Your search keyword '"Doya, Kenji"' showing total 19 results

1. A whole-brain analysis of functional connectivity and immediate early gene expression reveals functional network shifts after operant learning.

Author

Kasahara K, Hikishima K, Nakata M, Tsurugizawa T, Higo N, and Doya K

Subjects

Animals, Mice, Male, Neuronal Plasticity physiology, Mice, Inbred C57BL, Genes, Immediate-Early physiology, Nerve Net diagnostic imaging, Nerve Net physiology, Brain Mapping methods, Magnetic Resonance Imaging, Conditioning, Operant physiology, Early Growth Response Protein 1 metabolism, Early Growth Response Protein 1 genetics, Brain diagnostic imaging, Brain physiology, Brain metabolism

Abstract

Previous studies of operant learning have addressed neuronal activities and network changes in specific brain areas, such as the striatum, sensorimotor cortex, prefrontal/orbitofrontal cortices, and hippocampus. However, how changes in the whole-brain network are caused by cellular-level changes remains unclear. We, therefore, combined resting-state functional magnetic resonance imaging (rsfMRI) and whole-brain immunohistochemical analysis of early growth response 1 (EGR1), a marker of neural plasticity, to elucidate the temporal and spatial changes in functional networks and underlying cellular processes during operant learning. We used an 11.7-Tesla MRI scanner and whole-brain immunohistochemical analysis of EGR1 in mice during the early and late stages of operant learning. In the operant training, mice received a reward when they pressed left and right buttons alternately, and were punished with a bright light when they made a mistake. A group of mice (n = 22) underwent the first rsfMRI acquisition before behavioral sessions, the second acquisition after 3 training-session-days (early stage), and the third after 21 training-session-days (late stage). Another group of mice (n = 40) was subjected to histological analysis 15 min after the early or late stages of behavioral sessions. Functional connectivity increased between the limbic areas and thalamus or auditory cortex after the early stage of training, and between the motor cortex, sensory cortex, and striatum after the late stage of training. The density of EGR1-immunopositive cells in the motor and sensory cortices increased in both the early and late stages of training, whereas the density in the amygdala increased only in the early stage of training. The subcortical networks centered around the limbic areas that emerged in the early stage have been implicated in rewards, pleasures, and fears. The connectivities between the motor cortex, somatosensory cortex, and striatum that consolidated in the late stage have been implicated in motor learning. Our multimodal longitudinal study successfully revealed temporal shifts in brain regions involved in behavioral learning together with the underlying cellular-level plasticity between these regions. Our study represents a first step towards establishing a new experimental paradigm that combines rsfMRI and immunohistochemistry to link macroscopic and microscopic mechanisms involved in learning., Competing Interests: Declaration of competing interest The authors declare that they have no competing interests., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

2. The Brain/MINDS Marmoset Connectivity Resource: An open-access platform for cellular-level tracing and tractography in the primate brain.

Author

Skibbe H, Rachmadi MF, Nakae K, Gutierrez CE, Hata J, Tsukada H, Poon C, Schlachter M, Doya K, Majka P, Rosa MGP, Okano H, Yamamori T, Ishii S, Reisert M, and Watakabe A

Subjects

Animals, Brain Mapping methods, Prefrontal Cortex diagnostic imaging, Diffusion Magnetic Resonance Imaging, Neural Pathways, Callithrix, Brain diagnostic imaging, Brain physiology

Abstract

The primate brain has unique anatomical characteristics, which translate into advanced cognitive, sensory, and motor abilities. Thus, it is important that we gain insight on its structure to provide a solid basis for models that will clarify function. Here, we report on the implementation and features of the Brain/MINDS Marmoset Connectivity Resource (BMCR), a new open-access platform that provides access to high-resolution anterograde neuronal tracer data in the marmoset brain, integrated to retrograde tracer and tractography data. Unlike other existing image explorers, the BMCR allows visualization of data from different individuals and modalities in a common reference space. This feature, allied to an unprecedented high resolution, enables analyses of features such as reciprocity, directionality, and spatial segregation of connections. The present release of the BMCR focuses on the prefrontal cortex (PFC), a uniquely developed region of the primate brain that is linked to advanced cognition, including the results of 52 anterograde and 164 retrograde tracer injections in the cortex of the marmoset. Moreover, the inclusion of tractography data from diffusion MRI allows systematic analyses of this noninvasive modality against gold-standard cellular connectivity data, enabling detection of false positives and negatives, which provide a basis for future development of tractography. This paper introduces the BMCR image preprocessing pipeline and resources, which include new tools for exploring and reviewing the data., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Skibbe et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

3. Multi-modal brain magnetic resonance imaging database covering marmosets with a wide age range.

Author

Hata J, Nakae K, Tsukada H, Woodward A, Haga Y, Iida M, Uematsu A, Seki F, Ichinohe N, Gong R, Kaneko T, Yoshimaru D, Watakabe A, Abe H, Tani T, Hamda HT, Gutierrez CE, Skibbe H, Maeda M, Papazian F, Hagiya K, Kishi N, Ishii S, Doya K, Shimogori T, Yamamori T, Tanaka K, Okano HJ, and Okano H

Subjects

Animals, Databases, Factual, Neuroimaging methods, Age Factors, Brain diagnostic imaging, Callithrix, Magnetic Resonance Imaging methods

Abstract

Magnetic resonance imaging (MRI) is a non-invasive neuroimaging technique that is useful for identifying normal developmental and aging processes and for data sharing. Marmosets have a relatively shorter life expectancy than other primates, including humans, because they grow and age faster. Therefore, the common marmoset model is effective in aging research. The current study investigated the aging process of the marmoset brain and provided an open MRI database of marmosets across a wide age range. The Brain/MINDS Marmoset Brain MRI Dataset contains brain MRI information from 216 marmosets ranging in age from 1 and 10 years. At the time of its release, it is the largest public dataset in the world. It also includes multi-contrast MRI images. In addition, 91 of 216 animals have corresponding high-resolution ex vivo MRI datasets. Our MRI database, available at the Brain/MINDS Data Portal, might help to understand the effects of various factors, such as age, sex, body size, and fixation, on the brain. It can also contribute to and accelerate brain science studies worldwide., (© 2023. The Author(s).)

Published

2023

4. Diffusion functional MRI reveals global brain network functional abnormalities driven by targeted local activity in a neuropsychiatric disease mouse model.

Author

Abe Y, Takata N, Sakai Y, Hamada HT, Hiraoka Y, Aida T, Tanaka K, Bihan DL, Doya K, and Tanaka KF

Subjects

Animals, Brain diagnostic imaging, Brain Mapping methods, Disease Models, Animal, Excitatory Amino Acid Transporter 2 genetics, Gene Knockdown Techniques, Mice, Neural Pathways diagnostic imaging, Neural Pathways pathology, Neural Pathways physiopathology, Obsessive-Compulsive Disorder diagnostic imaging, Brain pathology, Brain physiopathology, Diffusion Magnetic Resonance Imaging, Obsessive-Compulsive Disorder pathology, Obsessive-Compulsive Disorder physiopathology

Abstract

Diffusion functional magnetic resonance imaging (DfMRI) has been proposed as an alternative functional imaging method to detect brain activity without confounding hemodynamic effects. Here, taking advantage of this DfMRI feature, we investigated abnormalities of dynamic brain function in a neuropsychiatric disease mouse model (glial glutamate transporter-knockdown mice with obsessive-compulsive disorder [OCD]-related behavior). Our DfMRI approaches consisted of three analyses: resting state brain activity, functional connectivity, and propagation of neural information. We detected hyperactivation and biased connectivity across the cortico-striatal-thalamic circuitry, which is consistent with known blood oxygen-level dependent (BOLD)-fMRI patterns in OCD patients. In addition, we performed ignition-driven mean integration (IDMI) analysis, which combined activity and connectivity analyses, to evaluate neural propagation initiated from brain activation. This analysis revealed an unbalanced distribution of neural propagation initiated from intrinsic local activation to the global network, while these were not detected by the conventional method with BOLD-fMRI. This abnormal function detected by DfMRI was associated with OCD-related behavior. Together, our comprehensive DfMRI approaches can successfully provide information on dynamic brain function in normal and diseased brains., Competing Interests: Declaration of Competing Interest The authors report no biomedical financial interests or potential conflicts of interest., (Copyright © 2020 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2020

5. [Artificial Intelligence and Brain Science: the Present and the Future].

Author

Doya K and Matsuo Y

Subjects

Humans, Artificial Intelligence trends, Brain, Neurobiology trends

Abstract

Artificial intelligence and brain science have kept a swinging relationship with opposing views: "Artificial realization of intelligence should be free from biological constraints" and "We should reverse-engineer the best existing implementation of intelligence." In this article, we first review today's achievements of artificial intelligence and its impacts on brain and life sciences. We then discuss how progresses in brain science can contribute to future developments in artificial intelligence.

Published

2019

6. Identification of depression subtypes and relevant brain regions using a data-driven approach.

Author

Tokuda T, Yoshimoto J, Shimizu Y, Okada G, Takamura M, Okamoto Y, Yamawaki S, and Doya K

Subjects

Adult, Antidepressive Agents therapeutic use, Databases, Factual, Depressive Disorder drug therapy, Female, Humans, Magnetic Resonance Imaging, Male, Middle Aged, Severity of Illness Index, Brain diagnostic imaging, Depressive Disorder diagnostic imaging, Nerve Net diagnostic imaging

Abstract

It is well known that depressive disorder is heterogeneous, yet little is known about its neurophysiological subtypes. In the present study, we identified neurophysiological subtypes of depression related to specific neural substrates. We performed cluster analysis for 134 subjects (67 depressive subjects and 67 controls) using a high-dimensional dataset consisting of resting state functional connectivity measured by functional MRI, clinical questionnaire scores, and various biomarkers. Applying a newly developed, multiple co-clustering method to this dataset, we identified three subtypes of depression that are characterized by functional connectivity between the right Angular Gyrus (AG) and other brain areas in default mode networks, and Child Abuse Trauma Scale (CATS) scores. These subtypes are also related to Selective Serotonin-Reuptake Inhibitor (SSRI) treatment outcomes, which implies that we may be able to predict effectiveness of treatment based on AG-related functional connectivity and CATS.

Published

2018

7. Prediction of clinical depression scores and detection of changes in whole-brain using resting-state functional MRI data with partial least squares regression.

Author

Yoshida K, Shimizu Y, Yoshimoto J, Takamura M, Okada G, Okamoto Y, Yamawaki S, and Doya K

Subjects

Adult, Aged, Case-Control Studies, Depression classification, Female, Humans, Least-Squares Analysis, Male, Middle Aged, Brain diagnostic imaging, Depression diagnostic imaging, Magnetic Resonance Imaging methods

Abstract

In diagnostic applications of statistical machine learning methods to brain imaging data, common problems include data high-dimensionality and co-linearity, which often cause over-fitting and instability. To overcome these problems, we applied partial least squares (PLS) regression to resting-state functional magnetic resonance imaging (rs-fMRI) data, creating a low-dimensional representation that relates symptoms to brain activity and that predicts clinical measures. Our experimental results, based upon data from clinically depressed patients and healthy controls, demonstrated that PLS and its kernel variants provided significantly better prediction of clinical measures than ordinary linear regression. Subsequent classification using predicted clinical scores distinguished depressed patients from healthy controls with 80% accuracy. Moreover, loading vectors for latent variables enabled us to identify brain regions relevant to depression, including the default mode network, the right superior frontal gyrus, and the superior motor area.

Published

2017

8. Brain computation mechanism of prediction and decision making by dorsal raphe serotonin neurons.

Author

Miyazaki K, Miyazaki K, and Doya K

Subjects

Animals, Humans, Light, Reward, Brain metabolism, Decision Making, Dorsal Raphe Nucleus metabolism, Serotonin metabolism

Published

2017

9. [Brain mechanisms of depression--preliminary evidence from fMRI studies].

Author

Okada G, Okamoto Y, Shishida K, Ueda K, Onoda K, Kunisato Y, Tanaka SC, Doya K, and Yamawaki S

Subjects

Brain metabolism, Brain Mapping, Depression metabolism, Humans, Reward, Serotonin metabolism, Brain pathology, Depression pathology, Magnetic Resonance Imaging

Abstract

Although brain monoamines serotonin, noradrenaline, and dopamine have been repeatedly shown to be linked to depression, it remains unclear how monoamine dysfunction is mechanistically related to symptoms of depression. We hypothesized that imbalances in the networks of regions innervated by monoamines disrupt patients' learning and decision-making abilities, and this disruption could, in turn, lead to symptoms of depression. We have conducted functional magnetic resonance imaging (fMRI) studies on learning and decision-making, mainly focusing on the role of serotonin. Our results suggest that parallel organization for reward prediction at different time scales in the striatum is under differential modulation by serotonin, and that depression is associated with a diminished recruitment of the dorsal striatum, involved in long-term reward prediction. Based on these findings, the brain mechanisms of depression are discussed.

Published

2014

10. The role of serotonin in the regulation of patience and impulsivity.

Author

Miyazaki K, Miyazaki KW, and Doya K

Subjects

Animals, Brain anatomy & histology, Humans, Rats, Behavior physiology, Brain physiology, Impulsive Behavior physiopathology, Serotonin physiology

Abstract

Classic theories suggest that central serotonergic neurons are involved in the behavioral inhibition that is associated with the prediction of negative rewards or punishment. Failed behavioral inhibition can cause impulsive behaviors. However, the behavioral inhibition that results from predicting punishment is not sufficient to explain some forms of impulsive behavior. In this article, we propose that the forebrain serotonergic system is involved in "waiting to avoid punishment" for future punishments and "waiting to obtain reward" for future rewards. Recently, we have found that serotonergic neurons increase their tonic firing rate when rats await food and water rewards and conditioned reinforcer tones. The rate of tonic firing during the delay period was significantly higher when rats were waiting for rewards than for tones, and rats were unable to wait as long for tones as for rewards. These results suggest that increased serotonergic neuronal firing facilitates waiting behavior when there is the prospect of a forthcoming reward and that serotonergic activation contributes to the patience that allows rats to wait longer. We propose a working hypothesis to explain how the serotonergic system regulates patience while waiting for future rewards.

Published

2012

11. Neural and personality correlates of individual differences related to the effects of acute tryptophan depletion on future reward evaluation.

Author

Demoto Y, Okada G, Okamoto Y, Kunisato Y, Aoyama S, Onoda K, Munakata A, Nomura M, Tanaka SC, Schweighofer N, Doya K, and Yamawaki S

Subjects

Adult, Analysis of Variance, Brain blood supply, Choice Behavior physiology, Emotions physiology, Functional Laterality, Humans, Magnetic Resonance Imaging, Male, Neuropsychological Tests, Oxygen blood, Personality Inventory, Reaction Time, Statistics, Nonparametric, Tryptophan blood, Young Adult, Brain physiology, Brain Mapping, Individuality, Personality physiology, Reward, Tryptophan deficiency

Abstract

Background/aims: In general, humans tend to discount the value of delayed reward. An increase in the rate of discounting leads to an inability to select a delayed reward over a smaller immediate reward (reward-delay impulsivity). Although deficits in the serotonergic system are implicated in this reward-delay impulsivity, there is individual variation in response to serotonin depletion. The aim of the present study was to investigate whether the effects of serotonin depletion on the ability to evaluate future reward are affected by individual personality traits or brain activation., Methods: Personality traits were assessed using the NEO-Five Factor Inventory and Temperament and Character Inventory. The central serotonergic levels of 16 healthy volunteers were manipulated by dietary tryptophan depletion. Subjects performed a delayed reward choice task that required the continuous estimation of reward value during functional magnetic resonance imaging scanning., Results: Discounting rates were increased in 9 participants, but were unchanged or decreased in 7 participants in response to tryptophan depletion. Participants whose discounting rate was increased by tryptophan depletion had significantly higher neuroticism and lower self-directedness. Furthermore, tryptophan depletion differentially affected the groups in terms of hemodynamic responses to the value of predicted future reward in the right insula., Conclusions: These results suggest that individuals who have high neuroticism and low self-directedness as personality traits are particularly vulnerable to the effect of low serotonin on future reward evaluation accompanied by altered brain activation patterns., (Copyright © 2012 S. Karger AG, Basel.)

Published

2012

12. Multi-scale, multi-modal neural modeling and simulation.

Author

Ishii S, Diesmann M, and Doya K

Subjects

Humans, User-Computer Interface, Brain physiology, Computer Simulation, Models, Neurological

Published

2011

13. A hierarchical Bayesian method to resolve an inverse problem of MEG contaminated with eye movement artifacts.

Author

Fujiwara Y, Yamashita O, Kawawaki D, Doya K, Kawato M, Toyama K, and Sato MA

Subjects

Bayes Theorem, Computer Simulation, Humans, Male, Reproducibility of Results, Sensitivity and Specificity, Young Adult, Algorithms, Brain physiology, Brain Mapping methods, Eye Movements physiology, Magnetoencephalography methods, Models, Neurological, Pattern Recognition, Automated methods

Abstract

The magnetic fields generated by eye movements are major artifacts in MEG measurements. We propose a hybrid hierarchical variational Bayesian method to remove eye movement artifacts from MEG data. Our method is an extension of the hierarchical variational Bayesian method for MEG source localization proposed by Sato et al. [Sato, M., Yoshioka, T., Kajihara, S., Toyama, K., Goda, N., Doya, K., and Kawato, M., (2004). Hierarchical Bayesian estimation for MEG inverse problem. NeuroImage 23(3), 806-826]. First, we assumed a single dipole at each left and right eyeball as a source of eye artifacts. Second, we constructed an EOG forward model describing the relationship between eye dipoles and electric potentials, i.e., EOG. Based on the Bayesian framework, the proposed method concurrently estimates eye and brain current sources from both MEG and EOG data. Thereby the brain current sources can be isolated from eye artifacts. The new method was tested in two ways. In the simulation experiments, the performance of eye artifact removal was evaluated from various aspects; locations of brain current sources, temporal correlation between eye and brain current sources, the level of MEG observation noise and so on. In real MEG experiments, we measured MEG and EOG data during smooth pursuit eye movements for a horizontally or circularly moving target. Our method successfully removed eye artifacts from the simulated and real MEG data with the estimation of brain current sources that were located in eye movement related areas. Our method should be widely applicable to MEG data obtained in tasks with non-negligible eye movements.

Published

2009

14. Brain mechanism of reward prediction under predictable and unpredictable environmental dynamics.

Author

Tanaka SC, Samejima K, Okada G, Ueda K, Okamoto Y, Yamawaki S, and Doya K

Subjects

Brain blood supply, Brain Mapping, Female, Humans, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging methods, Male, Models, Psychological, Oxygen blood, Predictive Value of Tests, Brain physiology, Choice Behavior physiology, Environment, Learning physiology, Nonlinear Dynamics, Reward

Abstract

In learning goal-directed behaviors, an agent has to consider not only the reward given at each state but also the consequences of dynamic state transitions associated with action selection. To understand brain mechanisms for action learning under predictable and unpredictable environmental dynamics, we measured brain activities by functional magnetic resonance imaging (fMRI) during a Markov decision task with predictable and unpredictable state transitions. Whereas the striatum and orbitofrontal cortex (OFC) were significantly activated both under predictable and unpredictable state transition rules, the dorsolateral prefrontal cortex (DLPFC) was more strongly activated under predictable than under unpredictable state transition rules. We then modelled subjects' choice behaviours using a reinforcement learning model and a Bayesian estimation framework and found that the subjects took larger temporal discount factors under predictable state transition rules. Model-based analysis of fMRI data revealed different engagement of striatum in reward prediction under different state transition dynamics. The ventral striatum was involved in reward prediction under both unpredictable and predictable state transition rules, although the dorsal striatum was dominantly involved in reward prediction under predictable rules. These results suggest different learning systems in the cortico-striatum loops depending on the dynamics of the environment: the OFC-ventral striatum loop is involved in action learning based on the present state, while the DLPFC-dorsal striatum loop is involved in action learning based on predictable future states.

Published

2006

15. The computational neurobiology of learning and reward.

Author

Daw ND and Doya K

Subjects

Animals, Brain anatomy & histology, Cerebral Cortex physiology, Corpus Striatum physiology, Decision Making physiology, Dopamine physiology, Humans, Artificial Intelligence, Brain physiology, Learning physiology, Neural Networks, Computer, Reward

Abstract

Following the suggestion that midbrain dopaminergic neurons encode a signal, known as a 'reward prediction error', used by artificial intelligence algorithms for learning to choose advantageous actions, the study of the neural substrates for reward-based learning has been strongly influenced by computational theories. In recent work, such theories have been increasingly integrated into experimental design and analysis. Such hybrid approaches have offered detailed new insights into the function of a number of brain areas, especially the cortex and basal ganglia. In part this is because these approaches enable the study of neural correlates of subjective factors (such as a participant's beliefs about the reward to be received for performing some action) that the computational theories purport to quantify.

Published

2006

16. Prediction of immediate and future rewards differentially recruits cortico-basal ganglia loops.

Author

Tanaka SC, Doya K, Okada G, Ueda K, Okamoto Y, and Yamawaki S

Subjects

Adult, Female, Humans, Magnetic Resonance Imaging, Male, Markov Chains, Middle Aged, Brain physiology, Brain Mapping, Discrimination Learning physiology, Reward

Abstract

Evaluation of both immediate and future outcomes of one's actions is a critical requirement for intelligent behavior. Using functional magnetic resonance imaging (fMRI), we investigated brain mechanisms for reward prediction at different time scales in a Markov decision task. When human subjects learned actions on the basis of immediate rewards, significant activity was seen in the lateral orbitofrontal cortex and the striatum. When subjects learned to act in order to obtain large future rewards while incurring small immediate losses, the dorsolateral prefrontal cortex, inferior parietal cortex, dorsal raphe nucleus and cerebellum were also activated. Computational model-based regression analysis using the predicted future rewards and prediction errors estimated from subjects' performance data revealed graded maps of time scale within the insula and the striatum: ventroanterior regions were involved in predicting immediate rewards and dorsoposterior regions were involved in predicting future rewards. These results suggest differential involvement of the cortico-basal ganglia loops in reward prediction at different time scales.

Published

2004

17. Metalearning and neuromodulation.

Author

Doya K

Subjects

Algorithms, Animals, Humans, Brain physiology, Learning physiology, Models, Biological, Neurotransmitter Agents physiology

Abstract

This paper presents a computational theory on the roles of the ascending neuromodulatory systems from the viewpoint that they mediate the global signals that regulate the distributed learning mechanisms in the brain. Based on the review of experimental data and theoretical models, it is proposed that dopamine signals the error in reward prediction, serotonin controls the time scale of reward prediction, noradrenaline controls the randomness in action selection, and acetylcholine controls the speed of memory update. The possible interactions between those neuromodulators and the environment are predicted on the basis of computational theory of metalearning.

Published

2002

18. Journal club.

Author

Doya, Kenji

Subjects

*SCIENTIFIC experimentation, *BRAIN

Abstract

The article presents information on the experiment to find the deliberative and intuitive decision-making process of the human brain.

Published

2010

19. Hierarchical Bayesian estimation for MEG inverse problem

Author

Sato, Masa-aki, Yoshioka, Taku, Kajihara, Shigeki, Toyama, Keisuke, Goda, Naokazu, Doya, Kenji, and Kawato, Mitsuo

Subjects

*MAGNETOENCEPHALOGRAPHY, *BRAIN, *MEDICAL imaging systems, *MAGNETIC resonance imaging

Abstract

Source current estimation from MEG measurement is an ill-posed problem that requires prior assumptions about brain activity and an efficient estimation algorithm. In this article, we propose a new hierarchical Bayesian method introducing a hierarchical prior that can effectively incorporate both structural and functional MRI data. In our method, the variance of the source current at each source location is considered an unknown parameter and estimated from the observed MEG data and prior information by using the Variational Bayesian method. The fMRI information can be imposed as prior information on the variance distribution rather than the variance itself so that it gives a soft constraint on the variance. A spatial smoothness constraint, that the neural activity within a few millimeter radius tends to be similar due to the neural connections, can also be implemented as a hierarchical prior. The proposed method provides a unified theory to deal with the following three situations: (1) MEG with no other data, (2) MEG with structural MRI data on cortical surfaces, and (3) MEG with both structural MRI and fMRI data. We investigated the performance of our method and conventional linear inverse methods under these three conditions. Simulation results indicate that our method has better accuracy and spatial resolution than the conventional linear inverse methods under all three conditions. It is also shown that accuracy of our method improves as MRI and fMRI information becomes available. Simulation results demonstrate that our method appropriately resolves the inverse problem even if fMRI data convey inaccurate information, while the Wiener filter method is seriously deteriorated by inaccurate fMRI information. [Copyright &y& Elsevier]

Published

2004