A new ultrasound instrument for in vivo microimaging of mice.

We report here on the design and evaluation of the first high-frequency ultrasound (US) imaging system specifically designed for microimaging of the mouse. High-frequency US or US biomicroscopy (UBM) has the advantage of low cost, rapid imaging speed, portability and high resolution. In combination with the ability to provide functional information on blood flow, UBM provides a powerful method for the investigation of development and disease models. The new UBM imaging system is demonstrated for mouse development from day 5.5 of embryogenesis through to the adult mouse. At a frequency of 40 MHz, the resolution voxel of the new mouse scanner measures 57 microm x 57 microm x 40 microm. Duplex Doppler provides blood velocity sensitivity to the mm per s range, consistent with flow in the microcirculation, and can readily detect blood flow in the embryonic mouse heart, aorta, liver and placenta. Noninvasive UBM assessment of development shows striking similarity to invasive atlases of mouse anatomy. The most detailed noninvasive in vivo images of mouse embryonic development achieved using any imaging method are presented.

High-frequency intracoronary ultrasound imaging.

Intravascular ultrasound is playing an increasingly important role in the clinical management of coronary interventions. In the past few years the technology for intracoronary ultrasound, in response to clinical pressure, has moved towards lower profile probes with improved handling. While new catheter designs are markedly improved on their predecessors, image quality has not seen significant gains due to the primitive nature of the ultrasound transducer designs. In this article, the potential for improving image quality by increasing the frequency and focusing the ultrasound beam is explored. Basic aspects of transducer implementation are discussed and the acoustic properties of vascular tissues and blood are reviewed. A variety of instruments are used to image coronary and femoral arteries at frequencies ranging from 40 to 200 MHz. These studies serve to illustrate the trade-offs in the development of high frequency IVUS systems. There would appear to be no fundamental reason why frequencies in excess of 50 MHz could not be implemented. Studies using prototype IVUS instruments in the 50 MHz range demonstrate significant improvements in image quality.