Difference between revisions of "Wiki page for 2013 Preliminary Draft"
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* Brief description of overall objectives of NA-MIC | * Brief description of overall objectives of NA-MIC | ||
− | The National Alliance for Medical Image Computing (NA-MIC) is a multi-institutional, interdisciplinary community of computer scientists, software engineers, and medical investigators who share the common goal | + | The National Alliance for Medical Image Computing (NA-MIC) is a multi-institutional, interdisciplinary community of computer scientists, software engineers, and medical investigators who share the common goal of improving healthcare through the development of computational tools for the analysis and visualization of medical image data. The Center maintains a robust and flexible infrastructure for developing and applying advanced imaging technologies across a range of important biomedical research disciplines. Our research and development effort is organized around the Computer Science Core, which includes independent teams for Algorithms and Engineering. The Algorithm effort responds to the challenges of the DBPs to expand the horizons of medical image analysis. As a result, the Algorithm activities are typically highly experimental, creating new approaches that are rapidly prototyped, tested, and improved. The Engineering effort supports the needs of the Algorithms effort by creating integrated software platforms that support research and eventual deployment of advanced technology. The Engineering team also develops and maintains processes used to build and sustain a large research community. A separate Core oversees operations and maintenance of The NA-MIC Kit, an integrated set of interoperable free open source software (FOSS) packages; developed, supported and deployed using a collaborative, agile, high quality software process. NA-MIC's current DBPs are investigating solutions to problems in patient-specific data analysis in four clinical areas: Atrial Fibrillation, Huntingdon's Disease, Adaptive Radiotherapy for Head and Neck Cancer, and Traumatic Brain Injury. NA-MIC further provides enabling technology and resources to XX collaborative research projects. |
− | of improving healthcare through the development of computational tools for the analysis and visualization of medical image data. The Center maintains a robust and flexible infrastructure for developing and | ||
− | applying advanced imaging technologies across a range of important biomedical research disciplines. Our research and development effort is organized around the Computer Science Core, which includes independent teams for Algorithms and Engineering. The Algorithm effort responds to the challenges of the DBPs to expand the horizons of medical image analysis. As a result, the Algorithm activities are typically highly experimental, creating new approaches that are rapidly prototyped, tested, and improved. The Engineering effort supports the needs of the Algorithms effort by creating integrated software platforms that support research and eventual deployment of advanced technology. The Engineering team also develops and maintains processes used to build and sustain a large research | ||
− | community. A separate Core oversees operations and maintenance of The NA-MIC Kit, an integrated set of interoperable free open source software (FOSS) | ||
− | packages; developed, supported and deployed using a collaborative, agile, high quality software process. NA-MIC's current DBPs are investigating solutions to problems in patient-specific data analysis in four clinical areas: Atrial Fibrillation, Huntingdon's Disease, Adaptive Radiotherapy for Head and Neck Cancer, and Traumatic Brain Injury. NA-MIC further provides enabling technology and resources to XX collaborative research projects. | ||
* Brief outline indicating strengths of NA-MIC as a national resource | * Brief outline indicating strengths of NA-MIC as a national resource | ||
[take from NA-MIC impact statement, August 2012] | [take from NA-MIC impact statement, August 2012] | ||
− | NA-MIC takes seriously the responsibility of representing US medical imaging software development activities in the | + | NA-MIC takes seriously the responsibility of representing US medical imaging software development activities in the national and international community. Through our collaborations and outreach programs, we have mobilized like-minded scientists to contribute to open source software development for biomedical image analysis. Attracted to the concept of sharing software development resources, leading international groups have adopted NA-MIC’s engineering framework in lieu of undertaking the costly and redundant option of developing their own. These collaborative efforts have greatly raised awareness of the benefits of open science, and as a result, government-funded efforts that complement NA-MIC are now in place in Canada, Germany, Spain, France, and Italy. |
− | national and international community. Through our collaborations and outreach programs, we have mobilized like-minded | ||
− | scientists to contribute to open source software development for biomedical image analysis. Attracted to the concept of | ||
− | sharing software development resources, leading international groups have adopted NA-MIC’s engineering framework in | ||
− | lieu of undertaking the costly and redundant option of developing their own. These collaborative efforts have greatly raised | ||
− | awareness of the benefits of open science, and as a result, government-funded efforts that complement NA-MIC are now | ||
− | in place in Canada, Germany, Spain, France, and Italy. | ||
* Summarize progress made in each Research and Core Project. | * Summarize progress made in each Research and Core Project. | ||
− | Algorithms. The NA-MIC Computer Science Algorithm effort responds to the challenges of the DBPs to | + | Algorithms. The NA-MIC Computer Science Algorithm effort responds to the challenges of the DBPs to expand the horizons of medical image analysis. As a result, the Algorithm activities are typically highly experimental, creating new approaches that are rapidly prototyped, tested, and improved. |
− | expand the horizons of medical image analysis. As a result, the Algorithm activities are typically highly | ||
− | experimental, creating new approaches that are rapidly prototyped, tested, and improved. | ||
− | Engineering. The NA-MIC Computer Science Engineering effort supports the needs of the Algorithms effort by | + | Engineering. The NA-MIC Computer Science Engineering effort supports the needs of the Algorithms effort by creating integrated software platforms that support research and eventual deployment of advanced technology. The Engineering team also develops and maintains processes used to build and sustain a large research community. |
− | creating integrated software platforms that support research and eventual deployment of advanced technology. | ||
− | The Engineering team also develops and maintains processes used to build and sustain a large research | ||
− | community. | ||
− | NA-MIC Kit. The NA-MIC Kit consists of an integrated set of interoperable free open source software (FOSS) | + | NA-MIC Kit. The NA-MIC Kit consists of an integrated set of interoperable free open source software (FOSS) packages; developed, supported and deployed using a collaborative, agile, high quality software process. The NA-MIC Kit has been constructed as a layered architecture to provide a spectrum of capabilities, ranging from compute-intensive algorithms to easy-to-use applications. Hence users and developers can choose to engage the NA-MIC Kit at a variety of levels, including developing extensions which can be readily deployed to the broader biomedical imaging community. |
− | packages; developed, supported and deployed using a collaborative, agile, high quality software process. The | ||
− | NA-MIC Kit has been constructed as a layered architecture to provide a spectrum of capabilities, ranging from | ||
− | compute-intensive algorithms to easy-to-use applications. Hence users and developers can choose to engage | ||
− | the NA-MIC Kit at a variety of levels, including developing extensions which can be readily deployed to the | ||
− | broader biomedical imaging community. | ||
− | In the following subsections we highlight the accomplishments from this reporting period for algorithms, | + | In the following subsections we highlight the accomplishments from this reporting period for algorithms, engineering, and NA-MIC Kit. |
− | engineering, and NA-MIC Kit. | ||
2.1. Algorithms | 2.1. Algorithms | ||
Line 87: | Line 66: | ||
previously, the following are other accomplishments. | previously, the following are other accomplishments. | ||
− | + | * We have begun integrating the SimpleITK module of ITKv4 into Slicer to ensure simple integration capabilities with emerging algorithms. | |
− | capabilities with emerging algorithms. | ||
− | + | * Additional open data support has been added to Slicer such as ultrasound (e.g., video) and 4D (e.g., gated CT) data. | |
− | gated CT) data. | ||
− | + | * We have integrated the extension writing and the documentation generation processes. The documentation created when an extension is written is now automatically ported to a web host for easier access from within and outside of Slicer, ensuring that documentation resources keep up with the rapid pace of development. | |
− | documentation created when an extension is written is now automatically ported to a web host for | ||
− | easier access from within and outside of Slicer, ensuring that documentation resources keep up with | ||
− | the rapid pace of development. | ||
2.3 NA-MIC Kit | 2.3 NA-MIC Kit | ||
− | The NA-MIC Kit is designed to accelerate the pace of research and facilitate clinical evaluation. Along these | + | The NA-MIC Kit is designed to accelerate the pace of research and facilitate clinical evaluation. Along these lines, the past year realized significant milestones toward the creation of a stable research platform, supporting the ability to easily extend and disseminate novel additions, all in the context of a world-wide, broad research community. Beyond the major highlights related to the Slicer4 application platform described in the previous section, the following are a few of the highlights of the past year. |
− | lines, the past year realized significant milestones toward the creation of a stable research platform, supporting | ||
− | the ability to easily extend and disseminate novel additions, all in the context of a world-wide, broad research | ||
− | community. Beyond the major highlights related to the Slicer4 application platform described in the previous | ||
− | section, the following are a few of the highlights of the past year. | ||
− | + | * CMake and its associated software process tools (CTest, CDash, and CPack) are used to build, test and deploy software in a cross-platform manner. CMake continues one of the most well-known pieces of the NA-MIC Kit, with more than 2,000 known downloads per day (as well as being included by various Linux distributions). CMake 2.8.7 was released with NA-MIC support. | |
− | and deploy software in a cross-platform manner. CMake continues one of the most well-known pieces | ||
− | of the NA-MIC Kit, with more than 2,000 known downloads per day (as well as being included by | ||
− | various Linux distributions). CMake 2.8.7 was released with NA-MIC support. | ||
− | + | * CDash Package Manager (CDash 2.0.2) was released with support from NA-MIC. One of the most significant contributions to CDash from NA-MIC was the package upload process. This process enables the many Slicer testing machines to upload the executables and packages created during testing to the main CDash server. This, in turn, allows users to download those testing packages and run additional tests or use them in their research. This complete automation of the test-release cycle is a massive time-saver for the Service core and has greatly reduced the time to discover and resolve bugs and to improve the stability of Slicer. | |
− | significant contributions to CDash from NA-MIC was the package upload process. This process enables | ||
− | the many Slicer testing machines to upload the executables and packages created during testing to the | ||
− | main CDash server. This, in turn, allows users to download those testing packages and run additional | ||
− | tests or use them in their research. This complete automation of the test-release cycle is a massive | ||
− | time-saver for the Service core and has greatly reduced the time to discover and resolve bugs and to | ||
− | improve the stability of Slicer. | ||
− | + | * Significant data integration efforts were completed over the past year. XNAT was greatly improved in its usability and interfaces. DICOM support was greatly enhanced, including the ability to embed Slicer MRML scene files as DICOM lollipops, meaning that Slicer data exchange across the DICOM standard is now possible. In addition, DCMTK was integrated into the NA-MIC Kit, meaning that DICOM support and functionality was greatly increased. | |
− | usability and interfaces. DICOM support was greatly enhanced, including the ability to embed Slicer | ||
− | MRML scene files as DICOM lollipops, meaning that Slicer data exchange across the DICOM standard | ||
− | is now possible. In addition, DCMTK was integrated into the NA-MIC Kit, meaning that DICOM support | ||
− | and functionality was greatly increased. | ||
− | + | * NA-MIC supports and nurtures an extensive biomedical research community. Along these lines it develops integration tools and interfaces with other communities. CTK, supported by NA-MIC funding, | |
− | develops integration tools and interfaces with other communities. CTK, supported by NA-MIC funding, | + | is one such community and interfaces with other open-source toolkits (e.g., MITK from the German Cancer Research Center in Heidelberg, XIP from Siemens, GIMIAS from UPF in Spain, and OpenMAF |
− | is one such community and interfaces with other open-source toolkits (e.g., MITK from the German | + | from U of Bologna). CTK now provides several innovative GUI and DICOM elements that specifically save GUI space, user-time, and developer effort when building custom medical applications. The NAMIC Kit also integrated the BRAINSFit system, a collection of programs for registering images with mutual information based metric. BRAINSFit uses the Slicer execution model framework to define the command line arguments and is fully integrated with Slicer using the module discovery capabilities. |
− | Cancer Research Center in Heidelberg, XIP from Siemens, GIMIAS from UPF in Spain, and OpenMAF | ||
− | from U of Bologna). CTK now provides several innovative GUI and DICOM elements that specifically | ||
− | save GUI space, user-time, and developer effort when building custom medical applications. The NAMIC | ||
− | Kit also integrated the BRAINSFit system, a collection of programs for registering images with | ||
− | mutual information based metric. BRAINSFit uses the Slicer execution model framework to define the | ||
− | command line arguments and is fully integrated with Slicer using the module discovery capabilities. | ||
− | + | * Recent developments are in the process of being integrated into the NA-MIC Kit and the Slicer application platform. | |
− | application platform. | ||
− | + | * The Slicer Catalog allows users to install, uninstall, search, browse, and rank Slicer extensions. This user experience is available from within Slicer and over the web, much like the Android and Apple App Stores. Developers can contribute, update, document, and post screenshots on their modules and receive community feedback. | |
− | user experience is available from within Slicer and over the web, much like the Android and Apple App | ||
− | Stores. Developers can contribute, update, document, and post screenshots on their modules and | ||
− | receive community feedback. | ||
− | + | * The analysis infrastructure for Diffusion Weighted MRI (DWI) IO and visualization has been generalized to be used for other time varying acquisitions like multivolume analysis, dynamic contrast enhanced MRI (DCE), and gated cardiac CT. | |
− | to be used for other time varying acquisitions like multivolume analysis, dynamic contrast enhanced | ||
− | MRI (DCE), and gated cardiac CT. | ||
− | + | * To cover the use of Qt and newer versions of VTK (both part of the NA-MIC Kit), advanced charting and analytics options have been demonstrated in Slicer4, and will be fleshed out in the coming year. | |
− | analytics options have been demonstrated in Slicer4, and will be fleshed out in the coming year. | ||
− | * | + | * Driving Biological Projects: |
− | The Center worked synergistically with the Driving Biological | + | |
− | Projects (DBPs) to achieve fundamental advances in shape representation, shape analysis, groupwise | + | The Center worked synergistically with the Driving Biological Projects (DBPs) to achieve fundamental advances in shape representation, shape analysis, groupwise registration, diffusion estimation, segmentation and quantification, functional estimation, distortion correction, and clustering. |
− | registration, diffusion estimation, segmentation and quantification, functional estimation, distortion correction, | ||
− | and clustering. | ||
Atrial Fibrillation (Rob MacLeod, progress report) | Atrial Fibrillation (Rob MacLeod, progress report) | ||
Line 187: | Line 129: | ||
Progress made by innovation and image analysis , and scientific CoresResearch Cores | Progress made by innovation and image analysis , and scientific CoresResearch Cores | ||
− | The scientific development is driven by 4 DBPs. In | + | The scientific development is driven by 4 DBPs. In addition to activities that sustain the NA-MIC Kit and integrity of the Center’s software infrastructure, NA-MIC has an impressive outreach program that delivers software, data, and innovative science to the broader biomedical community through its publications and training venues. NA-MIC also has instituted a unique validation effort where software developers and end-users participate in hands-on workshops to measure and improve medical image algorithms. |
− | addition to activities that sustain the NA-MIC Kit and integrity of the Center’s software infrastructure, NA-MIC | ||
− | has an impressive outreach program that delivers software, data, and innovative science to the broader biomedical community through its publications and training venues. NA-MIC also has instituted a unique validation effort where software developers and end-users participate in hands-on workshops to measure and improve medical image algorithms. | ||
Required elements: | Required elements: | ||
− | + | Finally, this year saw the release of Slicer version 4.0 and 4.1 (Slicer4) which represents a significant advance in capabilities and underlying technologies. The software was released at RSNA 2011 in | |
− | significant advance in capabilities and underlying technologies. The software was released at RSNA 2011 in | + | November. As in past years, a detailed presentation of current work was made at the All Hands Meeting in Salt Lake City, Utah, January 9-13, 2012, and can be viewed in detail on the NA-MIC Wiki [http://wiki.namic.org/Wiki/index.php/ 2012_Winter_Project_Week]. This represents the 8th Annual Progress Report and second year of the second cycle of funding. The report includes Highlights and Impact statements, individual progress reports from the four DBPs (Atrial Fibrillation, Huntington’s Disease, Adaptive Radiotherapy for Head and Neck Cancer, and Traumatic Brain Injury), a science and technology summary from the Computer Science Core (Algorithms, Engineering, and NA-MIC Kit), and a review of Training activities, including the validation effort. The report concludes with a bibliography of 33 peer-reviewed journal articles and 21 peer-reviewed conference reports and the annual recommendations of the External Advisory Board, which met on January 12, 2012 in Salt Lake City, coincident with Winter Project Week. |
− | November. As in past years, a detailed presentation of current work was made at the All Hands Meeting in Salt | ||
− | Lake City, Utah, January 9-13, 2012, and can be viewed in detail on the NA-MIC Wiki [http://wiki.namic. | ||
− | org/Wiki/index.php/ 2012_Winter_Project_Week]. | ||
− | This represents the 8th Annual Progress Report and second year of the second cycle of funding. The report | ||
− | includes Highlights and Impact statements, individual progress reports from the four DBPs (Atrial Fibrillation, | ||
− | Huntington’s Disease, Adaptive Radiotherapy for Head and Neck Cancer, and Traumatic Brain Injury), a | ||
− | science and technology summary from the Computer Science Core (Algorithms, Engineering, and NA-MIC Kit), | ||
− | and a review of Training activities, including the validation effort. The report concludes with a bibliography of 33 | ||
− | peer-reviewed journal articles and 21 peer-reviewed conference reports and the annual recommendations of | ||
− | the External Advisory Board, which met on January 12, 2012 in Salt Lake City, coincident with Winter Project | ||
− | Week. |
Latest revision as of 21:10, 11 April 2023
Home < Wiki page for 2013 Preliminary DraftBack to NAMIC_Annual_Reports
Required elements of the New Research Progress Template
1. RESEARCH AND RESOURCE METRICS
1A. Summary of Center Progress
- Brief description of overall objectives of NA-MIC
The National Alliance for Medical Image Computing (NA-MIC) is a multi-institutional, interdisciplinary community of computer scientists, software engineers, and medical investigators who share the common goal of improving healthcare through the development of computational tools for the analysis and visualization of medical image data. The Center maintains a robust and flexible infrastructure for developing and applying advanced imaging technologies across a range of important biomedical research disciplines. Our research and development effort is organized around the Computer Science Core, which includes independent teams for Algorithms and Engineering. The Algorithm effort responds to the challenges of the DBPs to expand the horizons of medical image analysis. As a result, the Algorithm activities are typically highly experimental, creating new approaches that are rapidly prototyped, tested, and improved. The Engineering effort supports the needs of the Algorithms effort by creating integrated software platforms that support research and eventual deployment of advanced technology. The Engineering team also develops and maintains processes used to build and sustain a large research community. A separate Core oversees operations and maintenance of The NA-MIC Kit, an integrated set of interoperable free open source software (FOSS) packages; developed, supported and deployed using a collaborative, agile, high quality software process. NA-MIC's current DBPs are investigating solutions to problems in patient-specific data analysis in four clinical areas: Atrial Fibrillation, Huntingdon's Disease, Adaptive Radiotherapy for Head and Neck Cancer, and Traumatic Brain Injury. NA-MIC further provides enabling technology and resources to XX collaborative research projects.
- Brief outline indicating strengths of NA-MIC as a national resource
[take from NA-MIC impact statement, August 2012]
NA-MIC takes seriously the responsibility of representing US medical imaging software development activities in the national and international community. Through our collaborations and outreach programs, we have mobilized like-minded scientists to contribute to open source software development for biomedical image analysis. Attracted to the concept of sharing software development resources, leading international groups have adopted NA-MIC’s engineering framework in lieu of undertaking the costly and redundant option of developing their own. These collaborative efforts have greatly raised awareness of the benefits of open science, and as a result, government-funded efforts that complement NA-MIC are now in place in Canada, Germany, Spain, France, and Italy.
- Summarize progress made in each Research and Core Project.
Algorithms. The NA-MIC Computer Science Algorithm effort responds to the challenges of the DBPs to expand the horizons of medical image analysis. As a result, the Algorithm activities are typically highly experimental, creating new approaches that are rapidly prototyped, tested, and improved.
Engineering. The NA-MIC Computer Science Engineering effort supports the needs of the Algorithms effort by creating integrated software platforms that support research and eventual deployment of advanced technology. The Engineering team also develops and maintains processes used to build and sustain a large research community.
NA-MIC Kit. The NA-MIC Kit consists of an integrated set of interoperable free open source software (FOSS) packages; developed, supported and deployed using a collaborative, agile, high quality software process. The NA-MIC Kit has been constructed as a layered architecture to provide a spectrum of capabilities, ranging from compute-intensive algorithms to easy-to-use applications. Hence users and developers can choose to engage the NA-MIC Kit at a variety of levels, including developing extensions which can be readily deployed to the broader biomedical imaging community.
In the following subsections we highlight the accomplishments from this reporting period for algorithms, engineering, and NA-MIC Kit.
2.1. Algorithms The Algorithms team develops computational methods that support patient-specific analysis of medical images. This effort requires analysis of images that vary significantly from one patient to another, or from one time point to another, presenting distinct challenges to existing state-of-art medical image analysis algorithms. These technical challenges are addressed using four computational approaches: (1) Statistical models of anatomy and pathology; (2) Geometric correspondence; (3) User interactive tools for segmentation; and (4) Longitudinal and time-series analysis. Highlights of these efforts are described in the following sections.
Statistical models of anatomy and pathology. Polina Golland--Please update this section with current progress.
Geometric correspondence
User interactive tools for segmentation
Longitudinal and time series analysis.
2.2 Engineering
The Engineering Team builds bridges between the various NA-MIC cores and ultimately to the wider
biomedical computing community. Working with the Algorithms Team, it deploys leading edge biomedical
computing tools back to the DBPs, which are then used to perform impactful health research. In addition, the
tools developed by the Engineering Team are used to train and disseminate technologies across the research
community. The Team places particular focus on developing sustainable communities through the creation of
open platforms, quality-inducing software processes, and integration to a broad variety of computational tools
and databases. The following describes some of the highlights of the past year's work.
3D Slicer, version 4
Downloads
Atlases
Downloads
Community support for NA-MIC and the various NA-MIC Kit tools continues. The goals of this effort are to
transition new technologies to the wider community, to enable community members to contribute back to Slicer
and the NA-MIC Kit, and to ensure high-quality systems. Beyond some of the support activities mentioned
previously, the following are other accomplishments.
- We have begun integrating the SimpleITK module of ITKv4 into Slicer to ensure simple integration capabilities with emerging algorithms.
- Additional open data support has been added to Slicer such as ultrasound (e.g., video) and 4D (e.g., gated CT) data.
- We have integrated the extension writing and the documentation generation processes. The documentation created when an extension is written is now automatically ported to a web host for easier access from within and outside of Slicer, ensuring that documentation resources keep up with the rapid pace of development.
2.3 NA-MIC Kit
The NA-MIC Kit is designed to accelerate the pace of research and facilitate clinical evaluation. Along these lines, the past year realized significant milestones toward the creation of a stable research platform, supporting the ability to easily extend and disseminate novel additions, all in the context of a world-wide, broad research community. Beyond the major highlights related to the Slicer4 application platform described in the previous section, the following are a few of the highlights of the past year.
- CMake and its associated software process tools (CTest, CDash, and CPack) are used to build, test and deploy software in a cross-platform manner. CMake continues one of the most well-known pieces of the NA-MIC Kit, with more than 2,000 known downloads per day (as well as being included by various Linux distributions). CMake 2.8.7 was released with NA-MIC support.
- CDash Package Manager (CDash 2.0.2) was released with support from NA-MIC. One of the most significant contributions to CDash from NA-MIC was the package upload process. This process enables the many Slicer testing machines to upload the executables and packages created during testing to the main CDash server. This, in turn, allows users to download those testing packages and run additional tests or use them in their research. This complete automation of the test-release cycle is a massive time-saver for the Service core and has greatly reduced the time to discover and resolve bugs and to improve the stability of Slicer.
- Significant data integration efforts were completed over the past year. XNAT was greatly improved in its usability and interfaces. DICOM support was greatly enhanced, including the ability to embed Slicer MRML scene files as DICOM lollipops, meaning that Slicer data exchange across the DICOM standard is now possible. In addition, DCMTK was integrated into the NA-MIC Kit, meaning that DICOM support and functionality was greatly increased.
- NA-MIC supports and nurtures an extensive biomedical research community. Along these lines it develops integration tools and interfaces with other communities. CTK, supported by NA-MIC funding,
is one such community and interfaces with other open-source toolkits (e.g., MITK from the German Cancer Research Center in Heidelberg, XIP from Siemens, GIMIAS from UPF in Spain, and OpenMAF from U of Bologna). CTK now provides several innovative GUI and DICOM elements that specifically save GUI space, user-time, and developer effort when building custom medical applications. The NAMIC Kit also integrated the BRAINSFit system, a collection of programs for registering images with mutual information based metric. BRAINSFit uses the Slicer execution model framework to define the command line arguments and is fully integrated with Slicer using the module discovery capabilities.
- Recent developments are in the process of being integrated into the NA-MIC Kit and the Slicer application platform.
- The Slicer Catalog allows users to install, uninstall, search, browse, and rank Slicer extensions. This user experience is available from within Slicer and over the web, much like the Android and Apple App Stores. Developers can contribute, update, document, and post screenshots on their modules and receive community feedback.
- The analysis infrastructure for Diffusion Weighted MRI (DWI) IO and visualization has been generalized to be used for other time varying acquisitions like multivolume analysis, dynamic contrast enhanced MRI (DCE), and gated cardiac CT.
- To cover the use of Qt and newer versions of VTK (both part of the NA-MIC Kit), advanced charting and analytics options have been demonstrated in Slicer4, and will be fleshed out in the coming year.
- Driving Biological Projects:
The Center worked synergistically with the Driving Biological Projects (DBPs) to achieve fundamental advances in shape representation, shape analysis, groupwise registration, diffusion estimation, segmentation and quantification, functional estimation, distortion correction, and clustering.
Atrial Fibrillation (Rob MacLeod, progress report) Huntingdon's Disease (Hans Johnson, progress report) Adaptive Radiotherapy for Head and Neck Cancer (Greg Sharp, progress report) Traumatic Brain Injury (Jack Van Horn, progress report0
NA-MIC further provides enabling technology and resources to XX collaborative research projects.
- Discuss at least 3 Collaborative Research Projects (these may include collaborating R01/R21s or other projects not directly funded by the Center's NCBC grant, but using Center tools or algorithms in a substantial and enabling manner.
Collaboration 1: TBA Collaboration 2: TBA Collaboration 3: TBA
- Brief description of new training and outreach activities conducted during reporting interval (7/1/2012 - 6/30/2013). Provide web-links if available.
Sonia Pujol: Please update and revised. This year NA-MIC hosted XX workshops and courses at national universities and international venues, providing training and exposure to medical researchers in 3D Slicer and other NA-MIC technologies. NA-MIC also xxxx launched the first DTI Tractography Challenge for Neurosurgical Planning at the XXth International Conference on Medical Image Computing and Computer Assisted Intervention (MICCAI 2011) conference in Toronto, Canada, demonstrating its continued commitment to validation. The purpose of the validation effort is to assess the performance of NA-MIC algorithms in a variety of settings.
- Impact of Center (i) on biomedical research and research training and outreach at our institution (BWH) and (i) broader scientific community. Institutional benefits might include, organization of special courses and meetings, attraction of students, and faculty participation. Scientific community benefits may include software released, workshops organized, collaborations established, service performed, technology developed, and technology disseminated through patents, publications, peer-reviewed citations of center collaborations by non-center investigators, and personnel trained.
Provide a Center Summary Table
Progress made by innovation and image analysis , and scientific CoresResearch Cores
The scientific development is driven by 4 DBPs. In addition to activities that sustain the NA-MIC Kit and integrity of the Center’s software infrastructure, NA-MIC has an impressive outreach program that delivers software, data, and innovative science to the broader biomedical community through its publications and training venues. NA-MIC also has instituted a unique validation effort where software developers and end-users participate in hands-on workshops to measure and improve medical image algorithms.
Required elements:
Finally, this year saw the release of Slicer version 4.0 and 4.1 (Slicer4) which represents a significant advance in capabilities and underlying technologies. The software was released at RSNA 2011 in November. As in past years, a detailed presentation of current work was made at the All Hands Meeting in Salt Lake City, Utah, January 9-13, 2012, and can be viewed in detail on the NA-MIC Wiki 2012_Winter_Project_Week. This represents the 8th Annual Progress Report and second year of the second cycle of funding. The report includes Highlights and Impact statements, individual progress reports from the four DBPs (Atrial Fibrillation, Huntington’s Disease, Adaptive Radiotherapy for Head and Neck Cancer, and Traumatic Brain Injury), a science and technology summary from the Computer Science Core (Algorithms, Engineering, and NA-MIC Kit), and a review of Training activities, including the validation effort. The report concludes with a bibliography of 33 peer-reviewed journal articles and 21 peer-reviewed conference reports and the annual recommendations of the External Advisory Board, which met on January 12, 2012 in Salt Lake City, coincident with Winter Project Week.