Using Real-Time fMRI to Control a Dynamical System by Brain Activity Classification

Eklund, Anders; Andersson, Mats; Rydell, Joakim; Ynnerman, Anders; Knutsson, Hans

doi:10.1007/978-3-642-04268-3_123

Cited by 16 publications

(14 citation statements)

References 15 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…We have demonstrated that it is possible to control a dynamical system [32] and communicate [33] by classifying the brain activity every second; similar work has been done by LaConte et al [34]. deCharms et al [35] helped subjects to suppress their pain by letting them see their own brain activity in real-time.…”

Section: More Advanced Real-time Analysissupporting

confidence: 54%

fMRI analysis on the GPU—Possibilities and challenges

Eklund

Andersson

Knutsson

2012

Computer Methods and Programs in Biomedicine

Self Cite

View full text Add to dashboard Cite

Functional magnetic resonance imaging (fMRI) makes it possible to non-invasively measure brain activity with high spatial resolution. There are however a number of issues that have to be addressed. One is the large amount of spatio-temporal data that needs to be processed. In addition to the statistical analysis itself, several preprocessing steps, such as slice timing correction and motion compensation, are normally applied. The high computational power of modern graphic cards has already successfully been used for MRI and fMRI. Going beyond the first published demonstration of GPU-based analysis of fMRI data, all the preprocessing steps and two statistical approaches, the general linear model (GLM) and canonical correlation analysis (CCA), have been implemented on a GPU. For an fMRI dataset of typical size (80 volumes with 64 x 64 x 22 voxels), all the preprocessing takes about 0.5 s on the GPU, compared to 5 s with an optimized CPU implementation and 120 s with the commonly used statistical parametric mapping (SPM) software. A random permutation test with 10 000 permutations, with smoothing in each permutation, takes about 50 s if three GPUs are used, compared to 0.5 -2.5 h with an optimized CPU implementation. The presented work will save time for researchers and clinicians in their daily work and enables the use of more advanced analysis, such as non-parametric statistics, both for conventional fMRI and for real-time fMRI.

show abstract

Section: More Advanced Real-time Analysissupporting

confidence: 54%

fMRI analysis on the GPU—Possibilities and challenges

Eklund

Andersson

Knutsson

2012

Computer Methods and Programs in Biomedicine

Self Cite

View full text Add to dashboard Cite

show abstract

“…Although our reported real-time system used an SVM implementation (Joachims, 1999), this is really a modular part of the system that allows future extensions in which multiple classifiers (either individually or combined) can be used (LaConte et al, 2007). Recently Eklund et al (2009) 4. An example AFNI rtfMRI display with stimulus window.…”

Section: Resourcesmentioning

confidence: 98%

“…Using this system, Papageorgiou et al (2009) has recently reported the ability to provide feedback based on slow vs. fast inner, automatic speech. Using a similar approach based on neural networks, Eklund et al (2009) has reported the ability to control the dynamics of a simulated inverted pendulum, using classification of left, right, and resting conditions. Using the relevance vector machine, Hollmann et al (2009) presented a subject's neuroeconomic decisions to the operator before that subject pressed a button to convey his decision.…”

Section: Introductionmentioning

confidence: 98%

Decoding fMRI brain states in real-time

2011

View full text Add to dashboard Cite

“…While previous fMRI based BCI have classified between two classes [1] or three classes [2], we instead classify between five different classes, to give the subject five degrees of freedom. We choose to use our system for communication, since EEG has been used for communication [3] and many have claimed that fMRI is far too slow for similar setups.…”

Section: Introductionmentioning

confidence: 99%

A Brain Computer Interface for Communication Using Real-Time fMRI

Eklund

Andersson

Ynnerman

et al. 2010

2010 20th International Conference on Pattern Recognition

Self Cite

View full text Add to dashboard Cite

Abstract-We present the first step towards a brain computer interface (BCI) for communication using real-time functional magnetic resonance imaging (fMRI). The subject in the MR scanner sees a virtual keyboard and steers a cursor to select different letters that can be combined to create words. The cursor is moved to the left by activating the left hand, to the right by activating the right hand, down by activating the left toes and up by activating the right toes. To select a letter, the subject simply rests for a number of seconds. We can thus communicate with the subject in the scanner by for example showing questions that the subject can answer. Similar BCI for communication have been made with electroencephalography (EEG). In these implementations the subject for example focuses on a letter while different rows and columns of the virtual keyboard are flashing. The system then tries to detect if the correct letter is flashing or not. In our setup we instead classify the brain activity. Our system is not limited to a communication interface, but can be used for any interface where five degrees of freedom is necessary.

show abstract

Using Real-Time fMRI to Control a Dynamical System by Brain Activity Classification

Cited by 16 publications

References 15 publications

fMRI analysis on the GPU—Possibilities and challenges

fMRI analysis on the GPU—Possibilities and challenges

Decoding fMRI brain states in real-time

A Brain Computer Interface for Communication Using Real-Time fMRI

Contact Info

Product

Resources

About