Optimal inter-electrode distances for maximizing single unit yield per electrode in neural recordings
Domokos Meszéna, Ward Fadel, Róbert Tóth, Angelique C. Paulk, Sydney S. Cash, Ziv Williams, Tamás Kiss, Marcell Stippinger, Lucia Wittner, Richárd Fiáth, Zoltán Somogyvári

TL;DR
This paper shows that spacing electrodes just right can significantly improve the number of neurons recorded in brain studies.
Contribution
The study identifies species- and region-specific optimal electrode spacing for maximizing spike sorting efficiency.
Findings
Optimal electrode spacing increases spike sorting efficiency by 1.7–3.75 times.
Electrode spacing needs to be tailored to specific brain regions and species.
Higher electrode density does not always improve sorting efficiency.
Abstract
State-of-the-art high-density multielectrode arrays enable the recording of simultaneous spiking activity from hundreds of neurons. Although significant efforts have been dedicated to enhancing neural recording devices and developing more efficient sorting algorithms, there has been relatively less focus on the allocation of microelectrodes–a factor that undeniably affects spike sorting effectiveness and ultimately the total number of detected neurons. Here, we systematically examined the relationship between optimal electrode spacing and spike sorting efficiency by creating virtual sparser layouts from high-density recordings through spatial downsampling. We assessed spike sorting performance by comparing the quantity of well-isolated single units per electrode in sparse configurations across various brain regions (neocortex and thalamus), species (rat, mouse, and human) and various…
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Taxonomy
TopicsNeuroscience and Neural Engineering · Neural dynamics and brain function · EEG and Brain-Computer Interfaces
