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CARMEN. Code Analysis, Repository and Modelling for e-Neuroscience
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CARMEN Code Analysis, Repository and Modelling for e-Neuroscience Jim Austin , Colin Ingram, Leslie Smith, Paul Watson, Stuart Baker, Roman Borisyuk, Stephen Eglen, Jianfeng Feng, Kevin Gurney, Tom Jackson, Marcus Kaiser, Phillip Lord, Stefano Panzeri, Rodrigo Quian Quiroga, Simon Schultz, Evelyne Sernagor, V. Anne Smith, Tom Smulders, Miles Whittington.
The CARMEN Project • CARMEN is a new e-Science Pilot Project, (UK research council funded) in Neuroinformatics. • Objectives: • To create a grid-enabled, real time ‘virtual laboratory’ environment for neurophysiological data • To develop an extensible ‘toolkit’ for data extraction, analysis and modelling • To provide a repository for archiving, sharing, integration and discovery of data • To achieve wide community and commercial engagement in developing and using CARMEN CARMEN is a 4 year project: if it is to last longer, it must become financially self-sufficient. See http://www.carmen.org.uk neurone 1 neurone 2 neurone 3
CARMEN Consortium Leadership & Infrastructure Colin Ingram Paul Watson Leslie Smith Jim Austin
University ofSt Andrews TheUniversity OfSheffield CARMEN Consortium Work Packages
Background: What is Neuroinformatics? • Informatics applied to Neuroscience (of all sorts) • Experimental Neuroscience: • Data recording, data analysis have used computers for a long time. • But a great deal more can be achieved by pooling data and analysis services • Cognitive and Computational Neuroscience • Modelling, • Matching models to more experimental data • Matching models to known appropriate behaviour • Defining and running more sophisticated models • Running models in real time • Clinical Neuroscience • Data-based understanding of neuropathology • Neuropharmaceutical assays and assessment
What is Neuroinformatics bringing to Experimental Neuroscience? Getting leverage from e-Science capabilities to allow better use of data. Example: Dataset re-use: Experimenter does experiment, records data, analyses data, writes the paper, perhaps makes the data available to a small number of colleagues. …and then? The dataset languishes, first on a spinning disk, then later on some DVD’s, then later still, is lost to view, as the experimenter changes lab,… Yet the data could be of use to other researchers… ?
What are the basic problems holding back dataset re-use? (1) • Two major technical problems: Data format, and Metadata • Data Format • There are different systems for Neuroscience data collection. • The data format is a particular structure • The structure may be • Proprietary: defined by a particular piece of software, and not made public • Locally generated: defined by a locally written piece of software, but not necessarily well documented • Public, but no suitable converter exists for the intending user
What are the basic problems holding back dataset re-use? (2) • Metadata problems • The data itself is useless unless the re-user knows exactly what the data represents. • (Presumably the experimenter knew) • But did they record this information in an accessible way? • Metadata is data about the dataset • How was it generated? • What were the experimental conditions? • What was the culture, or what preparation, or what animal,…? • What was the temperature of the recording? Etc. etc. • If the data is to be readily re-used these metadata problems need to be solved in a directly usable way • Simply describing the protocol in English is not enough • Can’t automate reading J. Neurosci yet! • There needs to be an automatically processable way of describing the experimental protocol. • Particularly true is datasets are used for a large-scale survey of data • e.g. for data-mining.
Enabling Neuroinformatics based collaboration • Solving data format problems • Force users to adopt a common format? • Alienates users: they won’t do it unless they can see real benefits • Support documented formats • Adopt a common internal format, providing translators to & from this format • Rely on proprietary format owners to come aboard because of customer pressure
Enabling Neuroinformatics based collaboration: solving metadata problems • Difficult problem: there are a number of attempts at solving it: • BrainML: (Cornell) brainml.org • “BrainML is a developing initiative to provide a standard XML metaformat • for exchanging neuroscience data. It focuses on layered definitions built • over a common core in order to support community-driven extension.” • NeuroML: http://www.neuroml.org/ • “NeuroML is an XML-based description language for defining and exchanging • neuronal cell, network and modeling data including reconstructions of cell anatomy, membrane physiology, electrophysiological data, network connectivity, and model specification” • Relevant not only for Neuroinformatics and experimental neuroscience: • Part of a cross-cutting problem for all aspects of neuroscience.
Solving Metadata problems continued: • As well as metadata systems for neuronal systems, there are related metadata systems which can be used by BrainML and NeuroML, • ChannelML: for defining ion channel models • MorphML: for defining the morphology of a neuron • SBML: Systems Biology markup language: models of biochemical reaction networks • CellML:to store and exchange computer-based mathematical models • SBML is particularly well advanced: see http://sbml.org/index.psp. • MathML: for describing mathematical notation and capturing both its structure and content. See http://www.w3.org/Math/ • Metadata is a big but soluble problem. • It is a multi-level problem, but the systems above provide a multi-level solution.
Enabling Neuroinformatics based collaboration: Sociological problems • There is a reluctance to permit re-use amongst some experimental neuroscientists. • What do experimental neuroscientists get from allowing others to reuse their data? • If the answer is only better science, then some experimental neuroscientists will not come on board. • They need to be convinced sharing that their hard-earned datasets will be of benefit to them • Names on papers? • The ability to be involved in the further research? • At the very least, some credit! • Some neuroscientists fear that their data will be used without their knowledge • There is therefore some reticence amongst the experimental neuroscience community.
Solving sociological problems • There are technical aspects to solutions: • Security aspects on the holding of data: • Ensure that datasets can be secured: for example that they can only be re-used with the experimenter’s permission. • Security is critically important for holding of data which is still being analysed prior to publication. • …and non-technical aspects too • Bringing experimental neuroscientists on board • Ensuring that the Neuroinformatics community is properly cross-disciplinary, with good representation from the experimentalists. • Getting journals on-side • Many journals are demanding that raw/processed data be made available in order to check results.
Neuroinformatics and clinical neuroscience • Clinical Neuroscience is about treatment of • Mental illness • Brain diseases • Trauma • Neuroinformatics has major application here, ranging from 3d imaging technologies to EEG recordings: much broader than the focus of CARMEN. • CARMEN is primarily concerned with neural recordings. • These can provide data on neurochemical effects on neural function. • Overall brain states (mental illness, disease) are believed to originate in the neurochemistry (research in depression and schizophrenia suggests this).
Neuropharmaceutical assays • Neural cell cultures • Different types: • Slice preparations • Cultures grown from neural cell lines • Cultures from neonate neurons • …have recordings made from them with and without added neuropharmaceuticals. • Interest is on changes in behaviour in these preparations. • Requires instrumentation and analysis techniques • Sharing these results can lead to major advances • Pharmaceutical companies are interested • Security implications
Work Packages WP1 Spike Detection & Sorting WP 3 Data-Driven Parameter Determination in Conductance-Based Models WP2 Information TheoreticAnalysis of Derived Signals WP 0 Data Storage & Analysis WP5 Multilevel Analysis and Modelling in Networks WP4 Measurement and Visualisation of Spike Synchronisation WP4 Intelligent Database Querying
Create ‘virtual laboratory’ for neurophysiological data Provide repository for: archiving, sharing, integration and discovery of data services that operate on the data Develop extensible ‘toolkit’ for data extraction, analysis and modelling Achieve wide community and commercial engagement in CARMEN CARMEN must become financially self-sufficient after 4 years CARMEN Objectives
Bowker’s “Standard Scientific Model”1 Collect data Publish papers Gradually loose the original data 1The New Knowledge Economy and Science and Technology Policy, G.C. Bowker, E1-30-03-05 Problems: papers often draw conclusions from unpublished data inability to replicate experiments data cannot be re-used Data in Science
Bowker’s Model Collect data Publish papers Gradually loose the original data Problems: papers often draw conclusions from unpublished data inability to replicate experiments data cannot be re-used Solution Data Repositories Computational Science Write codes Publish papers Gradually loose the codes Problems: papers often draw conclusions from the results of unpublished codes inability to replicate experiments codes cannot be re-used Solution Service Repositories but… codes can be lost too
Data Exploration DAME developed a tool to analyse large volumes of distributed signal data CARMEN will extend this to: allow search and management of labelled data link the search results to data descriptions to allow better ranking and data analysis
Import tools enable users to describe experimental conditions Analysis services describe their own functionality Registry of data and services “is there any data captured under conditions x, y & z?” “what services are available to process this spike train data?” Automatic provenance generation Metadata
Tool for locating patterns in time-series data across multiple levels of abstraction Dynamic service provisioning over a grid Extensible, standardised metadata for neuroscience Fine-grained access control Integrating data from multiple repositories e-Science Stretch
Work Packages WP1 Spike Detection & Sorting WP 3 Data-Driven Parameter Determination in Conductance-Based Models WP2 Information TheoreticAnalysis of Derived Signals WP 0 Data Storage & Analysis WP5 Multilevel Analysis and Modelling in Networks WP4 Measurement and Visualisation of Spike Synchronisation WP4 Intelligent Database Querying
Spike Detection & Sorting (WP1: Stirling & Leicester) Analogue recording (digitised) Doesn’t fit! Cluster 1 Cluster 2 (Clustering using wave_clus)
CARMEN and spike detection and sorting • Idea is to provide many services • Several different types of spike detection algorithms • Several different types of spike sorting techniques • (including different types of data reduction, as well as different types of clustering) • Allow the user to test with a variety of techniques, and then choose the techniques they prefer • High speed links should allow immediate transfer of some datasets to Grid based systems • Allow experimentalist to choose near-real-time detection and sorting for immediate feedback • To assist during the experiment • Slower (and more effective) techniques for later analysis off-line. • Allow comparison of different techniques on a wide variety of data • Which is best, and for what?
Information Theoretic Analysis of Electrically- and Optically-Derived Signals (WP2: Imperial College, Manchester, and UCL) • Action potentials will be detected both electrically and optically. • Action potentials (spikes) are the primary electrical communication mechanism between neurons. • How can one interpret neuronal action potentials? • Information Theory, can be used to establish the ‘neuronal code’ • quantifying how much information is carried by different potential neuronal coding mechanisms. • Issues: • Sampling problems, Spike correlation, Multimodal recording • By using Grid technology, we can assemble large quantities of optical and multi-electrode recordings and apply existing and novel techniques to its analysis. • We can make these techniques available as services.
Data-Driven Parameter Determination in Conductance-Based Models (WP3: Sheffield: Gurney et al) • Neuron modelling uses conductance based models. • [Many ionic species cross the neural membrane. • Ion channels embedded in the membrane accomplish this transport • There are many different ion channel types • Setting the parameters for each type would enable better understanding of neuron operation] • Determining parameters for neural models is difficult and requires a great deal of data. • The parameters are not constant, and vary with (e.g.) • Cell type • Presence and concentration of neuromodulators • Temperature • CARMEN aims to provide this volume of data, and hence to enable many of these parameters to be determined.
‘Compartmental’ modelling of morphology Real neural morphology approximation (Passive) electrical equivalent
5 0 m V Fitting the model to current clamp data Model 1 0 0 m s Data (Wilson) Wood et al., Neurocomputing, 2003
Measurement and Visualisation of Spike Synchronisation (WP5: Newcastle, Plymouth) • More advanced analytical techniques are required to handle large scale, simultaneous recordings arising from MEAs. • Visualisation is critical to understanding what is happening • WP5 aims to: • develop reliable and robust analysis techniques to address these issues, particularly sweeping statistical methods to test if measures show significant changes • develop novel visualisation methods for displaying the results from these techniques, particularly those working in high-dimensional space • conduct real-time analysis of spike coding through a distributed Grid-enabled virtual laboratory. • Advanced (but fast) visualisation techniques are important to the whole community using CARMEN
Gravitational Clustering Particle aggregation in gravitational clustering, (Gerstein and Lindsey(2006)). Each particle represents a cell; charges on each cells are incremented with each spike, and a force occurs between particles dependent on the charges.
Multilevel Analysis and Modelling in Networks (WP6: Newcastle, St. Andrews, Cambridge) • This WP aims to integrate the work of WP1-4, using the technology of WP0. • Understanding activity dynamics within neuronal networks is a major challenge in neuroscience • requires simultaneous recording from large numbers of neurons. • This WP will provide • integration of existing and novel network analysis techniques into CARMEN in order to build comprehensive models of network dynamics • data of exceptional quality and detailed provenance for the CARMEN repository for analysis of network properties • development of new dynamic Bayesian network algorithms to trace paths of neural information flow in networks. • For example: waves of activity in early turtle retina, recorded using Ca++ sensitive dye. (Thanks to Evelyne Sernagor, ION, Newcastle University)
Concluding remarks • CARMEN is a recent project (funding started October 2006). • The baseline support technology is still being assembled. • It’s not the first attempt at making neurophysiological recordings re-usable • But: • CARMEN will contain more than recordings • Services, workflows, capability of using multiple data formats • CARMEN builds on earlier e_Science projects • Re-use not re-invention • We have experimental neuroscientists, informaticians, and computational neuroscientists all on board • Tackling the broad range of issues from multiple perspectives.
