Biodegradable Radiopaque Composite Filaments Based on Poly(p-dioxanone)and 2,3,5-triiodobenzoic Acid

To determine the possibility of blending 2, 3, 5-triiodobenzoic acid( TIBA) and poly( p-dioxanone)( PPDO) to produce X-ray visible PPDO filaments,melt-blended PPDO with different concentrations of TIBA was obtained. Several radiopaque filaments of PPDO polymer filled with radiopaque TIBA particles were prepared via melt-blending. Material properties of the composite filaments were investigated using various material characterization techniques,including scanning electron microscope( SEM),thermogravimetric analysis( TGA),X-ray Diffraction( XRD),dynamic rheometry and micro-CT scan. In this article,the dispersion of TIBA in PPDO,the properties of the filament,and the ratio of PPDO and TIBA and the corresponding X-ray visibility in vivo were studied. SEM results showed the dispersion of the contrast imaging agent TIBA was relatively even in the PPDO polymer. Xray analysis in vitro confirmed the enhanced radiopacity of the filaments with respect to the pure PPDO filament. The presence of iodine element in the composite filament could allow the bioabsorbable material to be monitored in vivo, and made it potential to be used in biomedical applications.

TIBA对不同耐荫性大豆套作苗期生长和倒伏率的影响

三碘苯甲酸(TIBA)是一种生长素运输抑制剂,具有抑制顶端生长的作用。为分析套作模式中,喷施TIBA对不同耐荫性大豆品种幼苗期生长和倒伏的调控效应,本研究设置50,100,150,200和250 mg·kg^-1的TIBA浓度处理,以清水和无遮荫为对照处理,调查大豆形态、干物质和倒伏性状。结果表明:与无荫蔽对照相比,荫蔽下大豆株高增加,茎粗、节数、分枝数、SPAD、干物质则显著降低,倒伏率显著增加。喷施TIBA后,大豆株高显著降低,茎粗、节数无改变,分枝数增加,叶面积下降,叶片SPAD无变化,干物质下降,大豆倒伏率显著降低。套作模式下大豆幼苗期TIBA喷施的适宜浓度为50~100 mg·kg^-1,且适宜浓度与品种自身耐荫能力有关,强耐荫品种南豆12适宜浓度为50 mg·kg^-1,而荫蔽敏感型大豆XBM为100 mg·kg^-1。浓度高于150 mg·kg^-1处理虽然更有利于降低株高、减少倒伏,但大豆干物质积累量偏低,不利于培育壮苗。

构树去木质部后TIBA对组织再生的影响及其间过氧化物酶和酯酶同工酶的变化

构树(Broussonetiapapyrifera(L.)Vent.)去木质部后,IAA的运输抑制剂TIBA(三碘苯甲酸)可抑制IAA对维管形成层和木栓形成层的再生与活动,以及木质部和韧皮部分化等的促进作用。过氧化物酶和酯酶同工酶的变化与组织的分化过程密切相关。

不同生长抑制剂对盆栽梅花生理特性的影响

以‘骨里红’梅3年生扦插苗为试材,采用叶面喷施方法,对矮壮素(CCC)、多效唑(PBZ)、三碘苯甲酸(TIBA)3种生长抑制剂各设置4个不同质量浓度梯度(矮壮素、多效唑为500、1000、1500、2000 mg·L^(-1);三碘苯甲酸为50、100、150、200 mg·L^(-1)),分析不同质量浓度及种类的抑制剂对营养生长阶段梅花生理特性的影响。结果表明:外施中高质量浓度(≥1000 mg·L^(-1))的多效唑对株高、地径、新梢生长量、当年生枝径的调节作用最强,调节效果显著优于喷施矮壮素、三碘苯甲酸处理。喷施矮壮素、多效唑在不同程度对光合速率(P_(n))、气孔导度(G_(s))、胞间CO_(2)摩尔分数(C_(i))、蒸腾速率(T_(r))有显著促进作用,而喷施三碘苯甲酸则对植株光合作用有不同程度的抑制。3种抑制剂对‘骨里红’梅的调控效果由大到小依次为多效唑、矮壮素、三碘苯甲酸。外施质量浓度为1500 mg·L^(-1)的多效唑对植物营养生长的促进效果最佳;喷施质量浓度为1500 mg·L^(-1)的矮壮素次之。当喷施的三碘苯甲酸质量浓度高于100 mg·L^(-1)时,多数植株出现了烧苗现象。对于对照,清水、摘心处理优于清水、不摘心处理。

水稻体细胞培养中胚性细胞出现与IAA的关系

水稻体细胞培养中胚性细胞出现与ＩＡＡ的关系陈以峰１周燮２汤日圣２张金渝２梅传生１（南京农业大学农学系南京２１００９５）２（江苏省农业科学院农业生物遗传生理研究所南京２１００１４）关键词水稻，胚性细胞，ＩＡＡ，２，４二氯苯氧乙酸，２，３，５三碘...

生长素和赤霉素对离体水仙花茎切段伸长的影响

以离体水仙(Narcissustazettavar.chinensis)花茎切段为材料,通过外源吲哚-3-乙酸(Indole-3-aceticacid,IAA)和赤霉素A3(GA3)处理,结合内源激素分析,研究了这两种激素对水仙花茎切段伸长的影响,以及它们之间的相互作用。结果表明:外源50μmol/LIAA和30μmol/LGA3均能促进花茎切段的伸长,其中IAA的促进作用大于GA3。200μmol/L生长素运输抑制剂2,3,5-三碘苯甲酸(2,3,5-Triiodobenzoicacid,TIBA)和65μmol/L赤霉素合成抑制剂烯效唑(Uniconazole,S-3307)均显著抑制花茎切段的伸长。外源50μmol/LIAA处理明显增加内源GA1+3的含量,是对照的3.40倍;外源30μmol/LGA3处理对内源IAA含量影响不明显,说明IAA对维持花茎切段内源活性GA水平起重要作用,IAA和活性GA共同发挥调控花茎切段伸长的作用。

气相色谱法测定蔬菜中三碘苯甲酸残留量

建立三碘苯甲酸残留量的气相色谱测定方法,选取西红柿等6种基质,样品经0.1mol/L盐酸酸化,以二氯甲烷为提取剂,超声波提取,用三甲基硅重氮甲烷进行甲酯化,经弗罗里硅土固相萃取柱净化后上机测定,采用电子捕获检测器测定,保留时间定性,外标法定量。并对该方法的灵敏度、准确度和精密度进行实验,三碘苯甲酸的最低检出限可达0.001mg/kg,各水平的添加回收率为70%～95.7%。该方法可靠、灵敏、简便可行,可为制定国家标准分析方法提供参考。

几种抑制剂对钾和IAA诱导的离体黄瓜子叶不定根形成的影响

应用离体黄瓜(Cucumis sativus L.)子叶生根试法测定了几种抑制剂对钾和IAA诱导生根的影响。实验结果表明:7×10^(-4)～7×10^(-1)mmol/L的5-氟尿嘧啶和3.5×10^(-4)～1.05×10^(-2)mmoL/L的环已亚胺明显抑制钾和IAA诱导的离体黄瓜子叶的生根;0.1～1.0mmol/L的钒酸钠显著抑制钾和IAA诱导的离体黄瓜子叶的生根;2×10^(-4)～2×10^(-1)mmol/L的2,3,5-三碘苯甲酸也明显抑制钾和IAA诱导的离体黄瓜子叶的生根。钾诱导的生根与IAA诱导的生根密切相关,有可能钾对生根的促进作用是通过影响内源IAA的水平而实现的。

气相色谱法对水果样品中三碘苯甲酸残留的测定

分别选取了苹果、梨等6种水果基质，样品经1％硫酸酸化，用二氯甲烷提取，提取液蒸干后用三甲基硅重氮甲烷进行甲酯化衍生，经弗罗里硅土固相萃取柱净化后上机测定。采用气相色谱，程序升温，电子捕获检测器测定，保留时间定性，外标法定量。优化了衍生条件，并对方法的灵敏度、准确度、精密度和回收率进行了实验，三碘苯甲酸的检出限可达0．0008mg／kg，方法在0．01-20mg／L范围内线性关系良好。各浓度水平的添加回收率为63％～107％，相对标准偏差为1．8％～9．3％。建立的方法符合国家标准对食品中农药残留测定的要求，可用于对食品安全的监测。

生长抑制剂对大叶黄杨形态观赏性的影响

构建表征大叶黄杨形态观赏性指数并研究不同生长抑制剂对大叶黄杨观赏指数的影响。在北京市鹫峰苗圃,将不同质量浓度的3种生长抑制剂(脱落酸ABA(A)、多效唑PP333(P)以及三碘苯甲酸TIBA(T))以L27(313)正交设计方案混合,并用其对密植成绿篱状的大叶黄杨扦插苗进行叶面喷施,选取10个灌木观赏性相关指标,采用因子分析法构建叶片光彩度指数、分枝度指数、叶形态指数及绿度指数4个观赏性指数,分析生长抑制剂对各观赏性指数的影响。结果表明:脱落酸对叶片光彩度、叶形态以及分枝度均有抑制作用,对叶绿度有促进作用,且较高质量浓度脱落酸对叶光彩度及形态的抑制作用较低,较低质量浓度脱落酸对分枝度的抑制作用较低;多效唑对叶形态有较好促进作用,较低质量浓度多效唑对分枝度及叶绿度的负面作用较低;三碘苯甲酸对光彩度、叶形态以及分枝度均有抑制作用,且抑制作用随三碘苯甲酸质量浓度增加而增强,低质量浓度三碘苯甲酸对三者观赏性的负效应较低,三碘苯甲酸对叶绿度有显著促进作用,且促进作用随三碘苯甲酸质量浓度增加而增强。脱落酸、多效唑、三碘苯甲酸以及三者交互作用通过影响叶片光彩度、分枝度、叶绿度及叶形态而影响大叶黄杨篱观赏性。

紫外-可见分光光度法在定量监测2,3,5-三碘苯甲酸缓释中的应用

为研究显影剂2,3,5-三碘苯甲酸(TIBA)在显影纤维聚对二氧环己酮(PPDO)降解液中的缓释规律,采用紫外可见分光光度法探究了TIBA在不同体积比的磷酸盐缓冲溶液(PBS)和乙醇共混降解液(V_(PBS)∶V_(乙醇)分别为1∶3、1∶1和3∶1)中的紫外-可见分光光谱和回归曲线,根据回归曲线,测定降解液的吸光度值及计算PPDO纤维在降解过程中显影剂TIBA的释放量,借助药物缓释理论模型进行拟合,并分析相应的释放规律。结果表明:在3种共混溶液中,均能得到回归关系明显的线性方程,考虑到乙醇用量,选择PBS与乙醇的体积比为3∶1的溶液作为标准液,并且溶液在37℃的环境中静置8 d后仍能保持一定的稳定性;模型拟合结果表明TIBA的释放规律符合一级释放的函数模型。

Auxin distribution and transport during embryogenesis and seed germi-nation of Arabidopsis

Auxin distribution during embryogenesis and seed germination were studied with transgenic Arabidopsis plants expressing GUS gene driven by a synthetic DR5 promoter,an auxin responsive promoter. The results showed that GUS activity is higher in ends of hypophysis and cotyledon primordia of heart-, torpedo- and cotyledon-stage embryos, leaf tip area, lateral root primordia, root apex and cotyledon of young seedlings. And GUS accumulated in root apex of the seedlings grown on auxin transport inhibitor containing media. All these suggested that above-mentioned part of the organs and tissues have a higher level of auxin, and auxin polar transport inhibitor could cause the accumulation of auxin in root apex. And auxin transport inhibitor also resulted in aberration of Arabidopsis leaf pattern formation, root gravitropism and elongation.

How United States Agricultural Herbicides Became Military and Environmental Chemical Weapons: Historical and Residual Effects

Discoveries in Charles Darwin’s laboratory led to modern herbicides. Darwin discovered the internal mechanism that directed plants to grow toward sunlight and sources of water. Scientists in Europe and America later called this mechanism a plant’s hormone response system. Administrators and scientists, including Dr. Ezra J. Kraus, the Head of the Botany Department at the University of Chicago and a plant physiologist, suggested on the eve of WWII that weed killers had significant military value as chemical weapons. Dr. Kraus obtained access to a synthetic chemical, 2,4-D, and found that when the chemical was absorbed through the leaves of plants, it destroyed a plant’s hormones. After exposure, the plant experienced rapid and uncontrolled growth, and then the leaves shriveled, died and fell off. Dr. Kraus obtained funding for his Department of Botany research program from Department of Defense (DOD) during World War II (WWII). Camp Detrick (Biological Weapons Laboratory) scientists later obtained samples of newly created 2,4,5-T which contained unknown amounts of the by-product dioxin TCDD. In the 1950s and 1960s, Fort Detrick military scientists formulated the herbicide Agent Orange, which was a 50 - 50 mixture of 2,4-D and 2,4,5-T. These dual purpose herbicides were used by DOD and USDA. American and European farmers in the 1940s used 2,4-D and 2,4,5-T to eliminate weeds from pastureland and cropland. After WWII, synthetic herbicides (and pesticides) development continued in tandem with production of synthetic fertilizers and breeding of high-yield plant varieties. These new agricultural products were then shipped worldwide to increase crop yields, as part of the Green Revolution. This new system of agricultural technologies was intended to eliminate global starvation and increase food security by increasing field and farm crop yields. In contrast, the goal of military use of herbicides, as chemical weapons, was to defoliate jungle forests and destroy food crops as a strategy to win battles and wars. The primary objective of this research study is to describe how agricultural herbicides became tactical chemical weapons. A current assessment will address the environmental impacts of military and environmental chemical weapons on the United States and Vietnam ecosystems and need for additional dioxin TCDD hotspot clean-up efforts.

青花椒开黄花的生理变化及调控初步研究

花椒(Zanthoxylum armatum)开黄花后不能正常结实,严重影响了相关产业发展。为探究花椒开黄花的生理特点及其防治关键药剂,本研究对不同时期花椒形态进行了观察,对多种植物激素含量进行了测定测定。以重庆多地九叶青花椒(Z. armatum var. novemfolius)正常株和黄花株为试材,采用石蜡切片法对花椒形态进行观察并对花椒黄花株和正常株花叶数量质量进行统计,采用高效液相色谱法和酶联免疫法对茎尖、花序的植物激素指标进行测定分析。结果表明:(1)花椒开黄花的生理实质为雌蕊的缺失和雄蕊的出现。花芽分化期黄花株花芽发育时间比正常株早,且分化程度更高。初花期和盛花期黄花株表现为雄蕊异常发育、雌蕊缺失特征,正常株则为雌蕊发育;且在盛花期时,黄花株花芽表现出发育时间早、花芽数量过多的特征。花椒黄花株小花质量、小花数量和花叶质量比分别是正常株的1.61倍、2.86倍和7.65倍,黄花株新生叶质量降低23.3%,数量下降55.6%。(2)脱落酸(ABA)和水杨酸(SA)在黄花株和正常株的秋季茎尖及次年春季花序中的含量差异显著。黄花株秋季茎尖中ABA含量下降了45.6%, SA含量上升了1.18倍。(3)喷施三碘苯甲酸(TIBA)药物能够改善花椒开黄花现象。喷施100 mg·L^(-1)TIBA后,春季黄花株中的SA含量较正常株已无显著差异;喷施500 mg·L^(-1)TIBA后,黄花株中ABA和SA含量较正常株均无显著差异。综上结果显示ABA和SA在花椒开黄花中起到关键性作用。

核磁共振法定量测定盐酸氨溴索杂质

目的:建立以核磁共振(qNMR)技术测定盐酸氨溴索杂质含量的方法。方法:仪器为配备5mm BBO探头的Bruker Ascend 500MHz核磁共振仪,采集一维定量氢谱,延迟时间的d1为20s,温度为25℃,采样次数为128次。分别以2,3,5-三碘苯甲酸、对苯二甲酸二甲酯和对硝基甲苯为内标,对5种盐酸氨溴索杂质(杂质A、B、C、D和E)进行定量研究。结果:5种盐酸氨溴索杂质(杂质A、B、C、D和E)qNMR法测定结果与对照品标定的质量平衡法定值结果基本一致,相差最大为0.4%。结论:采用核磁共振法测定盐酸氨溴索5种杂质的含量,是对标准物质量值测量的一种良好佐证。