Leveraging anatomical information to improve transfer learning in brain–computer interfaces

Wronkiewicz, Mark; Larson, Eric; Lee, Adrian K. C.

doi:10.1088/1741-2560/12/4/046027

Cited by 27 publications

(21 citation statements)

References 46 publications

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“…A transfer learning method is worthwhile if the subjects share non-stationarities that can be modeled in an intersubject context, but ineffective if the subjects exhibit unlike non-stationarities (Samek et al, 2013). The term inter-subject associativity refers to potential inter-subject BCI performance predictors, which could be incorporated into BCI design to augment transfer learning (Kang and Choi, 2014;Wronkiewicz et al, 2015;Saha et al, 2017aSaha et al, ,b, 2019. Source-space analysis for detecting inter-subject associative EEG channels can improve SMR-based BCI performance (Wronkiewicz et al, 2015;Saha et al, 2017aSaha et al, , 2019.…”

Section: The Concept Of Inter-subject Associativitymentioning

confidence: 99%

“…The term inter-subject associativity refers to potential inter-subject BCI performance predictors, which could be incorporated into BCI design to augment transfer learning (Kang and Choi, 2014;Wronkiewicz et al, 2015;Saha et al, 2017aSaha et al, ,b, 2019. Source-space analysis for detecting inter-subject associative EEG channels can improve SMR-based BCI performance (Wronkiewicz et al, 2015;Saha et al, 2017aSaha et al, , 2019. For example, the classification accuracies for two different subject pairs are 90.36 ± 5.59% and 63.21 ± 8.43%, respectively, suggesting not both subject pairs can be used to achieve a good performance (Saha et al, 2019).…”

Section: The Concept Of Inter-subject Associativitymentioning

confidence: 99%

“…Recent advances in deep learning methods demonstrate a potential application that alleviates intraand inter-subject variability in BCI settings (Chiarelli et al, 2018;Fahimi et al, 2018). Meanwhile, recent studies suggest that the quantification of inter-subject associativity could be equally important to increase the efficacy of exclusively machine learning-based transfer learning strategies for covariate shift adaptation (Kang et al, 2009;Kang and Choi, 2014;Wronkiewicz et al, 2015;Saha et al, 2017bSaha et al, , 2019Perdikis et al, 2018).…”

Section: The Concept Of Inter-subject Associativitymentioning

confidence: 99%

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Intra- and Inter-subject Variability in EEG-Based Sensorimotor Brain Computer Interface: A Review

Saha

Baumert

2020

Front. Comput. Neurosci.

177

109

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Brain computer interfaces (BCI) for the rehabilitation of motor impairments exploit sensorimotor rhythms (SMR) in the electroencephalogram (EEG). However, the neurophysiological processes underpinning the SMR often vary over time and across subjects. Inherent intra-and inter-subject variability causes covariate shift in data distributions that impede the transferability of model parameters amongst sessions/subjects. Transfer learning includes machine learning-based methods to compensate for inter-subject and inter-session (intra-subject) variability manifested in EEG-derived feature distributions as a covariate shift for BCI. Besides transfer learning approaches, recent studies have explored psychological and neurophysiological predictors as well as inter-subject associativity assessment, which may augment transfer learning in EEG-based BCI. Here, we highlight the importance of measuring inter-session/subject performance predictors for generalized BCI frameworks for both normal and motor-impaired people, reducing the necessity for tedious and annoying calibration sessions and BCI training.

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Section: The Concept Of Inter-subject Associativitymentioning

confidence: 99%

Section: The Concept Of Inter-subject Associativitymentioning

confidence: 99%

Section: The Concept Of Inter-subject Associativitymentioning

confidence: 99%

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Intra- and Inter-subject Variability in EEG-Based Sensorimotor Brain Computer Interface: A Review

Saha

Baumert

2020

Front. Comput. Neurosci.

177

109

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“…Since the anatomy used for the forward model is common among all subjects and the selected ROIs are common among all subjects, we would like to check the potential of the algorithm in transfer learning between subjects. There is a study supporting that transfer learning between different subjects by means of source space can achieve higher average single-trial classification accuracy than with a conventional method [ 54 ]. Beyond the BCIC IV 2a dataset that is a common ground for the evaluation of methods decoding multiple MI, we aim to evaluate the improved method on dataset we compiled for the CSI: Brainwave project, containing EEG data of healthy or subjects with spinal cord injury performing multiple motor imagery mainly of the upper limbs [ 36 , 55 ].…”

Section: Resultsmentioning

confidence: 99%

Decoding Motor Imagery through Common Spatial Pattern Filters at the EEG Source Space

Xygonakis

Athanasiou

Pandria

et al. 2018

Computational Intelligence and Neuroscience

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Brain-Computer Interface (BCI) is a rapidly developing technology that aims to support individuals suffering from various disabilities and, ultimately, improve everyday quality of life. Sensorimotor rhythm-based BCIs have demonstrated remarkable results in controlling virtual or physical external devices but they still face a number of challenges and limitations. Main challenges include multiple degrees-of-freedom control, accuracy, and robustness. In this work, we develop a multiclass BCI decoding algorithm that uses electroencephalography (EEG) source imaging, a technique that maps scalp potentials to cortical activations, to compensate for low spatial resolution of EEG. Spatial features were extracted using Common Spatial Pattern (CSP) filters in the cortical source space from a number of selected Regions of Interest (ROIs). Classification was performed through an ensemble model, based on individual ROI classification models. The evaluation was performed on the BCI Competition IV dataset 2a, which features 4 motor imagery classes from 9 participants. Our results revealed a mean accuracy increase of 5.6% with respect to the conventional application method of CSP on sensors. Neuroanatomical constraints and prior neurophysiological knowledge play an important role in developing source space-based BCI algorithms. Feature selection and classifier characteristics of our implementation will be explored to raise performance to current state-of-the-art.

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“…Due to the necessity of additional constraints and the fact that the EEG and its underlying sources are not fully understood yet, new SLMs are continuously developed (Pizzagalli, 2007 ; Grech et al, 2008 ; Becker et al, 2015 ). For BCIs, mainly the well-known, most established SLMs have been applied, like minimum norm (Noirhomme et al, 2008 ; Besserve et al, 2011 ; Edelman et al, 2014 ; Wronkiewicz et al, 2015 , 2016 ), weighted minimum norm (Qin et al, 2004 ; Babiloni et al, 2007 ; Kamousi et al, 2007 ; Cincotti et al, 2008 ; Yuan and He, 2009 ; Goel et al, 2011 ; Edelman et al, 2015 , 2016 ), standardized low resolution electromagnetic tomography (Congedo et al, 2006 ; Lotte et al, 2009 ; Handiru et al, 2017 ), local autoregressive average (Menendez et al, 2005 ; Poolman et al, 2008 ) and beamformer methods (Grosse-Wentrup et al, 2009 ; Ahn et al, 2012 ). However, a comparison of different distributed SLMs has rarely been reported so far.…”

Section: Introductionmentioning

confidence: 99%

Empirical Comparison of Distributed Source Localization Methods for Single-Trial Detection of Movement Preparation

Seeland

Krell

Straube

et al. 2018

Front. Hum. Neurosci.

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The development of technologies for the treatment of movement disorders, like stroke, is still of particular interest in brain-computer interface (BCI) research. In this context, source localization methods (SLMs), that reconstruct the cerebral origin of brain activity measured outside the head, e.g., via electroencephalography (EEG), can add a valuable insight into the current state and progress of the treatment. However, in BCIs SLMs were often solely considered as advanced signal processing methods that are compared against other methods based on the classification performance alone. Though, this approach does not guarantee physiological meaningful results. We present an empirical comparison of three established distributed SLMs with the aim to use one for single-trial movement prediction. The SLMs wMNE, sLORETA, and dSPM were applied on data acquired from eight subjects performing voluntary arm movements. Besides the classification performance as quality measure, a distance metric was used to asses the physiological plausibility of the methods. For the distance metric, which is usually measured to the source position of maximum activity, we further propose a variant based on clusters that is better suited for the single-trial case in which several sources are likely and the actual maximum is unknown. The two metrics showed different results. The classification performance revealed no significant differences across subjects, indicating that all three methods are equally well-suited for single-trial movement prediction. On the other hand, we obtained significant differences in the distance measure, favoring wMNE even after correcting the distance with the number of reconstructed clusters. Further, distance results were inconsistent with the traditional method using the maximum, indicating that for wMNE the point of maximum source activity often did not coincide with the nearest activation cluster. In summary, the presented comparison might help users to select an appropriate SLM and to understand the implications of the selection. The proposed methodology pays attention to the particular properties of distributed SLMs and can serve as a framework for further comparisons.

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Leveraging anatomical information to improve transfer learning in brain–computer interfaces

Cited by 27 publications

References 46 publications

Intra- and Inter-subject Variability in EEG-Based Sensorimotor Brain Computer Interface: A Review

Intra- and Inter-subject Variability in EEG-Based Sensorimotor Brain Computer Interface: A Review

Decoding Motor Imagery through Common Spatial Pattern Filters at the EEG Source Space

Empirical Comparison of Distributed Source Localization Methods for Single-Trial Detection of Movement Preparation

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