES

Simvastatin (SMV), a poorly soluble drug, faces challenges in pharmaceutical formulation due to its limited solubility and poor flow properties. This study aimed to enhance the physicochemical properties of SMV by preparing spherical crystals using a crystallo-co-agglomeration. Spherical crystals of SMV were prepared by dissolving the drug in methanol and adding it to an aqueous solution containing PVP K-30 and PEG 6000 under constant stirring. The resulting agglomerates were filtered, dried, and characterized using Fourier Transform Infrared (FTIR) spectroscopy, Powder X-Ray Diffraction (PXRD), Differential Scanning Calorimetry (DSC), Scanning Electron Microscopy (SEM), and dissolution testing. Micromeritic properties, including bulk density, Hausner ratio, compressibility index, angle of repose, and flowability, were also evaluated. FTIR confirmed the chemical integrity of SMV with minor shifts indicating interactions with stabilizers. PXRD and DSC analyses revealed reduced crystallinity and partial amorphization in the spherical crystals. SEM showed spherical morphology. Dissolution testing demonstrated a significantly enhanced dissolution rate for the spherical crystals compared to pure SMV. Improved micromeritic properties were also observed, indicating better flowability and packing density. Spherical crystallization significantly improved the solubility, dissolution rate, and flowability of SMV. This technique offers a promising strategy for enhancing the bioavailability and pharmaceutical performance of poorly soluble drugs.

Jeffamine-based diblock copolymer nanoparticles via reverse sequence polymerization-induced self-assembly in aqueous media

Jeffamines® are commercially available amine-capped poly (alkylene oxides) that have been used for various applications. In this study, a weakly hydrophobic monoamine-capped propylene oxide-rich Jeffamine® (M2005) is derivatized to introduce a trithiocarbonate end-group via amidation. This precursor is then dissolved using N,N′-dimethylacrylamide (DMAC), 2-(N-acryloyloxy)ethyl pyrrolidone (NAEP) or N-acryloylmorpholine (NAM) as a co-solvent to produce a concentrated aqueous reaction mixture containing 20 % w/w water. Subsequently, reversible addition-fragmentation chain transfer (RAFT) polymerization is used to prepare Jeffamine®-core diblock copolymer nanoparticles by reverse sequence polymerization-induced self-assembly (PISA). At intermediate conversion, additional degassed water is added and each polymerization continues to almost full conversion (>99 %) within 4 h at 60 °C, resulting in a 10–20 % w/w aqueous dispersion of sterically-stabilized Jeffamine®-core nanoparticles. Efficient chain extension of the Jeffamine® precursor is achieved in most cases and relatively narrow molecular weight distributions are obtained (Mw/Mn < 1.30) as judged by GPC analysis. Transmission electron microscopy studies confirm a polydisperse spherical morphology and dynamic light scattering studies report hydrodynamic diameters ranging from 145 to 312 nm. Finally, aqueous electrophoresis studies indicate essentially neutral nanoparticles over a wide range of solution pH, as expected for the three types of non-ionic steric stabilizer chains selected for this study.

Determination of Antioxidant, Cytotoxicity, and Anti-human Lung Cancer Properties of Silver Nanoparticles Green-Formulated by Foeniculum vulgare Extract Combined with Radiotherapy.

The current investigation involved the silver nanoparticles green synthesis utilizing the aqueous extract derived from the Foeniculum vulgare leaves (AgNPs@FV). The effectiveness of these newly developed nanoparticles in conjunction with radiotherapy was evaluated on lung cancer cells. The synthesized AgNPs@FV underwent characterization through various analytical techniques such as energy dispersive X-ray (EDX), field emission-scanning electron microscopy (FE-SEM), X-ray diffraction (XRD), and ultraviolet-visible (UV-Vis) spectrophotometry. The efficacy of AgNPs@FV in conjunction with radiotherapy against human lung cancer was assessed through the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-2H-tetrazolium bromide (MTT) assay. The AgNPs@FV exhibited a spherical morphology ranging in size from 10.16 to 42.74 nm. The EDX diagram of nanoparticles shows energy signals at 3.02 and 2.64 keV, which are attributed to Ag Lβ and Ag Lα, respectively. During the antioxidant evaluation, AgNPs@FV and butylated hydroxytoluene (BHT) displayed IC50 values of 166 and 59 µg/mL, respectively. The cells treated with AgNPs@FV in conjunction with radiotherapy were evaluated using the MTT assay over 48h to determine cytotoxicity and anti-human lung cancer characteristics on normal (human umbilical vein endothelial cell (HUVEC)) and lung cancer cells and exhibited IC50 values of 211, 166, and 296µg/mL against NCI-H2126, NCI-H1299, and NCI-H1437, respectively. Furthermore, the malignant lung cell viability decreased when treated with a combination of AgNPs@FV and radiotherapy. Based on the aforementioned findings, it is possible that the newly developed AgNPs@FV could serve as a novel chemotherapeutic medication or adjunct for addressing lung cancer following the completion of clinical trials involving human subjects.

Extracellular vesicle-based formulation of doxorubicin: drug loading optimization, characterization, and cytotoxicity evaluation in tumor spheroids

Doxorubicin (DOX) is a chemotherapeutic with considerable efficacy, but its application is limited due to cardiotoxicity. Nanoparticles can improve DOX efficacy and prevent its adverse effects. Herein, DOX-loaded extracellular vesicles (DOX-EVs) were prepared using different loading methods including incubation, electroporation, and sonication in different hydration buffers to permeabilize nanostructures or desalinize DOX for improved entrapment. Different protein:drug (µg:µg) ratios of 1:10, 1:5, and 1:2, and incubation parameters were also investigated. The optimal formulation was characterized by western blotting, electron microscopy, Zetasizer, infrared spectroscopy, and release study. The cellular uptake and efficacy were investigated in MCF-7 spheroids via MTS assay, spheroid formation assay (SFA), confocal microscopy, and flow cytometry. The percentage of entrapment efficiency (EE) of formulations was improved from 1.0 ± 0.1 to 22.0 ± 1.4 using a protein:drug ratio of 1:2 and sonication in Tween 80 (0.1%w/v) containing buffer. Characterization studies verified the vesicles’ identity, spherical morphology, and controlled drug release properties. Cellular studies revealed the accumulation and cytotoxicity of DOX-EVs in the spheroids, and SFA and confocal microscopy confirmed the efficacy and cellular localization. Flow cytometry results revealed a comparable and amplified efficacy for DOX-EV formulations with different cell origins. Overall, the EV formulation of DOX can be applied as a promising alternative with potential advantages.

Biocompatibility and potential anticancer activity of gadolinium oxide (Gd2O3) nanoparticles against nasal squamous cell carcinoma

Chemotherapy as a cornerstone of cancer treatment is slowly being edged aside owing to its severe side effects and systemic toxicity. In this case, nanomedicine has emerged as an effective tool to address these drawbacks. Herein, a biocompatible carrier based on bovine serum albumin (BSA) coated gadolinium oxide nanoparticles (Gd2O3@BSA) was fabricated for curcumin (CUR) delivery and its physicochemical features along with its potential anticancer activity against nasal squamous cell carcinoma were also investigated. It was found that the fabricated Gd2O3@BSA containing CUR (Gd2O3@BSA-CUR) had spherical morphology with hydrodynamic size of nearly 26 nm, zeta-potential of -36 mV and high drug (CUR) loading capacity. Drug release profile disclosed that the release of CUR from the prepared Gd2O3@BSA-CUR nanoparticles occurred in a sustained- and pH-dependent manner. Also, in vitro cytotoxicity analysis revealed that the fabricated Gd2O3@BSA nanoparticles possessed excellent biosafety toward HFF2 normal cells, while Gd2O3@BSA-CUR appeared to display the greatest anticancer potential against RPMI 2650 and CNE-1 cancer cell lines. The results also show that the Gd2O3@BSA nanoparticles were compatible with the blood cells with minor hemolytic effect (< 3%). The manufactured NPs were found to be completely safe for biological applications in an in vivo subacute toxicity study. Taken together, these finding substantiate the potential anticancer activity of Gd2O3@BSA-CUR nanoparticles against nasal squamous cell carcinoma, but the results obtained demand further studies to assess their full potential.

Synergistically enhanced electromagnetic absorption in barium ferrite/hollow carbon spheres/epoxy composites

The ongoing technological advancements have emphasized the importance of absorbent coatings, which are essential for effectively absorbing electromagnetic waves across various industries, including electronics, healthcare, and security systems. In this research, barium ferrite particles and hollow spherical carbon particles have been synthesized to investigate the synergistic effect of different compounds in absorbing electromagnetic waves in the epoxy coating. The barium ferrite particles were synthesized in two distinctive rod and spherical morphologies at 600 and 900 °C, employing the sol-gel technique. Also, hollow spherical carbon particles were synthesized. Synthesized particles were analyzed structurally and chemically with an X-ray Powder Diffraction, Fourier infrared spectrometer, vibrating‐sample magnetometer, field emission Scanning Electron, and Raman spectroscopy.The absorption characteristics of a coating that contains rod and spherical morphologies of barium ferrite and hollow spherical carbon particles can be adjusted by controlling the amounts of synthetic compounds in the 8–12 GHz range. The results indicate that combining rod-shaped barium ferrite particles (900 °C) and hollow spherical carbon particles in a thin epoxy coating improves impedance matching and wave attenuation. Notably, when the epoxy coating is 1.5–2 mm thick and contains 20 % rod-shaped barium ferrite particles (900 °C) and 1 % hollow spherical carbon particles, reflection loss values of < -20 dB are observed at frequencies of 10–12 GHz.