Abstract: A variable density Cartesian sampling method that allows retrospective adjustment of temporal resolution, providing added flexibility for real-time applications where optimal temporal resolution may not be known in advance. The methods provide for a computationally efficient sampling methods where a first step includes producing a uniformly random sampling pattern using a golden ratio on a grid, and the second step is applying a nonlinear stretching operation to create a variable density sampling pattern. Diagnostic quality images may be recovered at different temporal resolutions.

Abstract: A method includes receiving from an administrator device a set of actions for a user to carry out. The method also includes receiving from the administrator device subtasks of the actions. Further, the method includes storing the actions and subtasks into a database and receiving from the database, assessment factors, mood factors, and actions and tasks completed related to a user. Further still, the method includes sending to a user device, associated with the user, a subtask to be completed.

Abstract: A variable density Cartesian sampling method that allows retrospective adjustment of temporal resolution, providing added flexibility for real-time applications where optimal temporal resolution may not be known in advance. The methods provide for a computationally efficient sampling methods where a first step includes producing a uniformly random sampling pattern using a golden ratio on a grid, and the second step is applying a nonlinear stretching operation to create a variable density sampling pattern. Diagnostic quality images may be recovered at different temporal resolutions.

Abstract: Methods and systems for accelerated Phase-contrast magnetic resonance imaging (PC-MRI). The technique is based on Bayesian inference and provides for fast computation via an approximate message passing algorithm. The Bayesian formulation allows modeling and exploitation of the statistical relationships across space, time, and encodings in order to achieve reproducible estimation of flow from highly undersampled data.

Abstract: A low-cost magnetic resonance imaging (MRI) apparatus that may be used for, e.g., Cardiac MRI (CMR). CMR is a clinical imaging tool that can investigate a wide range of cardiac conditions by exploring changes in the anatomy, physiology, or dynamics of the heart. The applications of CMR include, but are not limited to, the evaluation of congenital heart disease, coronary heart disease, ischemic heart disease, cardiac masses, the pericardium, cardiomyopathy, hibernating myocardium, and valvular and ventricular function. Generally, the MRI apparatus is a low-field (˜0.5T) system equipped with a high-end data processing unit (DPU) to enable the implementation of structure aware (SA) recovery in clinically relevant times.

Abstract: A low-cost magnetic resonance imaging (MRI) apparatus that may be used for, e.g., Cardiac MRI (CMR). CMR is a clinical imaging tool that can investigate a wide range of cardiac conditions by exploring changes in the anatomy, physiology, or dynamics of the heart. The applications of CMR include, but are not limited to, the evaluation of congenital heart disease, coronary heart disease, ischemic heart disease, cardiac masses, the pericardium, cardiomyopathy, hibernating myocardium, and valvular and ventricular function. Generally, the MRI apparatus is a low-field (˜0.5T) system equipped with a high-end data processing unit (DPU) to enable the implementation of structure aware (SA) recovery in clinically relevant times.

Abstract: A low-cost magnetic resonance imaging (MRI) apparatus that may be used for, e.g., Cardiac MRI (CMR). CMR is a clinical imaging tool that can investigate a wide range of cardiac conditions by exploring changes in the anatomy, physiology, or dynamics of the heart. The applications of CMR include, but are not limited to, the evaluation of congenital heart disease, coronary heart disease, ischemic heart disease, cardiac masses, the pericardium, cardiomyopathy, hibernating myocardium, and valvular and ventricular function. Generally, the MRI apparatus is a low-field (˜0.5 T) system equipped with a high-end data processing unit (DPU) to enable the implementation of structure aware (SA) recovery in clinically relevant times.

Abstract: Methods and systems for accelerated Phase-contrast magnetic resonance imaging (PC-MRI). The technique is based on Bayesian inference and provides for fast computation via an approximate message passing algorithm. The Bayesian formulation allows modeling and exploitation of the statistical relationships across space, time, and encodings in order to achieve reproducible estimation of flow from highly undersampled data.

Abstract: A low-cost magnetic resonance imaging (MRI) apparatus that may be used for, e.g., Cardiac MRI (CMR). CMR is a clinical imaging tool that can investigate a wide range of cardiac conditions by exploring changes in the anatomy, physiology, or dynamics of the heart. The applications of CMR include, but are not limited to, the evaluation of congenital heart disease, coronary heart disease, ischemic heart disease, cardiac masses, the pericardium, cardiomyopathy, hibernating myocardium, and valvular and ventricular function. Generally, the MRI apparatus is a low-field (˜0.5 T) system equipped with a high-end data processing unit (DPU) to enable the implementation of structure aware (SA) recovery in clinically relevant times.

Abstract: The present invention has demonstrated the presence of the zebrafish KIT protein resulting from the expression of the kit gene in the zebrafish GI tract. As expression of the KIT protein is correlated with ICC in other species, the expression of the KIT protein in zebrafish indicates the presence of ICC in the zebrafish GI tract. ICC are required for spontaneous, coordinated contractions of GI smooth muscle. The present invention provides a zebrafish-based model system useful for elucidating the cellular and molecular mechanisms of gastrointestinal (GI) function and for identifying molecular targets for treating GI motility disorders in human.

Abstract: The present invention has demonstrated the presence of the zebrafish KIT protein resulting from the expression of the kit gene in the zebrafish GI tract. As expression of the KIT protein is correlated with ICC in other species, the expression of the KIT protein in zebrafish indicates the presence of ICC in the zebrafish GI tract. ICC are required for spontaneous, coordinated contractions of GI smooth muscle. The present invention provides a zebrafish-based model system useful for elucidating the cellular and molecular mechanisms of gastrointestinal (GI) function and for identifying molecular targets for treating GI motility disorders in human.

Abstract: The present invention describes the novel human intracellular chloride ion channel-related protein HCLI and its encoding polynucleotide. Also described are expression vectors, host cells, antisense molecules, and antibodies associated with the HCLI polynucleotide and/or polypeptide of this invention. In addition, methods for treating, diagnosing, preventing, and screening for disorders or diseases associated with abnormal biological activity of HCLI are described, as are methods for screening for modulators, e.g., agonists or antagonists, of HCLI activity and/or function.