Method and apparatus for high slew rate single point magnetic resonance imaging of magnetizable nanoparticles

The invention claimed is: 1. An apparatus for magnetic resonance imaging, the apparatus comprising: at least one polarizing magnet controlled and positioned to polarize spins in a first region of interest; at least one gradient coil controlled and positioned to generate phase-encoding gradient pulses within a second region of interest; and at least one radiofrequency coil controlled and positioned to acquire radiofrequency signals from the second region of interest, wherein the at least one gradient coil and at least one radiofrequency coil are controlled such that application of phase-encoding gradient pulses stops before acquisition of radiofrequency signals, wherein at least one of the phase-encoding gradient pulses has a magnitude higher than 100 mT/m, and a rise-time or fall-time of less than 100 microseconds, and wherein the first region of interest and second region of interest is one of the same region or different regions. 2. The apparatus of claim 1 , in which operation of the at least one polarizing magnet and the at least one gradient coil are controlled such that no nerve stimulation occurs within a subject's body within the first and/or second regions of interest. 3. The apparatus of claim 1 , where the region of interest contains magnetizable material. 4. The apparatus of claim 1 , where multiple separate coil functions is carried out by one coil. 5. A method of collecting magnetic resonance images, the method comprising: controlling at least one polarizing magnet to polarize spins in a first region of interest; controlling at least one gradient coil to generate phase-encoding gradient pulses within a second region of interest; and controlling at least one radiofrequency coil controlled and positioned to acquire radiofrequency signals from the second region of interest, wherein the at least one gradient coil and at least one radiofrequency coil are controlled such that application of phase-encoding gradient pulses stops before acquisition of radiofrequency signals, wherein at least one of the phase-encoding gradient pulses has a magnitude higher than 100 mT/m, and a rise-time or fall-time of less than 100 microseconds, wherein the first region of interest and second region of interest is one of the same region or different regions, and wherein the at least one of least one of the phase-encoding gradient pulses has a duration of 10-200 microseconds. 6. The method of claim 5 , further comprising performing image processing on the acquired radiofrequency signals to create a set of images, wherein each image of the set of images corresponds to a radio frequency signal acquired at a different time after the cessation of at least one gradient pulse. 7. The method of claim 5 , further comprising performing image processing on the acquired radiofrequency signals to create a set of images, wherein at least one image of the set of images represents unaffected anatomy within a subject's body within the second region of interest and at least one image of the set of images represents distribution of magnetizable material within a subject's body within the second region of interest. 8. The method of claim 5 , further comprising performing image processing on the acquired radiofrequency signals to create a set of images, wherein at least one image of the set of images is a composite image that includes representation of an unaffected anatomy within a subject's body within the second region of interest as well as representation of distribution of magnetizable material within a subject's body within the second region of interest. 9. The apparatus of claim 1 , wherein the acquired radiofrequency signals are phase-encoded only. 10. The apparatus of claim 1 , wherein the at least one of least one of the phase-encoding gradient pulses has a duration of 10-200 microseconds.