Machine learning-based spike sorting reveals how subneuronal concentrations of monomeric Tau cause a loss in excitatory postsynaptic currents in hippocampal neurons

Author:

Brockhoff Marius,Träuble Jakob,Middya Sagnik,Fuchsberger Tanja,Fernandez-Villegas Ana,Stephens Amberley,Robbins Miranda,Dai Wenyue,Haider Belquis,Vora Sulay,Läubli Nino FORCID,Kaminski Clemens FORCID,Malliaras George G,Paulsen Ole,Kaminski Schierle Gabriele S

Abstract

AbstractExtracellular recordings of neuronal activity constitute a powerful tool for investigating the intricate dynamics of neural networks and the activity of individual neurons. Microelectrode arrays (MEAs) allow for recordings with a high electrode count, ranging from 10s to 1000s, generating extensive datasets of neuronal information. Furthermore, MEAs capture extracellular field potentials from cultured cells, resulting in highly complex neuronal signals that necessitate precise spike sorting for meaningful data extraction. Nevertheless, conventional spike sorting methods face limitations in recognising diverse spike shapes, thereby constraining the full utilisation of the rich dataset acquired from MEA recordings. To overcome these limitations, we have developed a machine learning algorithm, namedPseudoSort, which employs advanced self-supervised learning techniques, a distinctive density-based pseudo-labelling strategy, and an iterative fine-tuning process to enhance spike sorting accuracy. Through extensive benchmarking on large-scale simulated datasets, we demonstrate the superior performance ofPseudoSortcompared to recently developed machine learning-based (ML) spike sorting algorithms. We showcase the practical application ofPseudoSortby utilising MEA recordings from hippocampal neurons exposed to subneuronal concentrations of monomeric Tau, a protein associated with Alzheimer’s disease (AD). Our results, validated against patch clamp experiments, unveil that monomeric Tau at subneuronal concentrations induces stimulation-dependent disruptions in both local and global activity of hippocampal neurons. Remarkably, patch clamp electrophysiology highlights the effect of combined Tau and neuronal stimulation treatment on excitatory postsynaptic currents, whereasPseudoSortexcels in identifying neuronal clusters that exhibit diminished firing capacity following Tau treatment alone,i.e., in the absence of stimulation. This comprehensive approach validates the prowess ofPseudoSortand unravels the intricate effects of Tau on neuronal activity, particularly in the context of AD.

Publisher

Cold Spring Harbor Laboratory

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