三乙烯二胺促进炔酸聚乙二醇酯与苯酚的加成反应研究

以单甲氧基聚乙二醇和2-丁炔酸为起始原料,制得2-丁炔酸聚乙二醇酯(1);以异丙醇为溶剂,三乙烯二胺(DABCO)为催化剂,1与苯酚经Michael加成反应合成了苯酚的聚乙二醇化产物(2),其结构经1H NMR和FT-IR确证。在最优反应条件[n(苯酚)∶n(1)∶n(DABCO)=20∶1∶20,异丙醇0.5 m L,于室温反应12 h]下,2产率99%。     

6-硝基喹哪啶的合成工艺改进

以I2/KI为氧化剂,甲苯为乳化剂,对硝基苯胺(2)和巴豆醛(3)经环合反应合成了6-硝基喹哪啶(1)。最佳反应条件为:28.92 mmol,甲苯10 mL,混酸45.5 mL[V(AcOH)∶V(HCl)=1∶90],n(2)∶n(I2/KI)=1∶1,于100℃反应4 h,收率达93.1%。1的结构经1HNMR,IR和元素分析表征。     

利用改进的Pictet-Spengler反应合成多取代β-咔啉

β-咔啉结构广泛存在于生物活性分子之中,为探索非酸性反应条件下合成β-咔啉衍生物的方法,以色胺类化合物和醛类为原料,以改进的Pictet-Spengler反应为关键步骤,再经氧化脱氢合成4个多取代β-咔啉化合物(2a～2d),其结构经¹H NMR和MS(ESI)确证。经过对Pictet-Spengler反应步骤中物料比、溶剂、反应温度与时间进行考察后发现：在色胺类化合物为2.0 mmol,醛为3.0 mmol,六氟异丙醇钙为0.4 mmol,二氯甲烷为20.0 mL,室温反应24 h的最优条件下,四氢-β-咔啉化合物中间体(1a～1d)的收率为75%～89%,反应存在取代基效应,含芳香性基团底物收率较高。     

FeCl_3催化合成新型烯丙基醚类化合物

以烯丙基醇类化合物(1a~1i)和乙醇为起始原料,FeCl_3为催化剂,经分子间亲核取代反应合成了9个烯丙基醚类化合物(2a~2i,其中2c,2e~2i为新化合物),收率80%~95%,其结构经1H NMR,13C NMR和HRESI-MS表征。研究了催化剂,溶剂,反应温度和反应时间对2a产率的影响。结果表明:在最优反应条件[1a 0.5mmol,Fe Cl34 mg,Et OH 2.5 mmol,CH2Cl2为溶剂,于室温反应0.8 h]下,2a收率95%。     

相转移催化合成2-苯基喹啉衍生物

以喹啉(1)和取代苯肼(2a~2d)为原料,K_2S_2O_8为引发剂,TBAB为相转移催化剂,乙腈为溶剂,经自由基反应合成了4个2-苯基喹啉化合物(3a~3d,3d为新化合物),其结构经~1H NMR,~(13)C NMR和HR-ESI-MS表征。以3a的合成为模板反应,研究了引发剂,溶剂和反应温度对3收率的影响。结果表明:在最佳反应条件(1 1.0mmol,2 1.2 eq.,K_2S_2O_82.0 eq.,TBAB 0.2 eq.,于室温反应4 h)下,3a~3d收率54%~72%。     

H_2SO_4/AC无溶剂催化合成香豆素衍生物

以浓硫酸改性活性炭[H2SO4/AC(Cat)]为催化剂,在无溶剂条件下,取代酚和乙酰乙酸甲酯(2)经Pechmann缩合反应合成了5个香豆素衍生物,其结构经1H NMR,13C NMR和IR确证。以间甲酚(1a)和2合成4,7-二甲基香豆素(3a)为例,考察原料配比[r=n(1a)∶n(2)]、反应温度、Cat用量及反应时间对Pechmann反应的影响。在最佳反应条件[1a 5 mmol,r=1.0∶2.0,Cat 18%,于120℃反应3 h]下,3a收率80%。     

室温合成二硫化二正丁基黄原酸酯及其表征

以正丁醇、氢氧化钠和二硫化碳为原料,水作溶剂合成正丁基黄原酸钠,再与一氯化硫反应,室温条件下合成对称的二硫化二正丁基黄原酸酯,并探讨了反应条件对合成正丁基黄原酸钠和二硫化二正丁基黄原酸酯产率的影响。通过红外(FT-IR)、核磁(1H NMR)、质谱(MS)及元素分析等技术手段确定了产物的结构。优化的合成条件为:n(正丁基黄原酸钠)∶n(S2Cl2)=2∶1.1,温度为室温,溶剂为THF,反应时间为2 min,产率可达83.2%,反应条件温和,反应迅速、收率高。     

花青醛的合成工艺优化

以3-异丙基苯乙酮(1)为原料,经3步反应合成了花青醛[3-(3-异丙基苯基)丁醛(4)],并优化了反应条件。确定合成3-(3-异丙基苯基)-2-丁烯酸乙酯(2)的最优条件为：n(1)/n(磷酰基乙酸三乙酯)/n(氢化钠)=5/6/6,于室温反应12 h,收率84.5%;合成3-(3-异丙基苯基)-1-丁醇(3)的最佳条件为:n(2)/n(硼氢化钠)/n(六水合二氯化钴)/n(二异丙基胺)=10/20/1/2,于55 ℃反应24 h,收率87.8%;合成4的最优条件为: n(3)/n(乙酸酐)/n(亚硝酸钠)=5/4/15,投料顺序为:乙酸酐、3、亚硝酸钠,反应时间为2 min,收率91.0%。产物结构经¹H NMR, ¹³C NMR和MS(ESI)确证。     

对硝基邻苯二乙醚合成技术研究

以邻苯二酚与溴乙烷为原料、聚乙二醇为相转移催化剂合成邻苯二乙醚,再经过冰醋酸和硝酸硝化得到对硝基邻苯二乙醚。研究了反应温度、反应时间、原料摩尔比和催化剂用量等对反应收率的影响,获得了合成邻苯二乙醚的优化工艺条件:n(C6H4(OH)2)∶n(NaO H)∶n(C2H5Br)=1∶2.6∶2.4,反应温度80℃,反应时间4h,催化剂用量2g,该反应条件下邻苯二乙醚平均收率88%。混酸硝化条件下合成对硝基邻苯二乙醚的较佳工艺条件为n(C10H14O2)∶n(HNO3)=1∶1.2,乙酸25mL,反应时间30min,反应温度20℃,该反应条件下对硝基邻苯二乙醚平均收率为99%。     

纳米固体超强酸SO2-4/Fe2O3催化合成尼泊金酸乙酯

以纳米固体超强酸SO2-4/Fe2O3催化尼泊金酸与乙醇的酯化反应合成了尼泊金酸乙酯.较适宜的反应条件为:尼泊金酸25 mmol,n(尼泊金酸):n(乙醇)=1:4,ω(催化剂)=3.73%,甲苯15 mL,于84℃～86℃反应3 h,产率达到93.3%.     

Sol-gel low-temperature synthesis of stable anatase-type TiO2 nanoparticles under different conditions and its photocatalytic activity

In this work, TiO(2) nanoparticles in anatase phase was prepared by sol-gel low temperature method from titanium tetra-isopropoxide (TTIP) as titanium precursor in the presence of acetic acid (AcOH). The effects of synthesis parameters such as AcOH and water ratios, sol formation time, synthesis and calcination temperature on the photocatalytic activity of TiO(2) nanoparticles were evaluated. The resulting nanoparticles were characterized by X-ray diffraction, UV-Vis reflectance spectroscopy, transmission electron microscopy and Brunauer-Emmett-Teller techniques. Photocatalytic activity of anatase TiO(2) nanoparticles determined in the removal of C. I. Acid Red 27 (AR27) under UV light irradiation. Results indicate that with increasing AcOH/TTIP molar ratio from 1 to 10, sol formation time from 1 to 3 h and synthesis temperature from 0 to 25°C, increases crystallite size of synthesized nanoparticles. It was found that optimal conditions for low temperature preparation of anatase-type TiO(2) nanoparticles with high photocatalytic activity were as follows: TTIP:AcOH:water molar ratio 1:1:200, sol formation time 1 h, synthesis temperature 0°C and calcination temperature 450°C.     

蒙脱土负载碘催化合成双吲哚甲烷衍生物

以蒙脱土负载碘(MMT/I2)作催化剂,醛(1a~1g)与吲哚(2)反应合成双吲哚甲烷衍生物(3a~3g),其结构经1H NMR和IR确证。以3a的合成为例,研究了催化剂、溶剂、反应时间、温度和物料比r[n(1)∶n(2)]对3产率的影响。结果表明:在最佳合成条件(2 1 mmol,r=1.1∶2.0,10 mol%MMT/I2,乙腈1 m L,于25℃反应5min)下,3a~3g产率67.9%~96.2%。MMT/I2循环使用3次,3a产率78.6%。     

一步法合成2,4-二硝基苯甲醚

以1-氯-2,4-二硝基苯(CDNB)为原料,不使用相转移催化剂,用KOH溶液为反应介质,一步合成了2,4-二硝基苯甲醚,其结构经1H NMR,FT-IR和元素分析确证。最佳反应条件为:CDNB 0.20 mol,30%KOH溶液为反应介质,甲醇100 m L,于55℃反应60 min,收率96.5%,纯度99.8%。     

Titanium aminophosphates as efficient,economical, and recyclable catalysts for the synthesis of xanthenediones

Titanium aminophospates have been used as catalysts in the synthesis of xanthenediones at room temperature. Among the three catalysts tested, titanium n-propyl aminophosphate (TNPAP) was found to be more efficient catalyst for the synthesis of xanthenediones. The solvent-screening studies for this catalytic reaction reveals that MeOH: H₂O was the most suitable solvent system, yielding higher amounts (89%) of products. The TNPAP catalyst was found to be reusable for five successive cycles. The optimized reaction conditions are 1.0?mmol of benzaldehyde, 2.0?mmol of dimedone, methanol/water (5.0?mL) as solvent, rt, and 100?mg of TNPAP. A plausible mechanism for the catalytic reactions has been proposed.     

LiBr catalyzed solvent-free ring expansion of epoxides to 1,4-oxathian-2-ones with α-mercaptocarboxylic acids

An efficient and rapid (10-20 min) one-pot synthesis of chemically and pharmaceutically interesting 1,4-oxathian-2-ones is reported. The protocol involves LiBr catalyzed regioselective ring-opening-ring-closing reaction cascade of terminal epoxides with α-mercaptocarboxylic acids at rt under solvent-free conditions. Recycling of the catalyst, atom economy, and formation of water as the only by-product in the present synthesis are additional advantages relevant to green chemistry.     

系列烯基化芳香杂环化合物的合成及结构表征

报道了一个简单、 高选择性合成烯基化芳香杂环化合物的反应体系. 在钯的催化作用下, 以乙酸/乙酸酐或四氢呋喃为溶剂, 芳香杂环化合物与烯基化试剂进行交叉脱氢偶联, 合成了系列具有潜在光学活性的烯基化芳香杂环化合物, 确定了最佳反应条件. 采用紫外光谱、 核磁共振氢谱和X射线单晶衍射对目标化合物进行了表征, 并对反应机理进行了探讨.     

稀土固体超强酸SO_4~(2-)/TiO_2/La~(3 )催化合成水杨酸异丁酯

研究了以稀土固体超强酸SO_4~(2-)/TiO_2/La~(3 )为催化剂,水杨酸和异丁醇为原料合成水杨酸异丁酯,并考察了影响反应的因素。结果表明,醇酸比为3:1,催化剂用量为1.0g(水杨酸为0.1mol的情况下),带水剂苯为15mL,反应时间为3.0h是最适宜的反应条件,酯化率达96.2％。     

CO_2和丙三醇直接合成碳酸甘油酯的新方法

报道了一种以CO_2和丙三醇为原料,Cs_2CO_3为碱,DMF为溶剂,bmimBF_4为增溶剂,直接合成碳酸甘油酯(GC)的新方法。在最优反应条件[丙三醇5 mmol,Cs_2CO_310 mmol,CH_2Cl_25 m L,bmimBF_41 m L,DMF 5 m L,P(CO_2)1 MPa,于100℃反应24 h]下,GC收率76%,其结构经1H NMR和ESI-MS确证。在最优条件下进行50倍放大实验,GC收率72%。     

Synthesis and study of a molecularly imprinted polymer for specific solid‐phase extraction of vinflunine and its metabolite from biological fluids

A molecularly imprinted polymer (MIP) was synthesized in order to specifically extract vinflunine, an anticancer agent, and its metabolite (4‐O‐deacetylvinflunine) from bovine plasma and artificial urine by solid‐phase extraction (SPE). Vinorelbine, a non‐fluorinated analogue of vinflunine, was selected as a template for MIP synthesis. The selectivity of MIP versus the template (vinorelbine) and other alkaloids (catharanthine, vinblastine, vincristine, vinflunine and 4‐O‐deacetylvinflunine) was shown by a SPE protocol carried out with non‐aqueous samples. A second protocol was developed for aqueous samples with two consecutive washing steps (AcOH–NH₂OH buffer (pH 7, I=10 mM)–MeOH mixture 95:5 v/v and ACN–AcOH mixture 99:1 v/v) and an elution step (MeOH–AcOH mixture 90:10 v/v). Thus, MIP‐SPE of bovine plasma brought high recoveries, 81 and 89% for vinflunine and its metabolite, respectively. This protocol was slightly modified for artificial urine samples in order to obtain a good MIP/NIP selectivity; furthermore, elution recoveries were 73 and 81% for vinflunine and its metabolite, respectively. Repeatability was assessed in both biological matrices and RSD (%) were inferior to 4%. The MIP also showed a suitable linearity (r² superior to 0.99), between 0.25 and 10 μg/mL for plasma, and between 1 and 5 μg/mL for artificial urine.