The dependence on magnetic field strength of correlated internal gradient relaxation time distributions in heterogeneous materials.

Magnetic susceptibility differences in porous media produce local gradients within the pore space. At high magnetic fields, these inhomogeneities have the potential to greatly affect nuclear magnetic resonance measurements. We undertake a study using a new NMR technique to measure the internal gradients present in highly heterogeneous samples over a wide range of magnetic field strengths. Our results show that even at ultra-high fields there can exist signal at internal gradient strengths sufficiently small that techniques for suppressing unwanted side effects have the possibility to be used. Our findings encourage the use of these high and ultra-high field strengths for a broader range of samples. Our results also give experimental evidence to support the theory of internal gradient scaling as a function of field strength within pores.

A mobile one-sided NMR sensor with a homogeneous magnetic field: the NMR-MOLE.

A new portable NMR sensor with a novel one-sided access magnet design, termed NMR-MOLE (MObile Lateral Explorer), has been characterised in terms of sensitivity and depth penetration. The magnet has been designed to be portable and create a volume with a relatively homogeneous magnetic field, 15,000 ppm over a region from 4 to 16 mm away from the probe, with maximum sensitivity at a depth of 10 mm. The proton NMR frequency is 3.3 MHz. We have demonstrated that with this approach a highly sensitive, portable, unilateral NMR sensor can be built. Such a design is especially suited for the characterisation of liquids in situations where unilateral or portable access is required.

A method to distinguish between chemical shift and susceptibility effects in NMR microscopy and its application to insect larvae.

We propose a simple method of distinguishing Zeeman broadening arising from susceptibility inhomogeneity and chemical shift variation, applicable to NMR microscopy. The method is based on the use of a specially built probe-head in which orthogonal sample alignment is possible using the same radiofrequency (RF) coil. This allows the investigation of alignment effects in image distortion and relies on the fact that the isotropic chemical shift is invariant under reorientation, whereas the susceptibility-related local field will depend strongly on relative orientation of bounding surfaces with the external polarizing field. We apply this approach to the study of a simple phantom, and an insect larva (Spodoptera litura Fabricius), demonstrating in the latter case that susceptibility variations are sufficiently small to allow chemical shift imaging on a scale greater than 1 ppm.

Practical aspects of shielded gradient-coil design for localised in vivo NMR spectroscopy and small-scale imaging.

For a number of NMR applications the availability of screened gradients is crucial to minimize the effect of eddy currents on the NMR signal. In this paper we review two types of shielded gradient design: the target field and minimum inductance methods. The two designs are compared and construction details are presented. A novel coil design constructed with a double-sided primary and a single layered screen is outlined. Experimental results for both target field and minimum inductance coils are presented and compared.

Ciguatoxin-2 is a diastereomer of ciguatoxin-3.

Ciguatoxin-2, a major ciguatoxin present in the flesh and viscera of ciguateric fishes, has been shown by 1H nuclear magnetic resonance studies (2-dimensional homonuclear Hartman Hahn, nuclear Overhauser effect and decoupling difference experiments) to be a diastereomer of ciguatoxin-3, differing only in stereochemistry at carbon 52 (a quaternary carbon). This difference accounts for the significant changes in the chemical shift of resonances for protons in this region of ciguatoxin-2. Differences between ciguatoxin-1, -2 and -3 involve modifications at only one end of the ciguatoxins (ring M) and modest differences in potency, indicating that this ring contributes to, but is not critical for, high affinity binding of the ciguatoxins to voltage-dependent sodium channels. It is proposed that ciguatoxin-2 originates from a different precursor to the precursor (presumably gambiertoxin-4b) for ciguatoxin-1 and -3, and that both precursors are produced by a common biosynthetic pathway in Gambierdiscus toxicus.

In vitro tracheal mechanics by nuclear magnetic resonance imaging.

Images of rabbit tracheal cross sections were obtained at a series of transmural pressures ranging from 22 to -95 cmH2O by use of a nuclear magnetic resonance imaging microscope. The excised, washed tracheas were immersed in a solution of phosphate-buffered saline made up in deuterium oxide (D2O, pH 7.3). The images are maps of proton density in the image slice (2.5 mm thick). All but one series of images showed a collapse process in which the trachealis muscle invaginated asymmetrically, i.e., the muscle appeared to favor one side of the cartilage ring system more than the other. The connecting tissue between the cartilage rings appeared to be more compliant than the rings themselves, thus suggesting that the tracheal lumen became corrugated at negative pressures. In the plane of a cartilage ring, the lumen appeared to remain patent at pressures as low as -95 cmH2O. However, between rings, where the tracheal wall was more compliant, the lumen appeared to be totally occluded at -53 cmH2O. Lumen areas in both the plane of the cartilage rings and in a plane between rings were measured from each series of printed images for six tracheas. These measurements, when normalized, averaged, and plotted against transmural pressure gave asymptotic logarithmic compliances (n1 in the model of Lambert et al., J. Appl. Physiol. 52: 44-56, 1982) of 1.2 +/- 0.4 and 20 +/- 7 for the interring and ring regions, respectively. These values are greater than the critical value of 0.5 (J. Appl. Physiol. 62: 2426-2435, 1987) and are thus consistent with wave speed flow limitation being possible anywhere in the trachea during forced expiration.

Measurement of the self-diffusion coefficient of water as a function of position in wheat grain using nuclear magnetic resonance imaging.

A pulsed field gradient spin echo sequence has been incorporated in a nuclear magnetic resonance (NMR) imaging experiment to provide an image contrast dependent on local molecular self-diffusion. The consequent image attenuation is shown to exhibit a dependence on applied magnetic field gradient consistent with the Stejskal-Tanner relationship. The method used represents a novel extension of microscopic imaging and demonstrates the possibility of measuring localized motion.Water self-diffusion rates normal to the transverse 1.3-mm section of a wheat grain have been measured in structural features at 150-mum resolution. The results are consistent with averaged measurements in the bulk grain obtained by other methods while local differences in water mobility correlate with differences in physiological function.