羟丙基瓜尔胶中羟丙基摩尔取代度以及取代位置的表征

本文探索了表征羟丙基瓜尔胶(HPG)中羟丙基摩尔取代度(MS)以及取代位置的化学方法.当反应温度为110℃、反应时间为14h以及HPG中羟基与对甲苯磺酸-乙酸酐摩尔比为1:3.5时,用对甲苯磺酸-乙酸酐化学法和气相色谱法可准确测定HPG的羟丙基MS,与1H-NMR测定结果相对误差小于10%.在pH=10.30和0℃的条件下,瓜尔胶的伯羟基被2,2,6,6-四甲基哌啶氮--氧化物(TEMPO)-NaClO-NaBr体系选择性氧化成羧基,由此可表征羟丙基链段的取代位置.     

N,O-羧甲基化羟丙基壳聚糖的制备及结构表征

用NaOH作为催化剂, 在异丙醇悬浮体系中环氧丙烷(PO)与壳聚糖(CS)在60 ℃下反应8 h, 制备取代度超过0.8的羟丙基壳聚糖(HPCS). HPCS在水溶液中与氯乙酸反应, 制备了一种结构新颖的两性聚合物N,O-羧甲基化羟丙基壳聚糖(HPCMS), 羧甲基取代度可控制在0.42～1.38之间. 采用NMR和FTIR对产物结构进行表征. 结果表明, 在壳聚糖的羟丙基化改性过程中, C6位羟基首先与环氧丙烷反应, 生成HPCS; 在与氯乙酸反应过程中, HPCS上的羟基和氨基同时与氯乙酸发生取代反应.     

高碘酸钠氧化法测定羟丙基瓜尔胶上仲羟基取代度

高碘酸钠氧化可以使邻羟基C-C键发生高选择性断裂, 同时产生两分子醛基. 在pH=4.3及25 ℃的条件下, 对瓜尔胶及其衍生物羟丙基瓜尔胶进行高碘酸钠氧化, 采用红外光谱与核磁共振谱对氧化产物结构进行了表征. 结果表明, 氧化后的瓜尔胶和及羟丙基瓜尔胶结构中醛基主要以半缩醛的形式存在. 通过测定高碘酸钠的消耗量得到不同摩尔取代度羟丙基瓜尔胶糖单元上邻羟基的含量, 结合概率分析方法, 确定摩尔取代度分别为0.04, 0.14, 0.36, 0.51, 0.78, 1.05和1.53的羟丙基瓜尔胶在仲羟基上取代度分别为0.02, 0.09, 0.18, 0.30, 0.46, 0.59和1.03, 与其它方法得到的结果一致.     

羟乙基瓜尔胶中羟乙基摩尔取代度以及取代位置的表征

本文探索了表征羟乙基瓜尔胶(HEG)中羟乙基摩尔取代度(MS)以及取代位置的化学方法。当反应温度为110℃,时间为14hr,HEG中羟基与混酐比例为1:2.5时,用混酐化学法可准确测定HEG的羟乙基MS,测定结果与计算值的相对误差小于10%。在pH=10.30和0℃的条件下,瓜尔胶的伯羟基被2,2,6,6-四甲基哌啶氮氧化物(TEMPO)-NaClO-NaBr体系选择性氧化成羧基,由此可表征羟乙基链段的取代位置。在瓜尔胶醚化生成羟乙基瓜尔胶的过程中,醚化反应并不是完全发生在伯羟基上。伯羟基的反应活性是仲羟基的6-10倍。随着MS的增大,连接在仲羟基上羟乙基链段占所有羟乙基链段的比例逐渐增大,当MS=0.4时该比例基本不再变化,为40%左右。     

羟丙基瓜尔胶的制备及表征

瓜尔胶(guar gum)是一种天然半乳甘露聚糖，其水溶性和增稠性很好，广泛用做增稠剂、破乳剂等。原粉胶溶解较慢、水不溶物含量高、粘度不易控制，人们常利用化学手段改变其理化特性以满足实际工业生产需要，羟丙基化是有效的手段之一，但对羟丙基化的表征较为困难。S．     

2,2,6,6-四甲基哌啶氧自由基氧化糖类物质伯羟基研究进展

2,2,6,6-四甲基哌啶氧自由基(TEMPO)属于亚硝酰自由基类,能选择性氧化糖类物质的伯羟基,氧化产物的应用非常广泛。本文对TEMPO氧化糖类物质伯羟基的研究进展作一综述。     

羟丙基瓜尔胶在离子液体中的制备

本文以离子液体1-烯丙基-3-甲基咪唑氯盐(AmimCl)为反应介质,以氢氧化钠为催化剂合成了羟丙基瓜尔胶(HPG),并通过1H NMR确定了产品的摩尔取代度。探讨了水的用量、环氧丙烷的用量、反应温度和反应时间对摩尔取代度的影响。在水与瓜尔胶的质量比为1.7、氢氧化钠与瓜尔胶的质量比为5%、环氧丙烷与瓜尔胶的质量比为3.5、反应温度为60℃和反应时间为12h的条件下,摩尔取代度(MS)可以达到0.76。同时发现在不加催化剂NaOH的情况下,瓜尔胶在AmimCl中的羟丙基化反应同样可以发生,只是得到的HPG的MS相对较小。     

羟丙基田菁胶的结构研究

本文用IR、~(13)C-NMR、~1H-NMR、MS、元素分析手段对田菁胶原粉和环氧丙烷反应的合成样品进行系统地结构研究,证明样品为羟丙基型半乳甘露聚糖类,其主结构与田菁胶原粉一致,并用~1H-NMR法测定了羟丙基田菁胶的醚化度(D.S).     

含5,4′-多羟基黄酮苷及苷元分子的结构修饰方法

多羟基黄酮苷及苷元类化合物具有多种生物活性与生理功能,但它们在体内的稳定性与生物利用度相对较弱,在药理学上也表现出非特异性作用。由于其在制药、食品与化妆品领域中的重要性,本文根据其分子修饰的取代方式分为黄酮母核酚羟基的O-取代,苯环上C-取代与配糖羟基的酶促催化反应三类,以槲皮素(芦丁)及柚皮素(柚皮苷)等作为黄酮醇(苷)与二氢黄酮(苷)类化合物的典型代表,对酚羟基的保护方法进行了对比分析,简述了这三类半合成反应的特点。重点探讨了Mannich缩合应用于C-取代时,反应底物、单体以及体系酸碱度对反应的影响。研究指出,合理筛选黄酮母核羟基以及单体活性基团的保护方式是成功实现选择性半合成的重要途径。目前,对含有5,4′-多羟基黄酮醇与二氢黄酮类分子的O-取代以多取代产物为主,反应性能明显强于C-取代反应,区域选择性相对较弱。此外,这类活性分子与含长链烷基(C≥12)单体的反应一般属于单取代反应,其脂溶性取代产物在气/液界面上的物理化学行为具备重要的研究与应用价值。     

RuCl3·3H2O/DCHA体系在空气中对苄醇的选择性氧化

对RuCl3·3H2O/DCHA体系催化空气氧化苄醇的反应进行了详细研究,结果表明在RuCl3·3H2O/DCHA的催化下,苄醇被有效地氧化成相应的醛.重要的是该催化体系具有较好的化学选择性,对苯甲醇和1-苯基乙醇的混合物,能高选择性地氧化苯甲醇,而后者基本不被氧化;对含伯羟基和仲羟基的3-(1'-羟乙基)苯甲醇和4-(1'-羟乙基)苯甲醇,能高选择性地氧化伯羟基,而仲羟基大部分不被氧化.该反应具有反应条件温和、操作简单、化学选择性好等特点.     

Preparation of amidated derivatives of monocarboxy cellulose

Amidated derivatives of monocarboxy cellulose (MCC), the product of cellulose oxidation, containing carboxyl groups only at C-6 position, were prepared and characterised. Two-step way of amidation was based on the esterification of C-6 carboxyls in MCC by reaction with methanol at 60 °C for 72 h and further amino-de-alkoxylation (aminolysis) of the obtained methyl ester with n-alkylamines, hydrazine and hydroxylamine in the N,N-dimethylformamide medium. Purity and substitution degree of the products were monitored by vibration spectroscopic methods (FTIR and FT Raman) and organic elemental analysis. Analytical methods confirmed the preparation of highly or moderately substituted N-alkylamides, hydrazide and hydroxamic acid of MCC.     

Resin-capture and release strategy toward combinatorial libraries of 2,6,9-substituted purines

A resin-capture and release strategy for making combinatorial 2,6,9-trisubstituted purine libraries is demonstrated by capturing N9-derivatized purines at the C6 position with a thio-modified polymer. The C2 fluoro group is subsequently substituted with primary and secondary amines followed by thioether oxidation and release by C6 substitution with amines and anilines. This approach complements a previously reported strategy where a 6-phenylsulfenylpurine scaffold was captured at the C2 position with a resin-bound amine.(3)     

Gamma-linolenic acid biosynthesis: cryptoregiochemistry of delta6 desaturation

The valuable nutraceutical gamma-linolenic acid (GLA, (6Z,9Z,12Z)-octadecatrienoic acid) is biosynthesized by a series of regio- and stereoselective dehydrogenation reactions that are catalyzed by a set of enzymes known as fatty acid desaturases. As part of ongoing research into the mechanism of these remarkable catalysts, we have examined the cryptoregiochemistry (site of initial oxidation) of Delta6 desaturation as it occurs in the protozoan Tetrahymena thermophila. Two complementary approaches that address this issue are described. In the first set of experiments, we measured the individual primary deuterium kinetic isotope effects associated with the C-H bond cleavages at C-6 and C-7. Competition experiments using appropriately deuterium-labeled 4-thiasubstrates revealed that a large KIE (kH/kD = 7.1 +/- 0.5) was observed for the C-H bond-breaking step at C-6, whereas the C-H bond cleavage at C-7 was insensitive to deuterium substitution (kH/kD = 1.04 +/- 0.05). These results point to C-6 as the site of initial oxidation in Delta6 desaturation since the first chemical step in this type of reaction is rupture of a strong, unactivated C-H bond, an energetically difficult process that typically exhibits a large KIE. This conclusion was supported by the results of our second approach, which involved locating the position of the putative diiron oxo oxidant with respect to substrate by monitoring the efficiency of oxo transfer to a series of thia fatty acid probes. Thus only a 6-thia-analogue is converted to significant amounts of the corresponding sulfoxide (9% yield). The absolute configuration of this product was determined to be S using (S)-MPAA as a chiral shift reagent. Taken together, these results point to the abstraction of the C-6 pro S hydrogen as the initial event in Delta6 desaturation as it occurs in T. thermophila.     

Pyridyl groups for protection of the imide functions of uridine and guanosine. Exploration of their displacement reactions for site-specific modifications of uracil and guanine bases

For the protection of the O-4 function of uridine and the O-6 of guanosine, 2-, 3- and 4-hydroxypyridines, 2-pyridinethiol, 6-methyl-2-hydroxy- and 6-methyl-3-hydroxypyridines have been employed. These substituted pyridines gave pyridyl-N-and/or pyridyl-O-substituted derivatives, depending both upon the position of the hydroxyl and methyl groups in the pyridine ring, at the C-4 and the C-6 of the uracil and guanine residues, respectively. These groups were found to be good leaving groups for nucleophilic substitution reactions by amines, thiolates and oximate. If needed, the rate of these substitution reactions could be conveniently increased by almost 1000-fold by conversion of the pyridyl moiety to its methiodide.     

PREPARATION AND STRUCTURE OFFIVE DERIVATIVES OFβ-(1→3)-D-GLUCAN ISOLATED FROM PORIA COCOS SCLEROTIUM*

A new solvent of cellulose (1.5 mol/L NaOH/0.5 mol/L urea aqueous solution) was used as one of the homogeneous reaction media of polysaccharides for methylation, hydroxyethylation and hydroxypropylation. A water insoluble β-(1→3)-D-glucan, sample PCS3-Ⅱ, isolated from fresh sclerotium of Poria cocos was sulfated in dimethyl sulfoxide (Me2SO), carboxymethylated in NaOH, isopropanol solution, as well as methylated, hydroxyethylated and hydroxypropylated in the new solvent system, respectively, to obtain five water-soluble derivatives coded as S-PCS3-Ⅱ, C-PCS3-Ⅱ, M-PCS3-Ⅱ, HE-PCS3-Ⅱand HP-PCS3-Ⅱ. Their chemical structure and distribution of substitution were characterized by infrared spectroscopy (IR), elementary analysis (EA), ^1H-NMR, ^13C-NMR, 2D-COSY, 2D-TOCSY and 2D-^1H-detected ^1H ^13C HMQC spectra. The results reveal that the relative reactivity of hydroxyl groups of the β(1→3)-D-glucan is in the order C-6 ＞ C-4 ＞ C-2 on the whole. The substitution of the samples S-PCS3-Ⅱ, C-PCS3-Ⅱ and M-PCS3-Ⅱ occurred mainly at C-6 position and secondly at C-4 and C-2 positions, and that of HE-PCS3-Ⅱ occurred at C-6 and C-4 positions and of HP-PCS3-Ⅱ almost completely occurred at C-6 position. The degrees of substitution (DS) obtained from ^13C-NMR range from 0.23 to 1.27. The water solubility of the derivatives is in the order S-PCS3-Ⅱ ＞ C-PCS3-Ⅱ ＞ M-PCS3-Ⅱ ＞ HE-PCS3-Ⅱ ＞ HP-PCS3-Ⅱ. This work provides a novel and nonpolluting process for the methylation, hydroxyethylation and hydroxypropylation of β-(1→3)-D-glucan.     

N,O-heterocyclics. 13. Isoxazolidinium salts as synthons to N,N, O-trisubstituted hydroxylamines

Substituted isoxazolidinium salts react with lithium aluminium hydride to yield open-ring products which have hydroxylamine structures. The bimolecular reaction-mechanism has been investigated by substituent effect and the structure of the products ascertained by spectroscopic methods with the aid of the MIKE technique. The overall process of the ring-opening substitution is controlled by the polarisation of the C? N bond with steric and conformational factors acting mainly at the C-5 position of the nucleus. The mechanism of isoxazolidinium ion reaction defines the use of these synthons towards the synthesis of N,N,O-trisubstituted hydroxylamines and substituted 1,3-amino-alcohols.     

13C-NMR spectral studies on the distribution of substituents in some cellulose derivatives

¹³C-NMR spectra of trityl cellulose (Tr-Cell), tosyl cellulose (Ts-Cell), cellulose S-methyl xanthate (Cell-M-Xan), and cellulose formate (CF) in dimethylsulfoxide-d₆ were analyzed at 50.4 MHz. It was found that the distribution of substituents in the anhydroglucose units of these cellulose derivatives can be estimated from their ring carbon spectra. The results showed that (i) in Tr-Cell having degree of substitution (DS) lower than 1, the hydroxyl groups at C-6 carbon position are selectively tritylated, (ii) in the case of Ts-Cell, the difference in the relative DS value among three different types of hydroxyl groups is not large, although the relative reactivities of hydroxyl groups toward tosylation decrease in the order C-6 > C-2 > C-3, (iii) in Cell-M-Xan, the hydroxyl groups at C-3 carbon position are mainly substituted, and (iv) the ease of formylation is C-6 > C-2 > C-3. The 100.8 MHz ¹³C-NMR spectra of O-methyl cellulose (MC) revealed that the reactivity order in commercial MC prepared from alkali cellulose is C-6 ? C-2 > C-3. Concerning MC, its water solubility was also discussed in terms of the distribution of substituents along the cellulose chain.