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https://fsl.fmrib.ox.ac.uk/fsl/fslwiki/XTRACT
Software command line tool for automated tractography. Standardised protocols for automated tractography in human and macaque brain.
Proper citation: XTRACT (RRID:SCR_024933) Copy
https://fsl.fmrib.ox.ac.uk/fsl/fslwiki/verbena
Software tool for quantification of perfusion and other haemodynamic parameters from Dynamic Susceptibility Contrast perfusion MRI of the brain.
Proper citation: VERBENA (RRID:SCR_024919) Copy
https://support.inscopix.com/search/site/Mosaic
Mosaic software features apps designed to help you derive deeper insights from videos of large scale circuit dynamics by Inscopix Inc.
Proper citation: Mosaic (RRID:SCR_017408) Copy
Software tool for neuronal recording in intact brain.
Proper citation: Autopatcher (RRID:SCR_017464) Copy
https://github.com/dorianps/LESYMAP
Software R package to conduct lesion-to-symptom mapping from human MRI data.Takes lesion maps and cognitive performance scores from patients with stroke, and maps brain areas responsible for cognitive deficit.
Proper citation: LESYMAP (RRID:SCR_017967) Copy
http://surfer.nmr.mgh.harvard.edu/fswiki/Tracula
Software tool developed for automatically reconstructing a set of major white matter pathways in the brain from diffusion weighted images using probabilistic tractography. This method utilizes prior information on the anatomy of the pathways from a set of training subjects. By incorporating this prior knowledge in the reconstruction procedure, our method obviates the need for manual intervention with the tract solutions at a later stage and thus facilitates the application of tractography to large studies. The trac-all script is used to preprocess raw diffusion data (correcting for eddy current distortion and B0 field inhomogenities), register them to common spaces, model and reconstruct major white matter pathways (included in the atlas) without any manual intervention. trac-all may be used to execute all the above steps or parts of it depending on the dataset and user''''s preference for analyzing diffusion data. Alternatively, scripts exist to execute chunks of each processing pipeline, and individual commands may be run to execute a single processing step. To explore all the options in running trac-all please refer to the trac-all wiki. In order to use this script to reconstruct tracts in Diffusion images, all the subjects in the dataset must have Freesurfer Recons.
Proper citation: TRACULA (RRID:SCR_013152) Copy
https://github.com/mitragithub/Registration
Software package to align brain slice images in atlas free manner.
Proper citation: Registration Software Mitra Lab (RRID:SCR_018353) Copy
https://github.com/ABCD-STUDY/ABCDreport
Software application as a simple system to review study progress. Used in ABCD study.
Proper citation: ABCDreport (RRID:SCR_016030) Copy
Project whose goal is to improve health care and lessen the global burden of TBI through the discovery of causal relationships between treatments and clinically meaningful outcomes. InTBIR seeks to encourage well-designed, hypothesis-driven studies that include the collection of high quality data followed by rigorous statistical analysis.
Proper citation: International Initiative for Traumatic Brain Injury Research (RRID:SCR_016237) Copy
https://doi.org/10.1016/j.neuroimage.2018.07.046
Software package for simulation framework and codes for estimating nonparametric Granger causality. Used to study brain functions.
Proper citation: nonparametricGGC_toolbox (RRID:SCR_016539) Copy
http://www.brainsimagebank.ac.uk
A searchable collection of anonymised images and associated clinical data. It includes normal individuals at all ages (from prenatal to old age). The image bank contains integrated data sets already collected as part of research studies which include control subjects. New data is added as they become available.
Proper citation: BRAINS Imagebank (RRID:SCR_014576) Copy
https://github.com/Frederik-D-Weber/cosleep
Software Python tool for sleep EEG analysis. Used for Closed and Open loop in Slow Ocillations, Sleep Stimulation in Auditory or Recording in full PSG using OpenBCI Cyton.
Proper citation: COsleep (RRID:SCR_017053) Copy
https://github.com/zuoxinian/CCS
Software tool for multimodal human brain imaging data analysis. Computational pipeline for discovery science of human brain connectomes at macroscale with multimodal magnetic resonance imaging technologies.
Proper citation: Connectome Computation System (RRID:SCR_017342) Copy
https://github.com/cwatson/braingraph/
Software R package for performing graph theory analyses of brain MRI data.
Proper citation: brainGraph (RRID:SCR_017260) Copy
https://github.com/Mark-Kramer/Seizure-Waves
Analysis and modeling code for waves of seizure activity.
Proper citation: Seizure-Waves (RRID:SCR_017455) Copy
http://www.brainarchitecture.org/mouse-home
An atlas project whose goal is to enerate brainwide maps of inter-regional neural connectivity that specify the inputs and outputs of every brain region, at a "mesoscopic" level of analysis. A 3D injection viewer is used to view the mouse brain. To determine the outputs of a brain region, anterograde tracers are used which are taken up by neurons locally ("the input"), then transported actively down the axons to the "output regions." The whole brain is then sliced thinly, and each slice is digitally imaged. These 2-D images are reconstructed in 3D. The majority of the resulting 3-D brain image is unlabeled. Only the injected region and its output regions have tracer in them, allowing for identification of this small fraction of the connectivity map. This procedure is repeated identically, to account for individual variability. To determine the inputs to the same brain region as above, a retrograde tracer is injected in the same stereotaxic location ("the input"), and the process is repeated. In order to accumulate data from different mice (each of whom has a slightly different brain shape and size), 3-D spatial normalization is performed using registration algorithms. These gigapixel images of whole-brain sections can be zoomed to show individual neurons and their processes, providing a "virtual microscope." Each sampled brain is represented in about 500 images, each image showing an optical section through a 20 micron-thick slice of brain tissue. A multi-resolution viewer permits users to journey through each brain, following the pathways taken through three-dimensional brain space by tracer-labeled neuronal pathways. A key point is that at the mid-range "mesoscopic" scale, the team expects to assemble a picture of connections that are stereotypical and probably genetically determined in a species-specific manner. By dividing the volume of a hemisphere of the mouse brain into 250 equidistant, predefined grid-points, and administering four different kinds of tracer injections at each grid point -- in different animals of the same sex and age a complete wiring diagram that will be stitched together in "shotgun" fashion from the full dataset.
Proper citation: Mouse Brain Architecture Project (RRID:SCR_004683) Copy
RIKEN Brain Science Institute (BSI) has a mission to produce innovative research and technology leading to scientific discoveries of the brain. In addition, BSI aims to develop domestic and international brain researchers by creating an environment that will integrate various intellectual disciplines and from that convergence find solutions that will ultimately benefit society in the realms of medicine, engineering, business, and education. In striving toward this goal, BSI has become a leading international center for brain research with a reputation for discovery, innovation, training, and globalization of the scientific enterprise. Brain science is valuable not only for the advancement of science but also because it can greatly impact our society and economy. To meet these expectations, the Brain Science Institute (BSI) was established in 1997 as part of RIKEN, an independent research institution supported by the Japanese government.
Proper citation: RIKEN Brain Science Institute (RRID:SCR_004796) Copy
A non-profit organization that promotes research on hearing and balance disorders. The Registry database allows researchers to perform simple searches to locate specimens of interest. The results show the laboratories where specimens that match the query are located. Investigators should contact the individual laboratories for studying the specimens or for access to the sections. The Registry also serves the public and the scientific community through the dissemination of public information on temporal bone donation and research, enrollment of temporal bone donors, publication of The Registry, a newsletter for researchers, conservation of existing human temporal bone collections, and professional educational activities for physicians and scientists.
Proper citation: National Temporal Bone Pathology Resource Registry (RRID:SCR_004705) Copy
https://www.bannerhealth.com/research/locations/sun-health-institute/programs/body-donation
THIS RESOURCE IS NO LONGER IN SERVICE. Documented on January 11, 2023. An autopsy-based, research-devoted brain bank, biobank and biospecimen bank that derives its human donors from the Arizona Study of Aging and Neurodegenerative Disease (AZSAND), a longitudinal clinicopathological study of the health and diseases of elderly volunteers living in Maricopa county and metropolitan Phoenix, Arizona. Their function is studied during life and their organs and tissue after death. To date, they have concentrated their studies on Alzheimer's disease, Parkinson's disease, heart disease and cancer. They share the banked tissue, biomaterials and biospecimens with qualified researchers worldwide. Registrants with suitable scientific credentials will be allowed access to a database of available tissue linked to relevant clinical information, and will allow tissue requests to be initiated.
Proper citation: Brain and Body Donation Program (RRID:SCR_004822) Copy
National Brain Tumor Society (NBTS) is a nonprofit organization committed to finding a cure for brain tumors. We aggressively drive strategic research, advocate for public policies that meet the critical needs of the brain tumor community, and provide patient information. Headquartered in Watertown, Massachusetts, with offices in San Francisco, California and Wilmington, Delaware, we host activities throughout the United States. Formed in 2008 by the merger of two leading organizations that had served the brain tumor community, the National Brain Tumor Foundation and the Brain Tumor Society, the National Brain Tumor Society is now the largest brain tumor nonprofit organization in the country. Both legacy organizations had been formed in the 1980s by parents and other people who were committed to increasing both research funding and access to resources specific to brain tumors. In 2010, the Kelly Heinz-Grundner Foundation, a Delaware-based organization, joined NBTS as a wholly-owned subsidiary. Founded in 2005, after the death of Kelly Heinz-Grundner to a brain tumor, the group has contributed to NBTS''s efforts to pursue research and public policies that benefit the brain tumor community. NBTS grant programs are effective for academic researchers, inclusive of industry expertise, and promising for the patient community. All funding is open to both the domestic and international research communities. The Innovation Research Grant Program supports catalytic transformative projects that will significantly move the field forward. These may include out-of-the-box projects or research that is critical to move therapies down the pipeline. Research that represents an incremental advance is not considered innovative. NBTS will accept Innovation Letters of Intent throughout the year. Researchers in academic or industry labs and at all stages of their career may be funded through this program.
Proper citation: National Brain Tumor Society (RRID:SCR_004744) Copy
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