D24AC00380
Cooperative Agreement
Overview
Grant Description
Fully integrated acousto optical electronic photonic system for real time in vivo 3D photoacoustic imaging by Northeastern University and subawardees University of Washington, Johns Hopkins University, and Massachusetts General Hospital.
Endoscopic and intravascular photoacoustic imaging systems that navigate the body to diagnose and evaluate disease are a key element of the future of medicine addressing malfunction in cancer, cardiovascular, and other disease areas.
At present, however, wide deployment of these systems have been limited by low imaging speed and large size, frequently causing post-operative complications.
Emerging systems, on the other hand, suffer from poor image quality due to their inherent limitations of low signal to noise ratio and spatial resolution.
To address these core limitations, we need to break away from the conventional scheme of recording and relaying photoacoustic signals using electrical ultrasound transducers and cables.
We propose a disruptive approach based on advancements in microelectronics, nanofabrication, and options to develop an innovative electronic photonic photoacoustic imaging system based on acousto optic detection.
The system core element is a miniature probe in which photoacoustic waves from the tissue of interest are detected and transduced to optical signals.
The resulting optical signals are routed using a dense optical fiber bundle to a module outside the body.
The module embodies application specific electronic photonic integrated circuits and computational algorithms for data decoding and processing.
Our unique design approach will result in an almost order of magnitude reduction in probe area with a simultaneous order of magnitude improvement in spatial resolution at clinically relevant depths over the state of the art.
The result of our effort will be a radically new miniature optical photoacoustic imaging platform with advanced image reconstruction algorithms.
Such a system can transform the landscape of the photoacoustic imaging field by providing real time high contrast volumetric images that can assist the diagnosis and treatment of widespread diseases ranging from cancer to vascular diseases.
The commercialization of our technology will have broad societal impacts since it can provide opportunities with low invasiveness to personalize therapies and improve outcomes for patients.
Endoscopic and intravascular photoacoustic imaging systems that navigate the body to diagnose and evaluate disease are a key element of the future of medicine addressing malfunction in cancer, cardiovascular, and other disease areas.
At present, however, wide deployment of these systems have been limited by low imaging speed and large size, frequently causing post-operative complications.
Emerging systems, on the other hand, suffer from poor image quality due to their inherent limitations of low signal to noise ratio and spatial resolution.
To address these core limitations, we need to break away from the conventional scheme of recording and relaying photoacoustic signals using electrical ultrasound transducers and cables.
We propose a disruptive approach based on advancements in microelectronics, nanofabrication, and options to develop an innovative electronic photonic photoacoustic imaging system based on acousto optic detection.
The system core element is a miniature probe in which photoacoustic waves from the tissue of interest are detected and transduced to optical signals.
The resulting optical signals are routed using a dense optical fiber bundle to a module outside the body.
The module embodies application specific electronic photonic integrated circuits and computational algorithms for data decoding and processing.
Our unique design approach will result in an almost order of magnitude reduction in probe area with a simultaneous order of magnitude improvement in spatial resolution at clinically relevant depths over the state of the art.
The result of our effort will be a radically new miniature optical photoacoustic imaging platform with advanced image reconstruction algorithms.
Such a system can transform the landscape of the photoacoustic imaging field by providing real time high contrast volumetric images that can assist the diagnosis and treatment of widespread diseases ranging from cancer to vascular diseases.
The commercialization of our technology will have broad societal impacts since it can provide opportunities with low invasiveness to personalize therapies and improve outcomes for patients.
Awardee
Funding Goals
THE FOUR INITIAL FOCUS AREAS ARE(1) HEALTH SCIENCE FUTURES(2) SCALABLE SOLUTIONS(3) PROACTIVE HEALTH(4) RESILIENT SYSTEMS
Grant Program (CFDA)
Awarding / Funding Agency
Place of Performance
Massachusetts
United States
Geographic Scope
State-Wide
Related Opportunity
D-AQD-FA-24-008
Northeastern University was awarded
Miniature Acousto-Optical Electronic Imaging System Real-Time 3D Photoacoustic Imaging
Cooperative Agreement D24AC00380
worth $4,116,367
from Interior Business Center in September 2024 with work to be completed primarily in Massachusetts United States.
The grant
has a duration of 2 years and
was awarded through assistance program 93.384 ADVANCED RESEARCH PROJECTS AGENCY for HEALTH (ARPA-H).
Status
(Ongoing)
Last Modified 9/16/24
Period of Performance
9/12/24
Start Date
9/11/26
End Date
Funding Split
$4.1M
Federal Obligation
$0.0
Non-Federal Obligation
$4.1M
Total Obligated
Activity Timeline
Subgrant Awards
Disclosed subgrants for D24AC00380
Additional Detail
Award ID FAIN
D24AC00380
SAI Number
None
Award ID URI
None
Awardee Classifications
Private Institution Of Higher Education
Awarding Office
140D04 IBC ACQ SVCS DIRECTORATE (00004)
Funding Office
140D04 IBC ACQ SVCS DIRECTORATE (00004)
Awardee UEI
HLTMVS2JZBS6
Awardee CAGE
9A140
Performance District
MA-07
Senators
Edward Markey
Elizabeth Warren
Elizabeth Warren
Modified: 9/16/24