Periodic Reporting for period 3 - DISPATCH Neuro-Sense (Distributed Signal Processing Algorithms for Chronic Neuro-Sensor Networks)
Período documentado: 2022-01-01 hasta 2023-06-30
However, algorithms that extract information from neural signals are designed for traditional neuro-sensor arrays with central access to all data, which makes them unsuited for NSNs where the collected data is distributed over multiple neuro-sensor modules. Centralizing the data collected by an NSN would require unrealistic energy budgets which are not available in highly miniaturized (battery-powered) neuro-sensors.
The central idea of this project is to remove this algorithm bottleneck by designing novel distributed algorithms to let the modules of an NSN jointly process the recorded neural data through in-network data fusion and with a minimal exchange of data. This is viewed as the key enabler to exploit the vast amount of spatial information captured by NSNs, while maintaining a viable energy consumption and bandwidth.
We mainly focus on establishing these ideas within a new non-invasive NSN concept based on electroencephalography (EEG). By combining multiple smart miniature EEG modules into an ‘EEG sensor network’ (EEG-Net), we compensate for the lack of spatial information captured by a single module, without compromising in comfort, flexibility and wearability of such devices. Equipping such EEG-Nets with distributed neural signal processing algorithms will allow to process high-density EEG data at viable energy levels, which is a game changer towards high-performance chronic EEG for, e.g. epilepsy monitoring, neuroprostheses, and BCI applications. In addition to the algorithm design activities, we will also build an actual prototype of an EEG-Net and validate it within the three aforementioned use cases. Furthermore, to demonstrate the general applicability of our novel algorithms, we will validate them on data from other emerging NSN platforms as well, such as modular and/or untethered neural implants.
1) We have designed various novel distributed algorithms for various core tasks in the analysis of neural signals such as (1) artefact removal, (2) neural signal enhancement, extraction & decoding, and (3) spatial feature extraction and classification. These distributed algorithms are key enablers towards the exploitation of spatial information across the modules of a neuro-sensor network (NSN), while facilitating a viable bandwidth usage and energy consumption. All the developed algorithms are fully scalable in terms of network size and bandwidth requirements. In addition, the insights obtained during the algorithm design have been leveraged towards the development of a generic and more fundamental algorithm design framework, which contains several of these algorithms as special cases. This framework will be used in future distributed algorithm design activities within the project (and beyond). A particularly interesting feature of the framework is that, if an existing centralized algorithm satisfies some relatively mild properties, it automatically generates a distributed version of that algorithm that is applicable in an NSN with any possible topology.
2) We have collected and analyzed a high-density EEG data set to inform and validate the algorithm design, and to gain insight in the properties of the signals collected by an EEG-Net. The latter is necessary to establish EEG-Nets as a new chronic EEG recording platform, as the modular design will impact the signal content itself (due to short electrode distances and galvanic separation of the modules). To this end, we have emulated the sensors of an EEG-net by re-referencing the electrodes to their nearest neighbors, in order to analyze miniaturization effects and the lack of a common reference across the different sensors. Furthermore, in order to select the optimal locations to place these (emulated) sensors, we have designed automatic electrode selection algorithms for various neural signal processing tasks.
3) We have developed a prototype of a wireless miniature EEG sensor node in which an EEG amplifier, bluetooth LE radio, processing unit, and coin cell battery are all integrated in a small package of less than 1.5 square centimetres. In parallel, we are developing a dry electrode with a low-impedance for long-term use, with the goal of integrating these in future designs of the EEG sensor module.
Furthermore, based on our analysis of emulated EEG-Net signals, we were able to demonstrate that an EEG-Net with galvanically separated miniaturized EEG sensors can achieve the same neural decoding accuracy as with standard EEG with an equal amount of electrodes if (a) optimal sensor locations are selected in both cases, and (b) if the distance between the electrodes within a single EEG-Net module is at least 3cm.
Finally, our new wireless miniature EEG sensor prototype is the smallest to date, and has some novel functionality tailored to the EEG-Net concept that is not available in existing devices, such as a synchronization module based on human-body communication that allows to synchronize a multitude of these nodes with each other.
In the next phase of the project, we will leverage our algorithm design framework to design a larger toolbox of algorithms for neural decoding and feature extraction. We will further develop the framework itself towards a larger class of problems, and a faster convergence. Furthermore, we will test these algorithms in several use cases and validate them in terms of performance and energy consumption on actual EEG-Net hardware prototypes. The latter will be based on our EEG sensor node prototype, in combination with a new design of dry EEG electrodes. We will also validate our algorithms on data from other emerging neuro-sensor network types.