Mohamed Ghanem Senior Research Scientist mghanem@uw.edu Phone 206-616-7317 |
Department Affiliation
Center for Industrial & Medical Ultrasound |
Education
B.S. Civil Engineering, University of Washington - Seattle, 2009
M.S. Aerospace & Aeronautical Engineering, University of Washington - Seattle, 2012
Ph.D. Aerospace & Aeronautical Engineering, University of Washington - Seattle, 2018
Videos
Ultrasonic tweezers: Technology to lift and steer solid objects in a living body In a recent paper, a CIMU team describes successful experiments to manipulate a solid object within a living body with ultrasound beams transmitted through the skin. |
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15 Jul 2020
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A collaborative, international research teams developed and tuned an ultrasound transducer to create vortex shaped beams that can trap, grab, levitate, and move in three dimensions mm-scale objects. The team is working to apply this technology to their all-in-one kidney stone treatment system that, in clinical trials, uses ultrasound to non-invasively break, erode, and move stones and stone fragments out of the kidney so that they may pass naturally from the body. |
Characterizing Medical Ultrasound Sources and Fields For every medical ultrasound transducer it's important to characterize the field it creates, whether for safety of imaging or efficacy of therapy. CIMU researchers measure a 2D acoustic pressure distribution in the beam emanating from the source transducer and then reconstruct mathematically the exact field on the surface of the transducer and in the entire 3D space. |
11 Sep 2017
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Publications |
2000-present and while at APL-UW |
Phase holograms for the three-dimensional patterning of unconstrained microparticles Ghanem, M., A.D. Maxwell, D. Dalecki, O.A. Sapozhnikov, and M.R. Bailey, "Phase holograms for the three-dimensional patterning of unconstrained microparticles," Sci. Rep., 13, doi:10.1038/s41598-023-35337-8, 2023. |
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6 Jun 2023 |
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Acoustic radiation forces can remotely manipulate particles. Forces from a standing wave field align microscale particles along the nodal or anti-nodal locations of the field to form three-dimensional (3D) patterns. These patterns can be used to form 3D microstructures for tissue engineering applications. However, standing wave generation requires more than one transducer or a reflector, which is challenging to implement in vivo. Here, a method is developed and validated to manipulate microspheres using a travelling wave from a single transducer. Diffraction theory and an iterative angular spectrum approach are employed to design phase holograms to shape the acoustic field. The field replicates a standing wave and aligns polyethylene microspheres in water, which are analogous to cells in vivo, at pressure nodes. Using Gor'kov potential to calculate the radiation forces on the microspheres, axial forces are minimized, and transverse forces are maximized to create stable particle patterns. Pressure fields from the phase holograms and resulting particle aggregation patterns match predictions with a feature similarity index > 0.92, where 1 is a perfect match. The resulting radiation forces are comparable to those produced from a standing wave, which suggests opportunities for in vivo implementation of cell patterning toward tissue engineering applications. |
A prototype therapy system for boiling histotripsy in abdominal targets based on a 256-element spiral array Bawiec, C.R., T.D. Khokhlova, O.A Sapozhnikov, P.B. Rosnitskiy, B.W. Cunitz, M.A. Ghanem, C. Hunter, W. Kreider, G.R. Schade, P.V. Yuldashev, and V.A. Khokhlova, "A prototype therapy system for boiling histotripsy in abdominal targets based on a 256-element spiral array," IEEE Trans. Ultrason. Ferroelectr. Freq. Control, 68, 1496-1510, doi:10.1109/TUFFC.2020.3036580, 2021. |
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1 May 2021 |
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Boiling histotripsy (BH) uses millisecond-long ultrasound (US) pulses with high-amplitude shocks to mechanically fractionate tissue with potential for real-time lesion monitoring by US imaging. For BH treatments of abdominal organs, a high-power multielement phased array system capable of electronic focus steering and aberration correction for body wall inhomogeneities is needed. In this work, a preclinical BH system was built comprising a custom 256-element 1.5-MHz phased array (Imasonic, Besançon, France) with a central opening for mounting an imaging probe. The array was electronically matched to a Verasonics research US system with a 1.2-kW external power source. Driving electronics and software of the system were modified to provide a pulse average acoustic power of 2.2 kW sustained for 10 ms with a 12-Hz repetition rate for delivering BH exposures. System performance was characterized by hydrophone measurements in water combined with nonlinear wave simulations based on the Westervelt equation. Fully developed shocks of 100-MPa amplitude are formed at the focus at 275-W acoustic power. Electronic steering capabilities of the array were evaluated for shock-producing conditions to determine power compensation strategies that equalize BH exposures at multiple focal locations across the planned treatment volume. The system was used to produce continuous volumetric BH lesions in ex vivo bovine liver with 1-mm focus spacing, 10-ms pulselength, five pulses/focus, and 1% duty cycle. |
Noninvasive acoustic manipulation of objects in a living body Ghanem, M.A., A.D. Maxwell, Y.-N. Wang, B.W. Cunitz, V.A. Khokhlova, O.A. Sopozhnikov, and M.R. Bailey, "Noninvasive acoustic manipulation of objects in a living body," Proc. Nat. Acad. Sci. USA, 117, 16,848-16,855, doi:10.1073/pnas.2001779117, 2020. |
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21 Jul 2020 |
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In certain medical applications, transmitting an ultrasound beam through the skin to manipulate a solid object within the human body would be beneficial. Such applications include, for example, controlling an ingestible camera or expelling a kidney stone. In this paper, ultrasound beams of specific shapes were designed by numerical modeling and produced using a phased array. These beams were shown to levitate and electronically steer solid objects (3-mm-diameter glass spheres), along preprogrammed paths, in a water bath, and in the urinary bladders of live pigs. Deviation from the intended path was on average <10%. No injury was found on the bladder wall or intervening tissue. |
In The News
We’ve mastered acoustic levitation — and it is surprisingly useful New Scientist, Michael Allen Sonic tractor beams lift and manipulate objects with sound waves. They could be used to precisely deliver drugs inside our bodies or assemble delicate computer chips in mid air. Novel applications of this technology can be used from treating and moving kidney stones on Earth, minimizing the known risk of kidney stone development during space flights, and possibly guiding a pill-sized medical camera through a patient’s body. |
15 Sep 2021
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Acoustic tweezers move objects in the body remotely Physics World, Marric Stephens Acoustic tweezers that allow the remote manipulation of internal objects from outside the body could one day be used to expel urinary stones or control ingestible cameras. Researchers at the University of Washington and Moscow State University demonstrated the technique by trapping 3-mm glass beads in vortex-shaped beams of ultrasound. |
4 Aug 2020
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Ultrasound tweezers could help remove kidney stones without surgery New Scientist, Clare Wilson Beams of ultrasound could be used to remove kidney stones by steering them through the body. |
6 Jul 2020
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