A New Preclinical Ultrasound Platform for Widefield 3D Imaging of Rodents

Overview

Journal Rev Sci Instrum

Publisher American Institute of Physics

Specialties Biomedical Engineering
Biophysics

Date 2018 Aug 3

PMID 30068108

Citations 10

Authors

Tomasz J Czernuszewicz

Virginie Papadopoulou

Juan D Rojas

Rajalekha M Rajamahendiran

Jonathan Perdomo

James Butler

Max Harlacher

Graeme OConnell

Dzenan Zukic

Stephen R Aylward

Paul A Dayton

Ryan C Gessner

Affiliations

Soon will be listed here.

Abstract

Noninvasive in vivo imaging technologies enable researchers and clinicians to detect the presence of disease and longitudinally study its progression. By revealing anatomical, functional, or molecular changes, imaging tools can provide a near real-time assessment of important biological events. At the preclinical research level, imaging plays an important role by allowing disease mechanisms and potential therapies to be evaluated noninvasively. Because functional and molecular changes often precede gross anatomical changes, there has been a significant amount of research exploring the ability of different imaging modalities to track these aspects of various diseases. Herein, we present a novel robotic preclinical contrast-enhanced ultrasound system and demonstrate its use in evaluating tumors in a rodent model. By leveraging recent advances in ultrasound, this system favorably compares with other modalities, as it can perform anatomical, functional, and molecular imaging and is cost-effective, portable, and high throughput, without using ionizing radiation. Furthermore, this system circumvents many of the limitations of conventional preclinical ultrasound systems, including a limited field-of-view, low throughput, and large user variability.

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