Methods, systems and devices for local magnetic resonance imaging

What is claimed is: 1. A method of magnetic resonance imaging (MRI) of a specimen, comprising the steps of: providing a MRI device having a first coordinate frame of reference within a second coordinate frame of reference and a localized region of MRI sensitivity in at least one spatial dimension, wherein the MRI device is selected from the group consisting of an antenna, an endoscope, a probe, a needle, a catheter, a guidewire, and a therapy delivery device; introducing the MRI device into the specimen; locking in at least one spatial dimension to the first coordinate frame-of-reference of the MRI device; acquiring MRI image data while the second coordinate frame of reference for imaging is intrinsically locked to the localized sensitive region of the introduced MRI sensitive device; wherein the second coordinate frame of reference is intrinsically locked to the localized sensitive region of the MRI device by at least one of: (a) providing a spoiling magnetic field effect along a length of the MRI device except from an area where the MRI signal is desired, and (b) providing the MRI device with sensitivity confined to a predetermined shaped volume of the specimen about an area of the antenna coupled to the MRI device by selectively transmitting RF signal pulses from the MRI device and selectively receiving MRI signals from the shaped volume; wherein the acquiring image data includes selectively transmitting RF signal pulses from the MRI device and selectively receiving MRI signals from the localized sensitive region and providing an MR pulse sequence to perform 2D spatial encoding relative to the MRI device; and processing the MRI signals to provide MRI signal data from the coordinate frame of reference of the MRI device. 2. The method of claim 1 , wherein the antenna is a loopless antenna that is introduced into the specimen. 3. The method of claim 2 , further comprising configuring the loopless antenna such that the loopless antenna is provided with the localized sensitive region of the MRI device, wherein said configuring includes at least one of: (a) coating along a length of the loopless antenna except the area where the MRI signal is desired with a material having desired magnetic properties; (b) embedding at least one permanent magnet along a length of the loopless antenna except the area where the MRI signal is desired; (c) coiling wire along a length of the loopless antenna except the area where the MRI signal is desired, the wire being arranged to create a spoiling gradient magnetic field; (d) coiling wire along a length of the loopless antenna, the wire being arranged to create a linear magnetic field gradient over at least the area where the MRI signal is desired; and (e) providing a sleeve portion along a length of the loopless antenna that incorporates electrically conducting material to spoil the RF magnetic field except in the area where the MRI signal is desired, wherein said electrically conducting material is separated from the loopless antenna by a dielectric material. 4. The method of claim 3 , wherein the material having desired magnetic properties is one of a strongly paramagnetic material or a ferromagnetic material. 5. The method of claim 3 , further comprising the step of providing an insulating dielectric layer covering said loopless antenna. 6. The method of claim 1 , wherein the antenna includes one or more loops that is introduced into the specimen. 7. The method of claim 6 , wherein the MRI device has a long axis and wherein the one or more loops are arranged so an axis of the one or more loops is one of orthogonal to the device long axis or parallel to the device long axis. 8. The method of claim 1 , wherein said providing the MRI device includes providing an MRI scanner including an external excite coil and an MRI device, the MRI scanner and MRI device being arranged and configured so the frame of reference is inherently locked to the MRI device and so the selectively received MRI signal from the localized sensitive region is confined to the predetermined shaped volume of the specimen about the MRI device; and wherein said acquiring MRI image data further includes dephasing magnetization of the MRI device over a region of a MRI-sensitive length of the MRI device except for another region having a length for which signal selection is required, whereby the length of the another region establishes a third dimension of the shaped volume. 9. The method of claim 8 , wherein said providing an MR pulse sequence and performing 2D spatial encoding in the radial and azimuthal directions relative to the probe includes phase encoding and applying read-out gradients by the MRI scanner in the frame of reference of the MRI scanner. 10. The method of claim 9 , wherein said processing of MRI signals further comprises the step of: reconstructing an image from said predetermined shaped volume which is localized to the frame of reference of said MRI probe. 11. The method of claim 1 , wherein said MRI of a specimen is in three dimensions, and wherein said providing the MRI device includes providing an MRI scanner including an external excite coil and an MRI device, the MRI scanner and device being arranged and configured so the frame of reference is inherently locked to the MRI device and so the selectively received MRI signal from the localized sensitive region is confined to an extended volume of the specimen coaxial with the MRI device; and wherein said using the MRI device and processing the MR signals further includes spatial-encoding in the form of a read-out gradient being provided in the third dimension by changing a local magnetic field. 12. The method of claim 8 , wherein said predetermined shaped volume is an extended volume of the specimen coaxial with the MRI probe; said providing an MR pulse sequence is carried out so as to thereby 2D spatial encode the extended volume relative to the probe; and wherein the MRI probe being provided includes opposed solenoid coil windings on the body of the probe. 13. The method of claim 1 , wherein said providing the MRI device includes providing an MRI scanner including an external excite coil and an MRI device, the MRI device being arranged and configured so as to provide a non-uniform sensitivity profile and the MRI scanner and device being arranged and configured so the frame of reference is quasi-locked to the MRI device and so the selectively received MRI signal from the localized sensitive region is confined to a disk-shaped volume of the specimen; wherein said selectively transmitting RF signal pulses includes providing slice-shaped selection in a third dimension with use of at least one adiabatic excitation from the MRI device, and said selectively receiving MRI signals from a portion of the volume includes providing a non-uniform sensitivity profile of the device; 2D spatially encoding by phase encoding the volume to be imaged; and applying read-out gradients by the MRI scanner in a frame of reference of the MRI scanner. 14. The method of claim 13 , wherein said providing an MRI device having the non-uniform sensitivity profile comprises at least one of: (1) coating the device over a region of its MRI-sensitive length except for a portion from which signal selection is desired, and wherein said coating dephases the magnetization from adjacent regions; (2) providing at least one small permanent magnet on the MRI device, located in regions on the probe where the signal is to be eliminated thereby dephasing the magnetization by changing the local magnetic field; (3) providing a spoiling gradient winding on the MRI device over a region of