Scientific Technological Center of Organic and Pharmaceutical Chemistry of National Academy of Sciences of Republic of Armenia, Ave. Azatutyan 26, Yerevan 0014, Armenia; Eurasia International University of Republic of Armenia, Pharmacy faculty, Ave. Azatutyan 24/2, Yerevan 0014, Armenia.
Faculty of Chemistry, Moscow State University, 1, GSP-1, 1-3 Leninskiye Gory, 119991 Moscow, Russia.
Bioorg Chem. 2024 Jul;148:107435. doi: 10.1016/j.bioorg.2024.107435. Epub 2024 May 8.
Pyridine and its derivatives play a vital role in medicinal chemistry, serving as key scaffolds for drugs. The ability to bind to biological targets makes pyridine compounds significant, sparking interest in creating new pyridine-based drugs. Thus, the purpose of the research is to synthesize new thioalkyl derivatives of pyridine, predict their biological spectrum, study their psychotropic properties, and based on these findings, perform structure-activity relationships to assess pharmacophore functional groups.
Classical organic methods were employed for synthesizing new thioalkyl derivatives of pyridine, with a multifaceted pharmacological profiles. Various software packages and methods were employed to evaluate the biological spectrum of the newly synthesized compounds. For the evaluation of neurotropic activity of new synthesized compounds, some biological methods were used according to indicators characterizing anticonvulsant, sedative and antianxiety activity as well as side effects.
Effective synthetic methods for 6-amino-4-phenyl-2-thio-2H-thiopyran-5-carboxylic acid ethyl ester, 2-amino substituted thiopyridine derivatives and 6-cycloamino-2-thioalkyl-4-phenylnicotinate derivatives were obtained in high yield. Predicted biological spectra and pharmacokinetic data indicated high gastrointestinal absorption and low blood-brain barrier passage for most compounds and demonstrated potential various biological effects, particularly psychotropic properties. Studied compounds demonstrated high anticonvulsant activity through antagonism with pentylenetetrazole. They exhibited low toxicity without inducing muscle relaxation in the studied doses. In psychotropic studies, the compounds displayed activating, sedative, and anxiolytic effects. Notably, the 6-amino-2-thioalkyl-4-phenylnicotinate derivatives demonstrated significant anxiolytic activity (about four times more compared to diazepam). They also exhibited pronounced sedative effects. Ethyl 2-({2-[(diphenylmethyl)amino]-2-oxoethyl}thio)-4-phenyl-6-pyrrolidin-1-ylnicotinate exhibited anxiolytic activity even two times greater than diazepam. Moreover, all studied compounds showed statistically significant antidepressant effects. Noteworthy ethyl 2-({2-oxo-2-[(tetrahydrofuran-2-ylmethyl)amino]ethyl}thio)-4-phenyl-6-pyrrolidin-1-ylnicotinate showcasing its unique psychotropic effect.
The selected compounds demonstrate anticonvulsant properties, activating behavior, and anxiolytic effects, while simultaneously exhibiting antidepressant effects and these compounds as promising candidates for further exploration in the development of therapeutics with a broad spectrum of neuropsychiatric applications.
吡啶及其衍生物在药物化学中具有重要作用,是药物的关键骨架之一。吡啶化合物具有与生物靶标结合的能力,因此引起了人们对开发新型吡啶类药物的兴趣。因此,本研究旨在合成新型的吡啶硫烷基衍生物,预测其生物谱,研究其精神活性,并根据这些发现进行构效关系以评估药效基团的功能。
采用经典的有机方法合成具有多方面药理特性的新型吡啶硫烷基衍生物。使用各种软件包和方法评估新合成化合物的生物谱。为了评估新合成化合物的神经毒性活性,根据抗惊厥、镇静和抗焦虑活性以及副作用的指标,使用了一些生物学方法。
成功地以高产率获得了 6-氨基-4-苯基-2-硫代-2H-噻吩-5-羧酸乙酯、2-氨基取代的噻吩吡啶衍生物和 6-环氨基-2-硫代烷基-4-苯基烟酸盐衍生物等有效合成方法。预测的生物谱和药代动力学数据表明,大多数化合物具有较高的胃肠道吸收和较低的血脑屏障通透性,并表现出潜在的各种生物效应,特别是精神活性。研究的化合物通过与戊四氮的拮抗作用表现出高的抗惊厥活性。在研究剂量下,它们表现出低毒性而没有诱导肌肉松弛。在精神活性研究中,这些化合物表现出激活、镇静和抗焦虑作用。值得注意的是,6-氨基-2-硫代烷基-4-苯基烟酸盐衍生物具有显著的抗焦虑活性(约比地西泮高四倍)。它们还表现出明显的镇静作用。乙基 2-({2-[(二苯甲基)氨基]-2-氧代乙基}硫代)-4-苯基-6-吡咯烷-1-基烟酸盐甚至表现出比地西泮更强的抗焦虑活性。此外,所有研究的化合物都表现出统计学显著的抗抑郁作用。值得注意的是,乙基 2-({2-氧代-2-[(四氢呋喃-2-基甲基)氨基]乙基}硫代)-4-苯基-6-吡咯烷-1-基烟酸盐具有独特的精神活性。
所选化合物具有抗惊厥、激活行为和抗焦虑作用,同时具有抗抑郁作用,它们是进一步探索具有广泛神经精神应用的治疗药物的有前途的候选药物。
