Chemical Shift Correlations from Hyperpolarized NMR Using a Single SHOT
详细信息 查看全文
- 作者:Guannan Zhang ; Franz Schilling ; Steffen J. Glaser ; Christian Hilty
- 刊名:Analytical Chemistry
- 出版年:2013
- 出版时间:March 5, 2013
- 年:2013
- 卷:85
- 期:5
- 页码:2875-2881
- 全文大小:408K
- 年卷期:v.85,no.5(March 5, 2013)
- ISSN:1520-6882
文摘
A significant challenge in realizing the promise of the dissolution dynamic nuclear polarization technique for signal enhancement in high-resolution NMR lies in the nonrenewability of the hyperpolarized spin state. This property prevents the application of traditional two-dimensional correlation spectroscopy, which relies on regeneration of spin polarization before each successive increment of the indirect dimension. Since correlation spectroscopy is one of the most important approaches for the identification and structural characterization of molecules by NMR, it is important to find easily applicable methods that circumvent this problem. Here, we introduce the application of scaling of heteronuclear couplings by optimal tracking (SHOT) to achieve this goal. SHOT decoupling pulses have been numerically optimized on the basis of optimal control algorithms to obtain chemical shift correlations in C鈥揌 groups, either by acquiring a single one-dimensional 13C spectrum with 1H off-resonance decoupling or vice versa. Vanillin, which contains a number of functional groups, was used as a test molecule, allowing the demonstration of SHOT decoupling tailored toward simplified and accurate data analysis. This strategy was demonstrated for two cases: First, a linear response to chemical shift offset in the correlated dimension was optimized. Second, a pulse with alternating linear responses in the correlated dimension was chosen as a goal to increase the sensitivity of the decoupling response to the chemical shift offset. In these measurements, error ranges of 卤0.03 ppm for the indirectly determined 1H chemical shifts and of 卤0.4 ppm for the indirectly determined 13C chemical shifts were found. In all cases, we show that chemical shift correlations can be obtained from information contained in a single scan, which maximizes the ratio of signal to stochastic noise. Furthermore, a comprehensive discussion of the robustness of the method toward nonideal conditions is included based on experimental and simulated data. Unique features of this technique include the abilities to control the accuracy of chemical shift determination in spectral regions of interest and to acquire such chemical shift correlations rapidly鈥攖he latter being of interest for potential application in real-time spectroscopy.