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http://www.braintumorkids.org/
Established in 1983 in Atlanta, GA, the Brain Tumor Foundation for Children (BTFC) was the first nonprofit organization in the United States to focus on pediatric brain tumor disease. The mission of the Brain Tumor Foundation for Children is to provide financial assistance, social support, and information for families of children with brain and spinal cord tumors; fund research projects that improve treatment options and search for a cure; and raise public awareness of the disease and advocate on behalf of children who are affected.
Proper citation: Brain Tumor Foundation For Children (RRID:SCR_004735) Copy
The Brain Tumor Action Network is a not-for-profit 501(c)(3) organization established to bring awareness to the general public about brain tumors and to educate and empower brain tumor survivors, their families and friends. We foster grassroots advocacy on federal and state legislative issues affecting brain tumor survivors, their families and friends by providing information on brain tumor-related public issues and effective advocacy. BTAN has the following goals: * To encourage those living with brain tumors, their families and friends to become advocates for brain tumor awareness. * To foster grassroots advocacy on federal and state legislative issues affecting brain tumor survivors, their families and friends by providing information (and training) on brain tumor related public issues and effective advocacy. * To work independently and in collaboration with other brain tumor related organizations on behalf of the brain tumor community family. * To increase brain tumor awareness nationally through the Hidden Under Our Hats, National Brain Tumor Awareness Project in Washington, DC and at various treatment centers, conferences and fund raisers. * To raise funds to support specific research projects. * To create a PILOT respite care program for brain tumor survivors and their families at Moffitt Cancer Center & Research Institute (Tampa, FL). The respite care fund would assist brain tumor patients and their family members with additional care and support from home health care workers.
Proper citation: Brain Tumor Action Network (RRID:SCR_004733) Copy
An interactive, visual database containing more than 350 small molecule pathways found in humans. More than 2/3 of these pathways (>280) are not found in any other pathway database. SMPDB is designed specifically to support pathway elucidation and pathway discovery in metabolomics, transcriptomics, proteomics and systems biology. It is able to do so, in part, by providing exquisitely detailed, fully searchable, hyperlinked diagrams of human metabolic pathways, metabolic disease pathways, metabolite signaling pathways and drug-action pathways. All SMPDB pathways include information on the relevant organs, subcellular compartments, protein cofactors, protein locations, metabolite locations, chemical structures and protein quaternary structures. Each small molecule is hyperlinked to detailed descriptions contained in the HMDB or DrugBank and each protein or enzyme complex is hyperlinked to UniProt. All SMPDB pathways are accompanied with detailed descriptions and references, providing an overview of the pathway, condition or processes depicted in each diagram. The database is easily browsed and supports full text, sequence and chemical structure searching. Users may query SMPDB with lists of metabolite names, drug names, genes / protein names, SwissProt IDs, GenBank IDs, Affymetrix IDs or Agilent microarray IDs. These queries will produce lists of matching pathways and highlight the matching molecules on each of the pathway diagrams. Gene, metabolite and protein concentration data can also be visualized through SMPDB''s mapping interface. All of SMPDB''s images, image maps, descriptions and tables are downloadable.
Proper citation: Small Molecule Pathway Database (RRID:SCR_004844) Copy
http://www.pencerbraintrust.com/
The Gerry & Nancy Pencer Brain Trust is a not-for-profit organization with a mandate to make a difference in the quality of life of people living with brain tumors. This registered charity is the primary source of funding for The Gerry & Nancy Pencer Brain Tumor Centre, and carries out annual fundraising events to support its'' ongoing research and patient care activities. The Gerry & Nancy Pencer Brain Tumor Centre is located in Toronto, Canada at the world-renowned Princess Margaret Hospital. The Centre provides multidisciplinary care, treatment, support, and education for brain tumor patients and their families, and promotes brain tumor research in the hopes of one day finding a cure for brain cancer. All of this is made possible through your very generous donations.
Proper citation: Gerry and Nancy Pencer Brain Trust (RRID:SCR_004762) Copy
The Pediatric Brain Tumor Foundation (PBTF) is a nonprofit organization dedicated to eradicating childhood brain tumors and providing support to families. It is a 501(c)(3) nonprofit charitable organization that seeks to * find the cause of and cure for childhood brain tumors by supporting medical research * increase public awareness about the severity and prevalence of childhood brain tumors * aid in the early detection and treatment of childhood brain tumors * support a national database on all primary brain tumors * provide educational and emotional support for children and families affected by this life-threatening disease. As the world''s largest non-governmental source of funding for childhood brain tumor research, we''re dedicated to not only eradicating this disease, but to providing support to families. Our educational resources deliver comfort and hope to families in need of information, and our college scholarship program gives brain tumor survivors a boost for the future. Through our efforts to raise public awareness, more attention has been focused on this deadly disease. Whether addressing congressional briefings or funding international conferences, the PBTF is an unwavering advocate. Together, we''re making a difference in the lives of children with brain tumors. And with your continued help, we will cure the kids!
Proper citation: Pediatric Brain Tumor Foundation (RRID:SCR_004755) Copy
The Oklahoma Brain Tumor Foundation (OKBTF) is a nonprofit organization that provides education, advocacy and support for Oklahomans with brain tumors and their families to improve their quality of life and help find a cure. Founded by Nancy Thomason after the death of her son Cade Thomason to a brain stem PNET tumor on February 17, 2000, she vowed to fight the disease in honor and memory of her son Cade. OKBTF is dedicated to meeting the needs of Oklahoma families, caregivers and patients affected by primary brain or central nervous system tumors. We work to provide for needs through education, advocacy, research and service. Whatever your needs, whether financial, physical, mental or spiritual, we will work with you to fight the battle. Here you will find many of the services we offer in support of families just like yours, who are confused, hurting and just wanting straight answers. Feel free to browse around, get to know us, see what we are doing to help and send us your comments or questions... We are here for you.
Proper citation: Oklahoma Brain Tumor Foundation (RRID:SCR_004748) Copy
http://spot.colorado.edu/~dubin/talks/brodmann/brodmann.html
Reference atlas of Brodmann Areas in the Human Brain with an Emphasis on Vision and Language. Other Pages include: Flat Brodmann Maps, Brodmann Area Names (with locational Descriptions), Flat Visual Area Maps, Language Areas, PopUp Gyri Maps
Proper citation: Brodmann Areas in the Human Brain with an Emphasis on Vision and Language (RRID:SCR_004857) Copy
Common repository for diverse human microbiome datsets and minimum reporting standards for Common Fund Human Microbiome Project.
Proper citation: HMP Data Analysis and Coordination Center (RRID:SCR_004919) Copy
http://vision.ucsf.edu/hortonlab/index.html
Devise better ways to prevent and treat vision loss due to amblyopia and strabismus, and to advance medical science by understanding the human visual system. Various Images, Videos and Talks related to the research are available. In the Laboratory for Visual Neuroscience at the University of California, San Francisco, we are seeking to discover how visual perception occurs in the human brain. The function of the visual system is to guide our behavior by providing an efficient means for the rapid assimilation of information from the environment. As we navigate through our surroundings, a continuous stream of light images impinges on our eyes. In the back of each eye a light-sensitive tissue, the retina, converts patterns of light energy into electrical discharges known as action potentials. These signals are conveyed along the axons of retinal ganglion cells to the lateral geniculate body, a relay nucleus in the thalamus. Most of the output of the lateral geniculate body is relayed directly to the primary visual cortex (striate cortex, V1), and then to surrounding visual association areas. To understand the function of the visual pathways, our research is focused on 5 major themes: * Organization of Primary Visual Cortex * Mapping of Extrastriate Visual Cortex * Amblyopia and Visual Development * Strabismus and Visual Suppression * The Human Visual Cortex
Proper citation: UCSF Laboratory for Visual Neuroscience (RRID:SCR_004913) Copy
There are a lot of fine blogs out there covering the avalance of current neuroscience research. With this blog Thomas Rams��y & Martin Skov want to highlight the many consequences of this growing understanding of the human brain. We are especially interested in two types of consequences: Tinkering with the brain and What is it like to be a human being? * Tinkering with the brain: First and foremost, with an understanding of how the brain works comes the possibility of tinkering with it. We already use billions of dollars every year on psychopharmocologia trying to treat depression, schizophrenia, obsessive-compulsive disorder and other mental diseases. But should we also use our knowledge of the brain to treat undesirable mental traits such as pedophilia or sociopathy? And what about enhancing normal brains? Clearly, evolution hasn''t endowed us with the most efficient brain imaginable. Shouldn''t we do something about its many shortcomings? * What is it like to be a human being?: Secondly, our view of human behavior is sure to change with our improved understanding of the human brain. Our knowledge of core human faculties such as language, social reasoning, aesthetics, and economics is already being challenged by modern neuroscience, yielding multiple hard questions. Do we have a free will? Is the mind innate or plastic? If people are not responsible for their actions (since all actions are caused by blind molecular processes) does our legal system still make sense? In short, will modern neuroscience come to completely redefine human nature? We try to discuss contemporary research literature, not just news reports. Although we will occasionally also target popular science reports, since we believe they play an important role in dissemining lessons from the lab. And in the future we plan to also post interviews with interesting researchers, as well as link to our own publications in journals and books. Additionally, the latest and most important books in the multidisciplinary field of neuroscience, cognition, psychology, ethics and economics are presented.
Proper citation: BrainEthics (RRID:SCR_005530) Copy
http://hnrc.hivresearch.ucsd.edu/
The mission of the HIV Neurobehavioral Research Center (HNRC) is to increase our understanding of how HIV and other diseases affect the human nervous system. The HNRC conducts local, national, and international research devoted to advancing our knowledge of the prevention, diagnosis and treatment of HIV-related diseases as they affect the brain and nervous system, and result in impairment of everyday functioning. Research areas of the Center include: - The incidence, prevalence, and features of neurocognitive impairment caused by HIV - The attributes of the virus, host, and host-virus interactions that determine the presentation of HIV-associated neurocognitive disorders - Possible molecular and cellular mechanisms of nervous system impairment, including the mechanisms by which host-virus factors generate neural injury and neurobehavioral disorders - The cerebrospinal fluid (CSF) as a window on CNS events * The role of co-pathogens and comorbidities in neuroAIDS (e.g., hepatitis C infection, methamphetamine abuse) - Real life implications of neurocognitive impairment in terms of work, daily life, and survival - The effects of HIV disease and neurocognitive impairment on family and social adaptation - NeuroAIDS in resource limited settings - Treatments for neurocognitive impairment and behavioral interventions HNRC also has a Developmental Grants Program (DGP), the primary goal of which is the initiation of innovative studies by junior faculty and trainees at UCSD or affiliated institutions with the following objectives: 1. Recruitment to neuroAIDS research of new investigators or established investigators without prior experience in the field; 2. Generation and pilot testing of new research initiatives; 3. Fostering collaboration among investigators from throughout Southern California. The program provides to qualified investigators and trainees any appropriate combination of the following forms of support: 1. Small, 1-2 year grants to support pilot studies; 2. Access to HNRC core resources such as data, specimens, participants, equipment, administrative support, or expert consultation and technical assistance. Lastly, The the NHRC Mentored Investigator Program recruits, supports, and follows the progress of graduate students, postdoctoral (Ph.D. or M.D.) fellows, and junior faculty in disciplines relevant to HNRC research. The HNRC is committed to tailoring our training opportunities to the backgrounds and interests of candidates from a variety of disciplines who join us with various levels of training and experience in research. We have and will continue to provide training and mentoring of medical students, doctoral students in clinical psychology, and postdoctoral fellows in Medicine, Psychiatry, Neurology, and Psychology. Sponsors: The Center is supported by public funding from the National Institutes of Health, the State of California, and other sources.
Proper citation: HIV Neurobehavioral Research Center (RRID:SCR_005370) Copy
http://fcon_1000.projects.nitrc.org/
Collection of resting state fMRI (R-fMRI) datasets from sites around world. It demonstrates open sharing of R-fMRI data and aims to emphasize aggregation and sharing of well-phenotyped datasets.
Proper citation: 1000 Functional Connectomes Project (RRID:SCR_005361) Copy
http://www.med.harvard.edu/AANLIB/
An atlas of normal and abnormal brain images intended as an introduction to basic neuroanatomy, with emphasis on the pathoanatomy of several leading central nervous system diseases that integrates clinical information with magnetic resonance (MR), x-ray computed tomography (CT), and nuclear medicine images. A range of brain abnormalities are presented including examples of certain brain disease presented with various combinations of image type and imaging frequency. Submissions of concise, exemplary, clinically driven examples of neuroimaging are welcome.
Proper citation: Whole Brain Atlas (RRID:SCR_005390) Copy
http://science.education.nih.gov/home2.nsf/feature/index.htm
The NIH Office of Science Education (OSE) coordinates science education activities at the NIH and develops and sponsors science education projects in house. These programs serve elementary, secondary, and college students and teachers and the public. Activities * Develop curriculum supplements and other educational materials related to medicine and research through collaborations with scientific experts at NIH * Maintain a website as a central source of information about NIH science education resources * Establish national model programs in public science education, such as the NIH Mini-Med School and Science in the Cinema * Promote science education reform as outlined in the National Science Education Standards and related guidelines The OSE was established in 1991 within the Office of Science Policy of the Office of the Director of the National Institutes of Health. The NIH is the world''s foremost biomedical research center and the U.S. federal government''s focal point for such research. It is one of the components of the Department of Health and Human Services (HHS). The Office of Science Education (OSE) plans, develops, and coordinates a comprehensive science education program to strengthen and enhance efforts of the NIH to attract young people to biomedical and behavioral science careers and to improve science literacy in both adults and children. The function of the Office is as follows: (1) develops, supports, and directs new program initiatives at all levels with special emphasis on targeting students in grades kindergarten to 16, their educators and parents, and the general public; (2) advises NIH leadership on science education issues; (3) examines and evaluates research and emerging trends in science education and literacy for policy making; (4) works closely with the NIH extramural, intramural, women''s health, laboratory animal research, and minority program offices on science education special issues and programs to ensure coordination of NIH efforts; (5) works with NIH institutes, centers, and divisions to enhance communication of science education activities; and (6) works cooperatively with other public- and private-sector organizations to develop and coordinate activities.
Proper citation: NIH Office of Science Education (RRID:SCR_005603) Copy
http://en.wikibooks.org/wiki/MINC/Atlases
A linear average model atlas produced by the International Consortium for Brain Mapping (ICBM) project. A set of full- brain volumetric images from a normative population specifically for the purposes of generating a model were collected by the Montreal Neurological Institute (MNI), UCLA, and University of Texas Health Science Center at San Antonio Research Imaging Center (RIC). 152 new subjects were scanned using T1, T2 and PD sequences using a specific protocol. These images were acquired at a higher resolution than the original average 305 data and exhibit improved contrast due predominately to advances in imaging technology. Each individual was linearly registered to the average 305 and a new model was formed. In total, three models were created at the MNI, the ICBM152_T1, ICBM152_T2 and ICBM152_PD from 152 normal subjects. This resulting model is now known as the ICBM152 (although the model itself has not been published). One advantage of this model is that it exhibits better contrast and better definition of the top of the brain and the bottom of the cerebellum due to the increased coverage during acquisition. The entirely automatic analysis pipeline of this data also included grey/white matter segmentation via spatial priors. The averaged results of these segmentations formed the first MNI parametric maps of grey and white matter. The maps were never made publicly available in isolation but have formed parts of other packages for some time including SPM, FSL AIR and as models of grey matter for EEG source location in VARETTA and BRAINWAVE. Again, as these models are an approximation of Talairach space, there are differences in varying areas, to continue our use of origin shift as an example, the ICBM models are approximately 152: +3.5mm in Z and +-co-ordinate -3.5mm and 2.0mm in Y as compared to the original Talairach origin. In addition to the standard analysis performed on the ICBM data, 64 of the subjects data were segmented using model based segmentation. 64 of the original 305 were manually outlined and a resulting parametric VOI atlas built. The native data from these acquisitions was 256x256 with 1mm slices. The final image resolution of this data was 181x217x181 with 1mm isotropic voxels. Refer to the ICBM152 NonLinear if you are fitting an individual to model and do not care about left/right comparisons. A short history of the various atlases that have been produced at the BIC (McConnell Brain Imaging Center, Montreal Neurological Institute) is provided.
Proper citation: MINC/Atlases (RRID:SCR_005281) Copy
http://www.thehamner.org/technology-and-development/technology-transfer/index.html
THIS RESOURCE IS NO LONGER IN SERVICE, documented on June 24, 2013. BMDExpress is a Java application used to analyze dose-response data from microarray experiments. The program was designed to perform a stepwise analysis on microarray data that combines bench mark dose (BMD) calculations with gene ontology (GO) classification analysis. The combination provides dose estimates at which different cellular processes are altered at a defined increase in risk based on expression levels in the untreated controls. The fitting of the data to the statistical models (linear, 2 polynomial models, 3 polynomial, and power models) is performed using source code borrowed from the U.S. Environmental Protection Agency''''s BMDS software. The MPPD model is a computational model that can be used for estimating human and rat airway particle dosimetry. The model is applicable to risk assessment, research, and education. The MPPD model calculates the deposition and clearance of monodisperse and polydisperse aerosols in the respiratory tracts of rats and human adults and children (deposition only) for particles ranging in size from ultrafine (0.01 m) to coarse (20 m). The models are based on single-path and multiple-path methods for tracking air flow and calculating aerosol deposition in the lung. The single-path method calculates deposition in a typical path per airway generation, while the multiple-path method calculates particle deposition in all airways of the lung and provides lobar-specific and airway-specific information. Within each airway, deposition is calculated using theoretically derived efficiencies for deposition by diffusion, sedimentation, and impaction within the airway or airway bifurcation. Filtration of aerosols by the head is determined using empirical efficiency functions. The MPPD model includes calculations of particle clearance in the lung following deposition. Eight tutorials are provided so that the user can learn to interact with the software.
Proper citation: The Hamner Institute for Health Sciences: BMDExpress and The multiple-path particle dosimetry (RRID:SCR_005511) Copy
http://fcon_1000.projects.nitrc.org/indi/adhd200/index.html#
A grassroots initiative dedicated to accelerating the scientific community''''s understanding of the neural basis of ADHD through the implementation of open data-sharing and discovery-based science. They believe that a community-wide effort focused on advancing functional and structural imaging examinations of the developing brain will accelerate the rate at which neuroscience can inform clinical practice. The ADHD-200 Global Competition invited participants to develop diagnostic classification tools for ADHD diagnosis based on functional and structural magnetic resonance imaging (MRI) of the brain. Applying their tools, participants provided diagnostic labels for previously unlabeled datasets. The competition assessed diagnostic accuracy of each submission and invited research papers describing novel, neuroscientific ideas related to ADHD diagnosis. Twenty-one international teams, from a mix of disciplines, including statistics, mathematics, and computer science, submitted diagnostic labels, with some trying their hand at imaging analysis and psychiatric diagnosis for the first time. The data for the competition was provided by the ADHD-200 Consortium. Consortium members from institutions around the world provided de-identified, HIPAA compliant imaging datasets from almost 800 children with and without ADHD. A phenotypic file including all of the test set subjects and their diagnostic codes can be downloaded. Winner is presented. The ADHD-200 consortium included: * Brown University, Providence, RI, USA (Brown) * The Kennedy Krieger Institute, Baltimore, MD, USA (KKI) * The Donders Institute, Nijmegen, The Netherlands (NeuroImage) * New York University Medical Center, New York, NY, USA (NYU) * Oregon Health and Science University, Portland, OR, USA (OHSU) * Peking University, Beijing, P.R.China (Peking 1-3) * The University of Pittsburgh, Pittsburgh, PA, USA (Pittsburgh) * Washington University in St. Louis, St. Louis, MO, USA (WashU)
Proper citation: ADHD-200 Sample (RRID:SCR_005358) Copy
On March 8, 2008 in Havana, the Latin American Network for Brain Mapping (LABMAN) was created with participants from Argentina, Brazil, Colombia, Cuba and Mexico. The focus of LABMAN is to promote neuroimaging and systems neuroscience in the region through the implementation of training and exchange programs, and to increase public awareness of the Latin American potential to contribute both to basic and applied research in human brain mapping. The immediate LABMAN goals are to: * Train specialists in all major imaging techniques. * Expedite the transfer of new scientific and technical knowledge from abroad. * Increase the scientific productivity of the region. * Drastically increase the awareness of local governments, international organizations and of the general public of brain mapping results on potential. * Organize multinational projects in areas of special relevance to the region, e.g. nutrition, pediatric development, neurodegeneration. Latin American Brain Mapping Network (LABMAN) participants : * Cuban Neuroscience Center * University of Buenos Aires * University of Sao Paulo * Universidad del Valle, Cal��, Colombia * UAM Iztapalapa, Mexico City, Mexico
Proper citation: Latin American Brain Mapping Network (LABMAN) (RRID:SCR_005509) Copy
THIS RESOURCE IS NO LONGER IN SERVICE, documented on August 27, 2019.
Database for those interested in the consequences of Factor VIII genetic variation at the DNA and protein level, it provides access to data on the molecular pathology of haemophilia A. The database presents a review of the structure and function of factor VIII and the molecular genetics of haemophilia A, a real time update of the biostatistics of each parameter in the database, a molecular model of the A1, A2 and A3 domains of the factor VIII protein (based on the crystal structure of caeruloplasmin) and a bulletin board for discussion of issues in the molecular biology of factor VIII. The database is completely updated with easy submission of point mutations, deletions and insertions via e-mail of custom-designed forms. A methods section devoted to mutation detection is available, highlighting issues such as choice of technique and PCR primer sequences. The FVIII structure section now includes a download of a FVIII A domain homology model in Protein Data Bank format and a multiple alignment of the FVIII amino-acid sequences from four species (human, murine, porcine and canine) in addition to the virtual reality simulations, secondary structural data and FVIII animation already available. Finally, to aid navigation across this site, a clickable roadmap of the main features provides easy access to the page desired. Their intention is that continued development and updating of the site shall provide workers in the fields of molecular and structural biology with a one-stop resource site to facilitate FVIII research and education. To submit your mutants to the Haemophilia A Mutation Database email the details. (Refer to Submission Guidelines)
Proper citation: HAMSTeRS - The Haemophilia A Mutation Structure Test and Resource Site (RRID:SCR_006883) Copy
http://neuroade.christakou.org/
At neuroade, a Cognitive Neuroscience Laboratory, we study change in brain and behavior across multiple time-scales. Researchers in the lab combine a variety of methodologies to answer specific questions about typical and atypical behavior and development. We use functional magnetic resonance imaging (fMRI), peripheral psychophysiology (such as skin conductance responses), behavioral testing, genotyping analysis, and computational modeling. Most of our work takes place at the Centre for Integrative Neuroscience and Neurodynamics (CINN), and we all live in the Department of Psychology at the University of Reading. Our research is divided into several distinct yet highly interlinked themes, all converging in their application to understanding psychopathology -- summarised here in no particular order: * Decision-making and the Evaluation of Decision Outcomes * Dimensions of Impulsivity as a Foraging Strategy * Adolescent Development * Computational Modeling Probes of Individual Differences
Proper citation: neuroade (RRID:SCR_006758) Copy
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Welcome to the Neuroscience Information Framework Project, designed to serve the biomedical research community. NIF maintains the largest searchable collection of neuroscience data, the largest catalog of biomedical resources, and the largest ontology for neuroscience on the web. We welcome all feedback and suggestions and are actively looking for resource providers to make their resources accessible through NIF. Learn about the tools available to help you share your data and discover a dynamic inventory of Web-based neuroscience resources.
