沙蚕毒系农药中毒的诊治

沙蚕毒系农药是有机氮类农药的一个分支,它是仿照天然沙蚕毒素的化学结构,人工合成的一类仿生性杀虫新农药。目前已使用的品种有巴丹(又称杀螟丹、沙蚕丹或沙蚕胺)、杀虫双和杀虫环(又称易卫杀、杂虫环、虫噻烷和甲硫环)。杀虫双原系制造巴丹的中间体,由我国首先发现其杀虫活性,并首先生产,现已在我国农村中广泛使用。本类农药纯品多为白色结晶固体,易吸潮,在水中溶解度较大,故可制成水剂(市售杀虫双为25%水剂呈棕红色)     

L-酒石酸托特罗定的合成

用反式肉桂酸和对甲苯酚经脱水环合、单甲基化制得3-(2-甲氧基-5-甲基苯基)-3-苯基丙酸,经氯化、胺化、还原和脱甲基制得的N,N-二异丙基-3-(2-羟基-5-甲基苯基)-3-苯基丙胺再经L-酒石酸拆分后成盐,得到抗尿失禁药L-酒石酸托特罗定,总收率12%.     

2,2-二甲基-4-(2,5-二氟苯基)-5-[(4-氨基磺酰基)苯基]-3(2H)-呋喃酮的合成

用2,5-二氟苯乙酸与茴香硫醚经傅-克反应、与3-溴-3-甲基-2-氧代丁腈成环及硝酸氧化制得2,2-二甲基-4-(2,5-二氟苯基)-5-[(4-甲磺酰基)苯基]-3(2H)-呋喃酮(7),7与乙酐反应后再经过硫酸氢钾复合盐氧化、氢氧化钠水解得4-[2,2-二甲基-3-氧代-4-(2,5-二氟苯基)-3(2H)-呋喃-5-基]苯磺酸钠(9),最后依次与磺酰氯和氨水反应制得2,2-二甲基-4-(2,5-二氟苯基)-5-[(4-氨基磺酰基)苯基]-3(2H)-呋喃酮,总收率约46％.     

含 2-取代-1,3-二硫杂环戊烷席夫碱大环化合物的合成及其抑菌活性研究

目的 开发新型抗菌药物。方法 以不同的β-二酮、二硫化碳、1,2-二溴乙烷等为原料合成含2-取代-1,3-二硫杂环戊烷大环席夫碱化合物,并进行初步抑菌活性研究。结果 合成得到的中间体(Ⅰa~Ⅰc)及目标席夫碱大环化合物(Ⅱa~Ⅱc)经元素分析、红外光谱、1H-NMR、MS等手段进行了结构表征。合成的席夫碱大环化合物抑菌能力优越。结论 本试验合成了含2-取代-1,3-二硫杂环戊烷大环席夫碱化合物,其具有更加优越的抑菌能力。     

盐酸硫必利的合成

2-甲氧基苯甲酸通过氯磺化反应得到2-甲氧基-5-(氯磺酰基)苯甲酸,再用亚硫酸钠和硫酸二甲酯进行还原和甲基化反应得到2-甲氧基-5-(甲磺酰基)苯甲酸,在硫酸催化下和甲醇进行酯化得到2-甲氧基-5-(甲磺酰基)苯甲酸甲酯,与N,N-二乙基乙二胺进行酰化反应制得硫必利,最后成盐酸盐得到盐酸硫必利,总收率为46.0%。     

N-芳酰基取代的二氢吲哚-3-乙酸类衍生物的设计、合成与体外降糖活性研究

目的:设计、合成N-芳酰基取代的二氢吲哚-3-乙酸类衍生物,并评价其体外降糖活性。方法:以吲哚衍生物2-[5-(苄氧基)-1-(4-氯苯甲酰基)-2-甲基-1H-吲哚-3-基]乙酸(GY3)为先导化合物,以4-苯甲氧基苯肼盐酸盐及4-氧戊酸甲酯为原料,经Fischer吲哚环合、还原、酰胺化及水解等4步反应得到8种N-芳酰基(3-羟基苯甲酰基、3-氰基苯甲酰基、4-硝基苯甲酰基、4-甲磺酰基苯甲酰基、4-乙酰胺基苯甲酰基、3-乙酰氨基苯甲酰基、异烟酰基、吡啶-2-甲酰基)取代的二氢吲哚-3-乙酸类衍生物。采用人肝癌细胞HepG2测试目标化合物的体外促葡萄糖消耗活性。结果:共合成8个N-芳酰基取代的二氢吲哚-3-乙酸类目标化合物,其结构均经质谱、核磁共振氢谱及碳谱确证。在1.0μmol/L条件下,所合成化合物在HepG2细胞上的促葡萄糖消耗百分率为5.4%～9.1%,其中,2-[(2R,3S)-5-苄氧基-2-甲基-1-(4-甲磺酰基苯甲酰基)-2,3-二氢-吲哚-3-基]乙酸的降糖活性最好,其促葡萄糖消耗百分率为(9.10±1.81)%,与阳性对照药物二甲双胍接近[(10.58±1.68)%],但仍弱于先导化合物GY3[(12.15±0.78)%]。结论:二氢吲哚类化合物的N-芳酰基芳环上引入不同吸电子取代基团,如氰基、硝基、甲磺酰基等,其降糖活性不同程度下降,且弱于卤素取代基的GY3。     

2-取代亚肼基-1,3-二硫杂环戊烷类化合物的合成及抗菌活性

目的为了寻找高效、低毒的农用杀菌剂,用超声波法合成新型的2-取代亚肼基-1,3-二硫杂环戊烷类化合物。方法以CS2、NH2NH2·H2O、BrCH2CH2Br为原料,在超声波辐射下合成中间体1,3-二硫杂环戊烷,然后再和取代芳香醛缩合得到3种未见文献报道的新化合物。结果总收率在60%以上。结构经IR,MS,1HNMR和元素分析所确证。结论该类化合物合成方法简单。初步的生物活性实验表明,这3种化合物对大肠杆菌、肺炎克雷伯氏菌、草绿色链球菌等有较好的抑杀作用。     

磺酰胺用碘三甲基硅烷脱去磺酰基

N,N-二取代的磺酰胺与氯三甲基硅烷和碘化钠各 1.5摩尔当量 (生成碘三甲基硅烷 )在乙腈中中性条件下回流反应 ,脱去保护基得到仲胺 ,12例收率 70 %～ 88%磺酰胺用碘三甲基硅烷脱去磺酰基@马翔     

对映体选择性测定尿中N-甲基-1-(3,4-亚甲二氧苯基)-2-丙胺及其代谢物

建立了尿中N-甲基-(3,4-亚甲二氧苯基)-2-丙胺及其代谢物对映体浓度的分析方法。药物经手性衍生化后,于非手性GC固定相上分离。采用该法测定了大鼠屎中各对映体浓度,结果表明药物及其代谢物均呈立体选择性代谢.     

富马酸替硫福韦酯的合成

(R)-1,2-丙二醇与碳酸二乙酯经缩合、与腺嘌呤反应、与对甲苯磺酰氧甲基硫代膦酸二乙酯缩合、水解、保护氨基后氯代制得(R)-9-[2-(二氯硫代膦酰基甲氧基)丙基]腺嘌呤,与(S)-(-)-(3-氯苯基)-1,3-丙二醇在四氯化钛作用下反应后再经富马酸成盐制得抗病毒药富马酸替硫福韦酯,总收率约13%(以(R)-1,2-丙二醇计)。     

农药叶枯灵在大鼠原位灌流肝中的代谢研究

采用反相HPLC、TLC、UV、IR和MS对农药叶枯灵经大鼠原位灌流肝代谢后所形成的代谢产物进行分离和鉴定。结果表明,叶枯灵在大鼠肝脏中进行了广泛的代谢,包括S-氧化作用、水解作用、丙酮酸缩合作用和乙酰化作用,共分离鉴定出5种代谢产物。     

2-苯甲酰肼叉-1,3-二噻茂烷在大鼠原位灌流肝中的代谢动力学

采用反相高压液相色谱的三内标三波长切换技术对不同剂量的农药2-苯甲酰肼叉-1.3二噻茂烷在大鼠原位灌流肝中的代谢动力学进行了研究.结果表明,该农药经门静脉进入大鼠原位灌流肝后,很快分布于肝脏中,而在灌流肝中的消除过程较缓慢。随着给药剂量的增加,大鼠肝灌流液中各种代谢产物的生成量也逐渐增加,尤以肼叉1.3-二噻茂烷和苯甲酸生成量的增加更为显著.可见,该农药在大鼠原位灌流肝中的主要代谢途径为水解作用。     

大鼠尿中2-苯甲酰肼叉-1,3-二噻茂烷及其代谢产物定量研究

本文建立了线性梯度洗脱,两波长切换检测和两内标法测定染毒大鼠尿中2苯甲酰肼叉-1.3二噻茂烷(BADYH)及其代谢产物的反相高效液相色谱方法.研究了大鼠ig不同剂量BADYH后,经尿排泄的DADYH及其代谢产物累积量-时间过程.结果表明,BADYH及其代谢产物累积排泄量占染毒总量的39.7％。其中主要代谢产物丙酮缩肝叉1.3二噻茂烷,占23.6％;肼叉1.2二噻茂炼占14.0％     

Pharmacological and metabolic characterisation of the potent σ1 receptor ligand 1′‐benzyl‐3‐methoxy‐3H‐spiro[[2]benzofuran‐1,4′‐piperidine]

Objectives The pharmacology and metabolism of the potent σ1 receptor ligand 1′‐benzyl‐3‐methoxy‐3H‐spiro[[2]benzofuran‐1,4′‐piperidine] were evaluated. Methods The compound was tested against a wide range of receptors, ion channels and neurotransmitter transporters in radioligand binding assays. Analgesic activity was evaluated using the capsaicin pain model. Metabolism by rat and human liver microsomes was investigated, and the metabolites were identified by a variety of analytical techniques. Key findings 1′‐Benzyl‐3‐methoxy‐3H‐spiro[[2]benzofuran‐1,4′‐piperidine] (compound 1 ) is a potent σ1 receptor ligand (K_i 1.14 nM) with extraordinarily high σ1/σ2 selectivity (>1100). It was selective for the σ1 receptor over more than 60 other receptors, ion channels and neurotransmitter transporters, and did not interact with the human ether‐a‐go‐go‐related gene (hERG) cardiac potassium channel. Compound 1 displayed analgesic activity against neuropathic pain in the capsaicin pain model (53% analgesia at 16 mg/kg), indicating that it is a σ1 receptor antagonist. It was rapidly metabolised by rat liver microsomes. Seven metabolites were unequivocally identified; an N‐debenzylated metabolite and a hydroxylated metabolite were the major products. Pooled human liver microsomes formed the same metabolites. Studies with seven recombinant cytochrome P450 isoenzymes revealed that CYP3A4 produced all the metabolites identified. The isoenzyme CYP2D6 was inhibited by 1 (IC50 88 nM) but did not produce any metabolites. Conclusions 1′‐Benzyl‐3‐methoxy‐3H‐spiro[[2]benzofuran‐1,4′‐piperidine] is a potent and selective σ1 receptor antagonist, which is rapidly metabolised. Metabolically more stable σ1 ligands could be achieved by stabilising the N‐benzyl substructure.     

Metabolism of lovastatin by rat and human liver microsomes in vitro

The metabolism of lovastatin (Mevacor) was examined using isolated microsomes derived from the livers of normal and phenobarbital-treated rats and from human liver samples. Incubation of lovastatin with rat liver microsomes resulted in the formation of several polar metabolites of lovastatin. The metabolites were isolated by HPLC and identified by NMR and mass spectrometry. One fraction consisted of a 2:1 mixture of 6-hydroxy-lovastatin and the rearrangement product delta 4,5-3-hydroxy lovastatin. Addition of a trace of acid to this mixture resulted in the formation of a single aromatized product, the desacyl-delta 4a,6,8-dehydro analog of lovastatin. Another microsomal metabolite was determined to be the delta 4,8a,1-3-hydroxy-lovastatin derivative. The chromatographic pattern of metabolites produced from lovastatin by human liver microsomes was similar to that obtained with rat liver microsomes. Metabolism of lovastatin by rat liver microsomes was both time and concentration dependent; optimal microsomal metabolism occurred with 0.1 mM lovastatin, whereas higher lovastatin concentrations inhibited the reaction. The open acid form of lovastatin was poorly metabolized by both the rat and the human liver microsomes.     

五味子醇甲在大鼠肝微粒体内的代谢动力学和性别差异

体外研究五味子醇甲(schizandrin，SZ)在大鼠肝微粒体内的代谢动力学和性别差异。制备正常雌、雄大鼠肝微粒体，与SZ共同温孵，以高效液相色谱法测定SZ及其代谢产物。SZ在雄鼠肝微粒体内代谢反应的最大速率V_max、米氏常数K_m和清除率Cl_int分别为(21.88±2.30) μmol·L^-1·min^-1·mg^-1(protein)，(389.00±46.26) μmol·L^-1和(0.056 3±0.000 7) min·mg^-1(protein)；在雌鼠肝微粒体内代谢反应的最大速率V_max、米氏常数K_m和清除率Clint_{分别为(0.61±0.07) μmol·L^-1·min^-1·mg^-1(protein)，(72.64±13.61) μmol·L^-1和(0.008 4±0.000 8) min·mg^-1(protein)，雌、雄鼠肝微粒体内SZ的主要代谢物不同，分别为7,8-顺二羟基五味子醇甲(M1)和7,8-顺二羟基-2-去甲基五味子醇甲(M2b)。酮康唑、奎尼丁和奥芬得林对SZ的在雌、雄大鼠肝微粒体内代谢均有不同程度的抑制作用，西咪替丁对其在雄鼠肝微粒体内的代谢也有一定的抑制作用。SZ在雌、雄大鼠肝微粒体中代谢动力学及代谢产物存在明显的性别差异，这种差异可能主要是由CYP3A和CYP2C11在大鼠肝微粒体内的性别差异引起的。}     

双环醇在大鼠和人肝微粒体的代谢

目的研究参与双环醇代谢的主要药物代谢酶及代谢动力学参数，分离鉴定双环醇代谢产物。方法双环醇与大鼠和人肝微粒体进行温孵，以高效液相色谱、质谱、核磁共振技术检测并分离鉴定双环醇及其代谢产物。结果双环醇在地塞米松诱导大鼠肝微粒体中的代谢速率显著高于正常大鼠肝微粒体，酮康唑可显著抑制双环醇的代谢。双环醇主要代谢产物为:4-羟基-4′-甲氧基-6-羟甲基-6′-甲氧羰基-2，3，2′，3′-双亚甲二氧基联苯和4-甲氧基-4′-羟基-6-羟甲基-6′-甲氧羰基-2，3，2′，3′-双亚甲二氧基联苯。结论双环醇在大鼠和人肝微粒体的主要代谢产物为4-羟基-4′-甲氧基-6-羟甲基-6′-甲氧羰基-2，3，2′，3′-双亚甲二氧基联苯和4-甲氧基-4′-羟基-6-羟甲基-6′-甲氧羰基-2，3，2′，3′-双亚甲二氧基联苯，细胞色素P450 3A主要参与双环醇代谢。     

Theophylline metabolism by human, rabbit and rat liver microsomes and by purified forms of cytochrome P450

The capacity of human, rabbit and rat liver microsomes and purified isozymes of cytochrome P450 to metabolize theophylline has been assessed. In all three species the 8-hydroxylation of theophylline to 1,3-dimethyluric acid (1,3-DMU) was the major pathway. In human, control rabbit and rat liver microsomes this metabolite accounted for 59, 77 and 94%, respectively, of the total metabolites formed. In both human and control rabbit liver microsomes the N-demethylation of theophylline to 1-methylxanthine (1-MX) accounted for 20% of the total metabolites formed. N-demethylation of theophylline to 3-methylxanthine (3-MX) accounted for 21% of theophylline metabolism in human microsomes but was a minor pathway in control rabbit and rat microsomes. Acetone and phenobarbitone pretreatment markedly increased the formation of 1,3-DMU by rabbit liver microsomes. Rifampicin and 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) administration caused a slight but significant increase in this pathway. In general the N-demethylation pathways in rabbit liver microsomes were refractory to induction. In the rat, the metabolism of theophylline to 1-MX, 3-MX and 1,3-DMU were all significantly increased in Aroclor 1254, dexamethasone, phenobarbitone and 3-methylcholanthrene-treated microsomes. In reconstitution experiments the polycyclic hydrocarbon inducible rabbit cytochrome P450 Forms 4 and 6 and the constitutive Form 3b all metabolized theophylline to its three metabolites. In human liver microsomes from four subjects anti-rabbit cytochrome P450 Form 4 IgG inhibited the metabolism of theophylline to 1-MX, 3-MX and 1,3-DMU by approximately 30%. These data indicate that theophylline is metabolized by multiple forms of cytochrome P450 in human, rabbit and rat liver microsomes.     

Studies on the metabolic fate of M17055, a novel diuretic (4): species difference in metabolic pathway and identification of human CYP isoform responsible for the metabolism of M17055

The metabolic profile of M17055, a novel diuretic, after administration to experimental animals and after incubation with human liver microsomes was investigated. 1. Extensive metabolism was observed in rats and monkeys and the structures of six metabolites (RU1, RU2, and RU3 from rat urine or liver perfusate; MU1, MU2 and MU3 from monkey urine) were assumed or identified. The clear species difference of metabolism was revealed between rats and a monkey with different structures of the isolated metabolites. 2. When these metabolites were quantified using radioactive material, RU3, RU1 and MU3 were considered to be major metabolites in rat urine, rat bile and monkey urine respectively, while in a dog, unchanged drug was observed as the major component indicating only little metabolism occurred in dog, when administered intravenously. 3. RU1 and RU2 were also generated from [(14)C]M17055 after incubation with human liver microsomes, suggesting that the metabolic pathway of M17055 in humans involves that observed in rats. 4. [(14)C]M17055 metabolism in human liver microsomes was inhibited by CYP2C8/9 and CYP3A4/5 inhibitors, and also by the antibodies that recognize CYP2C8/9/19 and CYP3A4. Significant correlations were observed between the rate of [(14)C]M17055 metabolism and the activity of testosterone 6beta-hydroxylation or tolbutamide methyl-hydroxylation. cDNA-expressed CYP3A4 and CYP2C9 could catalyze the metabolism of [(14)C]M17055. These results suggest that the metabolism of M17055 in human liver microsomes is catalyzed mainly by CYP3A4 and CYP2C9.     

Metabolism of 2-nitrofluorene,an environmental pollutant,by liver preparations of sea bream,Pagrus major

1. The in vitro metabolism of 2-nitrofluorene (NF), an environmental pollutant, was examined in fish, focusing on nitro-reduction followed by N -acylation and hydroxylation. 2. When NF was incubated with liver microsomes or cytosol of sea bream, Pagrus major, in the presence of NADPH or 2-hydroxypyrimidine, 2-aminofluorene (AF) was formed. 3. When AF was incubated with liver cytosol in the presence of acetyl-CoA or N -formyl-L-kynurenine, 2-acetylaminofluorene (AAF) or 2-formylaminofluorene (FAF) was formed, respectively. AAF and FAF thus formed were deacylated to the parent AF by the liver preparations. 4. AF, AAF and FAF were oxidized to 7-hydroxy or 5-hydroxy derivatives by the liver microsomes. 5. Nitro-reduction, N -acylation and ring-hydroxylation of NF and the metabolites were also observed in rat liver preparations. These activities in sea bream livers were lower than those of rat liver. However, the order of magnitude of these activities in fish was the same as in rat. 6. It is suggested that NF is effectively reduced to AF by the cytochrome P450 system or aldehyde oxidase, and the acylated metabolites, AAF and FAF, generated by arylamine acetyltransferase and formamidase were hydroxylated by the cytochrome P450 system in fish in the same way as in rat. Further, the acetylamino and formylamino derivatives were interconverted via amino derivatives in the fish.