The present invention relates to obesity related diseases, such as cancer of non-alcoholic fatty liver disease (NAFLD). Tissue perfusion is currently investigated by using dynamic contrast-enhanced magnetic resonance imaging which is an invasive technique and does not provide enough accuracy. As a result, the inventors worked on post-processing images of subcutaneous adipose tissue or the epididymal adipose tissue taken with a magnetic resonance imaging technique and a multifrequency magnetic resonance elastography technique to obtain parameters such as loss modulus and storage modulus which are more accurate for a diagnosing purpose. This post-processing method may be applied for a method for predicting that a subject is at risk of suffering from said disease, identifying a therapeutic target or a biomarker and screening compounds useful as medicine.

Systems and methods are provided for medical diagnosis and analysis using mixed model inversions. For example, a medical analyzer using mixed model inversions according to an embodiment of the present disclosure can be used to diagnose traumatic brain injury (TBI), which allows for isotropic and anisotropic inversions to be performed, enabling more accurate information about brain stiffness to be obtained.

The present disclosure is directed to a motor for a magnetic resonance (MR) tomography room, to a patient table for the MR room, to a MR elastography device, and to a MR tomography device. A MR tomography device for a MR elastography imaging protocol is arranged within the MR tomography room, and includes a rotational drive for supplying rotational energy to power a MR elastography transducer usable during the MR elastography imaging protocol, and a support structure. The rotational drive comprises a terminal for connecting the MR elastography transducer to the rotational drive, and a bearing means configured such that the position of the terminal relative to the support structure is adaptable along a trajectory predetermined by the bearing means. The rotational drive is mounted to the support structure via the bearing means.

Disclosed are piston actuator devices and their uses for magnetic resonance elastography (MRE).

A method for reconstructing displacement and strain maps of human tissue of a subject in vivo or other objects includes applying a mechanical deformation for a target area, imaging tissues while deformation is applied on the target area, measuring the axial and lateral displacements and axial, lateral, and shear strains of tissue in the target area, differentiating between tissues of different stiffness and strain responses, and labeling tissues of different stiffness and strain responses. In some embodiments, displacement and strain imaging are performed using a high-resolution, high-speed, highly-accuracy hierarchy recursive displacement tracking from conventional ultrasound brightness mode images. Particularly, this invention relates to the reconstruction of displacement and strain images from conventional ultrasound B-mode images acquired using any ultrasound machine of different manufacturers without the need to use carrier signals.

An apparatus for use in a magnetic resonance (MR) system for capturing an MR Elastography measurement of a biological lifeform may include a platform; a gel pad on a surface of the platform; and a sensor array. In some embodiments, the sensor array includes at least one ultrasound transducer, and at least one radiofrequency (RF) transmitter and receiver coil. The sensor array is at least partially embedded within the gel pad, and the gel pad is configured to provide mechanical impedance matching between the at least one ultrasound transducer and the biological lifeform. In some embodiments, a system includes the apparatus and an MR system, the MR system including an ultrasonic wave generator, an interface circuit, and a computing device. In some such embodiments, the ultrasonic wave generator is configured to generate one or more shear waves in the biological lifeform.

Methods, systems, and devices for mechanically disturbing tissues of the central nervous system including a brain of a subject are provided. An elastogram of brain tissue may be generated using mesoscopic wavelength ultrasound composed of longitudinal waves in brain tissues to produce micromechanical disturbances of brain nuclei and circuits for characterization of their mechanical properties (e.g., stiffness, elasticity, rigidity, viscoelasticity). A magnetic resonance elastography (MRE) system includes an MRE engine in electronic communication with at least one transducer and with a magnetic resonance imaging (MRI) device. The MRE engine is configured to electronically control operation of the at least one transducer to emit ultrasound, to electronically receive, from the MRI device, at least one signal indicative of measurements of displacement of the brain tissue by the ultrasound, and to electronically generate an elastogram of the brain tissue based on the at least one signal.

A reverberant shear wave field in an object such as a patient's body or organ causes deformations in one or more selected directions measured with an imaging modality such as ultrasound or MR equipment or other imaging equipment, to estimate displacements in one or more selected directions over time increments and then viscoelastic properties such as stiffness or other parameters of the ROI.

Disclosed herein are example embodiments of devices, systems, and methods for mechanical fractionation of biological tissue using magnetic resonance imaging (MRI) feedback control. The examples may involve displaying an image representing first MRI data corresponding to biological tissue, and receiving input identifying one or more target regions of the biological tissue to be mechanically fractionated via exposure to first ultrasound waves. The examples may further involve applying the first ultrasound waves and, contemporaneous to or after applying the first ultrasound waves, acquiring second MRI data corresponding to the biological tissue. The examples may also involve determining, based on the second MRI data, one or more second parameters for applying second ultrasound waves to the biological tissue, and applying the second ultrasound waves to the biological tissue according to the one or more second parameters.

A method and system provides an acquisition scheme for generating MRE displacement data with whole-sample coverage, high spatial resolution, and adequate SNR in a short scan time. The method and system can acquire in-plane k-space shots over a volume of a sample divided into a plurality of slabs that each include a plurality of slices to obtain three dimensional multislab, multishot data, can apply refocusing pulses to the sample, can acquire navigators after the refocusing pulses, and can correct for phase errors based on an averaging of the navigators.