Implementation of magneto motive technique in an ultrasound diagnostic equipment.

The magneto motive ultrasound (MMUs) is a novel technique, which combines magnetism and acoustics, in order to observe viscoelastic behavior of medium labeled with inserted magnetic particles. The magnetic force with modulation frequency () creates a mechanical disturbance in the object of study with twice the modulation frequency (2). Was applied a pulse-echo ultrasonic beamforming with pulse repetition frequency (PRF) at least five times greater than frequency of internal structure movement. The aim of this study was to develop an acquisition, processing and analysis protocol for MMUs through implementation of an automated platform for acquisition, which provides structured datasets for further processing and analysis of different applications (tissue mimicking phantoms or in vivo) of MMUs. First step was to develop the acquisition platform using an ultrasound research interface (URI). At this stage was developed a software with graphical user interface (GUI) written using C++ and Qt. This software automates magnetic excitation and acoustic acquisition, which has high frame rate. In addition, were defined default presets to provide oscillatory movement or shear waves. Then was created datasets acquired were structured and a header and transferred to an external personal computer through TCP/IP network. Second, the processing software with graphical user interface for processing and analyzing was developed. The frames acquired in radiofrequency (RF) mode were processed into displacement or velocity maps of medium internal structures. In this stage, we adapted a cross correlation algorithm to optimize for MMUs datasets. The evaluation of these maps was based on tradeoff between spatial resolution and computation time. Protocols for analysis of motion frequency and segmentation/characterization of shear waves, extracting velocity and attenuation for experiments performed with phantoms or in vivo were developed . In this work, it was implemented an automated MMUs system integrated with a software framework running on an ultrasound research interface (URI), which is used for acquisition of RF maps, further transferred for a PC with robust hardware to process into displacement maps. These maps were analyzed to obtain viscoelastic parameters of the medium. Moreover, this implementation of MMUs enables clinical fast and efficient trials for gastric evaluation of meals with magnetic particles and shear wave production for viscoelastic characterization. (AU)