苯乙酮酸冰片酯的合成及其诱导不对称Henry反应

在四乙氧基钛催化下,用天然丰产的冰片为手性源与苯乙酮酸乙酯进行酯交换得到含手性基团的苯乙酮酸冰片酯,苯乙酮酸冰片酯在冰片基的立体控制下与硝基甲烷缩合,主要得到2R-2-羟基-2-苯基-3-硝基丙酸冰片酯,用高效液相色谱法分析了诱导不对称Henry缩合反应效果,其e.e.值为56.5%,用IR、1HNMR、13CNMR确...     

苯乙酮酸薄荷醇酯的合成及其不对称Henry反应

在四乙氧基钛催化下,用天然丰产的薄荷醇为手性源与非手性苯乙酮酸乙酯进行酯交换得到含手性基团的苯乙酮酸薄荷醇酯,经手性基团的立体选择性控制让其与硝基甲烷缩合,主要得到2s-2-羟基-2-苯基-3-硝基丙酸薄荷醇酯,用IR、1H NMR、13C NMR确认了合成物结构。并用高效液相色谱法分析了诱导不对称Henry缩合反应效果。     

用替代对照品羟苯乙酯高效液相色谱方法测定大蒜辣素

大蒜辣素极不稳定,制备供含量测定用对照品非常困难。大蒜辣素在溶液中相对稳定,用高效制备液相色谱制备高纯度的大蒜辣素溶液(>99%),HPLC-ESI-MS/MS和NMR法鉴定该溶液中主成分大蒜辣素的结构,用衍生化紫外分光光度间接测定法和EP5.0收载的类似方法分别测定该溶液含量,确定该溶液中大蒜辣素的含量为0.719mg/mL。以此溶液为基准,在条件为:AlltechC18柱(250mm×4.6mm,5μm),流动相为甲醇-0.4%甲酸(65∶35),流速为1.0mL/min,检测波长242nm,考察性质稳定而又易得的羟苯乙酯与大蒜辣素之间的校正因子。结果显示,测得1mg羟苯乙酯相当于4.71mg的大蒜辣素,该换算关系适用于大蒜辣素为0.018～2.9g/L的浓度范围,该方法与EP5.0的方法相比,分析时间明显缩短。     

生物合成咖啡酸苯乙酯体系的液相色谱-串联质谱快速分析

建立液相色谱-串联质谱(LC-MS/MS)检测生物合成咖啡酸苯乙酯体系中咖啡酸(Caffeic acid,CA)和咖啡酸苯乙酯(Caffeic acid phenethylester,CAPE)的方法。采用LC-MS/MS电喷雾电离(ESI),负离子选择反应监测(SRM)模式检测。以V(乙腈)∶V(水)∶V(冰醋酸)=55∶45∶0.5为流动相,流速1.0mL/min,Hypersil C18色谱柱分离并检测生物合成咖啡酸苯乙酯体系中的咖啡酸以及咖啡酸苯乙酯的含量,并对生物合成咖啡酸苯乙酯的收率进行了动力学分析。本方法在进样量为0.2～20μg时具有良好的线性关系,咖啡酸和咖啡酸苯乙酯样品的加标回收率分别为93.4%～98.2%和90.3%～97.8%,相对标准偏差分别为1.79%～2.56%和1.82%～3.67%,咖啡酸苯乙酯收率在3d内可以达到15.54%,表明本方法简便、快速、可靠。     

一种近红外光记录与存储材料——克酮酸染料的三阶非线性光学性质

克酮酸染料是一类新型的近红外吸收染料,由于具有良好的光热稳定性和荧光性能,因而在光记录与存储等领域有着潜在的应用价值.本文利用简并四波混频技术,在近红外区不同吸收波长,在脉宽为130 fs条件下研究了一种吲哚克酮酸染料在溶液和薄膜中的三阶非线性光学性质.该克酮酸染料在773 nm,四氢呋喃溶液中的共振三阶超分子极化率γ为5.3×10^-29esu,在薄膜中的共振三阶非线性极化率χ⁽³⁾值达到10^-8esu数量级.同时,对于三阶非线性光学响应及其动力学机制也进行了研究和探讨.     

α-环戊基扁桃酸甲酯的合成

苯乙酮酸与环戊二烯基溴化镁发生格氏反应,再经Pd/C催化氢化、甲酯化反应合成了α-环戊基扁桃酸甲酯,总收率23.4%,其结果经1H NMR表征.     

液液萃取-气相色谱-质谱联用法同时检测烟用水基胶中的23种酯类化合物

建立了一种同时检测烟用水基胶中23种酯类化合物的液液萃取-气相色谱-质谱联用方法。23种酯类化合物包括乙酸酯类、丙烯酸酯类、甲基丙烯酸酯类、邻苯二甲酸酯类化合物。水基胶样品经水分散后,用含内标物丙酸苯乙酯的正己烷溶液振荡萃取,萃取液离心后过0.45 μm有机相滤膜,用DB-WAXETR气相色谱柱(60 m×0.25 mm×0.25 μm)分离,质谱选择离子模式监测,内标法定量。结果表明,23种酯类化合物在0.4~50.0 mg/L范围内线性关系良好,线性相关系数大于0.998,样品加标回收率为81.8%~109.1%,相对标准偏差(RSD, n=5)小于4%,检出限为0.02~0.76 mg/kg,定量限为0.04~2.52 mg/kg。该方法前处理简便、快速、分析时间短、灵敏度高、重复性好,可用于烟用水基胶中23种酯类化合物的同时检测。     

五氟乙基硫叶立德:一类新的亲电五氟乙基化试剂（英文）

发展了两个基于硫叶立德骨架的亲电五氟乙基化试剂,其合成高效简洁、固体状态下稳定而溶液中反应活性高.在温和条件下,该试剂可以与β-酮酸酯、芳基/杂芳基碘化物以及富电子芳烃反应高产率地得到相应的五氟乙基化产物.     

α－酮酸酯和α－二酮制备方法的改进

α－酮酸酯和α－二酮制备方法的改进司宗兴，焦献云，胡秉方（北京农业大学应用化学系北京１０００９４）作者曾经报道过一条制备α－酮酸酯和α－二酮的简便易行、原料易得的新的合成路线［１］。该方法优于Ｃｏｏｐｅｒ于１９８３年综述过的１９种α－酮酸的合成方法［...     

一锅法N,N-二甲基-4-氨基吡啶催化合成蒎酮酸酯

以天然产物松节油的主要成分a-蒎烯和醇为原料,二氯甲烷为溶剂,N,N-二甲基-4-氨基吡啶(DMAP)催化下经臭氧化分解反应,一锅法合成了6种蒎酮酸酯类化合物,反应温度为40℃,反应时间为4h,6种蒎酮酸酯产率均在60％以上.该方法操作简便,条件温和,且产率较高,是合成蒎酮酸酯类化合物的一种简易可行的方法.采用1H NMR,IR,MS对6种化合物的结构进行了表征.     

Reductive carboxylation of aromatic esters by electron transfer from magnesium metal

Magnesium-promoted reductive carboxylation of ethyl benzoate in the presence of chlorotrimethylsilane in N,N-dimethylformamide brought about a new carbon-carbon bond formation between the carbonyl carbon atom and carbon dioxide to give the corresponding benzoylformic acid in good yield. It is noteworthy that only ethyl benzoates with substituents at the meta-position were converted into benzoylformic acid derivatives. Moreover, no mandelic acid was detected even under the reductive conditions. This result indicates that benzoylformic acid was obtained after hydrolysis of a carboxylated intermediate, which would be alive as a stabilized structure in the reaction media.     

Electrochemical Reduction of Benzoylformic Acid in Ionic Liquid

Ionic Hquids possess a number of unique properties that makethem ideal electrolytes. Electrochical reduction of benzoyl-formic acid in room temperature ionic liquids as reaction media could be conducted with excellent performances without any ad-ditional supporting electrolyte. Electrolysis at glassy carbon electrode results in the formation of mandelic acid in 91% yield. And the electrochemical behavior of benzoylformic acid was investigated with the technique of cyclic voltammetry.     

丙酮酸和苯甲酰甲酸热分解反应的速率常数

用从头算方法在6-31G的水平上研究了丙酮酸和苯甲酰甲酸热分解反应的机理．反应过程中各驻点都进行MP2相关能校准．计算结果表明：这两个反应都是羟基氢经历五元环过渡态迁移到α-羰基氧上形成氢键中间体;然后氢键中间体直接分解成异构体和二氧化碳;最后异构体经历三元环过渡态异构化成相应的醛．其中氢迁是决速步骤．在MP2／6-31G／／HF／6-31G基础上,对应于这两个反应速控步骤的活化位垒分别是186．0kJ·mol-1和169．3kJ·mol-1．在传统过渡态理论的基础上,计算了这两个反应在一定温度范围内热速率常数,理论的计算结果与实验值有很好的吻合．     

D-扁桃酸脱氢酶和L-亮氨酸脱氢酶级联催化的L-苯甘氨酸对映选择性生物合成

L-苯甘氨酸是重要的手性非天然α-氨基酸,可广泛用于合成多种食品添加剂及药物中间体,探索其绿色合成工艺具有重要的意义。 本研究将新型高活性的D-扁桃酸脱氢酶(LhDMDH)和L-亮氨酸脱氢酶(EsLeuDH)偶联,在辅酶内循环的前提下,仅需较低浓度的辅酶即可实现生物催化D-扁桃酸合成L-苯甘氨酸。 通过对加酶量、氧化型烟酰胺腺嘌呤二核苷酸(NAD⁺)浓度、NH₄⁺浓度和底物浓度等因素进行优化,获得了一个最经济的反应条件:200 mmol/L的D-扁桃酸、6.5 kU/L的加酶量、0.1 mmol/L NAD⁺、0.5 mol/L NH₄⁺的条件下、30 ℃,反应12 h,在此条件下,产物的得率和对映体过量(e.e.)值分别可达98%和99%以上,具有较大的产业化潜力,为实现L-苯甘氨酸规模化的生物合成奠定了坚实的基础。     

Biomimetic reduction of benzoylformic acid by an acid stable NADH analogue : a model reaction of lactate dehydrogenase

By the use of an acid-stable NADH analogue (3-carbamoyl-N-benzyl-1,4-dihydroquinoline) NADH model reduction of benzoylformic acid in aqueous solution was achieved, for the first time, at pH region where the carboxyl group is undissociated.     

A hollow-fiber membrane extraction process for recovery and separation of lactic acid from aqueous solution

An energy-efficient hollow-fiber membrane extraction process was successfully developed to separate and recover lactic acid produced in fermentation. Although many fermentation processes have been developed for lactic acid production, and economical method for lactic acid recovery from the fermentation broth is still needed. Continuous extraction of lactic acid from a simulated aqueous stream was achieved by using Alamine 336 in 2-octanol contained in a hollow-fiber membrane extractor. In this process, the extractant was simultaneously regenerated by stripping with NaOH in a second membrane extractor, and the final product is a concentrated lactate salt solution. The extraction rate increased linearly with an increase in the Alamine 336 content in the solvent (from 5 to 40%). Increasing the concentration of the undissociated lactic acid in the feed solution by either increasing the lactate concentration (from 5 to 40 g/L) or decreasing the solution pH (from 5.0 to 4.0) also increased the extraction rate. Based on these observations, a reactive extraction model with a first-order reaction mechanism for both lactic acid and amine concentrations was proposed. The extraction rate also increased with an increase in the feed flow rate, but not the flow rates of solvent and the stripping solution, suggesting that the process was not limited by diffusion in the liquid films or membrane pores. A mathematical model considering both diffusion and chemical reaction in the extractor and back extractor was developed to simulate the process. The model fits the experimental data well and can be used in scale up design of the process.     

Partial electro-neutralisation of -α-p-hydroxyphenylglycine in sulphuric acid medium

In the industrial synthesis of -α-p-hydroxyphenylglycine the separation of amino acid is carried out by precipitation. During this process, a mother liquor is produced with a high salt content (2 M phosphates and sulphates) and an amino acid concentration of 0.11–0.12 M. The disposal of this mother liquor causes an environmental problem and an economic loss. The salt content of this mother liquor can be reduced in 70% of the initial by means of an electrodialysis process previously carried out by us, with only an amino acid loss of 15% of the initial. To improve and simplify this process, an electro-electrodialysis process (a membrane electrolysis process; the electrode processes and the transport process across the membrane are used) has been developed in which as a first step, the electro-neutralisation of solutions containing sulphuric acid and -α-p-hydroxyphenylglycine is studied. The sulphuric acid content is reduced to 87% of the initial, without detected loss of amino acid. The final solution is posteriorly neutralised by working up the pH of the solution for precipitating the amino acid, and a mother liquor with approximately 0.10 M -α-p-hydroxyphenylglycine and a low salt content (0.08 M Na₂SO₄) is produced. This mother liquor with low salinity can be recirculated again to a new electro-electrodialysis process.     

Rapid determination of 4‐aminobutyric acid and L‐glutamic acid in biological decarboxylation process by capillary electrophoresis‐mass spectrometry

4‐Aminobutylic acid (GABA) is a monomer of plastic polyamide 4. Bio‐based polyamide 4 can be produced by using GABA obtained from biomass. The production of L ‐glutamic acid (Glu) from biomass has been established. GABA is produced by decarboxylation of Glu in biological process. High‐performance liquid chromatography (HPLC) with derivatization is generally used to determine the concentration of GABA and Glu in reacted solution samples for the efficient production of GABA. In this study, we have investigated the rapid determination of GABA and Glu by capillary electrophoresis‐mass spectrometry (CE‐MS) without derivatization. The determination was achieved with the use of a shortened capillary, a new internal standard for GABA, and optimization of sheath liquid composition. Determined concentrations of GABA and Glu by CE‐MS were compared with those by pre‐column derivatization HPLC with phenylisothiocyanate. The determined values by CE‐MS were close to those by HPLC with pre‐column derivatization. These results suggest that the determination of GABA and Glu in reacted solution is rapid and simplified by the use of CE‐MS.     

ADSORPTION OF PHENYLACETIC ACID ON MACROPOROUS POLYMERIC ADSORBENTS

Several macroporous polymeric adsorbents(NDA-999,XAD-8,X-5 and XAD-2)were emplyed in the study to adsorb phenylacetic acid from aqueous solution.Effect of salt and ambient temperature on adsorption was studied using NDA-999 adsorbent and the adsorption process conforms to Freundlich′s model reasonably.Adsorption dynamics were conducted in batch experiments in order to make clear the mechanism of adsorption process.It is proved that the squared driving force mass transfer model can be adopted to elucidate the process.The treatment process of industrial wastewater containing high strength of phenylacetic acid was proposed for cleaner production of phenylacetic acid.