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Low-dimensional representations of neural time-series data with applications to peripheral nerve decoding
File | Description | Size | Format | |
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Lubba-CH-2020-PhD-Thesis.pdf | Thesis | 10.82 MB | Adobe PDF | View/Open |
Title: | Low-dimensional representations of neural time-series data with applications to peripheral nerve decoding |
Authors: | Lubba, Carl Henning Thore |
Item Type: | Thesis or dissertation |
Abstract: | Bioelectronic medicines, implanted devices that influence physiological states by peripheral neuromodulation, have promise as a new way of treating diverse conditions from rheumatism to diabetes. We here explore ways of creating nerve-based feedback for the implanted systems to act in a dynamically adapting closed loop. In a first empirical component, we carried out decoding studies on in vivo recordings of cat and rat bladder afferents. In a low-resolution data-set, we selected informative frequency bands of the neural activity using information theory to then relate to bladder pressure. In a second high-resolution dataset, we analysed the population code for bladder pressure, again using information theory, and proposed an informed decoding approach that promises enhanced robustness and automatic re-calibration by creating a low-dimensional population vector. Coming from a different direction of more general time-series analysis, we embedded a set of peripheral nerve recordings in a space of main firing characteristics by dimensionality reduction in a high-dimensional feature-space and automatically proposed single efficiently implementable estimators for each identified characteristic. For bioelectronic medicines, this feature-based pre-processing method enables an online signal characterisation of low-resolution data where spike sorting is impossible but simple power-measures discard informative structure. Analyses were based on surrogate data from a self-developed and flexibly adaptable computer model that we made publicly available. The wider utility of two feature-based analysis methods developed in this work was demonstrated on a variety of datasets from across science and industry. (1) Our feature-based generation of interpretable low-dimensional embeddings for unknown time-series datasets answers a need for simplifying and harvesting the growing body of sequential data that characterises modern science. (2) We propose an additional, supervised pipeline to tailor feature subsets to collections of classification problems. On a literature standard library of time-series classification tasks, we distilled 22 generically useful estimators and made them easily accessible. |
Content Version: | Open Access |
Issue Date: | Jan-2020 |
Date Awarded: | Apr-2020 |
URI: | http://hdl.handle.net/10044/1/80541 |
DOI: | https://doi.org/10.25560/80541 |
Copyright Statement: | Creative Commons Attribution Licence |
Supervisor: | Schultz, Simon Jones, Nicholas |
Sponsor/Funder: | Galvani Bioelectronics |
Funder's Grant Number: | EP/L016737/1 |
Department: | Bioengineering |
Publisher: | Imperial College London |
Qualification Level: | Doctoral |
Qualification Name: | Doctor of Philosophy (PhD) |
Appears in Collections: | Bioengineering PhD theses |