Sami Publishing CompanyChemical Methodologies2645-77763420190701Sulfate Sulfuric Acid (SUSA)/NaNO2: Efficient Procedure for N-Nitrosation of Secondary Amines and DFT Studies of the Products3924078033010.22034/chemm.2018.150101.1095ENLotfi ShiriDepartment of Chemistry, Faculty of Science, Ilam University, P.O. Box 69315516, Ilam, IranDavood SheikhYoung Researchers & Elite Club, Hamedan Branch, Islamic Azad University, Hamedan, IranSakineh JaniniaDepartment of Chemistry, Faculty of Science, Ilam University, P.O. Box 69315516, Ilam, IranMasoome SheikhiYoung Researchers & Elite Club, Gorgan Branch, Islamic Azad University, Gorgan, IranJournal Article20180926We present the preparation and characterization of sulfate sulfuric acid (SUSA) for the first time. The SUSA showed the best activity in efficient nitrosation of secondary amines under mild condition with excellent yields. Sulfate sulfuric acid (SUSA), is a safe, stable and recyclable solid acid and is a suitable reagent for many organic reactions. The quantum theoretical calculations for products (<strong>2a-j</strong>) were performed by density functional theory (DFT/B3LYP/6-31+G*). Natural charge, frontier molecular orbitals (FMOs), total density of states (DOS), molecular electrostatic potential (MEP) and NBO analysis of the products were investigated by theoretical calculations. Also, molecular properties such as ionisation potential (<em>I</em>), electron affinity (<em>A</em>), chemical hardness (<em>η</em>), electronic chemical potential (<em>μ</em>) and electrophilicity (<em>ω</em>) were obtained for products.https://www.chemmethod.com/article_80330_3e16688f570d361a3417dfaccb799f34.pdfSami Publishing CompanyChemical Methodologies2645-77763420190701Synthesis, Characterization, Kinetics, Thermodynamic and Antimicrobial Studies of Fe(III), Cu(II), Zn(II), N,N'-Bis(2-hydroxy-1,2-diphenylethanone)ethylenediamine Complexes4084248184310.22034/chemm.2018.147922.1085ENMoses Saviour IorungwaInorganic/Physical Chemistry Research Group Federal University of Agriculture 970001, Makurdi-Nigeria0000 - 0001 - 9055 -Raymond WuanaInorganic/Physical Chemistry Research Group Federal University of Agriculture 970001, Makurdi-NigeriaSamuel Terungwa DafaInorganic/Physical Chemistry Research Group Federal University of Agriculture 970001, Makurdi-NigeriaJournal Article20180907Schiff base ligand derived from benzaldehyde and ethylenediimine and its Fe(III),Cu(II) and Zn(II) complexes were synthesized. The ligand <em>N,N’</em>-Bis(2-hydroxyl-1,2-diphenylethanone)ethylenediamine(B<sub>2</sub>HDE)and its complexes were characterized by molar conductivity, melting point, solubility test and spectrometrically (IR and UV-Vis). The Kinetics of complex formation obtained from a plot ln<em>k</em><sub>obs</sub> verses 1/T, thermodynamic parameters were obtained from plots of ln(<em>k</em><sub>obs</sub>/T) verses 1/T and antimicrobial activities of the ligand and its complexes were tested. The solubility results showed that B<sub>2</sub>HDE and its complexes were soluble in dimethylsulphoxide, dimethylformanide and acetone while the melting point of ligand and complexes showed they are fairly stable. The complexes molar conductivity indicated that they are non-electrolytes. The IR spectra showed a bidented ligand which coordinated through azomethine nitrogen and hydroxyl oxygen atom. UV-Vis results confirmed the complexation of the metal and ligand with a tetrahedral geometry for both complexes and the activation energy (E<sub>a</sub>) obtained were positive E<sub>a </sub>indicating that, the rate of formation increased with increasing temperature. The kinetic results showed that increase in time and temperature increased the yield of the complexes. The results of thermodynamics parameters showed the formation of an activated complex via an associative pathway. Antimicrobial studies results of complexes were higher than the one found for the free ligand.https://www.chemmethod.com/article_81843_54e1128bd4a61b6bcc061a1c93d83730.pdfSami Publishing CompanyChemical Methodologies2645-77763420190701Different Interface Engineering in Organic Solar Cells: A Review4254418397110.22034/chemm.2018.150142.1096ENOluwatobi O. AmusanDepartment of Chemistry, University of Ilorin, Ilorin, Kwara State, NigeriaHitler LouisDepartment of Pure and Applied Chemistry, Faculty of Physical Sciences, University of Calabar, Calabar, Cross River State, NigeriaCAS Key Laboratory for Nanosystem and Hierarchical Fabrication, CAS Centre for Excellence in Nanoscience, National Centre for Nanoscience and Technology, University of Chinese Academy of Sciences, Beijing, China0000-0002-0286-2865Saud-uz- ZafarCAS Key Laboratory for Nanosystem and Hierarchical Fabrication, CAS Centre for Excellence in Nanoscience, National Centre for Nanoscience and Technology, University of Chinese Academy of Sciences, Beijing, ChinaAdejoke T. HamzatDepartment of Chemistry, University of Ilorin, Ilorin, Kwara State, NigeriaDass M. PeterDepartment of Chemistry, Faculty of Physical Sciences, Modibbo Adama University of Technology, Yola, NigeriaJournal Article20180927The global quest for reliable sources of energy has led to the development of Organic solar cells (OSCs)/ Organic photovoltaics (OPVs). Over the past few years, they have shown great potentials and use as low cost devices for conversion of solar energy. OSCs are designed from different interface layers from different materials which form a major determinant for their energy conversion efficiency. The recent development in the modifications in design and engineering of these interface materials have shown increased power conversion efficiency (PCE%) of Organic photovoltaics. Interface materials are conductors, semiconductors or non-conductors which provide selective contact for carriers, determine polarity and acts as protective layers. This review discusses different materials which are used as interface materials as well as their structure and engineering.https://www.chemmethod.com/article_83971_81ec717978570019ccdb8d61d072f78e.pdfSami Publishing CompanyChemical Methodologies2645-77763420190701Molecular Docking Studies of Novel Aminopyrimidines as Potent Antifungal Agents4424508168610.22034/chemm.2018.151655.1100ENJudy JaysFaculty of Pharmacy, M.S. Ramaiah University of applied sciences, M.S.R.I.T. Post, Bangalore – 560054, Karnataka, India0000-0002-3872-0199S MohanPES college of pharmacy, Hanumanthnagar, Bangalore – 560050, Karnataka, IndiaJ SaravananPES college of pharmacy, Hanumanthnagar, Bangalore – 560050, Karnataka, IndiaJournal Article20181009<em>Candida albicans</em> is an opportunistic fungal pathogen that causes candidiasis in human hosts. Candidiasis includes a multitude of fungal infections, including invasive fungal infections, where most patients are immunocompromised; hence, the success of treatment is determined by the efficacy of the antifungal agent. However, with the increase in resistance to the existing drugs, the availability of effective antifungal agents is becoming scarce.<br /> Many pyrimidine derivatives exhibit powerful antifungal activity. In this study, In silico antifungal activity was carried out on twenty novel aminopyrimidine derivatives to identify the specificity of the pyrimidine analogues for the antifungal targets using ‘Glide’. Molecular docking studies were conducted on two antifungal targets; Dihydrofolate reductase of <em>C. albicans</em> (PDB ID: 4HOE); <em>N</em>-myristoyl transferase of <em>C. albicans</em> (PDB ID: 1IYK); energy minimization of title compounds was carried out using LigPrep, the protein targets were optimized and minimized, a 3-dimensional grid was generated at the active site, and molecular docking was carried out at both the standard precision (SP) and extra precision (XP) modes. The docking poses were ranked according to their docking scores (GScore) and their binding energy with the enzyme (Emodel). The obtained results for the docking of the title compounds with dihydrofolate reductase of <em>C. albicans</em> are quite promising. Molecular docking suggest that compounds 2N and 2A are potential inhibitors of dihyfrofolate reductase and are specific in binding at the active site of the enzyme. They form pi-pi stacking interactions with PHE 36 at the active site of the protein, similar to the standard drug. However the test compounds show lower docking scores against <em>N</em>-myristoyl transferase of <em>C. albicans</em> indicating that they may not be effective against the fungal protein.https://www.chemmethod.com/article_81686_97fccc06a9f1fc98494d3ff6cccd8296.pdfSami Publishing CompanyChemical Methodologies2645-77763420190701Preparation and Evaluation of Herbal Formulation Using Natural Extract4514568100610.22034/chemm.2018.146968.1079ENA. DongarwarManoharbhai Patel Institute of B. Pharmacy, Gondia, Maharashrtra, India-441614Bajiraoji Karanjekar College of Pharmacy, Sakoli, Maharashtra, India-441802Tulsidas NimbekarManoharbhai Patel Institute of B. Pharmacy, Gondia, Maharashrtra, India-441614Bajiraoji Karanjekar College of Pharmacy, Sakoli, Maharashtra, India-441802T. ParshuramkarManoharbhai Patel Institute of B. Pharmacy, Gondia, Maharashrtra, India-441614Bajiraoji Karanjekar College of Pharmacy, Sakoli, Maharashtra, India-441802N. IndurwadeManoharbhai Patel Institute of B. Pharmacy, Gondia, Maharashrtra, India-441614Bajiraoji Karanjekar College of Pharmacy, Sakoli, Maharashtra, India-441802Journal Article20180830<em>Butea monosperma </em>and<em> Psidium guajava</em> are traditional important medicinal plants. The plants were used in Ayurvedic unani and Siddha medicine for various ailments. Antibacterial activity was studied using extracts of <em>Butea monosperma</em> and <em>Psidium guajava</em> by agar well-diffusion method against <em>E. coli</em> and <em>S. aureus</em>. The ethanolic extracts of <em>Butea monosperma </em>flowers showed antibacterial activity against <em>E. coli</em> and <em>S. aureus</em>. In the same manner <em>Psidium guajava</em> leaf, extract showed antibacterial activity against <em>E. coli</em> and <em>S. aureus</em>. The objective of the present investigation was to formulate and evaluate herbal gel using specified concentration of powdered extracts of <em>Butea monosperma</em> flower and <em>Psidium guajava</em> leaves. https://www.chemmethod.com/article_81006_9a032b44e6dd9c3402131411e81ae543.pdfSami Publishing CompanyChemical Methodologies2645-77763420190701Cu Nanoparticle: Synthesis, Characterization and Application4574808219010.22034/chemm.2019.154075.1112ENN.S. PowarAmrita Institute of Nanoscience and Molecular Medicine, AIMS Ponekkara P. O. Kochi, Kerala, India – 68204V. J. PatelDivision of Biological & Life Sciences, Ahmedabad University, Ahmedabad, Gujarat, India-380009P.K. PagareDr. A. P. J. Abdul Kalam Research Laboratory, Department of Physics, Yashavantrao Chavan Institute of Science, Satara- 415001R.S. PandavDepartment of Chemistry, Yashavantrao Chavan Warana College, Warananager, Kolhapur, Maharashtra-416113Journal Article20181120The applications of copper nanoparticle are gradually increased because of Cu is inexpensiveness and high abundance in nature. However, synthesis of copper nanoparticles is very challenging because of transformation from Cu nanoparticles into copper oxide in presence of air, though colloidal Cu NPs have significantly catalytic activity and biological applications. This review article exploring the synthesis of copper nanoparticles by different methods such as wet chemical, microemulsion, micro-oven assisted and thermal decomposition, moreover, explains about green and biological modes of synthesis. Some of the characterization methods for copper nanoparticle have discussed seem, electron microscopes and X-ray spectroscopy. Furthermore, applications of degrading treatment of textile effluents containing methylene blue dye and expose the mechanism of degradation. The copper nanoparticles show a catalytic activity in organic transformation, while have mentioned the biological application for anti-microbial and wound healing of copper NPs. https://www.chemmethod.com/article_82190_fe397f819c7077da1dc24f4234fe16b9.pdfSami Publishing CompanyChemical Methodologies2645-77763420190701Improved Photostabilization of Chlorpyrifos Insecticide with Novel Benzil Derivatives4814938219110.22034/chemm.2018.151723.1101ENGautam M. PatelIndustrial Chemistry Department, Faculty of Life, Health & Allied Sciences, ITM Vocational University, Vadodara, IndiaHemant S. ParmarSolaris Chem Tech Industries limited, Vadodara, IndiaPradeep T. DeotaApplied Chemistry Department, Faculty of Technology & Engineering, The Maharaja Sayajirao University of Baroda, Vadodara, India0000-0002-9325-4717Journal Article20181009Chlorpyrifos, an organophosphorus insecticide, is widely used in agricultural and non-agricultural areas all over the world. During field application, it readily undergoes degradation due to microbial decomposition, hydrolysis, volatilization and photolysis. Among these, photodegradation is one of the major pathways for its decomposition on field. In the present study, eight novel benzil derivatives and their application for the photostabilization of chlorpyrifos under UV light are reported. The percentage recovery of chlorpyrifos after UV irradiation (in the presence and absence of the benzil derivatives) is obtained by HPLC analysis. Results indicate significant enhancement in the photostabilization of chlorpyrifos using these benzil derivatives (96.63% recovery) in comparison to 2,4-dihydroxy benzophenone taken as a reference photostabilizer (78.80% recovery). Enhanced photostabilization, in case of benzil derivatives, is attributed to the assembly of two hydroxy and keto pairs in a single structure. https://www.chemmethod.com/article_82191_d782418b0a77432f1a311198cc19177d.pdfSami Publishing CompanyChemical Methodologies2645-77763420190701Validated Stability Indicating RP-HPLC DAD Method for Simultaneous Determination of Amitriptyline Hydrochloride and Pregabalin in Presence of Stress degradation products in tablet dosage form4945088292710.22034/chemm.2019.154554.1107ENAmit J. VyasB. K. Mody Government Pharmacy College, Rajkot-360002, Gujarat, India0000-0003-4785-1841Grishma P. NathwaniB. K. Mody Government Pharmacy College, Rajkot-360002, Gujarat, IndiaAjay I. PatelB. K. Mody Government Pharmacy College, Rajkot-360002, Gujarat, IndiaNilesh K. PatelB. K. Mody Government Pharmacy College, Rajkot-360002, Gujarat, IndiaAshok B. PatelB. K. Mody Government Pharmacy College, Rajkot-360002, Gujarat, IndiaJournal Article20181101<strong>Background</strong>: High Performance liquid chromatography (HPLC) is an integral analytical tool in assessing drug product stability. HPLC methods should be able to separate, detect, and quantify the various drug-related degradants that can form on storage or manufacturing, plus detect any drug-related impurities that may be introduced during synthesis.<br /> <strong>Objectives</strong>: A simple, economic, selective, precise, accurate and stability indicating RP-HPLC (Reversed phase–HPLC) method was developed and validated for analysis of Amitriptyline Hydrochloride (AMI) and Pregabalin (PGB) in the formulation.<br /> <strong>Method:</strong> Reversed-phase chromatography was performed on a C<sub>18</sub> column with buffer (potassium dihydrogen phosphate) pH 4.0 and acetonitrile, (40:60 %v/v), as mobile phase at a flow rate of 1 mL/min.<br /> <strong>Result</strong>: The detection was performed at 230 nm (nanometer) and sharp peaks were obtained for PGB and AMI at retention time of 4.4 and 9.6 min, respectively. The detection limits were found to be 3.00 µg/mL and 0.59 µg/mL and quantification limits were found to be 9.11 µg/mL and 1.79µg/ml for Pregabalin and amitriptyline hydrochloride, respectively. The method was validated for accuracy, precision, reproducibility, specificity, robustness and detection and quantification limits, in accordance with ICH (international council of hormonization) guideline.<br /> <strong>Conclusion</strong>: Stress study was performed on Pregabalin and amitriptyline hydrochloride and it was found that these degraded sufficiently in all applied chemical and physical conditions. Thus, the developed RP-HPLC method was found to be suitable for the determination of both the drugs as well as stability samples of tablets containing various excipients.https://www.chemmethod.com/article_82927_0d3c32d557eee3e3b04d734999753823.pdfSami Publishing CompanyChemical Methodologies2645-77763420190701N1,N1,N2,N2-Tetramethylethylenediaminium-N1,N2-disulfonic Acid Trifluoroacetate as Highly Effectual and Dual-Functional Catalyst for the Reaction of β-Ketoesters with Aryl Aldehydes and Urea/Thiourea5095188397210.22034/chemm.2019.157916.1111ENMostafa KaramiDepartment of Chemistry, Payame Noor University, PO Box 19395-3697 Tehran, IranBentolhoda GholamiDepartment of Chemistry, Payame Noor University, PO Box 19395-3697 Tehran, IranTahereh Hekmat-ZadehDepartment of Chemistry, Payame Noor University, PO Box 19395-3697 Tehran, IranAbdolkarim ZareDepartment of Chemistry, Payame Noor University, PO Box 19395-3697 Tehran, Iran0000-0002-8210-3155Journal Article20181119In this research, the one-pot multi-component reaction of <em>β</em>-ketoesters with aryl aldehydes and urea/thiourea has been performed using a dual-functional ionic liquid-catalyst namely <em>N</em><sup>1</sup>,<em>N</em><sup>1</sup>,<em>N</em><sup>2</sup>,<em>N</em><sup>2</sup>-tetramethylethylenediaminium-<em>N</em><sup>1</sup>,<em>N</em><sup>2</sup>-disulfonic acid trifluoroacetate ([TMEDSA][TFA]<sub>2</sub>) in solvent-free conditions. By reason of dual-functionality of the catalyst (possessing acidic and basic sites), and also having two numbers of each site, it was highly effectual and general catalyst, and afforded the products {3,4-dihydropyrimidin-2-(1<em>H</em>)-ones and 3,4-dihydropyrimidin-2-(1<em>H</em>)-thiones} in short times with excellent yields. Moreover, a plausible mechanism based on dual-functionality of the catalyst has been proposed.https://www.chemmethod.com/article_83972_3637cda0af7e85cc011e9773e6a672f0.pdf