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CORRECTING and REPLACING: High-Frequency Ultrasound Confirms Stem Cells Grafted in Beating Mice Hearts Restores Normal Rhythms

Mayo Clinic researchers use advanced ultrasound software to document microscopic, regenerative improvements to damaged cardiac motion for published study

CORRECTION...by FUJIFILM VisualSonics, Inc.

TORONTO--(BUSINESS WIRE)--Please replace the release with the following corrected version due to multiple revisions.

“A high-resolution ultrasound revealed harmonized pumping where iPS cells were introduced to the previously damaged heart tissue”

HIGH-FREQUENCY ULTRASOUND CONFIRMS STEM CELLS GRAFTED IN BEATING MICE HEARTS RESTORES NORMAL RHYTHMS

Mayo Clinic researchers use advanced ultrasound software to document microscopic, regenerative improvements to damaged cardiac motion for published study

Using high-frequency ultrasound and special cardiac-assessment software by FUJIFILM VisualSonics, Inc., researchers have been able to implant engineered stem cells into the damaged heart tissue of mice and, over time, observe the regeneration of healthy cardiac rhythms.

Following a heart attack, scarred and infarcted (dead) tissue can interfere with the heart's ability to regain is regular synchronized motion. Findings published in the September Journal of Physiology by Mayo Clinic researchers reveal that, when mice underwent the grafting of stem cells—specifically, induced pluripotent stem (iPS) cells—into their damaged hearts, cardiac motion was resynchronized.

"A high-resolution ultrasound revealed harmonized pumping where iPS cells were introduced to the previously damaged heart tissue," says Satsuki Yamada, MD, PhD, first author of the study: Induced pluripotent stem cell intervention rescues ventricular wall motion disparity, achieving biological cardia resynchronization post-infarction (Yamada S, Nelson T, Kane G, et al., Journal of Physiology 591 (17), 4335-4349).

This first-time discovery offers a significant step towards validating the potential in stem cell-based regenerative solutions to cardiac dyssynchrony. It was captured in ultrasound imaging and hard data through "speckle tracking echocardiography" made possible by VevoStrain™ Advanced Cardiac Analysis Software manufactured by VisualSonics of Toronto, Ontario. This software provides advanced imaging and quantification capabilities for studying sensitive movements in heart muscles and is the only commercial cardiac-strain package optimized for assessing cardiovascular function in preclinical rodent studies.

Dr. Yamada and her co-researchers utilized this highly specialized software during the implantation and observation of the stem cells within the beating mice hearts. The software documented the following:

  • Regional and overall (global) heart-wall motion tracking in circumferential, radial and longitudinal directions
  • Measurements throughout cardiac cycle of displacement, velocity, strain and strain rate
  • Left ventricular function quantification across both long and short axes in 2D

By analyzing the data (specifically, measuring strain rate and time to peak analyses in systole), researchers were able to confirm that the irregular rhythms were corrected in those hearts engrafted with the iPS cells: homogenous wall motion was recovered; cell-mediated correction of dyssynchrony and discoordination occurred; and abnormal post-infarction ultrasound speckle patterns were normalized.

The VevoStrain software augments high-resolution imaging capabilities of the Vevo® 2100 Imaging system manufactured by VisualSonics for preclinical, in vivo research. VisualSonics regularly attends conferences within the medical and scientific research industry, such as the annual American Heart Association (AHA) Scientific Sessions where visitors can see the VevoStrain software tool in action at the company's booth.

To learn more about VevoStrain software, go to: http://www.visualsonics.com/vevostrain.

About FUJIFILM VisualSonics, Inc.

VisualSonics is the world leader in real time, in vivo, high-resolution micro imaging systems designed specifically for preclinical research. The company’s cutting edge technologies allow researchers at the world’s most prestigious pharmaceutical and biotechnology companies, hospitals and universities to conduct research in cardiovascular, cancer, neurobiology and developmental biology areas. The micro imaging technologies support research applications that include genetic research, phenotypic studies and drug development. VisualSonics high-frequency ultrasound and photoacoustic platforms combine high-resolution, real time in vivo imaging at reasonable cost with ease-of-use and quantifiable results. VisualSonics is a subsidiary of FUJIFILM SonoSite, Inc.

About FUJIFILM SonoSite, Inc.

SonoSite helped pioneer the concept of portable, point-of-care ultrasound, and it continues to be a world-leading manufacturer and innovator of bedside ultrasound systems as well as an industry leader in ultra high-frequency micro-ultrasound technology. Headquartered near Seattle, the company is represented by 26 subsidiaries and a global distribution network in over 100 countries. SonoSite’s portable, compact systems are expanding the use of ultrasound across the clinical spectrum by cost-effectively bringing high-performance ultrasound to the point of patient care. For more information, go to: www.sonosite.com.

Contacts

FUJIFILM VisualSonics, Inc.
Kathy Volpe, 416-895-0823
kvolpe@visualsonics.com