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Listening to the Sound of Light to Guide Surgeries

Jan 22, 2021
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Canon U.S.A. Inc., Industrial Products Div.
About This Webinar
Photoacoustic imaging offers "x-ray vision" to see beyond tool tips and underneath tissue during surgical procedures, yet no ionizing x-rays are required. Instead, optical fibers and acoustic receivers enable photoacoustic sensing of major structures — such as blood vessels and nerves — that are otherwise hidden from view. The entire process is initiated by delivering laser pulses through optical fibers to illuminate regions of interest, causing an acoustic response that is detectable with ultrasound transducers. Beamforming is then implemented to create a photoacoustic image.

Muyinatu Bell highlights novel light delivery systems, new spatial coherence beamforming theory, deep learning alternatives to beamforming, counterintuitive findings, and robotic integration methods — each pioneered by the Photoacoustic & Ultrasonic Systems Engineering (PULSE) Lab at Johns Hopkins University to enable this new frontier known as photoacoustic-guided surgery. This method has the potential to eliminate the occurrence of major complications (e.g., excessive bleeding, paralysis, or accidental patient death) during a wide range of delicate surgeries and procedures, including neurosurgery, cardiac catheter-based interventions, liver surgery, spinal fusion surgery, hysterectomies, biopsies, and teleoperative robotic surgeries.

***This presentation premiered during the 2021 Photonics Spectra Conference Biomedical track. For information on upcoming Photonics Media events, see our event calendar here.

About the presenter:
Muyinatu Bell, Ph.D.Muyinatu Bell, Ph.D. is an Assistant Professor of Electrical and Computer Engineering, Biomedical Engineering, and Computer Science at Johns Hopkins University, where she founded and directs the Photoacoustic and Ultrasonic Systems Engineering (PULSE) Lab. Dr. Bell earned a B.S. degree in Mechanical Engineering (biomedical engineering minor) from Massachusetts Institute of Technology (2006), received a Ph.D. degree in Biomedical Engineering from Duke University (2012), conducted research abroad as a Whitaker International Fellow at the Institute of Cancer Research and Royal Marsden Hospital in the United Kingdom (2009-2010), and completed a postdoctoral fellowship with the Engineering Research Center for Computer-Integrated Surgical Systems and Technology at Johns Hopkins University (2016). She is Associate Editor-in-Chief of IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control (T-UFFC), Associate Editor of IEEE Transactions on Medical Imaging, and holds patents for short-lag spatial coherence beamforming and photoacoustic-guided surgery. Dr. Bell is a recipient of multiple awards and honors, including MIT Technology Review's Innovator Under 35 Award (2016), the NSF CAREER Award (2018), the NIH Trailblazer Award (2018), the Alfred P. Sloan Research Fellowship (2019), the ORAU Ralph E. Powe Jr. Faculty Enhancement Award (2019), and Maryland's Outstanding Young Engineer Award (2019). She most recently received the inaugural IEEE UFFC Star Ambassador Lectureship Award (2020) from her IEEE society and the SPIE Early Career Achievement Award (2021).
biomedical imagingphotoacoustic imaging
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