Efficient, Distributed and Interactive Neuroimaging Data Analysis Using the LONI Pipeline.
Ivo D. Dinov,John D. Van Horn,Kamen Lozev,Rico Magsipoc,Petros Petrosyan,Zhizhong Liu,Allan MacKenzie-Graham,Paul Eggert,Douglas Stott Parker,Arthur W. Toga +9 more
TL;DR: Using brain imaging data from the Alzheimer's Disease Neuroimaging Initiative, the LONI Pipeline is demonstrated integration of disparate resources, graphical construction of complex neuroimaging analysis protocols and distributed parallel computing.
read more
Abstract: The LONI Pipeline is a graphical environment for construction, validation and execution of advanced neuroimaging data analysis protocols (Rex et al, 2003) It enables automated data format conversion, allows Grid utilization, facilitates data provenance, and provides a significant library of computational tools There are two main advantages of the LONI Pipeline over other graphical analysis workflow architectures It is built as a distributed Grid computing environment and permits efficient tool integration, protocol validation and broad resource distribution To integrate existing data and computational tools within the LONI Pipeline environment, no modification of the resources themselves is required The LONI Pipeline provides several types of process submissions based on the underlying server hardware infrastructure Only workflow instructions and references to data, executable scripts and binary instructions are stored within the LONI Pipeline environment This makes it portable, computationally efficient, distributed and independent of the individual binary processes involved in pipeline data-analysis workflows We have expanded the LONI Pipeline (V42) to include server-to-server (peer-to-peer) communication and a 3-tier failover infrastructure (Grid hardware, Sun Grid Engine/Distributed Resource Management Application API middleware, and the Pipeline server) Additionally, the LONI Pipeline provides three layers of background-server executions for all users/sites/systems These new LONI Pipeline features facilitate resource-interoperability, decentralized computing, construction and validation of efficient and robust neuroimaging data-analysis workflows Using brain imaging data from the Alzheimer's Disease Neuroimaging Initiative (Mueller et al, 2005), we demonstrate integration of disparate resources, graphical construction of complex neuroimaging analysis protocols and distributed parallel computing The LONI Pipeline, its features, specifications, documentation and usage are available online (http://Pipelineloniuclaedu)
read more
Chat with Paper
AI Agents for this Paper
Find similar papers on Google Scholar, PubMed and Arxiv
Write a critical review of this paper
Analyze citations of this paper to find unaddressed research gaps
Citations
Nipype: A Flexible, Lightweight and Extensible Neuroimaging Data Processing Framework in Python
Krzysztof J. Gorgolewski,Christopher Burns,Cindee Madison,Dav Clark,Yaroslav O. Halchenko,Michael Waskom,Satrajit S. Ghosh +6 more
TL;DR: Nipype solves issues by providing Interfaces to existing neuroimaging software with uniform usage semantics and by facilitating interaction between these packages using Workflows, and provides an environment that encourages interactive exploration of algorithms, eases the design of Workflows within and between packages, and reduces the learning Curve.
Best practices in data analysis and sharing in neuroimaging using MRI.
Thomas E. Nichols,Samir Das,Samir Das,Simon B. Eickhoff,Simon B. Eickhoff,Alan C. Evans,Alan C. Evans,Tristan Glatard,Tristan Glatard,Michael Hanke,Nikolaus Kriegeskorte,Michael P. Milham,Michael P. Milham,Russell A. Poldrack,Jean-Baptiste Poline,Erika Proal,Bertrand Thirion,David C. Van Essen,Tonya White,B.T. Thomas Yeo +19 more
TL;DR: Intentions from developing a set of recommendations on behalf of the Organization for Human Brain Mapping are described and barriers that impede these practices are identified, including how the discipline must change to fully exploit the potential of the world's neuroimaging data.
PANDA: a pipeline toolbox for analyzing brain diffusion images
TL;DR: A MATLAB toolbox named “Pipeline for Analyzing braiN Diffusion imAges” (PANDA) is developed, expected to substantially simplify the image processing of dMRI datasets and facilitate human structural connectome studies.
690
Nipype: A Flexible, Lightweight and Extensible Neuroimaging Data Processing Framework in Python
Krzysztof J. Gorgolewski,Christopher Burns,Cindee Madison,Dav Clark,Yaroslav O. Halchenko,Michael Waskom,Satrajit S. Ghosh +6 more
- 01 Aug 2011
TL;DR: Neuroimaging in Python: Pipelines and interfaces as discussed by the authors is an open-source, community-developed, software package and scriptable library for neuroimaging analysis using Python.
590
The connectome mapper: an open-source processing pipeline to map connectomes with MRI.
Alessandro Daducci,Stephan Gerhard,Alessandra Griffa,Alessandra Griffa,Alia Lemkaddem,Leila Cammoun,Xavier Gigandet,Reto Meuli,Patric Hagmann,Patric Hagmann,Jean-Philippe Thiran,Jean-Philippe Thiran +11 more
TL;DR: The Connectome Mapper is presented, a software pipeline aimed at helping researchers through the tedious process of organising, processing and analysing diffusion MRI data to perform global brain connectivity analyses.
References
Scientific Workflow Management and the Kepler System
Bertram Ludäscher,Bertram Ludäscher,Ilkay Altintas,Chad Berkley,Dan Higgins,Efrat Jaeger,Matthew B. Jones,Edward A. Lee,Jing Tao,Yang Zhao +9 more
TL;DR: Kepler as mentioned in this paper is a scientific workflow system, which is currently under development across a number of scientific data management projects and is a community-driven, open source project, and always welcome related projects and new contributors to join.
Automated Image Registration: I. General Methods and Intrasubject, Intramodality Validation
TL;DR: The registration algorithm described is a robust and flexible tool that can be used to address a variety of image registration problems and can be tailored to meet different needs by optimizing tradeoffs between speed and accuracy.
A survey of data provenance in e-science
Yogesh Simmhan,Beth Plale,Dennis Gannon +2 more
- 01 Sep 2005
TL;DR: The main aspect of the taxonomy categorizes provenance systems based on why they record provenance, what they describe, how they represent and storeprovenance, and ways to disseminate it.
1.3K
Ways toward an early diagnosis in Alzheimer’s disease: The Alzheimer’s Disease Neuroimaging Initiative (ADNI)
Susanne G. Mueller,Susanne G. Mueller,Michael W. Weiner,Michael W. Weiner,Leon J. Thal,Ronald C. Petersen,Clifford R. Jack,William J. Jagust,John Q. Trojanowski,Arthur W. Toga,Laurel A. Beckett +10 more
TL;DR: There is increasing evidence that a combination of currently existing neuroimaging and cerebrospinal fluid (CSF) and blood biomarkers can provide important complementary information and thus contribute to a more accurate and earlier diagnosis of AD.
Neuroimaging and neuropathological studies of depression: implications for the cognitive-emotional features of mood disorders.
TL;DR: Data suggest a role for dysfunction within the prefrontal cortical and striatal systems that normally modulate limbic and brainstem structures involved in mediating emotional behavior in the pathogenesis of depressive symptoms.
1.2K