Abstract: A method for shaping an RF pulse for use with an MRI system includes shaping an RF pulse for use with an MRI system that uses an RF coil. The RF pulse is shaped to reduce changes in B1 amplitude and in an off-resonance effect with respect to Larmor frequency as a function of distance from the RF coil.

Abstract: A system for NMR/MRI, having X, Y, Z directions, includes an RF coil having a B0 static magnetic field in the Z direction and a transverse B1 RF magnetic field in the XY directions. Currents in the RF coil are distributed so that the transverse B1 field is substantially uniform in the XY plane.

Abstract: A method for shaping an RF pulse for use with an MRI system includes shaping an RF pulse for use with an MRI system that uses an RF coil. The RF pulse is shaped to reduce changes in B1 amplitude and in an off-resonance effect with respect to Larmor frequency as a function of distance from the RF coil.

Abstract: A system includes an NMR system (10) including a coil (18) and a magnet (12) capable of obtaining NMR information from a tissue (17) and an MRI processor (19) for creating a pixel map of the tissue (17) from the NMR information. The system also includes an OCT system (20) with an OCT processor (21) capable of creating an optical coherence tomography of the tissue (17). A tissue sample holder (16) is coupled to a manipulator to move the tissue sample holder (16) to the NMR system (10) for creating the pixel map of the tissue (17) and to move the tissue sample holder (16) to the OCT system (20) for creating the optical coherence tomography of the tissue (17).

Abstract: A tissue imaging system (10) includes a stationary array of magnets (12) arranged to generate an inhomogeneous main magnetic field (B0), a tissue holder (16) adjacent the array of magnets (12) and operative to move tissue (14) placed therein about and/or along a coordinate axis, one or more RF receive coils (20) adjacent the tissue holder (16) and the magnets (12), and an MRI processor in communication with the magnets (12), the RF receive coils (20) and the tissue holder (16). An image of the tissue (14) is created by using spatial encoding of magnetic resonance signals generated by the magnets (12) and RF receive coils (20) for different spatial orientations of the tissue (14) moved by the tissue holder (16) with respect to the magnets. Spatial inhomogeneities in the main magnetic field spatially modulate a phase of each of the magnetic resonance signals.

Abstract: A system includes an NMR system (10) including a coil (18) and a magnet (12) capable of obtaining NMR information from a tissue (17) and an MRI processor (19) for creating a pixel map of the tissue (17) from the NMR information. The system also includes an OCT system (20) with an OCT processor (21) capable of creating an optical coherence tomography of the tissue (17). A tissue sample holder (16) is coupled to a manipulator to move the tissue sample holder (16) to the NMR system (10) for creating the pixel map of the tissue (17) and to move the tissue sample holder (16) to the OCT system (20) for creating the optical coherence tomography of the tissue (17).

Abstract: A marking system (10) includes a tissue holder (14) which has a cover (16). An inner surface of the cover (16) is coated with a donor layer (18). A pulsed laser (20) emits a laser pulse sufficient to transfer material from the donor layer (18) onto tissue (12) held in the tissue holder (14) by means of a laser-induced forward transfer (LIFT) technique, and the material transferred to the tissue (12) creates a mark on the tissue (12).

Abstract: A tissue imaging system (10) includes a stationary array of magnets (12) arranged to generate an inhomogeneous main magnetic field (BO), a tissue holder (16) adjacent the array of magnets (12) and operative to move tissue (14) placed therein about and/or along a coordinate axis, one or more RF receive coils (20) adjacent the tissue holder (16) and the magnets (12), and an MRI processor in communication with the magnets (12), the RF receive coils (20) and the tissue holder (16). An image of the tissue (14) is created by using spatial encoding of magnetic resonance signals generated by the magnets (12) and RF receive coils (20) for different spatial orientations of the tissue (14) moved by the tissue holder (16) with respect to the magnets. Spatial inhomogeneities in the main magnetic field spatially modulate a phase of each of the magnetic resonance signals.

Abstract: A system for margin assessment of an ex-vivo tissue (25) is provided, including a magnetic resonance imaging (MRI) scanner (14) controlled by a control unit (12), and a tissue container (24) for holding a sample of an ex-vivo tissue (25). The MRI scanner (14) includes a coil-magnet assembly (31) including magnets (34), wherein the tissue (25), placed in the container (24), is placed under a constant static magnetic field (Bo), which is induced by the magnets (34), and the container (24) is positioned so the sensitive region is within a measured field of view (FOV) excited by one or more transmit/receive coils (38) operative to generate a time-varying RF B1 electro-magnetic field pointing towards the tissue (25), and wherein the container (24) is fixed on a moving table (40).

Abstract: A system (10) for margin assessment of an ex-vivo tissue (18), including an imaging scanner (12) controlled by an imaging control unit (14), and an ex-vivo sample holder (16) for holding a sample of an excised tissue (18), the sample holder (16) being sized such that excised lump edges (24) of the excised tissue (18) are forced against a surface of the sample holder (16) such that the edges (24) change shape to have a predetermined geometry, and wherein the imaging scanner (12) is positioned relative to the sample holder (16) such that the imaging scanner (12) acquires images not of all the tissue (18) but rather of the edges (24) that have the predetermined geometry and which are in a sensitive region (40) extending into a peripheral margin of the tissue (18).