Title :
A High-Frame Rate Duplex Ultrasound Biomicroscopy for Small Animal Imaging In vivo
Author :
Sun, Lei ; Xu, Xiaochen ; Richard, William D. ; Feng, Ching ; Johnson, Jeffrey A. ; Shung, K. Kirk
Author_Institution :
Dept. of Health Technol. & Inf., Hong Kong Polytech. Univ., Kowloon
Abstract :
Much of the current knowledge of human cardiovascular pathologies and treatment strategies has been gained from understanding the cardiac physiologies and functions in small animal models, such as mice, rats, and zebraflsh. In this paper, we present the development of a high-frame-rate duplex ultrasound biomicroscopy (UBM) capable of B-mode imaging and pulsed-wave (PW) Doppler measurement for in vivo cardiovascular investigation in small animals. A frame rate of 200 frames per second (fps) was accomplished at a view of 5 mm times 8 mm, using a novel highspeed sector probe and specially designed lightweight transducers. In a reduced lateral view of 1.2 mm, a frame rate of 400 fps was achieved to examine more detailed cardiac motion. The UBM utilized transducers with different center frequencies (40-75 MHz) and geometries, which made it useful for various applications in small animal cardiac imaging. The highest spatial resolution the UBM achieved was 25 mum times 56 mum. In addition, the image-guided PW Doppler implemented in the UBM demonstrated the detection of the velocity of a moving wire as low as 0.1 mm/s, and flow in a polyimide tube as small as 200 mum in diameter. Furthermore, the UBM achieved a 15-muV minimal detectable signal and a 60-dB dynamic range using a low-cost PCB-based design. Finally, sample in vivo cardiac images of mouse and zebraflsh hearts were given. These results showed that the UBM integrated with B-mode and PW Doppler is useful to investigate the pathophysiological mechanism in the cardiovascular studies.
Keywords :
acoustic microscopy; biomedical ultrasonics; cardiovascular system; diseases; B-mode imaging; IEEE polyimide tube; cardiac motion; cardiovascular investigation; high-frame rate duplex ultrasound biomicroscopy; in vivo cardiac images; lightweight transducers; mouse heart; pathophysiological mechanism; pulsed-wave Doppler measurement; small animal imaging in vivo; zebraflsh heart; Animals; Cardiology; Doppler measurements; Humans; In vivo; Mice; Pathology; Pulse measurements; Rats; Ultrasonic imaging; Cardiac imaging; cardiac imaging; duplex; high frame rate; small animal; ultrasound biomicroscopy (UBM); zebrafish; Animals; Echocardiography; Equipment Design; Equipment Failure Analysis; Heart; Mice; Microscopy, Acoustic; Microscopy, Video; Transducers;
Journal_Title :
Biomedical Engineering, IEEE Transactions on
DOI :
10.1109/TBME.2008.919110