HOMO-LUMO Energy Research Articles

Synthesis, characterization, and computational analysis of novel imidazole-based derivative with tailored electronic properties

Imidazole-based ligand was developed via the Debus–Radziszewski synthetic method by direct reaction of 2,6-diformyl-4-methyl-phenol and 1,10-phenanthroline-5,6-dione and characterized by 1H NMR, 13C NMR, and LCMS. The Density Functional Theory (DFT) studies for the synthesized compound have been carried out at DFT/B3LYP/6-311G(d,p) level of theory to predict the optimized molecular geometry, HOMO-LUMO energy, vibrational frequencies, MEP mapping and global reactivity descriptors. The observed results correlated with experimental results. A synthesized compound bearing an imidazole group was created as an ON-OFF fluorescent chemosensor for Fe3+ and V5+ ions. The probe’s UV–visible absorption and fluorescence spectral behavior towards various cations were investigated in acetonitrile/water (9:1) solution. The absorbance intensity of the probe molecule was considerably enhanced whereas the fluorescence emission intensity was quenched in the presence of these two metal cations, while the presence of other metal ions had no notable interference.

Study of photosensitizer dyes for high-performance dye-sensitized solar cells application: A computational investigation

Dye-sensitized solar cells (DSSCs) offer a promising, cost-effective alternative to conventional photovoltaic systems. Organic sensitizers, capable of capturing a broad spectrum of sunlight, are key components in DSSCs, but their development and testing are often time-consuming and expensive. Quantum chemical calculations, specifically Density Functional Theory (DFT), have emerged as valuable tools to evaluate potential dye candidates, streamlining the design process and reducing costs. This study investigated the molecular structures and photophysical properties of three common dye classes used in high-performance DSSCs: natural pigments, anthocyanidin pigments, and squaraine dyes. Employing DFT and time-dependent DFT (TD-DFT) at the B3LYP/6–31G level, key parameters such as the HOMO-LUMO energy gap, free energy differences for electron injection and dye regeneration, short-circuit current density, total reorganization energy, and open-circuit voltage were analyzed. Additionally, maximum absorption wavelengths and oscillator strength values were calculated. Our findings provide valuable insights into the optical and electrical properties of these natural dyes, aiding DSSC manufacturers in selecting optimal sensitizers. This research highlights the potential of computational methods in accelerating dye development and improving the overall efficiency of DSSC technology.

Spectral Characteristics, In Silico Perspectives, Density Functional Theory (DFT), and Therapeutic Potential of Green-Extracted Phycocyanin from Spirulina.

Phycocyanin (PC) is a naturally occurring green pigment in Spirulina. It was extracted by ultrasonic extraction using green technology, and its structure was studied using IR- and NMR-spectroscopy. Spectral data confirmed the PC structure. This study also involves an in silico assessment of the diverse applications of green pigment PC. Utilizing QSAR, PreADME/T, SwissADME, and Pro-Tox, this study explores the safety profile, pharmacokinetics, and potential targets of PC. QSAR analysis reveals a favorable safety profile, with the parent structure and most metabolites showing no binding to DNA or proteins. PreADME/T indicates low skin permeability, excellent intestinal absorption, and medium permeability, supporting oral administration. Distribution analysis suggests moderate plasma protein binding and cautious blood-brain barrier permeability, guiding formulation strategies. Metabolism assessments highlight interactions with key cytochrome P450 enzymes, influencing drug interactions. Target prediction analysis unveils potential targets, suggesting diverse therapeutic effects, including cardiovascular benefits, anti-inflammatory activities, neuroprotection, and immune modulation. Based on the in silico analysis, PC holds promise for various applications due to its safety, bioavailability, and potential therapeutic benefits. Experimental validation is crucial to elucidate precise molecular mechanisms, ensuring safe and effective utilization in therapeutic and dietary contexts. DFT calculations, including geometry optimization, MEP analysis, HOMO-LUMO energy surface, and quantum reactivity parameters of the PC compound, were obtained using the B3LYP/6-311G(d,p) level. This integrated approach contributes to a comprehensive understanding of PC's pharmacological profile and informs future research directions.

A homobimetallic nickel(II) complex for discriminative chromogenic recognition of aqueous cyanide and silver(I) from medicinal products: Role of end-on thiocyanate bridging

Herein, a homobimetallic azomethine-functionalized nickel(II) complex, [Ni2L2(van)(μ1,1-NCS)] (AMR-1, where L = 2-[(2-Hydroxy-1,1-dimethyl-ethylimino)-methyl]-6-methoxyphenol, molecular weight = 788.20 (found)) has been judiciously synthesized with N-coordinated end-on thiocyanate. AMR-1 exhibited promising chromogenic variation from pale green to colourless with hypochromic shifting in the visible region in the presence of silver(I). Herein, the exposed sulfur site of the co-ligand acts as chemodosimetric recognition site for highly selective detection of a soft metal pollutant, silver ion (Ag+) with the limit of detection (LOD) of 0.37 ppm. Along with this, aqueous cyanide (CN−) recognition was accomplished in a mutually independent way with distinct chromogenic variation from pale green to yellowish color within ∼5 s. This led to the LOD of 0.46 ppm, which is much lower than the safe limit, set by the World Health Organization (WHO). The stability constant value for cyanide interaction with AMR-1 is obtained to be 1.49 × 103 M−1 as per 1:1 binding stoichiometry. Experimental findings, obtained from UV–Vis, HR-MS, FT-IR, and 1H NMR spectroscopic studies in conjugation with the decreased HOMO-LUMO energy gap from 3.40 eV to 2.07 eV, obtained from density functional theory studies, support the mechanistic pathway of interaction. Implementing molecular logic platforms benefits from fabricating three-input-two-output logic circuits by imitating variable spectroscopic outcomes. Real-time multifarious applications of AMR-1 have been accomplished with paper strip-based solid-state assay and recognition of the target-specific analytes from targeted medicinal specimens and from both cyanogenic as well as non-cyanogenic food sources. To the best of our knowledge, this is probably the first nickel(II) complex derived sensory receptor that is effectually implemented towards recognition of another metal ion, silver (I) along with CN− from aqueous as well as from real specimens.

A mechanism – based perspective on the interplay of new drug candidate with biomolecules

This research deals with the synthesis and analysis of a novel Pd(II) compound, [Pd(dach)(SA)], featuring 1,2-diaminocyclohexane (dach) and salicylic acid (SA). The compound's structure was refined and its electronic properties including HOMO-LUMO energies, molecular electrostatic potential and natural bond analysis were calculated using B3LYP functional of DFT. Biologically, the compound demonstrated significant antitumor efficacy against the K562 leukemia cell line (IC50 = 37 μM). In-silico methods predicted the favorable characteristics and low risks of new compound. Interactions with DNA and serum albumin were explored using both experimental and computational techniques, revealing that the compound binds through hydrogen bonds and van der Waals forces having Kb,DNA = 1.7 × 105, ΔG°DNA = - 7.32 kcal/mol, Kb,BSA = 1.25 × 106 and ΔG°BSA = - 8.36 kcal/mol, as indicated by fluorescence spectroscopy. UV–Vis spectroscopy showed a reduction in the absorption spectra of both DNA and BSA upon interaction. DNA binding affinity was confirmed via gel electrophoresis and viscosity measurements. Molecular docking suggested the groove binding with DNA, and site I of BSA, primarily through hydrogen binding. The stability and conformational changes of these interactions over the time were affirmed by molecular dynamics simulations and QM/MM calculations. These comprehensive studies underscore the potential of [Pd(dach)(SA)] complex as a candidate for cancer therapy, highlighting its strong binding interactions with crucial biomolecules.

Synthesis of novel chromeno-tethered imidazolone scaffold through one pot sequential multicomponent reaction mediated cyclization: A structural, computational and in silico investigation

A novel chromeno imidazole-based derivative was synthesized and characterized using single crystal X-ray diffraction technique. The MCR strategical methodology followed by the cyclization and the SN2 mechanism resulted in the formation of chromenoimidazolone molecular scaffold. The structural analysis revealed that the structure crystallizes in P1¯ space group and was stabilized by intra and intermolecular interactions. The dihedral angle of 82.85° indicated the non planarity of the molecule. The molecular interactions exhibited by the crystal structure were analysed by the Hirshfeld surface analysis and the H…H interactions was found to be major contributor to the overall interactions of the compound with the percentage contribution of 52.3%. The theoretical investigations were carried out using density functional theory calculations to predict various electronic properties of the compound. The HOMO-LUMO energy gap of the compound is found to be 1.4534 eV for alpha and 3.9367 eV for a beta spin. The MEP analysis revealed that the C = O exhibit the highest negative electrostatic potential with the value of -0.064 a.u. indicating its nucleophilic nature. Further, natural bond orbital analysis revealed that the LP(1)→π* interaction demonstrates the highest stabilization energy of 53.49 kcal/mol.The results of the molecular docking analysis of the compound against 6FS1 protein showed a docking score of -7.4 kcal/mol, indicating the potential of the compound to be a good anti-cancer agent. Further, the findings of the molecular docking were substantiated by the molecular dynamics simulation studies which showed very good stability of the protein-ligand complex.

Structural and computational analysis of a nickel(II) complex with S-benzyldithiocarbazate Schiff base ligand: Synthesis, X-ray crystallography, MEP, HOMO-LUMO, Hirshfeld surface analysis, and molecular docking

A new compound, benzyl N-[1-(thiophen-2-yl)propylidene]hydrazinecarbodithioate (LH), and its nickel(II) complex (NiL2), were synthesized and structurally identified. Single crystal X-ray diffraction analyses determined that both the LH ligand and the NiL2 complex crystallized in the monoclinic system, with space group P21/c and Z = 4. The LH ligand exhibited lattice parameters of a = 9.661(2)Å, b = 8.995(2)Å, c = 18.939(4)Å, β = 102.677(4)°, V = 1605.7(7)Å3, whereas, NiL2 exhibited a = 17.805(7)Å, b = 10.548(4)Å, c = 18.100(7)Å, β = 108.279(6)°, V = 3228(2)Å3. The NiL2 complex was found to possess a slightly distorted square planar geometry with the LH deprotonated ligand acting as a monoanionic bidentate by coordinating through the azomethine nitrogen and thiolate sulfur atoms. It was observed that the HOMO-LUMO energy gap of the NiL2 complex (0.3654 eV) was lower than that of the LH ligand (2.4425 eV), indicating that NiL2 possesses a higher reactivity than the LH ligand. Intermolecular hydrogen bonding interactions were examined by Hirshfeld surface and 2D fingerprint analysis, which showed predominant H…H interactions for both the LH ligand and the NiL2 complex. A molecular docking simulation study with the dopamine D4 receptor (DRD4) and farnesyltransferase (FTase) revealed that NiL2 was able to interact with 13 residues in FTase, as compared to the farnesyl-Cys drug interacted with 11 residues.

Exploring Biliverdin's Molecular Interactions with Cu- and Fe-Based MOFs: A Unified In Vitro Study with Photoacoustic Analysis.

Metal-organic frameworks (MOFs) have shown promise in enhancing the stability of biomolecules. Herein, biliverdin (BVD), a photoacoustic (PA) and fluorescent agent, was immobilized within the pores of NH2-MIL-101 (Fe) (FeMOFs) and on the surface of CuBTC crystallites (CuMOFs). MOFs were found to enhance the fluorescence emission and quench the PA intensity of biliverdin. Fluorescence and PA studies, in tandem with DFT simulations, demonstrated that the spectral interactions between MOFs and BVD resulted from interactions between biliverdin and the MOF pores and surfaces in addition to alterations in the HOMO-LUMO energy gap. The MOF internal structure of the MOF played a role in BVD loading, with the FeMOFs enabling greater BVD encapsulation, while CuMOF interactions with BVD primarily took place on the MOF surface. The role of these surface vs pore interactions in the release of biliverdin was explored. This study demonstrates that the effects of the MOF internal structure, surface interactions, and energy interactions should be taken into consideration for biomolecule loading in MOFs.

Complexes of Hydrogen Peroxide, the Simplest Chiral Molecule, with L- and D-Serine Enantiomers and Their Clusters: MP2 and DFT Calculations.

The interaction between natural amino acids and hydrogen peroxide is of paramount importance due to the widespread use of hydrogen peroxide in biological and environmentally significant processes. Given that both amino acids and hydrogen peroxide occur in nature in two enantiomeric forms, it is crucial to investigate the formation of complexes between them, considering the role of molecular chirality. In this work, we report a theoretical study on the hydrogen peroxide enantiomers and their interactions with L- and S-serine and their clusters. We aimed to evaluate the non-covalent interactions between each hydrogen peroxide enantiomer and the L- and D-enantiomers of the non-essential amino acid serine and their clusters. First, the potential energy surfaces (PES) of transitions between enantiomers of the simplest chiral molecule, hydrogen peroxide, in the gas phase and in aqueous solution were studied using the Møller-Plesset theory method MP2/aug-cc-pVDZ. The activation energies of such transitions were calculated. The interactions of both hydrogen peroxide enantiomers (P and M) with L- and D-serine enantiomers were analyzed by density functional theory (DFT) with ωb97xd/6-311+G**, B3Lyp/6-311+G**, B3P86/6-311+G**, and M06/6-311+G** functionals. We found that both enantiomers of hydrogen peroxide bind more strongly to L-serine and its clusters than to D-serine, especially highlighting that the L form is the predominant natural form of this and other chiral amino acids. The optimized geometric parameters, interaction energies, and HOMO-LUMO energies for various complexes were estimated. Furthermore, circular dichroism (CD) spectra, which are optical chirality characteristics, were simulated for all the complexes under study.

Unveiling the effects of thallium and bismuth p-n doping on germanium-based clusters (n5 to n12) for applications in semiconductor materials

We report a computational investigation utilizing density functional theory (DFT) concerning the pure Gen, as well as their doped analogues (BiGen-1, TlGen-1) and p-n doped BiTlGen-2 clusters with n ranging from 5 to 12. To get a deeper insight in their properties, we focus on the size dependency of these Gen, BiGen-1, TlGen-1, and BiTlGen-2 clusters as well as their shape, relative stabilities, and thermochemical characteristics including binding energy, fragmentation energy, second-order energy difference, and HOMO-LUMO energy gaps. The systematic observations from the data of binding energies indicate that BiGen-1, TlGen-1 and BiTlGen-2 cluster have more structural and thermodynamic stability when compared with the pure Gen clusters. To validate the electronic characteristics of these clusters, additional energy gap-related parameters such as chemical hardness, vertical ionization potentials (VIP), and vertical electron affinities (VEA) are also computed. The doping seems to stabilize the Gen clusters and the highest stability has been achieved for BiGe7, TlGe9, and BiTlGe7 clusters as suggested by the combined effect of all these parameters.

Metal-free phenothiazine dyes with alkoxy chains modified at different position for dye-sensitized solar cells

Long alkyloxy or alkoxyphenyl chains are commonly introduced to organic dye sensitizers in dye-sensitized solar cells (DSSCs) to inhibit the aggregation of sensitizer on the TiO2, thereby minimizing charge recombination. Here, we synthesized four D-D-π-A sensitizers (TP-C6, TP-PhOC6, C6O-TP-C6, C6O-TP-PhOC6), that feature alkyl-/alkoxyphenyl- moiety in phenothiazine (PTZ) donor’s N-position, and either alkoxy or no alkoxy groups in triphenylamine (TPA) auxiliary donor. Then, their photophysical, electrochemical and DSSCs properties were investigated. The UV-Vis and electrochemical studies revealed that all four dyes exhibited good light absorption ability and appropriate HOMO-LUMO energy levels. The introduction of alkoxy at the donor or auxiliary donor can result in a significant redshift in absorption. Among them, TP-PhOC6, which incorporates an alkoxy phenyl group at the N-position of PTZ and lacks alkoxy in TPA, induces a greater redshift in ICT absorption with strong absorption intensity. Additionally, in TP-PhOC6 based DSSC, mitigated charge recombination was observed. As a result, this device exhibited the strongest and widest IPCE spectrum, the highest Jsc (12.77 mA/cm²) and Voc (0.85 V), leading to the highest PCE (6.59 %).

Synthesis, spectral, Hirshfeld surface analysis, DFT, molecular docking and ADMET properties of (E)-4-fluoro-N'-(4‑hydroxy-3‑methoxy benzylidene)benzohydrazide (EFHMBH)

The synthesis, characterization, and theoretical studies of the E)-4-fluoro-N'-(4‑hydroxy-3-methoxybenzylidene)benzohydrazide (EFHMBH), have been reported in this study. The Single Crystal XRD, FT-IR, FT-Raman, and UV–Vis techniques were carried out to study the structural, and optical properties of the grown crystals. The molecular structure has been characterized by room-temperature single-crystal X-ray diffraction study which reveals that it has an angular shape with intramolecular and intermolecular hydrogen bonding. Crystal data for the title compound, C15H14FN2O4 (M = 305.28 g mol-1): monoclinic, space group P21/n, a = 8.0205 (6)Å, b = 17.0685 (13)Å, c = 10.9378 (9)Å, ß = 105.277 (3)°, V = 1452.9 (2) Å3, Z = 4, Dcalc = 1.396 Mg/m3, 21,326 reflections measured,4245 unique (Rint = 0.048) which were used in all calculations. The Hirshfeld surface analysis of the title compound shows that O…H/H…O(21.6 %), H…C/C…H(15.8 %), F…H/H…F(8.3 %), C…C(7.3 %) respectively, which exposed that the main intermolecular interactions. The geometrical optimization and the theoretical vibrational analysis are performed at B3LYP/6–31 ++ G(d,p) computational level under density functional theory (DFT) and correlated with experimental data. The HOMO-LUMO energy gap in the title compound is 4.0113 eV. The molecular electrostatic potential of the investigated compound has also been studied. The molecular docking analysis is performed against human HMG-CoA reductase-related target proteins, which shows better inhibitory activity of EFHMBH against the 1DQA receptor with the binding energy of -4.31 kcal/mol. Furthermore, to analysis, the physiochemical and pharmacokinetic features of EFHMBH are analyzed using the preADME online server.

A DFT study of eugenol adsorption onto pure and Si-doped Al12N12 and B12N12 fullerene-like nanocages

Density functional theory (DFT) methods have been employed in this work to study the adsorption behavior of eugenol (Eug) on the external surface of pure and Si-doped Al12N12 and B12N12 fullerene-like nanocages. All calculations were performed using the M062X-D3 functional combined with the 6-311 + G(d,p) basic sets. In order to probe the reliability of the DFT method, three other functionals (B3LYP-D3, CB3LYP-D3 and WB97XD) were employed and no significant difference was observed in the adsorption energy values of the most stable configurations (AEII and BEII). Also, the complexes are found to be stable in standard conditions in gas and aqueous phases, and the adsorption process is found to be exothermic and spontaneous. Interestingly, Si-doped nanomaterials (Si-AEII and Si-BEII) form the most stable adsorbent-adsorate molecular states (Eads = −90.07 and −61.42 kcal/mol respectively) in gas phase. Furthermore, Si-AEII and Si-BEII complexes exhibit the highest reactivity, characterized by the lowest values of the HOMO-LUMO energy gap (5.50 and 7.07 eV respectively). MEP map of the studied systems showed electron rich and electron deficient sites. Natural bond orbital analyses revealed that the interaction of Al12N12 with Eug is mainly due to the strong electron delocalization LP(2)O10 → LP*(2)Al47 (E(2) = 34 kcal/mol), whereas in Eug-B12N12 complex, it is mainly due to the electron delocalization LP(2)O10 → P*(4)B36 (E(2) = 96.53 kcal/mol). The QTAIM analysis revealed that Si–O and Al–C/B–C bonds linking eugenol to doped cages are attractive weak interactions and their nature have been confirmed via RDG/NCI analyses. Indeed, the present study revealed the suitability of Si-doped Al12N12 and B12N12 fullerene-like nanocages for the efficient drug delivery of eugenol.

Aldose Reductase Evaluation against Diabetic Complications Using ADME and Molecular Docking Studies and DFT Calculations of Spiroindoline Derivative Molecule

In this study, the target molecule ethyl-2-(5-nitro-5'-(4-nitrophenyl)-2-oxo-3'H-spiro[indoline-3,2'-[1,3,4]oxadiazol]-1-yl)acetate, which is a spiroindoline derivative, were performed NBO analysis, molecular electrostatic potential surface (MEPS), nonlinear optics (NLO), HOMO-LUMO energy calculations, optimized molecular geometry, and mulliken atomic charges using B3LYP/B3PW91 basis set and 6-311G(d,p) approximations. Calculated results were reported. Density Functional Theory (DFT) computations were utilized to research the molecule theoretically. Moreover, molecular docking analysis of the tested compound, a spiroindoline derivative molecule targeting aldose reductase against diabetic complications, was performed using molecular docking to determine the structure-activity connection. The molecular docking study provided important information worth considering for further research. A notable outcome of bioisosteric and isosteric substitutions is the alteration in lipophilic character, an impressive characteristic in several aspects. Thus, utilizing SwissADME, lipophilic character assessments were performed for the concerned compounds.

Cl©Li5Cl5-: A Star-like Superhalogen Anion Featuring a Planar Pentacoordinate Chlorine at the Center.

Among the known planar pentacoordinate atoms, chlorine is missing due to its large radius and high electronegativity. Herein, we report the first star-like superhalogen anion D5h Cl©Li5Cl5- (1), which contains a planar pentacoordinate chlorine (ppCl) at the center. Computer structural searches and high-level calculations reveal that 1 is a true global minimum (GM) on the potential energy surfaces. Molecular dynamics simulations indicate it is kinetically stable against isomerization or decomposition. Although detailed chemical bonding analyses reveal one delocalized 6c-2e σ bond over the Cl©Li5 central unit and five delocalized 3c-2e σ bonds along the periphery, while aromaticity has very little beneficial effect on stability, instead, ionic interaction dominates the stability of the system. More encouragingly, with the large HOMO-LUMO energy gap of 7.66 eV and vertical detachment energy of 7.87 eV, the highly chemically inert 1 can be viewed as a typical superhalogen anion and is possible to be synthesized and characterized in future experiments.

Novel emissive styryl dyes from 9-methoxy anthracene: Synthesis, photophysical, thermal stability, viscosity, and DFT study

Novel styryl colorants based on anchoring methoxy with anthracene as a donor linked with various active methylene acceptor groups to derive a conjugated π-system along with push-pull geometry were synthesized and well characterized. Photophysical properties were studied in different polarity solvents. The impact of solvent polarizability is delivered in redshifts in absorption and emission spectra, in addition to enhancing the quantum yield. The benzoxazole and benzimidazole moieties in 4c and 4d demonstrated heat stability of more than 300 °C. Fluorescent intensity is directly proportional to the viscosity and 4a demonstrates a notable viscosity sensor through 1.36 fold increase in intensity. In comparison to other styryl dyes, 4c and 4d were shown to have higher values in DMSO for polarizability (53.3496 × 10−24 esu and 53.7459 × 10−24 esu) and first-order hyperpolarizability (86.3467 × 10−30 esu and 89.1941 × 10−30 esu) as well as second-order hyperpolarizability (1768.9121 × 10−36 esu and 1740.6940 × 10−36 esu) due to presence of heterocyclic character. NLO properties of all the styryl dyes 4a-4e are within the fundamental boundary limits. The 4d (benzoxazole) dye exhibited a small HOMO-LUMO energy gap of 2.8825 eV, whereas the 4b and 4e dyes had a larger band gap due to the presence of a carbonyl group.

Study of chemical reactivity and molecular interactions of the hydrochlorothiazide-4-aminobenzoic acid cocrystal using spectroscopic and quantum chemical approaches

In this study, the molecular, electronic, and chemical properties of the drug hydrochlorothiazide (HCTZ) are determined after cocrystallization with 4-aminobenzoic acid (4-ABA). Analysis has been performed to understand how those variations lead to alteration of physical properties and chemical reactivity in the cocrystal HCTZ-4ABA. IR and Raman characterizations were performed along with quantum chemical calculations. A theoretical investigation of hydrogen bonding interactions in HCTZ-4ABA has been conducted using two functionals: B3LYP and wB97X-D. The results obtained by B3LYP and wB97X-D are compared which leads to the conclusion that B3LYP is the best applied function (density functional theory) to obtain suitable results for spectroscopy. The chemical reactivity descriptors are used to understand various aspects of pharmaceutical properties. Natural bond orbital (NBO) analysis and quantum theory of atoms (QTAIM) are used to analyze nature and strength of hydrogen bonding in HCTZ-4ABA. QTAIM analyzed moderate role of hydrogen bonding interactions in HCTZ-4ABA. The calculated HOMO-LUMO energy gap shows that HCTZ-4ABA is chemically more active than HCTZ drug. These chemical parameters suggest that HCTZ-4ABA is chemically more reactive and softer than HCTZ. The results of this study suggest that cocrystals can be a good alternative for enhancing physicochemical properties of a drug without altering its therapeutic properties.

Zn(II) and Cd(II) complexes of dithiocarbamate ligands: synthesis, characterization, anticancer, and theoretical studies

ABSTRACT A potassium 4-(ethoxycarbonyl)phenyldithiocarbamate, (4-etphdtc), and 6-ethoxybenzothiazol)-dithiocarbamate, (6-etbedtc), ligands have been isolated and four metal dithiocarbamate complexes of the type [M(4-etphdtc)2] and [M(6-etbedtc)2] (M = Zn, Cd;) were synthesized and characterized by elemental analysis and spectroscopic techniques (FT-IR,1H and13C{1H}-NMR, HRMS, UV–vis). Thermogravimetric studies of all four complexes were performed and the final product of the thermal decomposition was metal sulfides. The theoretical study with density functional theory (DFT) has been utilized to optimize the structures of the complexes for HOMO–LUMO energy calculation. Non-bonding orbitals (NBO) analysis was performed to determine the numerous hyper-conjugative interactions responsible for the stability of the compound. In addition, Molecular Electrostatic Potential (MEP) analysis was conducted to identify the compounds’ electron-rich, electron-poor, reactive sites, and bonding characteristics. The Electron Localization Function (ELF), and AIM Charges are also calculated. In vitro cytotoxicity, the complexes were examined against cervical cancer cells (HeLa) to assess their reactivity. Molecular docking studies were conducted to confirm the biological activity by simulating the binding orientation and affinity of the ligands and their complexes against VEGFR-2 kinase, The investigated ligands interact with the binding site as; hydrophilic (Lys868, Glu885, His1026, Cys1045, and Asp1046) and hydrophobic (Val889 and Leu889) for 4-etphdtc; hydrophilic (Lys868, Glu885, Cys1045, and Asp1046) and hydrophobic (Val889, Leu889, Leu1035, and Phe1047) for 6-etphdtc. The calculated binding free energy values for Zn(4-etphdtc)2 and Zn(6-etphdtc)2complexes are – 9.700 kcal/mol, – 10.003 kcal/mol, respectively.

Synthesis, Characterization and Energetic Properties of Hydroxymethyl-Bishomocubanone Derivatives.

The present work reports synthesis, characterization and theoretical insights on novel hydroxymethyl-bishomocubanone derivatives. Twelve new bishomocubanes (BHCs) were synthesized and fully characterized by various spectroscopic techniques and single crystal X-ray analysis. The densities of the title compounds were in the range of 1.30-1.59 g/cm3. Density-functional theory (DFT) based calculations at B3LYP/6-311++G(d,p) level of theory were performed on ten selected BHC based cage compounds. Propulsive and ballistic properties of newly synthesized hydroxymethyl-bishomocubanone derivatives in solid and liquid propulsion systems were calculated, and the results suggested that these compounds are superior to conventional fuel RP1 and binder HTPB. The detonation parameters revealed that these compounds are not explosive in nature and safe to use as solid propellants. Furthermore, kinetic and thermal stabilities of the title compounds were determined by HOMO-LUMO energy gap, ESP maps, impact sensitivity (h50) and bond dissociation energies (BDEs) followed by thermogravimetric analysis (TGA) and differential thermal analysis (DTA). Three compounds, a dinitroazide (Isp,vac=310.98 s), a dinitrate (Isp,vac=309.51 s), and a dinitronitrate (Isp,vac=309.20s) were found to be excellent candidates for volume limited applications.

Theoretical study of the antioxidant mechanism and structure-activity relationships of 1,3,4-oxadiazol-2-ylthieno[2,3-d]pyrimidin-4-amine derivatives: a computational approach.

A theoretical thermodynamic study was conducted to investigate the antioxidant activity and mechanism of 1,3,4-oxadiazol-2-ylthieno[2,3-d]pyrimidin-4-amine derivatives (OTP) using a Density Functional Theory (DFT) approach. The study assessed how solvent environments influence the antioxidant properties of these derivatives. With the increasing prevalence of diseases linked to oxidative stress, such as cancer and cardiovascular diseases, antioxidants are crucial in mitigating the damage caused by free radicals. Previous research has demonstrated the remarkable scavenging abilities of 1,3,4-oxadiazole derivatives, prompting this investigation into their potential using computational methods. DFT calculations were employed to analyze key parameters, including bond dissociation enthalpy (BDE), ionization potential (IP), proton dissociation enthalpy (PDE), and electron transfer enthalpy (ETE), to delineate the antioxidant mechanisms of these compounds. Our findings indicate that specific electron-donating groups such as amine on the phenyl rings significantly enhance the antioxidant activities of these derivatives. The study also integrates global and local reactivity descriptors, such as Fukui functions and HOMO-LUMO energies, to predict the stability and reactivity of these molecules, providing insights into their potential as effective synthetic antioxidants in pharmaceutical applications.