Search Results (6,887)

Promethazine hydrochloride (PMH) is a first-generation antipsychotic drug created from phenothiazine derivatives that is widely employed to treat psychiatric disorders in human healthcare systems. However, an overdose or long-term intake of PMH can lead to severe health issues in humans. Hence, establishing a sensitive, accurate, and efficient detection approach to detect PMH in human samples is imperative. In this study, we designed orthorhombic copper molybdate microspheres decorated on reduced graphene oxide (Cu₃Mo₂O₉/RGO) composite via the effective one-pot hydrothermal method. The structural and morphological features of the designed hybrid were studied using various spectroscopic methods. Subsequently, the electrochemical activity of the composite-modified screen-printed carbon electrode (Cu₃Mo₂O₉/RGO/SPCE) was assessed by employing voltammetric methods for PMH sensing. Owing to the uniform composition and structural benefits, the combination of Cu₃Mo₂O₉ and RGO has not only improved electrochemical properties but also enhanced the electron transport between PMH and Cu₃Mo₂O₉/RGO. As a result, the Cu₃Mo₂O₉/RGO/SPCE exhibited a broad linear range of 0.4–420.8 µM with a low limit of detection (LoD) of 0.015 µM, highlighting excellent electrocatalytic performance to PMH. It also demonstrated good cyclic stability, reproducibility, and selectivity in the presence of chlorpromazine and biological and metal compounds. Furthermore, the Cu₃Mo₂O₉/RGO/SPCE sensor displayed satisfactory recoveries for real-time monitoring of PMH in human urine and serum samples. This study delivers a promising electrochemical sensor for the efficient analysis of antipsychotic drug molecules. Full article

The pharmacology of antimicrobial agents comprises pharmacodynamics and pharmacokinetics. Pharmacodynamics refers to studying drugs’ mode of action on their molecular targets at various concentrations and the resulting effect(s). Pharmacokinetics refers to studying the way(s) in which drugs enter the body and are distributed to their targets in various compartments (such as tissues) and how local drug concentrations are modified in time, such as by metabolism or excretion. Pharmacodynamics and pharmacokinetics constitute pivotal knowledge for establishing the breakpoints used to identify the appropriate antimicrobial agents for infection therapy. Antibiotic resistance is the biological force opposing antimicrobials’ pharmacological effects. However, we do not have a term similar to pharmacology for microbial antibiotic resistance reactions. Here, we propose the new scientific field of antechology (from the classic Greek antechó, resistance), studying the dynamics and kinetics of antibiotic resistance molecules which oppose the effect of antimicrobial drugs. Antechodynamics refers to the study of the molecular mechanisms through which antibiotic molecules are chemically modified or degraded by particular bacterial resistance enzymes (primary effectors) or drive the modification of an antibiotic’s target inhibition sites through molecules released by antibiotic action on the microorganism (secondary effectors). Antechokinetics refers to the study of the processes leading to bacterial spatial cellular (subcellular, pericellular, extracellular) localizations of the molecules involved in antibiotic detoxifying mechanisms. Molecules’ local concentrations change over time due to their production, their degradation, and ultimately their excretion rates. We will examine the antechodynamics and antechokinetics for various antimicrobial classes and the relation between pharmacodynamics/pharmacokinetics and antechodynamics/antechokinetics. Full article

Peripheral nerve injuries, caused by trauma or iatrogenic damage, often lead to permanent disabilities with limited effectiveness of current therapeutic treatments. This has driven the growing interest toward natural bioactive molecules, including ursolic acid (UA). Literature studies have shown that white grape pomace oleolyte (WGPO), a natural source of UA, is a promising candidate for promoting peripheral nerve regeneration. Considering that many neurological injuries involve compression or partial damage, the present study examined the effects of WGPO on peripheral neuropathy using a neuropathic pain mouse model. Briefly, 14 days after starting the WGPO-enriched diet, mice underwent cuffing of the right sciatic nerve to induce nerve injury and inflammation. At sacrifice, the WGPO-fed mice exhibited reduced muscle atrophy, as indicated by a greater number and larger diameter of muscle fibers, along with decreased expression of Atrogin-1 and Murf-1, compared with the injured control-diet group. To determine the functional impact of the WGPO treatment, the WGPO-supplemented group was compared with a control group receiving only sunflower oil, evaluating exercise performance post-cuffing via a treadmill test. Mice on the WGPO diet exhibited improved physical performance and a significantly lower expression of pro-inflammatory interleukins than controls. Our findings suggest WGPO as a promising candidate for managing peripheral neuropathy and related muscular impairments. Full article

Benzimidazole derivatives are well known for their anthelmintic activity. Investigating the potential efficacy of new derivatives of this class against various parasites is essential to identify novel drug candidates. For this purpose, an in-house molecular database was screened, and four benzimidazole-based molecules were chosen to evaluate antiprotozoal activity. The compounds (K1–K4) had been previously synthesized through a four-step procedure. The potential in vitro cytotoxic properties of the compounds were assessed against the Leishmania (L.) major strain and L929 mouse fibroblast cells. The tests indicated that K1 (3-Cl phenyl) demonstrated an antileishmanial effect (IC₅₀ = 0.6787 µg/mL) and cytotoxicity at elevated concentrations (CC₅₀ = 250 µg/mL) in healthy cells. These findings were comparable to those of AmpB. The antileishmanial activity values were determined as follows: K2; 8.89 µg/mL, K3; 45.11 µg/mL, K4; and 69.19 µg/mL. The CC₅₀ values were determined as follows: K2, 63 µg/mL; K3; 0.56 µg/mL; and K4, 292 µg/mL. Molecular docking and dynamic simulations were conducted to elucidate the potential mechanisms of action of the test substances. In silico investigations indicated interactions between the compounds and the active site of pteridine reductase 1 (PTR1), which is a biosynthetic enzyme essential for parasite proliferation. N-alkyl benzimidazole-based compounds exhibit potential inhibitory activity against L. (L.) major promastigotes. Therefore, these findings suggest that in vivo evaluation is warranted, and structural modifications may lead to the identification of more effective antileishmanial agents. Full article

Surface charge accumulation is considered one of the key factors that lead to unexpected insulator flashover failures in gas-insulated switchgear (GIS). With the existence of metal particles, charge accumulation characteristics on insulator surfaces become intricate in eco-friendly gases under AC voltage. In this study, the surface charge behavior on a down-scaled 252 kV AC GIS basin insulator model with a linear metal particle adhered to the HV electrode on the convex surface in compressed air (80%N₂/20%O₂) and C₄F₇N/CO₂ mixtures was investigated. After applying an AC voltage of 40 kV for 5 min, the charge densities on both surfaces were measured, and the effect of the metal particle and gas parameters was discussed. The results showed that charge spots were induced by metal particles on the insulator surfaces, and the polarities of which varied with the gas atmosphere. A decrease in maximum charge density was detected with an increase in C₄F₇N proportion at 0.1 MPa, and soar of which was observed at 0.5 MPa. With an increase in gas pressure, the maximum charge density increased in both atmospheres. The total quantity of charges showed similar behavior to the charge densities. It is indicated that the high electronegativity of C₄F₇N molecules presents a competing relationship in charge accumulation as the pressure increases. Full article

Colorectal cancer (CRC) remains the leading cause of morbidity and mortality for both men and women worldwide. Tumor-associated macrophages (TAMs) are the most abundant immune cells in the tumor microenvironment (TME) of solid tumors, including CRC. These macrophages are found in the pro-inflammatory M1 and anti-inflammatory M2 forms, with the latter increasingly recognized for its tumor-promoting phenotypes. Many signaling molecules and pathways, including AMPK, EGFR, STAT3/6, mTOR, NF-κB, MAPK/ERK, and HIFs, are involved in regulating TAM polarization. Consequently, researchers are investigating several potential predictive and prognostic markers, and novel TAM-based therapeutic targets, especially in combination therapies for CRC. Macrophages of the gastrointestinal tract, including the normal colon and rectum, produce growth hormone-releasing inhibitory peptide/somatostatin (SRIF/SST) and five SST receptors (SSTRs, SST1-5). While the immunosuppressive function of the SRIF system is primarily known for various tissues, its role within CRC-associated TAMs remains underexplored. This review focuses on the following three aspects of TAMs: first, the role of macrophages in the normal colon and rectum within the broader context of macrophage biology; second, the various bioactive factors and signaling pathways associated with TAM function, along with potential strategies targeting TAMs in CRC; and third, the interaction between the SRIF system and macrophages in both normal tissues and the CRC microenvironment. Full article

Small cell lung cancer (SCLC) remains a challenge prognostically. A clinically silent early stage and predilection for early metastasis leads to over half of patients presenting with metastatic disease at the time of diagnosis. Akin to many other cancers, once SCLC metastasizes, current therapies begin to lose their effectiveness. The future of SCLC rests in innovative treatments aimed at improving patient outcomes. Chemotherapy and radiation remain the backbone treatment for SCLC. Most patients diagnosed with SCLC begin treatment with combination chemotherapy consisting of a platinum analog and topoisomerase inhibitor with or without concurrent radiation. Disease progression or recurrence warrants new treatment approaches. New chemotherapy combinations and advances in radiation precision offer patients novel approaches using the same backbone of treatment used in many other cancers. The introduction of newer therapeutic approaches, such as immune checkpoint inhibitors, small molecule targeted therapies, bispecific antibodies, and antibody–drug conjugates offer a bright future for patients with SCLC who fail first-line therapy. This review will focus on advancing treatment paradigms for SCLC in the era of precision medicine. Such a study might be helpful for pulmonologists and oncologists to manage precisely patients with SCLC. Full article

Background: One of the challenges of applying artificial intelligence (AI) methods to drug discovery is the difficulty of laboratory synthesizability for many AI-discovered molecules. Often, in silico techniques and metrics such as the computationally enabled synthesizability score and AI-based retrosynthesis analysis are used. Methods: In this paper, we present a predictive synthesizability method that integrates the gains of synthetic accessibility scoring and the benefits of AI-driven retrosynthesis analysis tools to evaluate the synthesizability of AI-generated lead drug molecules. Results: We explored the proposed method by using it to analyze the synthesizability of a set of 123 novel molecules generated using AI models. The analysis of the synthesis route of the four best molecules from the set in terms of synthesizability, as identified using the proposed method, is presented. Conclusions: This strategy enables quick initial screening and more comprehensive actionable synthetic pathways, thereby balancing speed and detail, and favoring simple routes to avoid the risk of pursuing non-synthesizable compounds in the drug development pipeline. Full article

This review paper highlights the importance of educating current and future professionals about epigenetic mechanisms and recognizing epigenetics as a crucial model for protection against ionizing radiation. Two basic models for radiation-induced DNA damage are currently in use. The association between mutations and chromosomal aberrations provides a framework for analyzing risks at low radiation doses and exposure to small doses. However, there is no monitoring of epigenetic changes in professionals exposed to low doses of ionizing radiation. Epigenetic events regulate gene activity and expression not only during cell development and differentiation but also in response to environmental stimuli, such as ionizing radiation. Furthermore, the potential occurrence of malignant and hereditary diseases at low doses of ionizing radiation is linearly correlated and is considered a scientifically accepted assumption, despite recognized scientific limitations associated with this assessment. The aim of this review is to integrate novel and intriguing radiobiological paradigms regarding the effects of ionizing radiation on DNA methylation and epigenetic regulation of the DNA molecule. Several hypothesized biological responses to ionizing radiation are examined, linking them to epigenetic mechanisms involved in health risk assessment for professionals. The second part of the review includes published research related to epigenetics, supplementation, and virus reactivation in the context of epigenetic modifications of the DNA molecule. We hypothesize that different cycles lead to changes in the epigenome, which may be associated with the reactivation of certain viruses and the deficiency of specific dietary elements. These findings are linked to minimal deficiencies in vitamin B12 and folic acid, which may contribute to epigenomic changes. This aspect is crucial for the immune status of individuals working in high-risk environments. Full article

When studying molecular communication (MC) systems within fluid environments of the Internet of Nano Things (IoNT), fluid resistance has a significant impact on molecular transmission characteristics. In single-input multiple-output (SIMO) scenarios with multiple receivers, the interaction between fluid effects and inter-receiver interference complicates the modeling process. To address these challenges, this paper incorporates fluid resistance into a three-dimensional SIMO model and investigates the impact of the angle between receivers and the direction of the molecular pulse—considering both azimuth and polar angles—on the number of molecules received. Additionally, the interference from other receivers on the primary receiver is analyzed, and a mathematical expression for the number of received molecules is derived. Simulation results validate the model’s accuracy. The experiments show that as the distance between the interfering receiver and the transmitter increases from 0.10 m to 0.95 m, the number of molecules received by the primary receiver first rises and then falls, exhibiting a nonlinear interference pattern. Moreover, reception efficiency peaks when the receiver is positioned at a polar angle of 90° and an azimuth of 0°, with deviations from these angles leading to performance degradation. The spatial arrangement of receivers and transmitters, the number of receivers, and the initial velocity of molecules all significantly influence reception performance. Full article

Definitive endoderm (DE) differentiation leads to the development of the major internal organs including the liver, intestines, pancreas, gall bladder, prostate, bladder, thyroid, and lungs. The two primary methods utilized for in vitro differentiation of induced pluripotent stem cells (iPSCs) into DE cells are the growth factor (GF) and the small molecule (SM) approaches. The GSK-3 inhibitor (CHIR99021) is a key factor for the SM approach. Activin A and Wnt3a are utilized in the GF approach. In this study, both the GF and SM protocols were compared to each other. The results show that both the GF and SM protocol produce DE with a similar morphological phenotype, gene and protein expression, and a similar level of homogeneity and functionality. However, on both the gene expression and proteomic level, there is a divergence between the two protocols during hepatic specification. Proteomic analysis shows that hepatoblasts from the GF protocol have significantly differentially expressed proteins (DEPs) involved in liver metabolic pathways compared to the SM protocol. Well-validated DE differentiation protocols are needed to fully unlock the clinical potential of iPSCs. In the first step of generating DE-derived tissue, either protocol can be utilized. However, for hepatic specification, the GF protocol is more effective. Full article

Iron accumulation in the brain is widespread in Alzheimer’s disease (AD), the most common cause of dementia. According to numerous studies, too much iron triggers the development of neurofibrillary tangles (NFTs) and amyloid-β (Aβ) plaques, both of which accelerate the onset of AD. Iron sequestration and storage were disrupted by high iron, and the pattern of interaction between iron regulatory proteins (IRPs) and iron-responsive elements (IREs) was altered. The 5′-untranslated regions (5′-UTRs) of their APP mRNA transcripts have an IRE stem-loop, which is where iron influx enhances the translation of the amyloid precursor protein (APP). Iron regulated APP expression via the release of the repressor interaction of APP mRNA with IRP1 by a pathway similar to the iron control translation of the ferritin mRNA by the IREs in their 5′-UTRs. This leads to an uncontrolled buildup of redox active Fe²⁺, which exacerbates neurotoxic oxidative stress and neuronal death. Fe²⁺ overload upregulates the APP expression and increases the cleavage of APP and the accumulation of Aβ in the brain. The level of APP and Aβ, and protein aggregates, can be downregulated by IRPs, but are upregulated in the presence of iron overload. Therefore, the inhibition of the IRE-modulated expression of APP or Fe²⁺ chelation offers therapeutic significance to AD. In this article, I discuss the structural and functional features of IRE in the 5′-UTR of APP mRNA in relation to the cellular Fe²⁺ level, and the link between iron and AD through the amyloid translational mechanism. Although there are currently no treatments for AD, a progressive neurodegenerative disease, there are a number of promising RNA inhibitor and Fe²⁺ chelating agent therapeutic candidates that have been discovered and are being validated in April 2025 clinical trials. Future studies are expected to further show the therapeutic efficacy of iron-chelating medications, which target the APP 5′-UTR and have the ability to lower APP translation and, consequently, Aβ levels. As a result, these molecules have a great deal of promise for the development of small-molecule RNA inhibitors for the treatment of AD. Full article

To investigate the effects of water-soluble taste substances (WSTSs) on the physical properties and thermal coagulation properties of reconstituted surimi gels, this study used large yellow croaker muscle (FM) and the WSTS from by-product minced meat (MM) (skin, tail, and head meat (HM)). It was observed that these exogenous additions could effectively improve the surimi gel’s whiteness, gel strength and umami amino acid content. When these were added, the relaxation times of bound water in FM, MM and HM groups were shorter in the 10% exogenous addition treatment, and the surimi particle size (D10, D50, D90, d4, 3, d2, 3) was smaller. This implies a correlation between the WSTS and the moisture preservation capacity of recombinant surimi gels, whereby WSTS facilitates the cross-linking of protein molecules, leading to the formation of a densely interconnected network architecture. This research can provide theoretical guidance for the processing of surimi gel combined fish flavor substances and freshwater surimi, thereby improving the flavor characteristics of freshwater surimi gel. Full article

Stroke is a leading cause of morbidity and mortality worldwide, with ischemic stroke (IS) accounting for approximately 85% of cases. Recent research has highlighted the critical role of microRNAs (miRNAs), a class of small non-coding RNA molecules, in the pathogenesis of stroke. Among these, the miR-17-92 cluster and its paralogs have emerged as key regulators in the development of stroke pathology and the subsequent recovery processes. We emphasize their regulatory roles in key pathological processes, including inflammation, apoptosis, neuroprotection, and tissue repair. We provide an overview of these mechanisms to support the identification of novel miRNA-based therapeutic targets and to improve stroke diagnosis, treatment, and recovery strategies. Specific miRNAs, such as miR-19a, miR-18a, and miR-92a, contribute to processes including neurogenesis, axonal growth, and a reduction in neuronal apoptosis. The miR-17-92 cluster also offers potential therapeutic applications by targeting injury-induced pathways, such as modulating apoptosis, promoting axonal elongation, or inhibiting neurodegeneration. Preclinical studies have suggested their potential to enhance neural regeneration and promote functional recovery. Future research should further elucidate the regulatory mechanisms of the miR-17-92 members and their therapeutic potential to enhance stroke treatment strategies. Full article

A series of novel fluorescent donor–acceptor–donor (D-A-D) dyes containing [1,2,5]oxadiazolo[3,4-d]pyridazine and its 1-oxide as electron-withdrawing groups has been synthesized and thoroughly investigated using X-ray diffraction and molecular spectroscopy methods. This study showed that the introduction of N-oxide into the 1,2,5-oxadiazole ring in the acceptor fragment leads to a significant decrease in the luminescence intensity and quantum yield of the dyes. A comprehensive comparison of the photophysical properties of the obtained compounds containing the 1,2,5-oxadiazole ring with the previously studied [1,2,5]thia- and 1,2,5-selenadiazolo[3,4-d]pyridazine analogs showed that the oxygen substitution in the acceptor fragment shifts the phosphorescence maximum from the NIR region of 980–1100 nm to the red region of 690–770 nm. In contrast, for oxygen- and sulfur-containing dyes, purely red fluorescence with a maximum in the spectral range of 620–900 nm is observed. The crystal structures of furoxan-containing 3d·½CHCl₃ and furazan-containing 4d exhibit a non-planar [1,2,5]oxadiazolo[3,4-d]pyridazine fragment. We have found that short non-covalent interactions of the furoxan system with a lattice chloroform molecule in 3d lead to luminescence quenching. Meanwhile, in the 4d dye, the intermolecular π-π interactions of pyridazine nitrogen atoms with the N-carbazolyl group of the adjacent molecule should facilitate intermolecular charge transfer (ICT) emission. Thus, the luminescence maxima for these dyes can be tuned across a broad range of 700–1100 nm by varying the number of chalcogen atoms, highlighting the potential for tailoring optical properties in optoelectronic applications. Full article