The goal of the proposed program is to address several technical feasibility questions (in Phase I), and then demonstrate (in a subsequent Phase II) incorporation of Sonetics' groundbreaking CMUT-in-CMOS ultrasound transducer technology into a novel, high-performance 2D ultrasound array suitable for commercial applications. Phase I specific aims will investigate bandwidth improvement for 2D array elements, scaling and enhancement of on-chip readout circuits, and reduction of dielectric charging effects related to device membrane sealing layers. This phase will culminate with the fabrication and characterization of a 64-element 2D array prototype, which will be used to evaluate the imaging potential of a larger scale array. Full implementation into a prototype scanhead (including a 128x128 element CMUT array) suitable for real-time 3D imaging would be demonstrated in Phase II, with the long-term goal of commercializing the technology (as well as other CMUT-in-CMOS-based products) for the ultrasound equipment market, forecast to be $3.75B globally by 2010. The academic segment of this market would benefit from the practical realization of fully-populated 2D ultrasound arrays, which will improve the quality and speed of 3D imaging for disease diagnosis. As well, the potential of CMUT-based scanheads to reduce the largest cost element of many state-of-the-art ultrasound systems, while simultaneously exhibiting improved imaging capability, will provide increased opportunity for researchers and students to undertake real-time, in vivo studies of living systems-something 3D ultrasound is uniquely positioned to do from a cost, availability, and convenience perspective (vs. MRI, PET, or CT, for example, all of which require expensive, dedicated facilities and technicians). The clinical market stands to gain similarly, as 3D ultrasound provides safe, convenient, real-time imaging technology-enabling improved triage and better patient outcomes, lower-cost imaging, and reduced staffing needs, all of which will serve the U.S. healthcare industry well as it seeks to control skyrocketing costs.
Public Health Relevance: Potential benefits to public health from the successful development of Sonetics' novel ultrasound transducer technology include: improved availability and affordability of high-quality 3D medical imaging for disease diagnosis; improved medical training as low-cost 3D ultrasound enters the classroom; and lowered health-care costs for society as a whole, as better ultrasound improves clinical triage and patient outcomes. Furthermore, ultrasound is the only technology with the potential to become a convenient, safe, real-time imaging tool for use in limited-budget facilities such as lowincome health clinics.
Public Health Relevance Statement: Relevance: Potential benefits to public health from the successful development of Sonetics' novel ultrasound transducer technology include: improved availability and affordability of high-quality 3D medical imaging for disease diagnosis; improved medical training as low-cost 3D ultrasound enters the classroom; and lowered health-care costs for society as a whole, as better ultrasound improves clinical triage and patient outcomes. Furthermore, ultrasound is the only technology with the potential to become a convenient, safe, real-time imaging tool for use in limited-budget facilities such as low- income health clinics.
Project Terms: 3-D Imaging; 3D image; 3D imaging; Acoustic; Acoustics; Address; Area; Arts; Budgets; Charge; Clinic; Clinical; Data; Deposit; Deposition; Development; Devices; Diagnosis, Ultrasound; Echography; Echotomography; Elements; Equipment; Exhibits; Flexibility; Future; Goals; Health; Health Care Costs; Health Care Industry; Health Costs; Healthcare Costs; Healthcare Industry; Hybrids; Hydrogen Oxide; Image; Images, 3-D; Imaging Device; Imaging Tool; Imaging technology; Imaging, Three-Dimensional; Industry, Healthcare; Investigators; Low income; MR Imaging; MR Tomography; MRI; Magnetic Resonance Imaging; Magnetic Resonance Imaging Scan; Marketing; Mechanics; Medical; Medical Imaging; Medical Imaging, Magnetic Resonance / Nuclear Magnetic Resonance; Medical Imaging, Positron Emission Tomography; Medical Imaging, Three Dimensional; Medical Imaging, Ultrasound; Membrane; Metals; Methods; Modeling; NMR Imaging; NMR Tomography; Nuclear Magnetic Resonance Imaging; Organism; Outcome; PET; PET Scan; PET imaging; PETSCAN; PETT; Patients; Performance; Phase; Physiologic pulse; Pliability; Position; Positioning Attribute; Positron Emission Tomography Scan; Positron-Emission Tomography; Process; Programs (PT); Programs [Publication Type]; Proton Magnetic Resonance Spectroscopic Imaging; Public Health; Pulse; Rad.-PET; Research Personnel; Researchers; Risk; Route; Sampling; Savings; Scanning; Side; Simulate; Societies; Speed; Speed (motion); Staging; Structure; Students; System; System, LOINC Axis 4; Technology; Testing; Three-Dimensional Image; Three-Dimensional Imaging; Time; Training; Transducers; Triage; Ultrasonic Imaging; Ultrasonic Transducer; Ultrasonogram; Ultrasonography; Ultrasound Test; Ultrasound transducer; Ultrasound, Medical; Variant; Variation; Water; Zeugmatography; aged; base; commercial application; commercially viable technology; cost; design; designing; diagnostic ultrasound; disease diagnosis; experiment; experimental research; experimental study; imaging; improved; in vivo; living system; manufacturing process; meetings; membrane structure; novel; programs; prototype; public health medicine (field); public health relevance; research study; seal; simulation; sonogram; sonography; sound measurement; sub micron; submicron; ultrasound; ultrasound imaging; ultrasound scanning
