R01CA271309
Project Grant
Overview
Grant Description
High Resolution Ultrasound in Interventional Radiology - We seek to create a real-time ultrasound imaging tool for guiding interventions, with resolution that exceeds that obtained using CT but without the need for radiation or iodinated contrast agents.
Advancements in medical imaging and device technology allow minimally-invasive procedures for the diagnosis and treatment of various disorders. Real-time ultrasound has become an integral aspect of many image-guided interventions. Advantages of US imaging include the low cost, lack of ionizing radiation, and real-time visualization of anatomy and physiology.
Our approach will be to:
1) Create an extended aperture 2D transducer (512 by 16 elements) capable of imaging an extended azimuthal field of 9 cm with in-plane resolution of hundreds of microns (to provide a wide field of view at high resolution).
2) Apply the 2D array to image multiple adjacent planes (to facilitate the view of biopsy needles or ablations).
3) Achieve a 30 volume per second update rate by using plane wave transmissions to enhance contrast imaging modes and implement novel beam formation algorithms.
4) Integrate methods for aberration correction.
5) Apply this technology in B-mode, color Doppler, volumetric vector flow imaging, and contrast imaging.
The array will be realized using tiled modules that can be switched in a mode-dependent fashion to accomplish B-mode imaging, color Doppler, and contrast imaging. Over the past 4 years, Stanford and the University of Southern California have designed an adult extended-aperture abdominal-imaging system and demonstrated the improved spatial resolution, field of view, and contrast that can be achieved. We exploit these tools here to develop a high-volume rate capability for monitoring liver interventions.
Our aims to accomplish this are to:
1) Create and integrate tileable acoustic/electronic modules to implement signal buffering and multiplexing and create a large aperture array with elevational focusing. Utilizing newly designed integrated circuits (IC)'s and highly sensitive and wide-bandwidth single crystal transducer material, we will construct individual 2D array modules with co-integrated transducers and electronics.
2) Optimize the protocols for guiding biopsy and ablation in phantom and animal studies.
a) Create software for imaging of small lesions and microwave ablation. We will implement singular value decomposition (SVD) based beam formation for aberration correction.
b) Evaluate performance in phantoms and ex vivo tissue.
c) Assess speed and accuracy of needle placements.
d) Conduct contrast imaging and ablative studies in porcine liver in vivo.
3) Conduct diagnostic and interventional imaging studies as a proof of concept.
a) Test the protocols to image the liver of adult volunteers and establish the signal-to-noise ratio in vivo as compared with phantoms.
b) Assess 3D visualization of liver vasculature and lesions in patients referred for MR or CT imaging of a liver lesion.
c) Compare the 3D visualization of ablated zones to contrast-enhanced CT (CECT) in patients that are referred for liver ablation.
Advancements in medical imaging and device technology allow minimally-invasive procedures for the diagnosis and treatment of various disorders. Real-time ultrasound has become an integral aspect of many image-guided interventions. Advantages of US imaging include the low cost, lack of ionizing radiation, and real-time visualization of anatomy and physiology.
Our approach will be to:
1) Create an extended aperture 2D transducer (512 by 16 elements) capable of imaging an extended azimuthal field of 9 cm with in-plane resolution of hundreds of microns (to provide a wide field of view at high resolution).
2) Apply the 2D array to image multiple adjacent planes (to facilitate the view of biopsy needles or ablations).
3) Achieve a 30 volume per second update rate by using plane wave transmissions to enhance contrast imaging modes and implement novel beam formation algorithms.
4) Integrate methods for aberration correction.
5) Apply this technology in B-mode, color Doppler, volumetric vector flow imaging, and contrast imaging.
The array will be realized using tiled modules that can be switched in a mode-dependent fashion to accomplish B-mode imaging, color Doppler, and contrast imaging. Over the past 4 years, Stanford and the University of Southern California have designed an adult extended-aperture abdominal-imaging system and demonstrated the improved spatial resolution, field of view, and contrast that can be achieved. We exploit these tools here to develop a high-volume rate capability for monitoring liver interventions.
Our aims to accomplish this are to:
1) Create and integrate tileable acoustic/electronic modules to implement signal buffering and multiplexing and create a large aperture array with elevational focusing. Utilizing newly designed integrated circuits (IC)'s and highly sensitive and wide-bandwidth single crystal transducer material, we will construct individual 2D array modules with co-integrated transducers and electronics.
2) Optimize the protocols for guiding biopsy and ablation in phantom and animal studies.
a) Create software for imaging of small lesions and microwave ablation. We will implement singular value decomposition (SVD) based beam formation for aberration correction.
b) Evaluate performance in phantoms and ex vivo tissue.
c) Assess speed and accuracy of needle placements.
d) Conduct contrast imaging and ablative studies in porcine liver in vivo.
3) Conduct diagnostic and interventional imaging studies as a proof of concept.
a) Test the protocols to image the liver of adult volunteers and establish the signal-to-noise ratio in vivo as compared with phantoms.
b) Assess 3D visualization of liver vasculature and lesions in patients referred for MR or CT imaging of a liver lesion.
c) Compare the 3D visualization of ablated zones to contrast-enhanced CT (CECT) in patients that are referred for liver ablation.
Funding Goals
TO IMPROVE SCREENING AND EARLY DETECTION STRATEGIES AND TO DEVELOP ACCURATE DIAGNOSTIC TECHNIQUES AND METHODS FOR PREDICTING THE COURSE OF DISEASE IN CANCER PATIENTS. SCREENING AND EARLY DETECTION RESEARCH INCLUDES DEVELOPMENT OF STRATEGIES TO DECREASE CANCER MORTALITY BY FINDING TUMORS EARLY WHEN THEY ARE MORE AMENABLE TO TREATMENT. DIAGNOSIS RESEARCH FOCUSES ON METHODS TO DETERMINE THE PRESENCE OF A SPECIFIC TYPE OF CANCER, TO PREDICT ITS COURSE AND RESPONSE TO THERAPY, BOTH A PARTICULAR THERAPY OR A CLASS OF AGENTS, AND TO MONITOR THE EFFECT OF THE THERAPY AND THE APPEARANCE OF DISEASE RECURRENCE. THESE METHODS INCLUDE DIAGNOSTIC IMAGING AND DIRECT ANALYSES OF SPECIMENS FROM TUMOR OR OTHER TISSUES. SUPPORT IS ALSO PROVIDED FOR ESTABLISHING AND MAINTAINING RESOURCES OF HUMAN TISSUE TO FACILITATE RESEARCH. SMALL BUSINESS INNOVATION RESEARCH (SBIR) PROGRAM: TO EXPAND AND IMPROVE THE SBIR PROGRAM, TO INCREASE PRIVATE SECTOR COMMERCIALIZATION OF INNOVATIONS DERIVED FROM FEDERAL RESEARCH AND DEVELOPMENT, TO INCREASE SMALL BUSINESS PARTICIPATION IN FEDERAL RESEARCH AND DEVELOPMENT, AND TO FOSTER AND ENCOURAGE PARTICIPATION OF SOCIALLY AND ECONOMICALLY DISADVANTAGED SMALL BUSINESS CONCERNS AND WOMEN-OWNED SMALL BUSINESS CONCERNS IN TECHNOLOGICAL INNOVATION. SMALL BUSINESS TECHNOLOGY TRANSFER (STTR) PROGRAM: TO STIMULATE AND FOSTER SCIENTIFIC AND TECHNOLOGICAL INNOVATION THROUGH COOPERATIVE RESEARCH AND DEVELOPMENT CARRIED OUT BETWEEN SMALL BUSINESS CONCERNS AND RESEARCH INSTITUTIONS, TO FOSTER TECHNOLOGY TRANSFER BETWEEN SMALL BUSINESS CONCERNS AND RESEARCH INSTITUTIONS, TO INCREASE PRIVATE SECTOR COMMERCIALIZATION OF INNOVATIONS DERIVED FROM FEDERAL RESEARCH AND DEVELOPMENT, AND TO FOSTER AND ENCOURAGE PARTICIPATION OF SOCIALLY AND ECONOMICALLY DISADVANTAGED SMALL BUSINESS CONCERNS AND WOMEN-OWNED SMALL BUSINESS CONCERNS IN TECHNOLOGICAL INNOVATION.
Grant Program (CFDA)
Awarding / Funding Agency
Place of Performance
Palo Alto,
California
94304
United States
Geographic Scope
Single Zip Code
Related Opportunity
Analysis Notes
Amendment Since initial award the total obligations have increased 401% from $624,599 to $3,130,444.
The Leland Stanford Junior University was awarded
High Resolution Ultrasound for Interventional Radiology Procedures
Project Grant R01CA271309
worth $3,130,444
from National Cancer Institute in March 2022 with work to be completed primarily in Palo Alto California United States.
The grant
has a duration of 5 years and
was awarded through assistance program 93.394 Cancer Detection and Diagnosis Research.
The Project Grant was awarded through grant opportunity NIH Research Project Grant (Parent R01 Clinical Trial Not Allowed).
Status
(Ongoing)
Last Modified 3/5/26
Period of Performance
3/4/22
Start Date
2/28/27
End Date
Funding Split
$3.1M
Federal Obligation
$0.0
Non-Federal Obligation
$3.1M
Total Obligated
Activity Timeline
Subgrant Awards
Disclosed subgrants for R01CA271309
Transaction History
Modifications to R01CA271309
Additional Detail
Award ID FAIN
R01CA271309
SAI Number
R01CA271309-972734980
Award ID URI
SAI UNAVAILABLE
Awardee Classifications
Private Institution Of Higher Education
Awarding Office
75NC00 NIH National Cancer Institute
Funding Office
75NC00 NIH National Cancer Institute
Awardee UEI
HJD6G4D6TJY5
Awardee CAGE
1KN27
Performance District
CA-16
Senators
Dianne Feinstein
Alejandro Padilla
Alejandro Padilla
Budget Funding
| Federal Account | Budget Subfunction | Object Class | Total | Percentage |
|---|---|---|---|---|
| National Cancer Institute, National Institutes of Health, Health and Human Services (075-0849) | Health research and training | Grants, subsidies, and contributions (41.0) | $1,230,701 | 100% |
Modified: 3/5/26