Azadirachta indica leaves mediated green synthesized copper oxide nanoparticles induce apoptosis through activation of TNF-α and caspases signaling pathway against cancer cells

Green nanotechnology elucidates highly prioritized anticancer activity. We synthesized Copper oxide nanoparticles (CuONPs) using leaves of Azadirachta indica (A. indica) plants and studied the molecular mechanism of cancer cell apoptosis. After their synthesis, with the help of expository tools like Fourier transform infrared spectroscopy (FT-IR), Transmission electron microscopy (TEM), Dynamic light scattering (DLS) and surface zeta potential we confirmed the successful synthesis of CuONPs. Here, crystalline structure of green synthesized CuONPs of 36?±?8?nm size and spherical shape was able to kill MCF-7 and Hela cells, estimated by MTT assay. Successful internalization of Cu⁺² ions inside the cell was estimated by the atomic absorption study. Cellular uptake of Cu⁺² ions inflicted significant Reactive Oxygen Species (ROS) generation inside the cancer cells, thereby leading to DNA fragmentation as observed by DAPI staining. In in vivo model, CuONPs reduced the breast tumor volume in Balb/C mice and increased the mean survival time through the alteration of pro-inflammatory cytokines level. In case of both in vivo and in vitro models, CuONPs altered the pro-inflammatory cytokine level and pro-apoptotic protein expressions. In future, green synthesized CuONPs might be beneficial for its application as an anticancer drug in in vivo (mice model) and in vitro, though further study is needed on its toxicity.     

An access to α, β-unsaturated ketones via dual cooperative catalysis

A dual cooperative organocatalytic approach for the synthesis of α, β-unsaturated ketones is described. This one pot transformation is realized via a domino Knoevenagel-Michael-retro Michael reaction sequence. Various aliphatic ketones reacted smoothly with aromatic as well as aliphatic aldehydes in presence catalytic amount of Meldrum’s acid and bifunctional amine. The highlights of this protocol are the easy availability of catalysts, high selectivity, and functional group tolerance. The reaction proved to highly E-selective with no side products emanating from self-condensation, unlike the base-mediated reactions.     

Thermoreversible Gelation of Polybenzimidazole in Phosphoric Acid

Summary: We report a study of thermoreversible gelation of polybenzimidazole (PBI) in phosphoric acid (PA). The PBI gel in PA exhibits fibrillar network morphology and reversible first order phase transition. The gelation rate is measured by the tube tilting method and found to depend both upon gelation concentration and gelation temperature. The UV‐vis study demonstrates that the gelation process is a two‐step process: conformational transformation and aggregation which produces crystallites for gel formation. The WAXS study supports the presence of crystallites in the gel. The PA doping level of the membrane increases significantly because of gelation.

Thermoreversible gelation of polybenzimidazole in phosphoric acid and the membrane produced from the gel.     

Perturbation of the PET process in fluorophore-spacer-receptor systems through structural modification: transition metal induced fluorescence enhancement and selectivity

Several fluorescent signaling systems are built in the format fluorophore-spacer-receptor with ethylenediamine or N,N-dimethylethylenediamine as the receptor, anthracene as the fluorophore, and a methylene group as the spacer. The receptors are derivatized with different electron-withdrawing groups such as 4-nitrobenzene, 4-nitro-2-pyridine, and 2,4-dinitrobenzene, to perturb the photoinduced intramolecular electron transfer (PET) process from the nitrogen lone-pair to the fluorophore. The photophysical properties of these supramolecular systems and their fluorescence responses toward a number of quenching transition metal ions are reported. It is shown that the PET is highly efficient in the absence of a metal ion. With a metal ion input, the fluorescence can be recovered to a different extent depending on the nature of the metal and on the overall architecture of the system as well. Despite the possibility of strong interaction between the fluorophore and the metal ion, significant fluorescence enhancement is observed with quenching of paramagnetic transition metal ions. The complex stability data show that the stability constants for the metal ions showing fluorescence enhancement are of the order of 10(4) M(-1). This study shows that structurally simple fluorescent signaling systems for quenching transition metal ions can be built by maximizing the PET. It is also shown here that simple structural modification can make these systems highly specific for particular transition metal ions for potential applications in several contemporary areas of research.     

Mechanical heterogeneities in model polymer glasses at small length scales

Molecular simulations of a model, deeply quenched polymeric glass show that the elastic moduli become strongly inhomogeneous at length scales comprising several tens of monomers; these calculations reveal a broad distribution of local moduli, with regions of negative moduli coexisting within a matrix of positive moduli. It is shown that local moduli have the same physical meaning as that traditionally ascribed to moduli obtained from direct measurements of local constitutive behaviors of macroscopic samples.     

Influence of confinement on the vibrational density of states and the Boson peak in a polymer glass

We have performed a normal-mode analysis on a glass forming polymer system for bulk and free-standing film geometries prepared under identical conditions. It is found that for free-standing film glasses, the normal-mode spectrum exhibits significant differences from the bulk glass with the appearance of an additional low-frequency peak and a higher intensity at the Boson peak frequency. A detailed eigenvector analysis shows that the low-frequency peak corresponds to a shear-horizontal mode which is predicted by continuum theory. The peak at higher frequency (Boson peak) corresponds to motions that are correlated over a length scale of approximately twice the interaction site diameter. These observations shed some light on the microscopic dynamics of glass formers, and help explain decreasing fragility that arises with decreasing thickness in thin films.     

SU(3) breaking in pseudoscalar-meson charge radii from QCD sum rules

TheSU(3)-symmetry breaking observed in theπ ⁺,K ⁺ andK ⁰ charge-radii or, equivalently, in the ?ππ, ?KK and φKK coupling constants is discussed in the Shifman-Vainshtein-Zakharov approach to three-point functions in the symmetrical subtraction configuration. The results are very stable and in good agreement with the data.     

Design of a fused triazolyl 2-quinolinone unnatural nucleoside via tandem CuAAC-Ullmann coupling reaction and study of photophysical property

This report presents the design and synthesis of a novel fused triazolyl 2-quinolinone (FTQuon) nucleoside as a new generation of angularly widened unnatural nucleobase surrogate with two possible H-bonding faces-one H-bond acceptor and another donor. The synthesis via a tandem CuAAC-Ullmann coupling, the study of photophysical properties and theoretical calculation in the context of DNA are the main contents of this report. The newly designed nucleoside shows interesting photphysical property with slight blue shifted solvatochromicity. It also shows pH sensitive emission. All the theoretical DNA duplexes containing the FTQuon show right?handed B-form helicity as revealed from a molecular dynamics simulation using Schrodinger Macromodel. A theoretical (DFT) study indicates a good stabilizing property of FTQuon via pairing with natural pyrimidine bases. It also shows good interaction property with BSA protein signalled via a switch on fluorescence response.     

Manganese‐Doping‐Induced Quantum Confinement within Host Perovskite Nanocrystals through Ruddlesden–Popper Defects

The concept of doping Mn²⁺ ions into II–VI semiconductor nanocrystals (NCs) was recently extended to perovskite NCs. To date, most studies on Mn²⁺ doped NCs focus on enhancing the emission related to the Mn²⁺ dopant via an energy transfer mechanism. Herein, we found that the doping of Mn²⁺ ions into CsPbCl₃ NCs not only results in a Mn²⁺‐related orange emission, but also strongly influences the excitonic properties of the host NCs. We observe for the first time that Mn²⁺ doping leads to the formation of Ruddlesden–Popper (R.P.) defects and thus induces quantum confinement within the host NCs. We find that a slight doping with Mn²⁺ ions improves the size distribution of the NCs, which results in a prominent excitonic peak. However, with increasing the Mn²⁺ concentration, the number of R.P. planes increases leading to smaller single‐crystal domains. The thus enhanced confinement and crystal inhomogeneity cause a gradual blue shift and broadening of the excitonic transition, respectively.