Current Naturopathy to Combat Alzheimer's Disease.

Neurodegeneration is the progressive loss of structure or function of neurons, which may ultimately involve cell death. The most common neurodegenerative disorder in the brain happens with Alzheimer's disease (AD), the most common cause of dementia. It ultimately leads to neuronal death, thereby impairing the normal functionality of the central or peripheral nervous system. The onset and prevalence of AD involve heterogeneous etiology, either in terms of genetic predisposition, neurometabolomic malfunctioning, or lifestyle. The worldwide relevancies are estimated to be over 45 million people. The rapid increase in AD has led to a concomitant increase in the research work directed towards discovering a lucrative cure for AD. The neuropathology of AD comprises the deficiency in the availability of neurotransmitters and important neurotrophic factors in the brain, extracellular betaamyloid plaque depositions, and intracellular neurofibrillary tangles of hyperphosphorylated tau protein. Current pharmaceutical interventions utilizing synthetic drugs have manifested resistance and toxicity problems. This has led to the quest for new pharmacotherapeutic candidates naturally prevalent in phytochemicals. This review aims to provide an elaborative description of promising Phyto component entities having activities against various potential AD targets. Therefore, naturopathy may combine with synthetic chemotherapeutics to longer the survival of the patients.

Natural Sourced Inhibitors of EGFR, PDGFR, FGFR and VEGFRMediated Signaling Pathways as Potential Anticancer Agents.

The molecular mechanisms of mitotic cell cycle progression involve very tightly restricted types of machinery which are highly regulated by a fine balance between the positive and negative accelerators (or regulators). These regulators include several checkpoints that have proteins acting as enzymes and their activating partners. These checkpoints incessantly monitor the external as well as internal environments such as growth signals, favorable conditions for growth, cell size, DNA integrity of the cell and hence function to maintain the highly ordered cell cycle progression by sustaining cell homeostasis and promoting error-free DNA replication and cell cycle division. To progress through the mitotic cell cycle, the cell has to successfully drive past the cell cycle checkpoints. Due to the abnormal behavior of some cell cycle proteins, the cells tend to divide continuously overcoming the tight regulation of cell cycle checkpoints. Such anomalies may lead to unwanted cell division, and this deregulation of cell cycle events is considered as one of the main reasons behind tumor development, and thus, cancer progression. So the understanding of the molecular mechanisms in cancer progression might be insightful for designing several cancer treatment strategies. The deregulation in the checkpoints is caused due to the changes in the tyrosine residues of TPKs via PDGFR, EGFR, FGFR, and VEGFR-mediated signaling pathways. Therefore, the inhibitors of PDGFR, EGFR, FGFR, and VEGFR-mediated signaling pathways could be potential anticancer agents. The resistance and toxicity in the existing synthetic anticancer chemotherapeutics may decrease the life span of a patient. For long, natural products have played an essential alternative source of therapeutic agents due to having least or no side effect and toxicity. The present study is an attempt to promote natural anticancer drug development focusing on the updated structural information of PDGFR, EGFR, FGFR, and VEGFR inhibitors isolated from the plant sources. The data used in this review has been collected from internet resources, viz. GOOGLE Web, GOOGLE SCHOLAR, and PubMed Central. The citation of each report was first checked, after which the articles were selected as an authentic reference for the present study. Around 200 journal articles were initially selected, of which around 142 were finally chosen for presenting the study on the natural sourced inhibitors of EGFR, PDGFR, FGFR, and VEGFR-mediated signaling pathways which may help to enhance the potential cancer treatment.

Exploring the Potential Inhibition of Candidate Drug Molecules for Clinical Investigation Based on their Docking or Crystallographic Analyses against M. tuberculosis Enzyme Targets.

Tuberculosis (TB) is a devastating disease responsible for millions of humans' deaths worldwide. It is caused by a mycobacterial organism, the tubercle bacillus or Mycobacterium tuberculosis. Although TB can be treated, cured and can be prevented if patients take prescribed medicines, scientists have never come close to wiping it out due to a sharp rise in the incidence of multidrug-resistant (MDR) and extensively drug-resistant (XDR) mycobacterium strains. Due to long regimen treatment and emergence of MDR and XDR-TB, it is urgent to re-engineer and reposition old drugs for developing new antimycobacterial entities with novel mechanisms of action to achieve effective TB control even against the resistant forms of TB. To combat the dreadful MDR and XDR-TB, potential targets are being extensively searched for the last couple of years for the design and discovery of active potential antitubercular chemotherapeutics. To explore the disease virulence, potential new tubercular target enzymes such as InhA, MmpL3, ATP synthase, DprE1, QcrB and MenA have been taken into consideration in the present study and the structure-based design of the corresponding target inhibitors which are under clinical investigation has been attempted to identify structural features for the discovery of new chemical entities (NCEs) having specificity towards MDR and XDR Mycobacterium tuberculosis (M. tuberculosis).

Novel Glycoprotein VI Antagonists as Antithrombotics: Synthesis, Biological Evaluation, and Molecular Modeling Studies on 2,3-Disubstituted Tetrahydropyrido(3,4-b)indoles.

The development of small molecule inhibitors targeting GPVI has promising therapeutic role, as they inhibit arterial thrombosis with limited risk of bleeding. Among the compounds showing in vivo antithrombotic activity, the most active compound 6b (ED50 = 28.36 µmol/kg po in mice) showed improved inhibition for collagen (IC50 = 6.7 µM), CRP-XL (IC50 = 53.5 µM), and convulxin (CVX) (IC50 = 5.7 µM) mediated platelet aggregation as compared to losartan (LOS) (collagen, IC50 = 10.4 µM; CRP-XL, IC50 = 158 µM; CVX, IC50 = 11 µM) than any of its enantiomers S (6c) (collagen, IC50 = 25.3 µM; CRP-XL, IC50 = 181.4 µM; CVX, IC50 = 9 µM) and R (6d) (collagen, IC50 = 126.3 µM; CRP-XL, IC50 > 500 µM; CVX, IC50 = 86.8 µM). Compound 6b also inhibited platelet P-selectin expression and thus may diminish atherosclerosis. The molecular interactions of both enantiomers 6c and 6d at the GPVI receptor have been explained through docking studies.

Cohort profile: the German Diabetes Study (GDS).

BACKGROUND: The German Diabetes Study (GDS) is a prospective longitudinal cohort study describing the impact of subphenotypes on the course of the disease. GDS aims at identifying prognostic factors and mechanisms underlying the development of related comorbidities. STUDY DESIGN AND METHODS: The study comprises intensive phenotyping within 12 months after clinical diagnosis, at 5-year intervals for 20 years and annual telephone interviews in between. Dynamic tests, including glucagon, mixed meal, intravenous glucose tolerance and hyperinsulinemic clamp tests, serve to assess beta-cell function and tissue-specific insulin sensitivity. Magnetic resonance imaging and multinuclei spectroscopy allow quantifying whole-body fat distribution, tissue-specific lipid deposition and energy metabolism. Comprehensive analyses of microvascular (nerve, eye, kidney) and macrovascular (endothelial, cardiorespiratory) morphology and function enable identification and monitoring of comorbidities. The GDS biobank stores specimens from blood, stool, skeletal muscle, subcutaneous adipose tissue and skin for future analyses including multiomics, expression profiles and histology. Repeated questionnaires on socioeconomic conditions, patient-reported outcomes as quality of life, health-related behavior as physical activity and nutritional habits are a specific asset of GDS. This study will recruit 3000 patients and a group of humans without familiy history of diabetes. 237 type 1 and 456 type 2 diabetes patients have been already included.

Drug/drug interaction of common NSAIDs with antiplatelet effect of aspirin in human platelets.

Nonsteroidal anti-inflammatory drugs (NSAIDs) may interfere with the anti-platelet activity of aspirin at the level of the platelet cyclooxygenase-1 (COX-1) enzyme. In order to examine the interference of common NSAIDs with the anti-platelet activity of aspirin the human platelet rich plasma from voluntary donors was used for arachidonic acid-induced aggregation and determination of thromboxane synthesis. Further, docking studies were used to explain the molecular basis of the NSAID/aspirin interaction. The experimental results showed that celecoxib, dipyrone (active metabolite), ibuprofen, flufenamic acid, naproxen, nimesulide, oxaprozin, and piroxicam significantly interfere with the anti-platelet activity of aspirin, while diclofenac, ketorolac and acetaminophen do not. Docking studies suggested that NSAIDs forming hydrogen bonds with Ser530, Arg120, Tyr385 and other amino acids of the COX-1 hydrophobic channel interfere with antiplatelet activity of aspirin while non interfering NSAIDs do not form relevant hydrogen bond interactions within the aspirin binding site. In conclusion, docking analysis of NSAID interactions at the COX-1 active site appears useful to predict their interference with the anti-platelet activity of aspirin. The results, demonstrate that some NSAIDs do not interfere with the antiplatelet action of aspirin while many others do and provide a basis for understanding the observed differences among individual non-aspirin NSAIDs.