A Comprehensive Framework to Capture the Arcana of Neuroimaging Analysis
Autor: | Thomas G. Close, Phillip G. D. Ward, Zhaolin Chen, Wojtek Goscinski, Francesco Sforazzini, Gary F. Egan |
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Rok vydání: | 2019 |
Předmět: |
Data Analysis
Workstation Computer science Information Storage and Retrieval Neuroimaging Reuse computer.software_genre 050105 experimental psychology Workflow law.invention 03 medical and health sciences 0302 clinical medicine Software law Humans 0501 psychology and cognitive sciences Implementation Reusability computer.programming_language business.industry General Neuroscience 05 social sciences Brain Python (programming language) Magnetic Resonance Imaging Software framework Software engineering business computer 030217 neurology & neurosurgery Information Systems |
Zdroj: | Neuroinformatics. 18:109-129 |
ISSN: | 1559-0089 1539-2791 |
DOI: | 10.1007/s12021-019-09430-1 |
Popis: | Mastering the “arcana of neuroimaging analysis”, the obscure knowledge required to apply an appropriate combination of software tools and parameters to analyse a given neuroimaging dataset, is a time consuming process. Therefore, it is not typically feasible to invest the additional effort required generalise workflow implementations to accommodate for the various acquisition parameters, data storage conventions and computing environments in use at different research sites, limiting the reusability of published workflows.We present a novel software framework, Abstraction of Repository-Centric ANAlysis (Arcana), which enables the development of complex, “end-to-end” workflows that are adaptable to new analyses and portable to a wide range of computing infrastructures. Analysis templates for specific image types (e.g. MRI contrast) are implemented as Python classes, which define a range of potential derivatives and analysis methods. Arcana retrieves data from imaging repositories, which can be BIDS datasets, XNAT instances or plain directories, and stores selected derivatives and associated provenance back into a repository for reuse by subsequent analyses. Workflows are constructed using Nipype and can be executed on local workstations or in high performance computing environments. Generic analysis methods can be consolidated within common base classes to facilitate code-reuse and collaborative development, which can be specialised for study-specific requirements via class inheritance. Arcana provides a framework in which to develop unified neuroimaging workflows that can be reused across a wide range of research studies and sites. |
Databáze: | OpenAIRE |
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