Project Details
Description
As the management of multiple intracranial metastases is rapidly evolving, the demands for
detection and delineation of a large number of potentially very small metastatic lesions in the
brain on 3D magnetic resonance images (MRI) are increasing dramatically. Artificial intelligence
(AI) systems can assist both the radiologist as well as radiation oncologist in their roles in
management of patients with multiple tumors metastatic to the brain. In response to PAR-20-
155, we have assembled an academic-industrial partnership including investigators from three
academic institutes and an industrial AI team to develop, translate and validate AI systems to
address this unmet clinical question. In this proposal, a neural network system based upon
multiple scale 3D fully convolutional one-stage objective detectors containing segmentation
heads will be optimized and investigated. Training and testing data will be provided from clinical
images of patients treated with radiosurgery to multiple small metastases acquired from three
academic centers, curated by experts, and augmented by addition of realistic synthetic lesions
injected into images. The clinical utility of the network will be investigated for its ability to assist
a) radiologists in detecting multiple metastases accurately and efficiently, and b) radiation
oncologists in delineating multiple metastatic lesions to support selection of therapeutic strategies
and planning of treatments.
detection and delineation of a large number of potentially very small metastatic lesions in the
brain on 3D magnetic resonance images (MRI) are increasing dramatically. Artificial intelligence
(AI) systems can assist both the radiologist as well as radiation oncologist in their roles in
management of patients with multiple tumors metastatic to the brain. In response to PAR-20-
155, we have assembled an academic-industrial partnership including investigators from three
academic institutes and an industrial AI team to develop, translate and validate AI systems to
address this unmet clinical question. In this proposal, a neural network system based upon
multiple scale 3D fully convolutional one-stage objective detectors containing segmentation
heads will be optimized and investigated. Training and testing data will be provided from clinical
images of patients treated with radiosurgery to multiple small metastases acquired from three
academic centers, curated by experts, and augmented by addition of realistic synthetic lesions
injected into images. The clinical utility of the network will be investigated for its ability to assist
a) radiologists in detecting multiple metastases accurately and efficiently, and b) radiation
oncologists in delineating multiple metastatic lesions to support selection of therapeutic strategies
and planning of treatments.
Status | Active |
---|---|
Effective start/end date | 1/8/21 → 31/7/24 |
Links | https://projectreporter.nih.gov/project_info_details.cfm?aid=10683991 |
Funding
- National Cancer Institute: US$351,135.00
- National Cancer Institute: US$410,695.00
- National Cancer Institute: US$456,195.00
ASJC Scopus Subject Areas
- Cancer Research
- Oncology
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