Micellar Choline-Acetyltransferase Complexes Exhibit Ultra-Boosted Catalytic Rate for Acetylcholine Synthesis-Mechanistic Insights for Development of Acetylcholine-Enhancing Micellar Nanotherapeutics.

Choline-acetyltransferase (ChAT) is the key cholinergic enzyme responsible for the biosynthesis of acetylcholine (ACh), a crucial signaling molecule with both canonical neurotransmitter function and auto- and paracrine signaling activity in non-neuronal cells, such as lymphocytes and astroglia. Cholinergic dysfunction is linked to both neurodegenerative and inflammatory diseases. In this study, we investigated a serendipitous observation, namely that the catalytic rate of human recombinant ChAT (rhChAT) protein greatly differed in buffered solution in the presence and absence of Triton X-100 (TX100).

R(3780) Resonance Interpreted as the 1^{3}D_{1}-Wave Dominant State of Charmonium from Precise Measurements of the Cross Section of e^{+}e^{-}→Hadrons.

We report the precise measurements of the cross section of e^{+}e^{-}→hadrons at center-of-mass energies from 3.645 to 3.871 GeV.

Origin of the Suppression of Magnetic Order in MnSi under Hydrostatic Pressure.

We experimentally study the evolution of the magnetic moment m and exchange interaction J as a function of hydrostatic pressure in the zero-field helimagnetic phase of the strongly correlated electron system MnSi. The suppression of magnetic order at ≈1.5  GPa is shown to arise from the J collapse and not from a quantum fluctuations induced reduction of m.

Fabrication and characterization of ConA-conjugated curcumin-loaded solid lipid nanoparticles for theranostic applications in lung cancer treatment.

The main issues with current and traditional cancer therapy delivery systems include a lack of selectivity towards tumors, causing harm to healthy cells, low efficiency in loading drugs, and the inability to visually track the drug's localization after administration. These limitations negatively impact the effectiveness of therapy and result in increased treatment costs. Furthermore, conventional cancer therapies typically target tumor cells through a single mechanism, which eventually leads to the emergence of drug resistance.

Optimal adaptive SMART designs with binary outcomes.

In a sequential multiple-assignment randomized trial (SMART), a sequence of treatments is given to a patient over multiple stages. In each stage, randomization may be done to allocate patients to different treatment groups. Even though SMART designs are getting popular among clinical researchers, the methodologies for adaptive randomization at different stages of a SMART are few and not sophisticated enough to handle the complexity of optimal allocation of treatments at every stage of a trial.

Biochemical and steady-state kinetic analyses of arsenate reductases from an arsenic-tolerant strain of Citrobacter youngae IITK SM2.

Arsenic (As) poisoning in aquifers is a serious problem worldwide, especially in the middle-Gangetic Plain (MGP) of India. Microbially-mediated As speciation in such aquifers is governed by the arsenate-reductase enzyme, ArsC, encoded by the arsC gene of As-metabolizing bacteria. In this study, ArsC1 (119 aa) and ArsC2 (141 aa) of a highly resistant strain to arsenic, Citrobacter youngae IITK SM2 (CyIITKSM2), isolated from a mixed-oxic MGP groundwater were biochemically characterized.

Iodine-Catalyzed Regioselective C-3 Chalcogenation of 7-Azaindoles: Access to Benzothiophene-Fused 7-Azaindole Analogs.

An iodine-catalyzed method has been reported for efficient regioselective C-3 sulfenylation, selenylation, thiocyanation, and selenocyanation of -free 7-azaindoles using thiophenols, diselenides, potassium thiocyanates, and selenocyanates, respectively. This approach showcases high efficiency and remarkable versatility, facilitating the synthesis of diverse chalcogenated 7-azaindoles. Additionally, the sulfenylated derivatives have been further diversified to generate a new array of benzothiophene-fused 7-azaindole cores of pharmaceutical interest.

MARTINI Coarse-Grained Force Field for Thermoplastic Starch Nanocomposites.

Thermoplastic starch (TPS) is an excellent film-forming material, and the addition of fillers, such as tetramethylammonium-montmorillonite (TMA-MMT) clay, has significantly expanded its use in packaging applications. We first used an all-atom (AA) simulation to predict several macroscopic (Young's modulus, glass transition temperature, density) and microscopic (conformation along 1-4 and 1-6 glycosidic linkages, composite morphology) properties of TPS melt and TPS-TMA-MMT composite. The interplay of polymer-surface (weakly repulsive), plasticizer-surface (attractive), and polymer-plasticizer (weakly attractive) interactions leads to conformational and dynamics properties distinct from those in systems with either attractive or repulsive polymer-surface interactions.

Copper-assisted anticancer activity of hydroxycinnamic acid terpyridine conjugates on triple-negative breast cancer.

The development of active therapeutic agents to treat highly metastatic cancer while minimizing damage to healthy cells is of utmost importance. Due to potential antioxidant properties, hydroxycinnamic acid derivatives (caffeic acid and -coumaric acids) were found to inhibit highly metastatic breast cancer cell growth both and without much effect on normal cells. Especially due to the structure-activity relationships, ester and amide derivatives of hydroxycinnamic acids are reported to gain much higher radical scavenging ability than their naked hydroxycinnamic acid analogs like caffeic acid and -coumaric acid.

Synthesis of N-Methyluridine- and 2'-O-Alkyl/2'-Fluoro-N-Methyluridine-Modified Phosphoramidites and Their Incorporation into DNA and RNA Oligonucleotides.

In this article, we describe the synthesis of N-methyluridine (mU) and 2'-O-alkyl/2'-fluoro-N-methyluridine (2'-O-alkyl/2'-F-mU) phosphoramidites as well as their incorporation into a 14-mer DNA and RNA oligonucleotide sequence. Synthesis of the 2'-O-alkyl-mU phosphoramidite starts with commercially available uridine to achieve a tritylated mU intermediate, followed by 2'-O-alkylation and finally phosphitylation. Synthesis of the 2'-F-mU phosphoramidite is obtained from a commercially available 2'-F-uridine nucleoside.

Drug-Induced Differential Gene Expression Analysis on Nanoliter Droplet Microarrays: Enabling Tool for Functional Precision Oncology.

Drug-induced differential gene expression analysis (DGEA) is essential for uncovering the molecular basis of cell phenotypic changes and understanding individual tumor responses to anticancer drugs. Performing high throughput DGEA is challenging due to the high cost and labor-intensive multi-step sample preparation protocols. In particular, performing drug-induced DGEA on cancer cells derived from patient biopsies is even more challenging due to the scarcity of available cells.

Folic acid-targeted redox responsive polylactic acid-based nanoparticles co-delivering pirarubicin and salinomycin suppress breast cancer tumor growth .

Targeted cancer therapy using nanocarriers has emerged as a promising solution to the majority of drawbacks associated with conventional chemotherapy. The present research work describes the development of folic acid (FA)-targeted redox responsive [S-(PLA--PEG-CONH)] polymeric nanoparticles for the co-delivery of pirarubicin (Pira) and salinomycin (Sal). The nanoparticles' redox responsiveness arises from embedded disulfide bonds within the polymer, which gradually break in response to high GSH levels in tumors, enabling sustained drug release.

Camptothecin and its derivatives: Advancements, mechanisms and clinical potential in cancer therapy.

Camptothecin (CPT), an alkaloid isolated from the Camptotheca tree, has demonstrated significant anticancer properties in a range of malignancies. However, its therapeutic efficacy is limited by its hydrophobicity, poor bioavailability, and systemic toxicity. Derivatives, analogues, and nanoformulations of CPT have been synthesized to overcome these limitations.

Computational Insights Into the Mechanism of EGCG's Binding and Inhibition of the TDP-43 Aggregation.

Misfolding and aggregation of TAR DNA-binding protein, TDP-43, is linked to devastating proteinopathies such as ALS. Therefore, targeting TDP-43's aggregation is significant for therapeutics. Recently, green tea polyphenol, EGCG, was observed to promote non-toxic TDP-43 oligomer formation disallowing TDP-43 aggregation.

Therapeutic potential of 18-β-glycyrrhetinic acid-loaded poly (lactic-co-glycolic acid) nanoparticles on cigarette smoke-induced in-vitro model of COPD.

Chronic obstructive pulmonary disease (COPD) is strongly linked to cigarette smoke, which contains toxins that induce oxidative stress and airway inflammation, ultimately leading to premature airway epithelial cell senescence and exacerbating COPD progression. Current treatments for COPD are symptomatic and hampered by limited efficacy and severe side effects. This highlights the need to search for an optimal therapeutic candidate to address the root causes of these conditions.

Epigallocatechin-3-gallate Synergistically Inhibits the Proliferation of Lung Cancer Cells with Gemcitabine by Induction of Apoptosis Mediated by ROS Generation.

The present study focused on the formulation, characterization, and evaluation of solid lipid nanoparticles (SLNs) loaded with gemcitabine (GEM) and epigallocatechin-3-gallate (EGCG) for lung cancer treatment. A 2-level, 3-factor factorial design was used to optimize various process parameters in the preparation of SLNs. The average particle size and polydispersity index (PDI) of GEM-EGCG SLNs were found to be 122.