Скачать книгу

axis (Figure 1.2), that is, B0 = B0k, where k in this expression is the usual unit vector along the z direction in a 3-dimensional (3D) Cartesian coordinate system. The direction of this z axis in Cartesian coordinates, however, can be either in the vertical direction (for vertical-bore superconducting magnets, which are common in research labs, or “open” MRI scanners, which reduce claustrophobia for some patients) or in the horizontal direction (for the electromagnets in research labs, the “vertical donut” magnet MRI, or the horizontal-bore superconducting magnets in common clinical MRI scanners).

      Figure 1.2 The B0 direction in NMR and MRI. (a) Vertical-bore superconducting magnet, which is common for NMR spectrometers in science and industry laboratories. (b) “Horizontal double-donut” magnet for “open” MRI. (c) Electromagnet or magnet in “vertical double-donut” MRI. (d) Horizontal-bore superconducting magnet, which is common for whole-body imagers for humans or animals.

      Figure 1.3 The positive directions of rotations in a 3D Cartesian coordinate system, (a) when one looks into the +z axis, and (b) when one looks into the +x axis.

      1.3 MAJOR MILESTONES IN THE HISTORY OF NMR AND MRI

      Figure 1.4 The first NMR spectrum of ethanol (CH3CH2OH), which demonstrated the huge potential of NMR spectroscopy by identifying three sets of non-equivalent 1H nuclei in the same molecule. Three separate peaks corresponded to the resonant frequencies of the 1H nuclei in the OH, CH2, and CH3 groups, respectively. Furthermore, the relative areas under the three peaks corresponded to the number of protons in each different chemical environment. Source: Reproduced with permission from Arnold et al. [9].

      Figure 1.5 The first proton NMR image of two tubes of H2O, which was produced by P.C. Lauterbur by combining four projections taken from different angles from his setup on a Varian A-60 spectrometer, which is currently on display at the State University of New York at Stony Brook. Source: Reproduced with permission from Lauterbur [15].

      The latest “history” of this fascinating field is still being written as of today in the twenty-first century. NMR and MRI are very active and still evolving, with diverse applications in biology and medicine and various industries. There are many new and exciting developments in recent years, such as the optical pumping in NMR and MRI that improves SNR by more than 1000 times, compressed sensing that can shorten the experimental time tremendously, and exotic pulse sequences that fascinate our imagination. So far, a number of Nobel prizes have been awarded for discoveries related to NMR and MRI, including Rabi (1944) in physics, Bloch and Purcell (1952) in physics, Ernst (1991) in chemistry, Wüthrich

Скачать книгу