CNS & neurological disorders drug targets最新文献

Drug addiction is a chronic relapsing disorder that makes it a global problem. Genetics and environmental factors are the two most important factors that make someone vulnerable to drug addiction. Investigations in the past decade highlighted the role of epigenetics in the inter/transgenerational inheritance of drug addiction. A growing body of evidence showed that parental (paternal, maternal, and biparental) drug exposure before conception changes the phenotype of the offspring, which is correlated with neurochemical and neurostructural changes in the brain. The current paper reviews the effects of parental (maternal, paternal, and biparental) exposure to drugs of abuse (opioids, cocaine, nicotine, alcohol, and cannabis) before gestation in animal models.

G-protein-coupled receptors (GPCRs) are activated by manifold neurotransmitters, and their activation, in turn, evokes slow synaptic transmission. They are profoundly related to numerous psychiatric and neurological disorders such as schizophrenia and Parkinson's disease. The significant malady indications for GPCR modulators demonstrate a change towards obesity, diabetes, and Alzheimer's disease, while other central nervous system disorders persist highly represented. GPR52, GPR6, and GPR8 are recognised as orphan GPCRs, co-exist either with both the dopamine D2 and D1 receptors in neurons of the basal ganglia or with the dopamine D2 receptor alone, and recommend that between these orphan receptors, GPR52 has the maximum potential of being a therapeutic psychiatric receptor. Genetically modified creature models and molecular biological investigations have suggested that these improved GPCRs could be potential therapeutic psychiatric receptors. In this perspective, the role of molecular targets in GPCR-mediated signalling has been discussed that would be novel drug design and discovery options for a scientist to elaborate previous knowledge with modern techniques.

Background: Depression and anxiety belong to a family of mental disturbances that have increased significantly in recent years. The etiology of both disorders comprises multiple and complex factors, from genetic background to environmental influence. Since depression and anxiety present severe symptoms, they represent a greater clinical burden and greater therapeutic difficulty. Currently, standardized diagnostic procedures for depression and anxiety allow for the addition of further treatments, including psychotherapy and/or pharmacological intervention, with effective outcomes. However, further steps should be considered with regard to consideration of the endocannabinoid system's role in depression and anxiety.

Objective: This study aimed to review the evidence from animal research and clinical studies on the role of cannabinoid receptors, the major endocannabinoids -anandamide (AEA) and 2-arachidonoylglycerol (2-AG)- and the enzymes related to the synthesis and degradation of these chemicals as putative biomarkers for diagnostic and therapeutic elements of depression and anxiety.

Methods: This review included the online search, identification, and analysis of articles (basic and clinical trials) published in English in PubMed linked to the role of cannabinoid receptors, AEA, 2- AG, and the enzymes associated with the synthesis and degradation of these endocannabinoids in depression and anxiety.

Results: The neurobiological relevance of the endocannabinoid system offers genetic or pharmacological manipulation of this system as a potential strategy for the diagnostic and clinical management of mood disorders, including depression and anxiety.

Conclusion: Although the described approach in this review is promising, no solid evidence is yet available, and along with additional experiments using animal models that mimic human depression and anxiety, clinical trials are needed to explore the role of the endocannabinoid system's elements as well as the anandamide membrane transporter, none of which have been adequately studied in depression and anxiety.

Drug design is one of the critical aspects of the drug development process. The present review focused on different heterocyclic molecules having anticonvulsant activity with structural diversity and common pharmacophoric features. For the first time (1995), Dimmock and his team introduced specific arrangements of three important pharmacophores for anticonvulsant activity. These pharmacophores include two hydrophobic binding sites and one hydrogen binding site. After a few years (2012), Pandeya modified Dimmock's concept by adding one more pharmacophoric feature as an electron donor in the previously suggested pharmacophoric arrangement of the anticonvulsant. As a result, numerous scientists designed anticonvulsant drugs based on Dimmock's and Pandeya's concept. In addition, marketed anticonvulsant preparation containing Riluzole, Phenobarbital, Progabide, Ralitoline, etc., also holds the suggested pharmacophores by Dimmock and Pandeya's pharmacophoric concept. This review mainly focuses on the compilation of reported scientific literature in the last decade on the pharmacophoric features of different heterocyclic anticonvulsants, which will help develop new anticonvulsants.

The behavior of an individual changes from neonate to elderly due to the development of the central nervous system (CNS). One of the important components of the CNS is the cerebrospinal fluid (CSF), which bathes the brain and spinal cord. CSF has changing properties throughout life, including composition and volume imbalance. However, a specific age group that shows prevailing abnormality- corresponding behavior remains unclear. The objective of this article is to explore how such changes reflect on one's psychological as well as physical processing. Production of CSF could be affected by many factors, including its flow, absorption, volume, and composition. Prenatally, congenital malformations and infections hold the greatest risk of impacting the child's physical and mental growth. In adolescents, transmission of external substances like alcohol or drugs in the cerebrospinal fluid is known to impact severe mood changes that potentially result in suicide and depression. In the adult working population, the influence of stress levels on CSF composition causes anxiety and sleep disorders. Finally, the reduced production of CSF was found to be associated with memory deficits and Alzheimer's disease in the aging group. From the collected evidence, it can be observed that CSF played an important role in behavioral changes and may be associated with neurodegenerations. By linking the CSF abnormalities to the clinical symptoms at different stages of life, it may provide additional information in the diagnosis of diseases that are associated with neuropsychological changes.

Background: Chemotherapy with the oral alkylating agent temozolomide still prevails as a linchpin in the therapeutic regimen of glioblastoma alongside radiotherapy. Because of the impoverished prognosis and sparse chemotherapeutic medicaments associated with glioblastoma, the burgeoning resistance to temozolomide has made the whole condition almost irremediable.

Objective: The present review highlights the possible mechanisms of drug resistance following chemotherapy with temozolomide.

Methods: The review summarizes the recent developments, as published in articles from Scopus, PubMed, and Web of Science search engines.

Description: One of the prime resistance mediators, O-6-methylguanine-DNA methyltransferase, upon activation, removes temozolomide-induced methyl adducts bound to DNA and reinstates genomic integrity. In the bargain, neoteric advances in the conception of temozolomide resistance have opened the door to explore several potential mediators like indirect DNA repair systems, efflux mechanisms, epigenetic modulation, microenvironmental influences, and autophagy-apoptosis processes that constantly lead to the failure of chemotherapy.

Conclusion: This review sheds light on recent discoveries, proposed theories, and clinical developments in the field of temozolomide resistance to summarize the complex and intriguing involvement of oncobiological pathways.

Background and objective: Parkinson's disease (PD) is a neurodegenerative disorder characterized by the degeneration of the dopaminergic neurons in the substantia nigra pars compacta, resulting in the loss of dopamine in the striatum, leading thus to the PD classic movement symptoms: resting tremor, rigidity, and bradykinesia/akinesia. Furthermore, Levodopa's efficacy declines with long-term use, generating serious motor complications. Neuroprotection implies the use of different agents exhibiting various neuroprotective strategies to prevent brain degeneration and neuron loss. The present review aims to summarize and analyze the natural neuroprotective compounds that have been tested against PD induced by the 6-hydroxydopamine (6-OHDA) in zebrafish.

Results: The current study collected 23 different natural substances, divided into five distinct categories, namely herbal extracts, herbal formulations, bioactive compounds, marine products, and marine extracts. They modulate various signaling pathways involved in PD pathogenesis and exhibit specific activities such as an anxiolytic profile, improving locomotor impairment, restoring memory troubles, preventing DNA loss, inhibiting acetylcholinesterase, reducing lipid peroxidation and antiinflammatory activity, and enhancing the brain antioxidant enzymes.

Conclusion and perspectives: This review discusses the most promising natural neuroprotective compounds that have been evaluated for their potential efficiency on the 6-OHDA-induced lesions in the zebrafish model. These natural substances deserve further consideration for determination of their optimum concentrations, bioavailability, and their ability to cross the blood-brain-barrier to exert their effects on PD. Furthermore, a complete understanding of the molecular mechanisms involved in PD and larger epidemiologic and randomized clinical trials in humans is also required.