Soil transformation of wheat and corn metabolites mboa and DIM2BOA into aminophenoxazinones

The defensive cyclic hydroxamates 7-methoxy-2,4-dihydroxy-1,4(2H)-benzoxazin-3-one (DIMBOA) and 7,8-dimethoxy-2,4-dihydroxy-1,4(2H)-benzoxazin-3-one (DIM₂BOA) of wheat and corn are transformed in nonsterile soil, via 6-methoxy-2(3H)-benzoxazolone (MBOA) and 6,7-dimethoxy-2(3H)-benzoxazolone (M₂BOA) respectively, into 2-amino-7-methoxy-3H-phenoxazin-3-one and 2-amino-4,6,7-trimethoxy-3H-phenoxazin-3-one. The soil transformation is similar of that undergone by the rye metabolite 2(3H)-benzoxazolone (BOA) into 2-amino-3H-phenoxazin-3-one. The transformations to phenoxazinones are not observed in sterile soil. The 2-amino-3H-phenoxazin-3-one inhibits barnyard grass radicle elongation, but the methoxylated aminophenoxazinones are not significantly inhibitory.     

Biotransformation of 2-Benzoxazolinone to 2-Amino-(3<Emphasis Type="Italic">H</Emphasis>)-Phenoxazin-3-one and 2-Acetylamino-(3<Emphasis Type="Italic">H</Emphasis>)-Phenoxazin-3-one in Soil

An alternative to the use of synthetic pesticides is to exploit the natural defense chemicals produced by cereals. An important class of allelochemicals is cyclic hydroxamic acids and related benzoxazolinones. A prolonged degradation experiment of the allelochemical compound from rye 2-benzoxazolinone (BOA) was carried out for up to 90 d at 15°C at three different concentration levels, 3, 3000, and 30,000 nmol BOA· g soil^–1, respectively, in a sandy loam soil. Two main degradation products, 2-amino-(3H)-phenoxazin-3-one (APO) and 2-acetylamino-(3H)-phenoxazin-3-one (AAPO), were identified and quantified by LC-ESI-MS-MS. The half-life of BOA increased with higher levels of BOA added to the soil. Half-lives of BOA, APO, and AAPO were determined by fitting a single first-order model to the degradation data. Half-life of BOA was determined to be 0.6 d in the 3 nmol BOA g soil^–1 treatment. Half-lives of BOA, APO, and AAPO were 3.1, 2.7, and 2.1 d, respectively, in the 3000 nmol BOA· g soil^–1 treatment. In the 30,000 nmol BOA· g soil^–1 treatment, the half-lives were 31 d for BOA and 45 d for APO. The microbial community structure was not affected by addition of BOA to the soil as investigated by analysis of signature fatty acids. The results suggest that the exploitability of BOA for crop protection is dependent on the existing concentration of BOA in the soil and the timing of incorporation of hydroxamic acid synthesizing crops into the soil.     

Effects of fertility on biomass,phytotoxicity, and allelochemical content of cereal rye

Studies were conducted to evaluate biomass production, tissue phytotoxicity, and allelochemical content of rye (Secale cereale L.) shoots grown in three fertility regimes (low, medium or high) in the greenhouse. Wheeler rye or a polyculture of rye and hairy vetch (Vicia villosa Roth) grown with high fertility produced the greatest biomass (78.7 and 82.7 g), with the lowest root-to-shoot ratio (0.22 and 0.43) produced in the high-fertility treatments. The polyculture treatment grown with low fertility had a greater proportion of hairy vetch (18%) than when grown with high fertility (6%). Rye shoot residue phototoxicity was affected by fertility regime. Radicle elongation of cress (Lepidium sativum L.) and barnyardgrass [Enchinochloa crus-galli (L.) Beauv. I was inhibited by rye shoot residues in a modified Parker bioassay. Rye shoot residue grown with low fertility was less inhibitory to cress radicle elongation than rye residue from the medium- or high-fertility regimes. Extracts of dried rye shoots grown with high fertility were less inhibitory than extracts from other fertility regimes. The concentrations of ether extracts of rye causing 50% inhibition (I₅₀) of cress radicle elongation were between 125 and 276 µg/ml for greenhouse-grown and 60 and 138 µg/ml for the field-grown rye shoots. The major phytotoxic compounds in the rye shoot extracts were identified as DIBOA and BOA. The concentration of DIBOA in the greenhouse-grown rye shoots ranged between 128 and 423 µg/g while BOA concentration ranged between 2.5 and 31 µg/g. DIBOA and BOA levels were lowest in rye shoots grown with high fertility. Correlations between rye shoot biomass, DIBOA and BOA concentration, and cress barnyardgrass radicle length were significant.     

苯并呋喃-2(3H)-酮的合成

在乙醇钠催化下邻硝基甲苯与草酸二乙酯缩合后,经水解、双氧水氧化、盐酸酸化得到邻硝基苯乙酸,收率为62%。邻硝基苯乙酸再经硫化铵还原、重氮化反应、水解得到苯并呋喃-2(3H)-酮。考察了重氮化反应时间和水解温度对反应的影响,适宜的重氮化反应时间为30 m in,适宜的水解温度135℃,在此条件下苯并呋喃-2(3H)-酮的收率为51%。两步总收率为32%。     

微波辐射合成5-氨基-噻唑[4,5-d]嘧啶-2(3H)-酮

以硫脲和氯乙酸为原料,在无溶剂和350 W微波辐射4 m in条件下,缩合生成中间体2,4-噻唑烷二酮(Ⅰ)产率91.5%;随后在无溶剂和400 W微波辐射5 m in条件下,通过V ilsm e ier甲酰化反应,生成中间体4-氯-5-甲酰基噻唑-2(3H)-酮(Ⅱ),产率86.7%;最后以正丙醇为溶剂,450 W微波辐射7 m in条件下,成环得到5-氨基-噻唑[4,5-d]嘧啶-2(3H)-酮(Ⅲ),产率80.5%。反应总产率为63.9%。合成产物与中间体的结构经1HNMR,MS和元素分析确认。     

6-氨基-7-氟-2H-1,4-苯并(噁)嗪-3(4H)-酮的高效液相色谱法测定

叙述了采用反向高效液相色谱法,以甲醇为溶剂,甲醇与水(体积比65∶35)为流动相,ODS为填料和紫外检测器分离测定6-氨基-7-氟-2H-1,4-苯并嗪-3(4H)-酮。该方法的标准偏差为0.29,变异系数为0.32%,回收率为99.85%,线性关系系数为0.9997。     

6,7-二(2-甲氧基乙氧基)喹唑啉-4-酮的合成

以3,4-二羟基苯甲酸乙酯为原料,通过醚化、硝化、还原、成环四步反应合成新型抗癌药物中间体6,7-二(2-甲氧基乙氧基)喹唑啉-4-酮,改进了工艺,考察了各类工艺条件对目标产物收率的影响,得到最适宜反应条件,在优化条件下,总收率为83.7%。     

苯并呋喃-2,3-二酮3-（O-甲基-肟）2-肟合成工艺研究

以4-羟基-3-硝基香豆素为起始原料,经过开环、脱羧,得到2-硝基-2,-羟基苯乙酮,再和甲氧胺盐酸盐反应生成中间体1-（2-羟基苯基）-2-硝基-乙酮-O-甲基肟。最后通过碱性条件下关环得到苯并呋喃-2,3-二酮3-（O-甲基-肟）2-肟。目标化合物及中间体结构经1H-NMR确证。反应总收率70.4%,产品纯度99.2%。该工艺原料廉价,操作简单,收率较高,具有较好的工业化应用前景。     

催化加氢合成6-氨基-7-氟-2H-1,4-苯并口恶嗪-3(4H)-酮

6-氨基-7-氟-2H-1,4-苯并口恶嗪-3(4H)-酮(Ⅱ)是合成除草剂丙炔氟草胺的关键中间体,该文采用雷尼镍催化加氢还原7-氟-6-硝基-2H-1,4-苯并口恶嗪-3(4H)-酮(Ⅰ)高收率的制得了目标化合物Ⅱ,确定了最佳合成工艺条件:反应温度80℃,反应时间5 h,催化剂用量为原料质量的5%,氢气压力6 MPa,产品的收率95.2%,质量分数98.5%,溶剂和催化剂循环使用5次,对收率和产品质量分数无影响。产品结构经元素分析、红外光谱、核磁共振确证。     

2-苯基-1,2-苯并异硒唑-3-(2H)-酮的合成研究

在N2保护下,采用水合肼的碱性水溶液还原硒粉制备了K2Se2,不经分离直接与邻氨基苯甲酸的重氮盐反应得到了中间体2,2'-二硒化苯甲酸;在环合反应合成2-苯基-1,2-苯并异硒唑-3-(2H)-酮(Ebselen)时改用了乙醚-水为反应体系,K2CO3水溶液作为副产物HCl的吸收剂,促使胺解关环反应顺利进行,产物易分离、纯化得2-苯基-1,2-苯并异硒唑-3-(2H)-酮。     

H4GeW12O40/Cu3(BTC)2催化Biginelli反应合成3,4-二氢嘧啶-2(1H)-酮衍生物

采用浸渍法以金属有机骨架Cu_3(BTC)_2负载锗钨酸(H_4GeW_(12)O_(40))制备H4Ge W_(12)O_(40)/Cu_3(BTC)_2催化剂,并用该催化剂催化芳醛、尿素和乙酰乙酸乙酯通过"一锅法"Biginelli缩合反应,以无水乙醇为溶剂,合成6种3,4-二氢嘧啶-2(1H)-酮衍生物;通过熔点的测定,IR,1H NMR和MS等对产物3,4-二氢嘧啶-2(1H)-酮衍生物进行表征。结果表明:在芳醛用量为0.04 mol,n(芳醛)∶n(乙酰乙酸乙酯)∶n(尿素)=1∶1.5∶1.5,催化剂的用量占反应物料总质量的4.0%,反应温度为90℃,反应时间为90 min的条件下,目标产物收率可达63.0%~76.3%。     

1,3,5-三硝基-六氢化-1,3,5-三嗪-2-酮的合成与表征

以尿素、甲醛和叔丁胺为原料,通过Mannich缩合反应制备出5-叔丁基-1,3,5-三嗪-2-酮(TBT),再经硝酸-乙酸酐硝化合成出1,3,5-三硝基-六氢化-1,3,5-三嗪-2-酮(Keto-RDX),用核磁、红外光谱、质谱、元素分析等对TBT和Keto-RDX的结构进行了表征.探讨了TBT环化反应历程,确定了制...     

3-氨基-7,8-二甲氧基-2(1H)-喹诺酮的合成

为了改进和优化3-氨基-2(1H)-喹诺酮环的合成工艺,从芳草醛出发,依次经过乙酰化、硝化、甲基化、还原,制备出2-氨基-3,4-二甲氧基苯甲醛(Ⅴ),Ⅴ与硝基乙酸甲酯环合得3-硝基-7,8-二甲氧基-2(1H)喹诺酮(Ⅵ),还原Ⅵ,得到3-氨基-7,8-二甲氧基-2(1H)-喹诺酮。优化后的环合条件为:以体积比7∶3的甲苯和环己烷为混合溶剂,哌啶为催化剂;Ⅵ最佳还原条件为:乙醇为溶剂,5%钯碳和甲酸铵为还原剂。在该条件下,3-氨基-7,8-二甲氧基-2(1H)-喹诺酮合成总收率从邻氨基苯甲醛(Ⅴ)计可达70%以上。     

微波辐射下合成4-(4-氯苯基)-6-甲基-5-乙氧羰基-3,4-二氢嘧啶-2(1H)-酮

研究了微波辐射催化合成标题化合物的方法。最优合成条件:催化剂氨基磺酸0.8g,微波功率240W,辐射时间4min,n4-氯苯甲醛∶n乙酰乙酸乙酯∶n尿素为1.0∶1.2∶1.5,在此条件下产率达94.2%。     

雷尼镍催化加氢合成7-氟-2H-1,4苯并噁嗪-3(4H)-酮

研究了雷尼镍为催化剂加氢还原2-(5-氟-2-硝基苯氧基)乙酸甲酯(1)合成7-氟-2H-[1,4]苯并噁嗪-3(4H)-酮(2)的方法,使还原、合环一次完成。考察了反应温度、催化剂、氢气压力、时间、溶剂及回收的催化剂和溶剂对反应收率的影响,确定了合成工艺条件:反应温度70℃,反应时间4h,催化剂用量为原料质量的5%,氢气压力5MPa,溶剂甲醇用量为1000mL/mol1。产品的收率92.4%,含量98%,溶剂和催化剂循环使用4次,对收率无影响。产品结构经元素分析、红外光谱、核磁共振确证。     

N-苯甲酰基苯并异噻唑-3-酮硫代甲酰胺类化合物的合成及生物活性

通过1,2-苯并异噻唑啉-2(3H)-酮和硫代异氰酸苯甲酸酐类化合物反应,合成了7种N-苯甲酰基苯并异噻唑-3-酮硫代甲酰胺类化合物,用IR、MS、1HNMR、13CNMR对其结构进行了表征;活性测试表明,浓度为0.005mol/L的该类化合物溶液对鳗孤菌、拟态孤菌、溶藻弧菌、大肠杆菌和嗜水性单胞菌的抑菌率达40.5%~100%。     

H4SiW12O40/SiO2催化一锅法合成4-苯基-6-甲基-5-乙氧羰基-3,4-二氢嘧啶-2(H)-酮

采用一锅法Biginelli反应以H4SiW12O40/SiO2为催化剂,以苯甲醛、乙酰乙酸乙酯和尿素为原料,无水乙醇为溶剂合成了4-苯基-6-甲基-5-乙氧羰基-3,4-二氢嘧啶-2(H)-酮。探讨了原料摩尔比、反应温度、催化剂用量及反应时间对收率的影响。结果表明,固定苯甲醛用量为0.04 mol的条件下,n(苯甲醛)∶n(乙酰乙酸乙酯)∶n(尿素)=1∶1.5∶1.5,催化剂的用量占反应物料总质量的2.0%,反应温度为90℃,反应时间为60 min,产品平均收率可达71.7%。通过熔点的测定,IR,1HNMR和MS对合成的3,4-二氢嘧啶酮化合物进行了表征。     

MgO-CeO2 nanocomposite: efficient catalyst for the preparation of 2-aminothiophenes and thieno[2,3-d]pyrimidin-4(3H)-one derivatives

MgO-CeO₂ nanocomposite was prepared by a co-precipitation method and characterized by X-ray diffraction (XRD), FE-SEM, and particle size distribution analysis. The XRD pattern shows the cubic phase of cerium oxide as the dominate phase. FE-SEM images show the homogeneity distribution of magnesium and cerium oxides in the sample. The mean particle size of nanocomposite determined by the dynamic light scattering technique is 66?nm. The catalytic activity of MgO-CeO₂ nanocomposite was examined on the synthesis of 2-aminothiophenes and thieno[2,3-d]pyrimidin-4(3H)-one derivatives. In all cases, products were obtained in good to excellent yields.     

相转移催化合成4,5-二氢-3-甲基-1-(4-氯-2-氟苯基)-1,2,4-三唑-5(1H)酮的工艺

[方法]4,5-二氢-3-甲基-1-(4-氯-2-氟苯基)-1,2,4-三唑-5(1H)酮是唑酮草酯的重要中间体。以4-氯-2-氟苯肼为原料,乙酸乙酯为反应溶剂,PEG-1000为相转移催化剂,经过脱水缩合、1,3-偶极加成、氧化脱氢等3步反应,合成4,5-二氢-3-甲基-1-(4-氯-2-氟苯基)-1,2,4-三唑-5(1H)酮。[结果]研究了催化剂种类与用量、溶剂、反应温度、物料配比对反应收率的影响,得到优化后的反应条件:n(乙醛)∶n(氰酸钠)∶n(乙酸)∶n(次氯酸钠)∶n(聚乙二醇-1000)∶(4-氯-2-氟苯肼)为1.80∶1.60∶1.84∶1.60∶0.04∶1.0,反应温度20~25℃。[结论]该工艺原料易得、反应条件温和、操作简单、收率较好,具有良好的工业应用价值。     

2-氯-6，7-二氢喹啉-8（5H）-酮的合成研究

2-氯-6,7-二氢喹啉培（5H）-酮是四氢喹啉是一个重要的含氮杂环化合物。文章以2-氯-5,6,7,8-四氢喹啉为原料,经氧化、酯化、水解反应后得到2．氯-5,6,7,8-四氢喹啉-8-醇,再经Anelli氧化后得到总收率为57,8％的目标产物。所得化合物的结构均经核磁和质谱确证。