FTIR Studies Research Articles

Enhanced electrochemical properties of MnFe2O4/reduced graphene oxide nanocomposite with a potential for supercapacitor application

A single-step solvothermal method has been employed to synthesize MnFe2O4 composite nanoparticles where graphene sheets were incorporated into spherical MnFe2O4 nanoparticles of size ∼57 nm. The synthesized MnFe2O4/reduced graphene oxide (rGO) composite exhibits enhanced electrochemical properties due to its improved porosity, surface area, and conductivity. FTIR, Raman, and XPS studies confirmed the effective reduction of GO and the successful formation of MnFe2O4/rGO composite. When employed as an electrochemical cell electrode, the MnFe2O4/rGO composite showed an enhanced specific capacitance of 253 F g−1, as opposed to 133 F g−1 for the bare nanoparticles. The composite attains significantly improved energy density of 76.06 Wh kg−1 and power density of 7.49 kW kg−1 at current density of 10 A g−1. The unification of 2D graphene and MnFe2O4 nanoparticles yields enhanced electrochemical performance and an outstanding 96 % cyclic stability (after 5000 cycles), which offers a viable approach for developing better supercapacitor electrode materials in the future.

A QbD-Navigated Approach to the Development and Evaluation of Etodolac-Phospholipid Complex Containing Polymeric Films for Improved Anti-Inflammatory Effect.

The current study focuses on development of phospholipid complex-loaded films of etodolac for enhanced transdermal permeation and anti-inflammatory effect. An etodolac-phospholipid complex was developed using the solvent evaporation method and was characterized by DSC, XRD, FTIR, and 1H-NMR studies. The formation of the complex led to conversion of a crystalline drug to an amorphous form. A stoichiometric ratio of 1:1 (drug-phospholipid) was selected as the optimized ratio. Further, the developed complex was incorporated into films and systematic optimization using a central composite design was carried out using a response surface methodological approach. The desirable design space based on minimum contact angle and maximum tensile strength was selected, while the water vapour transmission rate and swelling index were set within limits. The results for swelling index, contact angle, tensile strength, and water vapour transmission rate were 60.14 ± 1.01%, 31.6 ± 0.03, 2.44 ± 0.39 kg/cm2, and 15.38 g/hm2, respectively. These values exhibited a good correlation with the model-predicted values. The optimized formulation exhibited improved diffusion and permeation across skin. In vivo studies revealed enhanced anti-inflammatory potential of the developed films in comparison to the un-complexed drug. Hence, the study demonstrated that etodolac-phospholipid complex-loaded films improve the transdermal permeation and provided enhanced anti-inflammatory effect.

Novel facile fabrication of a label-free femto-molar serotonin electrochemical biosensor based on functional MoS2 nano flakes

Our bodies contain a neurotransmitter called serotonin, which regulates several activities connected to our temporary state of mind or temper. Serious disorders linked to mood disorders, anxiety, and depression are diagnosed due to serotonin disturbance. If diagnosed early, serotonin fluctuations could be controlled through proper medication. We present the electrochemical detection of serotonin molecules at the femtomolar level using carboxylate molybdenum disulfide (MoS2-COOH) functionalized on the gold electrode surface. X-ray diffraction spectroscopy explores the synthesized MoS2-COOH conjugates structural properties, and their functional behavior is confirmed by FT-IR study. The square wave voltammetry confirmed that the carboxylated MoS2 nanocomposite-modified electrode offered excellent electrocatalytic activity towards serotonin oxidation. The sensor excels in sensing serotonin over a wide dynamic range from 1 µM to 1 fM, with a limit of detection of 12.038 fM, excellent reproducibility, and high selectivity towards serotonin in interfering medium containing dopamine. This sensitive, selective, and cost-effective electrochemical sensor shows significant potential in direct serotonin analysis for clinical applications.

Highly saturated red-emitting novel europium doped yttrium calcium borate (Eu3+: Y2CaB10O19) phosphor materials for eco-friendly solid-state lighting applications

Optical parameters like low correlated color temperature (CCT), color rendering index (CRI), color purity, thermal stability and etc. are crucial parameters for the practical applications of white light emitting diode applications. High color purity around 100 % red emitting novel europium doped yttrium calcium borate (Eu3+: Y2CaB10O19) phosphors were harvested by conventional solid-state synthesis technique. The novel host material possesses monoclinic crystal structure with no observable shift in the diffraction lines with varying dopant concentrations. FTIR studies revealed the presence of BO3 and BO4 networks in the host lattice responsible for structural rigidity and good thermal stability. The phosphor materials synthesized xEu3+: Y2CaB10O19 (x = 0.01, 0.03, 0.05, 0.07 and 0.09), are sensitive to both 250 nm (UV) and 393 nm (Near UV/blue LED) for excitation that can produce deep orange (594 nm) emission along with red emission (612 nm). The optimum Eu3+ ion concentration was fixed at 5 mol% of dopant ions to prevent the concentration quenching. As prepared optimal phosphor material possesses high color purity around 100 %, CCT of 1214 K defines its applicability in WLED applications. The synthesized phosphor materials pertain excellent switching response, thermal stability and the fabricated P-i-G possesses desired photometric parameters for its practical applications.

An alternative approach in the synthesis of strontium-hydroxyapatite and strontium hydroxyapatite embedded in graphitic carbon nitride nanocomposites for potential tissue engineering applications

Sr-hydroxyapatite has drawn much attention with promising applications in biomedical engineering especially in drug delivery and tissue repair. A novel protocol for the preparation of Strontium hydroxyapatite (Sr-HAP) and Strontium hydroxyapatite encapsulated by graphitic carbon nitride (Sr-HAP@gCN) with high purity and better homogeneity was adopted for potential use in orthopaedic surgeries. The physiological pathway of Strontium and calcium inside humans follow the same trend leading to the mineral deposition of the bone. In the present study, a novel attempt in synthesizing Sr-HAP and Sr-HAP@gCN by the hydrothermal method is proposed for obtaining an ideal biomaterial with potential biocompatibility and pharmacological activity. Phase identification by X-ray diffraction (XRD), Fourier transform Infra-Red spectroscopic analysis (FTIR), Electron & atomic force microscopic studies, Thermogravimetric and Raman spectroscopic analysis was performed on the prepared Sr-HAP and Sr-HAP@gCN to characterize the incorporation efficiency of Strontium. Resazurin microtiter assay and MTT assay were used to evaluate antimicrobial susceptibility and biocompatibility. The typical crystal phase of Sr-HAP and a phase change in Sr-HAP@gCN have been demonstrated with special reference to the interfacial connection between gCN and Sr-HAP through FT-IR studies. Raman spectroscopy revealed the archetypal signature of symmetric and asymmetric PO vibrations pertaining to linearity change with the addition of Strontium. The biological effect of Sr-HAP and Sr-HAP@gCN was quite significant in inducing mineralization when kept immersed in simulated body fluid (SBF) for 21 days. Promising results pertaining to antimicrobial susceptibility and biocompatibility have been proved as an encouraging choice for drug delivery applications and bone filling applications.

Mechanistic studies on bioremediation of dye using Aeromonas veronii immobilized peanut shell biochar

Recalcitrant chemicals in the environment not only present obstacles to living organisms but also contribute to the degradation of natural resources. One contribution to environmental pollution is the discharge of synthetic dyes from the textile sector. This study investigates the combined effect of microbial cells and biochar on eliminating methyl orange (MO) dye. The immobilization of Aeromonas veronii on peanut shell biochar (APSB) was conducted to investigate its efficacy in removing MO dye from water. PSB synthesized by pyrolysis at 300 °C for 120 min showed maximum bacterial immobilization potential. The highest degradation rate of 96.19 % was achieved in APSB within 96 h using MO dye concentration of 100 mg L−1, incubation temperature of 37 °C, pH 7, and biocatalyst dosage of 1g L−1. In comparison, free cells achieved degradation rates of 72.53 % and 61.56 % for PSB. Moreover, the adsorption process was primarily controlled by PSB, with subsequent dye mineralization by A. veronii, as supported by FTIR and LC-MS studies. Moreover, this innovative approach exhibited the reusability of the biocatalyst, giving 76.23 % removal after fifth cycle, suggesting sustainable alternative in dye remediation and potential option for real-time applications.

Exploring the synergistic effect in polyherbal chewable antacid tablets: formulation and evaluation study

Abstract Polyherbal chewable tablets of Phyllanthus emblica and Glycyrrhiza glabra were developed with the objective to formulate an effective, safe and convenient dosage form for acid-related disorders. A standard calibration curve was constructed for Polyherbal extracts through UV-Spectrophotometry, achieving an absorbance maximum at 275 nm. Compatibility between the drug and excipients was examined through FTIR studies. Various pre-compression parameters, like bulk density, tapped density, compressibility index, Hausner’s ratio and angle of repose, were assessed for the powder blend. The tablets were evaluated for post-compression parameters, such as thickness, hardness, friability, and weight variation and disintegration time. The drug release study was conducted in vitro. The acid-neutralizing capacity of the formulated batches was compared with marketed formulations. The calibration curve showed a high correlation coefficient (r2=0.9972), suggesting accuracy and reliability. FTIR analysis confirmed the compatibility between the drug and excipients. Pre-compression studies revealed an acceptable range for all parameters, indicating good flow properties. For instance, Carr’s Index for all batches varied from 14.31% to 24.41%, and the angle of repose ranged from 33.7 to 35.21 degrees. Post-compression parameters were within the standard limits with hardness between 4.9 to 6.1 kg/cm2 and friability less than 1% for all batches. In vitro drug release showed a gradual increase over time with PF9 achieving 98.63% release at 60 min. The acid-neutralization capacity was highest for the combined extract at 27.83±0.34 mEq/g and PF9 batch at 28.12±0.43 mEq/g, demonstrating their effectiveness in neutralizing acid. The study successfully formulated a Polyherbal chewable tablet with optimized pre and post-compression parameters. The tablet exhibited promising in vitro drug release and an efficient acid-neutralizing capacity. It holds potential as an effective treatment option for acid-related disorders.

Graphene Oxide Decorated with Nickel Cobaltite Nanoparticles as an Adsorbent for Cationic Methyl Green Dye: Kinetic, Isotherm, and Thermodynamic Studies

‎تم في هذه الدراسة ، تزيين ‏رقائق أكسيد الجرافين (‏GO‏) بجسيمات ‏كوبلتيت النيكل النانوية ‏NiCo2O4‎‏(‏NC‏) عن طريق الترسيب في ‏الموقع ، وتم استخدام المتراكب ‏المحضر (‏NC: GO‏) كسطح ماز لإزالة ‏صبغة الميثيل الخضراء ( ‏MG‏) من ‏المحاليل المائية. تم التحقق من ‏التغطية الناجحة لأوكسيد الجرافين ‏بجزيئات كوبلتيت النيكل النانوية ‏‏(‏NC‏) باستخدام دراسات ‏FT-IR‏ وحيود ‏الأشعة السينية (‏XRD‏). كانت أحجام ‏الجسيمات البلورية لل ‏NC‏ و ‏ لل ‏GO‏ المزين ب NCهي ‏‎10.53‎‏ نانوميتر ‏‏9.30 نانومتر على التوالي. تم دراسة ‏تأثير العديد من العوامل التجريبية ‏، بما في ذلك زمن التلامس ، وكمية ‏السطح الماز ، ودرجة الحرارة. كان ‏وقت التلامس الأمثل وكمية السطح 120 ‏دقيقة و 3 مجم / لتر على التوالي. ‏تتلائم بيانات الامتزاز بشكل أفضل مع ‏ايزوثيرم ‏Freundlich‏. تم استخدام ‏أربعة نماذج حركية لتتبع عملية ‏الامتزاز: معادلة زائفة من الدرجة ‏الأولى ، ومعادلة زائفة من الدرجة ‏الثانية ، ومعادلة الانتشار داخل ‏الجسيمات ، ومعادلة بويد. أظهرت ‏نمذجة البيانات التجريبية أن حركية ‏الامتزاز كانت ممثلة بشكل جيد ‏بنموذج الرتبة الثانية الزائفة (‏R2 ‎‎= 0.9945‎‏) مع معدل ثابت سرعة يبلغ 3.2 ‏‏× 10 - 3 (جم / مجم. دقيقة). يتم ‏امتصاص صبغة ‏MG‏ تدريجيًا بواسطة ‏الجسيمات النانوية ‏NC‏ من خلال ‏الانتشار داخل الجسيمات ويتم ‏الاحتفاظ بها بعد ذلك في مسام أصغر. ‏أظهرت قيم التحليل الديناميكي ‏الحراري أن عملية امتزاز صبغة ‏MG‏ ‏كانت ماصة للحرارة بطبيعتها ، و ‏تلقائية وعملية الامتزاز فيزيائية. الكلمات المفتاحية: الانتشار داخل الجسيمات ، المسافات البينية، النموذج الزائف من الدرجة الأولى ، معادلة بويد

Formulation Design and Characterization of Nilotinib Polymeric Nanoparticles by Nanoprecipitation Technique for the Improved Drug Solubility and Dissolution Rate

Introduction: Nilotinib is a BCS class-IV poorly water-soluble kinase inhibitor drug, that was used for this study to prepare the polymeric nanoparticles by nanoprecipitation technique using Eudragit RL-100 and RS-100 as polymers, Killophore P-188 as a surfactant, and PEG 400 used as a non-volatile, and nontoxic solvent for the improvement of the drug solubility and dissolution rate. Method: The initial process and formulation variables are screened out based on the selected critical quality attributes such as drug release (%), particle size (nm), zeta potential (mV), and polydispersity index. The FT-IR and DSC studies reveal that the drug has no compatibility between the selected drug and the polymers and does not show any additional drug peaks after physical mixing and formulations. The prepared nanoparticles were further characterized to evaluate the particle size (nm), polydispersity index (PDI), zeta potential (mV), entrapment efficiency (%), and in-vitro drug release (%). From the in vitro drug release study, Eudragit RL-100 and Killophore P-188-based formulations showed optimum drug entrapment efficiency with improved drug solubility and dissolution rate in PEG 400 compared to Eudragit RS-100-based formulations. The accelerated stability data for the optimized formulation batch (F6) before and after storage conditions at 40±2 0C and 75±5% RH indicates that the optimized formulation (F6) is more stable for up to 6 months without changes in drug entrapment efficiency and in vitro dissolution rate. Dissolution kinetic data and diffusion exponent values suggested that optimized formulation followed the Higuchi model with a non-Fickian transport mechanism. Result: According to the results, the preparation method proposed in this study is the most suitable for generating polymeric nanoparticles of nilotinib for improved drug solubility and dissolution rate. Conclusion: The nilotinib-based polymeric nano-formulation proved a potential alternative for better drug release with an enhanced solubility rate.

Preparation and characterization of novel polyols-based DESs and their use in efficient sequestration of radioactive iodine

The utilization of Novel DESs can be greener alternative to traditional organic solvents. In present study, four polyols-based DESs are synthesized and characterized by several techniques. The prepared DESs are used for the efficient capture of hazardous iodine. In present study by simple combination of two readily accessible, economical, and biodegradable components four polyols-based DESs have been prepared. For the creation of these DESs, a hydrogen bond donors (HBDs) (polyols) and hydrogen bond acceptors (HBAs) (BTEAC) are used, which havemelting points far lower than their respective melting points. The developed DESs were investigated for their physicochemical properties such as density, dynamic viscosity. Our results revealed distinct trends in these properties across different DES compositions, highlighting unique molecular interactions and solvation capabilities. The FTIR and NMR characterization study indicated considerable intermolecular interaction between the various component of the DES system. Further, Kamlet-Taft solvatochromic parameters were determined using Nile red dye, and other solvatochromic dyes. For synthesized DESs, the solvatochromic parameters ENT, normalized polarity parameter, π*, polarity / polarizability; β, hydrogen-bond acceptor basicity and α, hydrogen-bond donor acidity, have been determined. The ENT parameters demonstrate that both non-specific and specific interactions play a significant role in solute–solvent interactions. The synthesized DESs have been utilized for the efficient capture of the iodine. The removal efficiency of DES depends upon the mass of the DESs taken and time duration. These findings deepen our understanding of DES behavior and underscore their versatility in diverse industrial and scientific applications.

Synthesis, nonlinear optical activity, solvents effect, β-cyclodextrin effect, and cytotoxic activity on skin fibroblast and breast cancer cell lines of a new chalcone derivative of nabumetone

The use of small organic molecules, such as chalcones, for efficient applications as organic luminescent materials has attracted increasing attention owing to their interesting optical, photophysical, and biological properties. In this study, a new chalcone, 1-(4-isopropylphenyl)-5-(6-methoxynaphthalen-2-yl)pent-1-en-3-one (INM), was synthesized via base condensation between nabumetone and cuminaldehyde. INM was subsequently identified and characterized by FT-IR, NMR spectroscopy (1H and 13C), mass spectrometry, elemental analysis, X-ray diffraction, thermogravimetric analysis, and FESEM studies. Investigation of the solvent effect revealed that the π → π* transition involved a bathochromic shift from hexane to water and a large Stokes-shifted, twisted intramolecular charge-transfer emission in water. Diffuse reflectance spectral studies confirmed the formation of transparent INM chalcones with excellent crystallinity, and photoluminescence studies substantiated the low recombination rate of electrons and holes. Tauc plot analysis with the Kubelka–Munk algorithm revealed higher direct (3.57 eV) and indirect (3.41 eV) bandgap energies of INM. Density functional theory calculations at B3LYP/6-31G(d,p) revealed that INM had promising nonlinear optical activity (β ≈ 30.504 × 10−30 compared to a reference material, urea. Cell biocompatibility was evaluated after culturing skin fibroblasts and breast cancer cells with INM using the MTT assay and fluorescence microscopy of the live/dead cell assay. It was observed that INM exhibited good NIH/3T3 cell adhesion and proliferation and the weak inhibiting ability of MDA-MB231.

Synthesis, photoluminescence, Judd-Ofelt parameters, and high energy neutron/charged particle transmission efficiencies of Nd3+ ion-activated sodium-borate glasses

Sodium borate glasses doped with Nd3+ ions and having the molar formulations 75B2O3 – 15Na2O – 9.5x – 0.5Nd2O3, where x = Bi2O3; SrO and Li2O were prepared by employing the melt quenching technique. The glasses were coded as BiNd, SrNd, and LiNd for x = Bi2O3; SrO and Li2O, respectively. The prepared glasses were characterized for their physical and optical attributes. The influence of the glass composition on the photoluminescence and fast neutron (FN) and charged radiation (CR) transmission efficiencies were also investigated. The density of BiNd, SrNd, and LiNd is 3.32, 2.43, and 3.32 g/cm3, respectively. Optical constants of the glasses showed variations with glass composition. The FTIR study of the glass also revealed the structure of the glasses. The BiNd glass has the most intense PL of all the samples, followed by SrNd glass, while LiNd had the weakest PL emission. The value of for BiNd, SiNd, and LiNd is 0.1029 cm-1, 0.1009 cm-1, and 0.0987 cm-1, respectively. The projected ranges of electrons, protons, helium ions, and carbon ions were generally lower for denser XNd glass. The XNd glasses are potentially useful of optical, shielding and dosimetry applications.

Design, development, and optimization of sumatriptan loaded ethosomal intra-nasal nanogel for brain targeting

Background: Sumatriptan is one of the most essential drugs for treating migraine. However, dosage-related side effects are still a worry despite its 14 % oral bioavailability and recurrence of migraine-associated diseases. Methodology: The fundamental focus of the study is to develop the sumatriptan intra-nasal nano-ethsomal gel by film hydration technique with the aid of QbD principles that govern the varied compositions and blends of polymers like HPMC K100M and Phospolipon 90G to develop a sustained release dosage form. Results and discussion: The preliminary FT-IR and DSC studies revealed no interactions between the drug and their physical mixtures. The present study considered three observable responses: vesicle size, zeta potential, and percent drug release after 24 h, taken into consideration during the optimization of the ethosomal formulations utilizing 32 central composite designs (CCD). The vesicle size (122.23 nm), zeta potential (-40.2 mV), and drug release percentage (92.61 %) for all formulations were seen in the F12 batch after 24h. The p-XRD and SEM studies indicated that the nano-ethosomal gel was stable. The stability studies indicated the preparation of a more stable formulation for the parameters under the study protocol. Conclusion: Using a novel intra-nasal brain targeting approach by adapting the film hydration technique, the current issues might be addressed, and the drug's duration of residence at the absorption site uptake substantially increase. To efficiently modify the drug's residence through the intra-nasal route, this work focuses on developing a nano-ethosomal gel loaded with sumatriptan.

The Viability of Emerging Public and Private Generic Drug Infrastructure in India: An in-vitro Case Study Using Statins as Model Drug

The healthcare system has been fundamentally altered by the introduction of generic medications, and their market share continues to rise because these are genuine, dependable, secure, affordable, and accessible to all the needy and poor in society. In this regard, the generic drug industry, which strives for authenticity, affordability, and accessibility, plays a significant role. Using HMG CoA reductase inhibitors (Atorvastatin and Rosuvastatin) as model drugs, the study aimed to determine the viability of the emerging public and private generic drug infrastructure in India, which included Janaushadhi, Dava India, and other assorted companies. The organoleptic properties and official and non-official quality control tests were evaluated. According to the in-vitro dissolution profiles, the Mankind brand of atorvastatin has shown the highest dissolution profile (75.29%), and the Dava India brand of rosuvastatin has the maximum drug release (97.26%) in one hour release. The Peppas model best explained the drug release model, which inferred the release profile to be diffusion-specific. The compatibility analysis of the tablet formulation has been shown through FTIR studies. These results concluded that public generic drugs are as effective as private generic drugs, and patients can easily take the cost-effective brand of medication.

Green Synthesis, Spectroscopic, Electrochemical and Antifungal Characteristics of Ni-doped CeO2 Nanoparticles

This study intended to synthesize Nickel-doped Cerium oxide (Ni-CeO2 NPs) nanoparticles using Pedalium Murex leaf extract. X-ray diffraction (XRD) was used to investigate the structure of the Ni-CeO2 NPs. The XRD measurements showed that the Ni-CeO2 NPs crystallized into the face-centered cubic system. The Ni(1%)-CeO2 and Ni(3%)-CeO2 NP’s crystallite sizes were between 47[Formula: see text]nm and 59[Formula: see text]nm. FTIR and Raman spectral studies were conducted to investigate the sample’s atomic vibrations and chemical bonding. Energy-dispersive X-ray study and field-emission scanning electron microscopy were performed to examine the surface texture and chemical assembly of the Ni-CeO2 NPs. UV–Vis DRS spectrum study was performed to ascertain the reflectance characteristics and bandgap of Ni-CeO2 NPs. The Ni(1%)-CeO2 and Ni(3%)-CeO2 NPs were found to have bandgaps of 2.73[Formula: see text]eV and 2.82[Formula: see text]eV, respectively. Electrochemical impedance spectroscopy and cyclic voltammetry were employed to explore the electrochemical nature of Ni-CeO2 NPs and their capacitive properties at various scanning rates. Using the agar well-diffusion technique, the antifungal activities of Ni-CeO2 NPs were assessed. The experimental findings illustrate the utility of Ni-CeO2 NPs for supercapacitor electrode material and healthcare applications.

Adding mineral-enriched biochar to the rhizosphere reduces heavy metal toxicity on plants and soil microbes

In this study, a mineral-enriched (Ca and P) bagasse biochar was synthesized and characterized. The formulation of Ca and P-enriched bagasse biochar (CPB) was examined for immobilizing arsenic (As), cadmium (Cd), and lead (Pb) in rhizospheric soil. The potential of CPB to alleviate heavy metal stress on plants and soil microbial communities was also investigated. The Ca and P-enriched bagasse biochar demonstrated loading of 88 % Ca and 86 % P with improved pore volume, cation exchange capacity, and water-holding capacity. The FTIR and morphology studies demonstrated an increase in surface functionalities on biochar surface and porous morphology. CPB had 1089±21 µm particle size, 1.1 µm pore size, 0.35±0.01 mv PDI, and 20.8±0.2 mv zeta potential, and displayed no phytotoxicity. The application of the CPB in the soil significantly reduced the availability of As, Cd, and Pb in the soil and their uptake in A. paniculata. CPB application altered the subcellular distribution of As, Cd, and Pb in plant tissues. The CPB spray significantly enhanced the biomass (16–27 %), protein (8–44 %), and chlorophyll (15–61 %) contents of A. paniculata. The application of CPB in metal-contaminated soil resulted in an increased relative abundance of the phylum Proteobacteria and the genera Bacillus, Gemmata, and Sphingobium in the microbial community structure of the rhizospheric soil. The study suggested that CPB formulation can be used as a potential solution to alleviate different metal uptake and toxicity of crops planted in contaminated soil, improve rhizospheric soil quality, and reconstruct the microbial community structure.

Optimization of solid dispersion technique and gliclazide to carrier (PVP K30) ratio for solubility enhancement

Background and objective: Poorly water-soluble dugs provide less dissolution rate and bioavailability; hence, it minimizes the pharmacological effect of orally administered medications. Gliclazide is a sulfonylurea antidiabetic medication of the second generation, used to treat type II diabetes mellitus. It belongs to the class II drugs of biopharmaceutic classification system, indicating that it has high permeability and poor aqueous solubility. The aim of this study is to determine an optimum solid dispersion method and drug to carrier ratio to improve the solubility of gliclazide. Methods: Solid dispersions of gliclazide were formulated with polyvinyl pyrrolidone K30 using various drug to carrier ratios (1:1, 1:3, and 1:5) by utilizing kneading and solvent evaporation methods. Solubility and dissolution rate of solid dispersion formulas were compared with pure drug and co-ground mixtures. The formulations were further evaluated in terms of percentage of yield, drug content, FTIR, SEM, DSC, and XRD studies. Results: The highest solubility improvement of gliclazide was obtained at the ratio 1:5 of gliclazide and PVP K30 utilizing solvent evaporation method, solubility increased about 2.54 folds (98.299 ± 5.77 µg/ml) as compared to pure gliclazide (38.739 µg/ml). Meanwhile, the greatest improvement in gliclazide dissolution rate was observed in the same solid dispersion formula that was about 105.76 % after 30 minutes. FTIR demonstrated no unwanted interaction between the drug and carrier. While, SEM, DSC, and XRD showed crystallinity of the drug was minimized and converted to amorphous form in solid dispersion formula. Conclusion: Based on the investigations of this study, it can be concluded that the drug to carrier weight ratios and preparation methods had the influence on the drug solubility and the release rate. The obtained data revealed that the solvent evaporation is the best method of solid dispersion for enhancing gliclazide solubility using PVP K30 with the ratio 1:5 of the drug and carrier.

Bulk scale synthesis of high-performance carbon nanomaterial from biogas plant residual waste: Tuned porosity and composition for advanced supercapacitor applications

Carbon based nanomaterials with tuned porosity and compositions are of great interest in terms of energy storing materials. Nevertheless, it is still a challenge to produce such nanostructures on a large scale in cost-effective manner. In this work, we demonstrate that carbon nanomaterial (CNM) can be prepared using biogas plant residual waste (BPRW) as the precursor on a bulk scale under the specific two step pyrolysis technique. The optimized process along with the catalyst used is crucial as the simple pyrolysis of precursor can only produce traditional activated carbon with significantly lower specific capacitance values. The spherical structure of silica nanoclusters and graphitic skeleton of synthesized CNM confirmed with the help of FE-SEM, AFM and HR-TEM along with Raman and XRD while EDX, XPS, and FT-IR studies confirm the presence of various functional groups along with their respective percentage composition. These CNMs show mesoporous structure of the nanomaterial. Among three different aqueous electrolytes, the maximum specific capacitance of 371.88 Fg−1 at 0.5 Ag−1 current density in 1 M H2SO4 indicates its suitability for the practical supercapacitor applications. The fabricated symmetric supercapacitor device using CNMs as the electrode material and 1 M H2SO4 as the electrolyte shows very good specific capacitance value with the high energy density of 34.4 Whkg−1 corresponding to 360 Wkg−1 power density along with the good cyclic stability over 10,000 cycles of charge–discharge. This innovative technique paves the way towards upcycling any lignin containing waste material into carbon-based nanomaterial on a bulk scale by an effective method, which can be further used as high-performance electrode material for energy storage applications like in supercapacitors and batteries.

Evaluating the Impact of Green Coffee Bean Powder on the Quality of Whole Wheat Bread: A Comprehensive Analysis.

The current investigation focuses on the effect of different concentrations of green coffee bean powder (GCBp) on the physicochemical, microbiological, and sensory characteristics of whole wheat bread (WWB). C1 bread formulation (containing 1% GCBp) exhibited the highest loaf volume, suggesting optimal fermentation. Moisture analysis revealed minor alterations in the moisture retention attributes of the bread formulations. Impedance analysis suggested that C1 exhibited the highest impedance with a high degree of material homogeneity. Swelling studies suggested similar swelling properties, except C5 (containing 5% GCBp), which showed the lowest swelling percentage. Furthermore, color and microcolor analysis revealed the highest L* and WI in C1. Conversely, higher concentrations of GCBp reduced the color attributes in other GCBp-containing formulations. FTIR study demonstrated an improved intermolecular interaction in C1 and C2 (containing 2% GCBp) among all. No significant variation in the overall textural parameters was observed in GCBp-introduced formulations, except C2, which showed an improved gumminess. Moreover, the TPC (total phenolic content) and microbial analysis revealed enhanced antioxidant and antimicrobial properties in GCBp-incorporated formulations compared to Control (C0, without GCBp). The sensory evaluation showed an enhanced appearance and aroma in C1 compared to others. In short, C1 showed better physicochemical, biological, and sensory properties than the other formulations.

Design, In-Vitro Characterization and Optimization of Fast Dissolving Sublingual Film containing Aripiprazole

The present research work aim was to formulate a fast-dissolving sublingual film containing Aripiprazole, which is used in the treatment of schizophrenia and bipolar disorder. Fast Dissolving Sublingual Film Containing Aripiprazole prepared by using the solvent casting method. Aripiprazole is a BCS IV drug with poor solubility and poor permeability causing poor systemic absorption. Fast dissolving sublingual film prepared by using Design-Expert® version13 software with 32 full factorial designs in which Film-forming polymer HPMC K4M and plasticizers like PEG 400, and PVA are used in different concentrations. The formulated batches was evaluated for mechanical properties, surface pH, folding endurance, drug content, swelling property, SEM analysis, and in vitro % drug release. The characterization of the film shows satisfactory results following mechanical properties of a film like weight variation and thickness. The formulation (F4, F12) containing the highest concentration of plasticizer shows a high folding endurance ranges from 90-100%. FTIR and DCS studies reveal that there are no interactions means drugs and excipients are compatible with each other. Formulation F4 is optimized batch passes evaluation parameters and maximum % drug release i.e. 98.79 % ±0.36 within 1.5 min. Therefore, the sublingual film is an effective approach for BCS IV and III class drugs by avoiding first-pass metabolism with rapid onset of action and better patient compliance in psychotic disorders.