Abstract: A system and method for transporting a hyperpolarized substance is disclosed. A transport vessel for transporting such a hyperpolarized substance includes a vessel housing, a chamber formed within the vessel housing that is configured to receive a container holding a hyperpolarized substance, and an electromagnet configured to generate a magnetic containment field about the chamber when a current is supplied thereto, the magnetic containment field comprising a homogeneous magnetic field. The transport vessel also includes a non-magnetic power source to supply the current to the electromagnet and a control circuit configured to selectively interrupt the supply of current to the electromagnet so as to control generation of the magnetic containment field, with the transport vessel being magnetically inert when the supply of current to the electromagnet is interrupted by the control circuit.

Abstract: A system and method for transporting a hyperpolarized substance is disclosed. A transport vessel for transporting such a hyperpolarized substance includes a vessel housing, a chamber formed within the vessel housing that is configured to receive a container holding a hyperpolarized substance, and an electromagnet configured to generate a magnetic containment field about the chamber when a current is supplied thereto, the magnetic containment field comprising a homogeneous magnetic field. The transport vessel also includes a non-magnetic power source to supply the current to the electromagnet and a control circuit configured to selectively interrupt the supply of current to the electromagnet so as to control generation of the magnetic containment field, with the transport vessel being magnetically inert when the supply of current to the electromagnet is interrupted by the control circuit.

Abstract: An echo-based single point imaging (ESPI) system (10) providing high-resolution oxygen images of a sample is disclosed. The ESPI system (10) employs spin echo detection of the resonance from a spin probe and concurrent Single Point Imaging (SPI) for spatial encoding of the oxygen concentration within the sample. Images are derived by comparing spin echo intensities of two images reconstructed at two time points selected at identical time intervals on either side of a refocusing pulse, eliminating artifacts associated with sample magnetic susceptibility and field inhomogeneity effects.

Abstract: An electron paramagnetic resonance imaging system that includes means for continuously irradiating a sample with RF irradiation; means for imposing on the sample a sinusoidally varying magnetic field along with rotating gradients for spatial encoding; means for directly detecting signal data from the sample, without using field modulation, while irradiating the sample with RF radiation continuously, the means for directly detecting having means for sweeping the sinusoidally varying magnetic field; and means for processing the signal data, using means including a digital signal processor.

Abstract: An electron paramagnetic resonance imaging system that includes means for continuously irradiating a sample with RF irradiation; means for imposing on the sample a sinusoidally varying magnetic field along with rotating gradients for spatial encoding; means for directly detecting signal data from the sample, without using field modulation, while irradiating the sample with RF radiation continuously, the means for directly detecting having means for sweeping the sinusoidally varying magnetic field; and means for transmitting, receiving and processing the signal data, using means including a digital signal processor.

Abstract: An echo-based single point imaging (ESPI) system (10) providing high-resolution oxygen images of a sample is disclosed. The ESPI system (10) employs spin echo detection of the resonance from a spin probe and concurrent Single Point Imaging (SPI) for spatial encoding of the oxygen concentration within the sample. Images are derived by comparing spin echo intensities of two images reconstructed at two time points selected at identical time intervals on either side of a refocusing pulse, eliminating artifacts associated with sample magnetic susceptibility and field inhomogeneity effects.

Abstract: An electron paramagnetic resonance imaging system that includes means for continuously irradiating a sample with RF irradiation; means for imposing on the sample a sinusoidally varying magnetic field along with rotating gradients for spatial encoding; means for directly detecting signal data from the sample, without using field modulation, while irradiating the sample with RF radiation continuously, the means for directly detecting having means for sweeping the sinusoidally varying magnetic field; and means for transmitting, receiving and processing the signal data, using means including a digital signal processor.

Abstract: An electron paramagnetic resonance imaging system that includes means for continuously irradiating a sample with RF irradiation; means for imposing on the sample a sinusoidally varying magnetic field along with rotating gradients for spatial encoding; means for directly detecting signal data from the sample, without using field modulation, while irradiating the sample with RF radiation continuously, the means for directly detecting having means for sweeping the sinusoidally varying magnetic field; and means for processing the signal data, using means including a digital signal processor.

Abstract: A radiofrequency (RF) coil design, suitable for detecting time domain electron paramagnetic resonance (EPR) responses from spin probes after pulsed excitation using radiofrequency irradiation (60-400 MHz), is configured in an array of numerous surface coils of appropriate diameters connected in a parallel or axial configuration with appropriate spacing between individual surface coils to form a volume type resonator.