Translational Molecular Imaging Computing: Advances in Theories and Applications
1Beijing University of Technology, Beijing, China
2Rensselaer Polytechnic Institute, Troy, USA
3Technical University of Munich, Munich, Germany
4Xidian University, Xi'an, China
5University of North Carolina at Chapel Hill, Chapel Hill, USA
Translational Molecular Imaging Computing: Advances in Theories and Applications
Description
Molecular imaging is capable of revealing cellular and molecular features of biology and disease in vivo, meeting the increasing needs in noninvasive understanding of biological processes. Computational technologies are essential for the development of cutting-edge molecular imaging. During the past decades, the advancement of molecular imaging computing has been well recognized and continuously extends the application potential of molecular imaging.
With this in mind we are editing this special issue, providing a forum for researchers to summarize and discuss the latest advances of computational technologies in molecular imaging including theories and applications. We encourage authors to submit original research papers as well as review articles. New developments of both theoretical study and preclinical/clinical applications of molecular imaging are welcome. Computational approaches for multimodality imaging are of great interest.
Potential topics include, but are not limited to:
- Mathematical and computational modeling of molecular imaging
- Reconstruction methods of CT, MRI, PET, SPECT, and optical molecular imaging
- Numerical methods to simulate imaging signal in tissues
- Sparse representation in molecular imaging
- Multimodality fusion imaging
- Big data strategies for molecular imaging processing (i.e., cloud computation)
- Translational molecular imaging computing for personalized medicine
- Advanced applications in preclinical and clinical research (e.g., for oncology and neurology)
- New molecular imaging modalities and techniques