天然结晶辣椒碱的NMR谱研究

用一维¹H NMR谱、¹H-¹H COSY谱和一维¹³C NMR谱、DEPT谱研究辣椒碱分子和二氢辣椒碱分子及其混合物,得到¹H和¹³C的化学位移,采用¹H NMR谱测定天然辣椒碱中辣椒碱和二氢辣椒碱的相对含量.     

20(R)和20(S)-人参皂甙Rg2碳氢NMR信号全指定

20(R)和20(S)人参皂甙Rg₂属于达玛烷型四环三萜类化合物.应用2DNMR技术:¹H-¹H COSY、HMQC和HMBC全归属20(R)和20(S)人参皂甙Rg₂碳和氢质子信号,为该类型化合物的结构鉴定提供波谱学依据.     

果糖二丙酮的结构全归属

2,3：4,5-双-O-（1-甲基亚乙基）-β-D-吡喃果糖又称为果糖二丙酮（diacetonefructose）,是一类重要的药物合成中间体,它是抗癫痫药物托吡酯中的母体部分,在药物合成中具有重要的作用.果糖二丙酮结构中含有手性碳原子,核磁共振（NMR）谱图较为复杂,本文首先应用¹H NMR、¹³C NMR、DEPT135、¹H-¹³C HMBC、¹H-¹³C HSQC、¹H-¹H COSY和NOESY实验对果糖二丙酮的¹H和¹³C NMR信号进行了指认归属,确定了其空间构型.然后,利用计算化学的方法对其结构进行了模拟,进一步佐证了该构型的正确性.     

卡泊三醇的核磁共振谱解析

利用核磁共振氢谱（¹H NMR）、碳谱（¹³C NMR）、同核位移相关谱（¹H-¹H COSY）、异核单量子相干谱（HSQC）和异核多键相关谱（HMBC）等多种核磁研究方法对抗银屑病药物卡泊三醇的¹H、¹³C信号进行完全归属.     

蒽加氢产物的结构指认和定量核磁共振分析

本文利用多种液体核磁共振（NMR）技术,综合分析了在三个不同反应条件下蒽催化加氢反应获得的产物混合物.利用二维扩散排序谱（DOSY）和一维选择性激发谱（selTOCSY）确定了产物中含有的二氢蒽、四氢蒽、对称八氢蒽和非对称八氢蒽;利用¹H NMR、¹³C NMR、DEPT135、¹H-¹H COSY、¹H-¹³C HSQC实验对二氢蒽、四氢蒽和对称八氢蒽的¹H和¹³C NMR信号进行了详细归属;利用定量核磁共振氢谱（QNMR）计算得到了蒽的转化率和产物的选择性.本研究可用于指导优化催化反应条件,提高产物对称八氢蒽的选择性,同时为稠环类芳烃催化加氢产物的分析提供系统的NMR技术方案.     

南海海绵Dysidea fragilis中两个倍半萜内酯的NMR研究

用一维¹H、¹³C NMR谱、DEPT ¹³C NMR谱、选择性远程DEPT ¹³C NMR、¹H-¹H COSY和¹³C-¹H COSY二维核磁共振技术研究了南海海绵Dysidea fragilis中的两个倍半萜herbadysidolide(1)和furodysinin lactone(2),确认了化学结构,并对其¹³C NMR和¹H NMR谱进行了归属.药理活性试验表明:1和2具有一定的心血管活性.     

一种1,4-噻嗪酰胺类FKBPs配体的波谱学数据解析

（3R）-4-[（4-甲基苯磺酰基）]-1,4-噻嗪-3-酰基-[（2R）-2-氨基-4-甲基]-戊酸异丙酯（代号：HD5-6）,是一个拥有完全自主知识产权的FK506结合蛋白家族（FKBPs）配体,具有显著的促神经再生作用,有望在临床实现对神经退行性疾病和肌萎缩侧索硬化、脑卒中的有效治疗.本文采用多种核磁共振（NMR）技术,包括¹H NMR、¹³C NMR、DEPT、1D NOESY、¹H-¹H COSY、¹H-¹³C HSQC和¹H-¹³C HMBC等,并结合质谱（MS）、紫外光谱（UV）和红外光谱（IR）等方法对此化合物进行解析,对其¹H和¹³C NMR谱峰进行全归属,通过多种谱学技术确证了该化合物的化学结构.     

七-O-乙酰基-β-麦芽糖基羧酸酯的NMR研究

通过对6种七-O-乙酰基-β-麦芽糖基羧酸酯的¹H NMR和IR谱的分析, 确证其糖苷键为β-构型, 对其一般特征进行了对比和讨论, 用¹H-¹H COSY, gHMQC, gHMBC等技术对它们的¹H和¹³C NMR谱峰进行了全归属.     

盐酸马尼地平的核磁共振数据解析

盐酸马尼地平是第三代合成降压新药．本文利用一维、二维核磁共振（NMR）技术,包括¹H NMR、¹³C NMR DEPT-135、¹H-¹H NOESY、¹H-¹H COSY、¹H-¹³C HSQC和¹H-¹³C HMBC,对其¹H和¹³C NMR信号进行了全归属,进一步确证了其分子结构．同时,对其¹H NMR和¹³C NMR谱中一些异常信号进行了讨论．     

二氢沉香呋喃倍半萜的2D NMR研究

利用¹H-¹³C相关(¹H-¹³C COSY)谱对1β-乙酰氧基-2β(α-甲基丁酰氧基)-6α-羟基-8β,9α-二苯甲酰氧基-β-二氢沉香呋喃(A),和1β-乙酰氧基-2β(α-甲基丁酰氧基)-6α-羟基-8β(β-呋喃甲酰氧基)-9α-苯甲酰氧基-β-二氢沉香呋喃(B)的¹³C NMR谱化学位移进行了全指定,利用¹H-¹H远程相关(¹H-¹H COSYLR)谱确定了化合物A和B中6-Ha和7-He,8-He和9-He的弱偶合,以及7-He和9-He的弱W型远程偶合.     

洛莫司汀的1H、13C NMR全归属

应用~1H NMR、~(13)C NMR、DEPT135、~1H-~(13)C HMBC、~1H-~(13)C HSQC、~1H-~1H COSY和~1H-~1H NOESY等多种NMR技术,对文献报道的洛莫司汀(Lomustine)~1H和~(13)C NMR数据进行了修正与补充;特别是应用2D NMR对重叠程度较高的环己烷区进行了指认归属,并确定了其空间构型.     

保护的氨基葡萄糖苷结构测定中的核磁共振光谱研究

以D-氨基葡萄糖盐酸盐、三氯乙晴、三氯乙氧甲酰氯和三甲基硅三氟甲基磺酸酯(TMSOTF)为主要原料,合成了保护的氨基葡萄糖5,8,9,12,13和两种保护的2脱氧2氨基葡二糖10和11,它们均为新化合物。用1HNMR和13CNMR谱等进行了表征。所列核磁共振氢谱数据表明保护的氨基葡萄糖、保护的氨基葡二糖中的NH上质子化学位移(δ)显著地移向低场至507～526。9,10,11,12,13化合物中的J1,2值在72～88Hz,均为β糖苷;而J1,2值在300和496Hz,为α糖苷(5和6)。H2的化学位移一般处在较高场,δ在310～430。所列13C谱数据表明C1的化学位移处于最低场,C2处于较高场,相应的氢有类似情况。一般C1的δ>100(如化合物91019)为β苷;而δ<100(如化合物5δ=9520,化合物6δ=9721)为α糖苷。讨论了糖环上其他H和C的化学位移特征。用DEPT(DistortionlessEnhancementbyPolarizationTransfer)法配合13CNMR谱方便而清楚地鉴别了化合物6中碳原子的级数。     

3，5-二甲基金刚胺盐酸盐的NMR研究

NMR核磁共振谱显示3，5-二甲基金刚胺盐酸盐是一个刚性结构，但其分子结构包含2个非对映体的立体构型形式. 我们通过利用DEPT，¹H-¹H COSY，HSQC和HMBC等技术所测得的二维谱图数据对NMR数据进行了完整的归属分析，其中¹³C NMR谱图显示在δ=29~54 ppm之间的十组峰表示所有碳的共振，而且由于不同的分子构象导致在¹³C NMR谱中有3个不同的季碳峰和¹H NMR中的2个不同的甲基峰. 由于H-5的叔碳H原子与邻近CH₂ 的平面二面夹角均约为600，致使耦合常数极其小，波谱仪难以分辨它们从而使¹H NMR峰为单重峰.     

Chemical shift anisotropy edited complete unraveling of overlapped 1H NMR spectra of enantiomers: application to small chiral molecules

The differential values of NMR spectral parameters like chemical shift anisotropies, dipolar couplings and quadrupolar couplings of enantiomers in chiral liquid crystalline media are employed not only for their visualization but also for their quantification. Large differences in chemical shift anisotropies and the quadrupolar couplings between the enantiomers enable the use of 13C and extensive 2H NMR detection for such a purpose. In spite of high magnetic moment, high sensitivity and abundant presence of protons in all the chiral molecules, 1H detection is not routinely employed due to severe overlap of unresolved transitions arising from short and long distance couplings. Furthermore, the doubling of the spectra from two enantiomers and their indistinguishable overlap due to negligible difference in chemical shift anisotropies hampers their discrimination. The present study demonstrates the use of proton chemical shift anisotropy as an exclusive parameter for such a discrimination. The method employs the non-selective excitation of homonuclear Nth quantum coherence of N coupled protons. The simultaneous flipping of all the coupled spins results in a single transition in the multiple quantum dimension at the cumulative sum of their anisotropic chemical shifts for each enantiomer, with the measurable difference between them, resulting in their complete unraveling.     

阿替烷类型二萜衍生物的NMR研究

从钩腺大戟中分出的八个阿替烷(Atisane)类型的二萜和一个贝壳杉烷(Kaurane)类型的二萜进行¹H-H COSY,¹³C-1 COSY和¹H-¹H NOESY测定,使得它们的¹H NMR和¹³C NMR谱的化学位移值得以归属.通过比较这两类二萜的¹³C NMR谱数据,观察到对于阿替烷类型二萜衍生物中碳20位上的甲基碳的化学位移总在14ppm左右,而贝壳杉烷类二萜,则出现在17ppm左右.这有助于区分现有的这两类二萜的基本骨架.     

NMR Studies of Hindered Rotation. The Diels-Alder Adduct of Phencyclone with Maleic Anhydride: Restricted Motion of Bridgehead Phenyls

¹H NMR studies at 300 MHz have been performed for the Diels-Alder adduct of phencyclone and maleic anhydride in CDCl₃ at ambient temperatures. The 1D spectrum shows four equal (2H) intensity doublets in the aryl region (in addition to other absorptions) which is fully consistent with a slow exchange limit (SEL) spectrum of a system in which the unsubstituted bridgehead phenyls exhibit hindered rotation around the C(sp²)-C (sp³) bond on the NMR timescale. These protons are assigned to H-1,8 and H-4,5 of the phenanthrene moiety and to H-2′ and H-6′ of the phenvls based on the two-dimensional (2D) homonuclear chemical shift correlation spectrum (COSY) together with arguments regarding carbonyl and aromatic ring anisotropy. Full proton assignments are given.     

Binuclear spin state selective detection of 1H single quantum transitions using triple quantum coherence: a novel method for enantiomeric discrimination

In the present work a novel methodology is developed for the unambiguous discrimination of enantiomers aligned in chiral liquid crystalline media and the simultaneous determination of 1H-1H and 13C-1H couplings in a single experiment. An INEPT transfer and back transfer of magnetization to protons retain the 13C edited 1H magnetization which is utilized to generate spin selective homonuclear triple quantum coherence of dipolar coupled methyl protons. Spin selective correlation of triple quantum to single quantum coherence results in spin state selective detection by 13C spin and the remaining passive protons. The difference between the successive transitions in the triple quantum dimension pertains to sum of the passive couplings and results in enhanced resolution by a factor of three. This results in unambiguous chiral visualization. The masked 13C satellite transitions in the single quantum spectrum are extracted for chiral discrimination. The technique retains all the passive homo- and heteronuclear couplings in the triple quantum dimension by the application of non-selective refocusing pulse on 1H as well as on 13C spins. This, however, refocuses the chemical shift evolution in the triple quantum dimension, and also overcomes the problem of field inhomogeneity. The method enables the determination of spectral information which is otherwise not possible to derive from the broad and featureless proton spectra. The elegant experimental technique has been demonstrated on different chiral molecules.     

Selective dephasing of OH and NH proton magnetization based on (1)H chemical-shift anisotropy recoupling

A method for selectively suppressing the signals of OH and NH protons in (1)H combined rotation and multiple-pulse spectroscopy (CRAMPS) and in (1)H-(13)C heteronuclear correlation (HETCOR) solid-state NMR spectra is presented. It permits distinction of overlapping CH and OH/NH proton signals, based on the selective dephasing of the magnetization of OH and NH protons by their relatively large (1)H chemical-shift anisotropies. For NH protons, the (14)N-(1)H dipolar coupling also contributes significantly to this dephasing. The dephasing is achieved by a new combination of heteronuclear recoupling of these anisotropies with (1)H homonuclear dipolar decoupling. Since the 180 degrees pulses traditionally used for heteronuclear dipolar and chemical-shift anisotropy recoupling would result in undesirable homonuclear dephasing of proton magnetization, instead the necessary inversion of the chemical-shift Hamiltonian every half rotation period is achieved by inverting the phases of all the pulses in the HW8 multiple-pulse sequence. In the HETCOR experiments, carefully timed (13)C 180 degrees pulses remove the strong dipolar coupling to the nearby (13)C spin. The suppression of NH and OH peaks is demonstrated on crystalline model compounds. The technique in combination with HETCOR NMR is applied to identify the CONH and NH-CH groups in chitin and to distinguish NH and aromatic proton peaks in a peat humin.     

质子化学位移各向异性的测量

测量质子化学位移各向异性（CSA）有助于表征分子结构与其动力学,但由于¹H-¹H同核偶极耦合相互作用很强及质子各向异性化学位移较小,测量质子化学位移各向异性仍具有巨大挑战,特别是对含有多种质子的生物大分子,如蛋白质.本文简要综述了测量质子化学位移各向异性的方法,包括同核去耦慢速魔角旋转方法、超快魔角旋转方法、对称重耦（RN_n^v）方法、xCSA方法以及量子化学计算方法.我们重点介绍了在高速魔角旋转条件下蛋白质氨基质子化学位移各向异性的测量及它们与氢键长度、蛋白质二级结构之间的关系.     

C60-脱异丙基脱氢枞胺衍生物的NMR光谱分析

C_(60)与脱氢枞胺发生环加成反应可生成多种功能性富勒烯衍生物.该论文测定了目标化合物N,N-四氯邻苯二甲酰基-13-硝基-7,7-C_(60)-脱异丙基脱氢枞胺的~1H NMR和~(13)C NMR谱图,并利用~1H-~1H COSY、~1H-~1H ROESY、~1H-~(13)C HSQC和~1H-~(13)C HMBC等2D NMR技术,对其~1H和~(13)C NMR信号进行了归属,为表征类似化合物的结构提供了参考.