Spike sorting for large, dense electrode arrays

Rossant, Cyrille; Kadir, Shabnam N.; Goodman, Dan F. M.; John, Sabu; Belluscio, Mariano; Buzsáki, György; Harris, Kenneth D. M.

doi:10.1101/015198

Cited by 28 publications

(32 citation statements)

References 39 publications

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“…Wilson; MClust, A.D. Redish; Offline Sorter, Plexon). In other situations, clustering is automated, but the user must curate the results by selecting which clusters to reject, merge, or even split (Hill et al, 2011; Kadir et al, 2014; Rossant et al, 2016). There also exist post-processing steps that resolve overlapping spikes (Ekanadham et al, 2014; Franke et al, 2015; Pachitariu et al, 2016; Pillow et al, 2013), and algorithms based on independent component analysis (ICA) that do not explicitly involve clustering (Takahahi et al, 2002).…”

Section: Introductionmentioning

confidence: 99%

“…Manual sorting can have error rates in excess of 20% (Wood et al, 2004) and there is substantial variability in labeling across different sorting sessions (Harris et al, 2000; Pedreira et al, 2012; Rossant et al, 2016). Furthermore, the human spike sorter could never keep up with the increasing volume of data arising from increasingly large electrode arrays applied over increasingly long durations (Berenyi et al, 2014; Dhawale AK, 2015; Du et al, 2011; Lopez et al, 2016; Santhanam et al, 2007; Shobe et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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A Fully Automated Approach to Spike Sorting

Chung

Magland

Barnett

et al. 2017

Neuron

369

396

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Summary Understanding the detailed dynamics of neuronal networks will require the simultaneous measurement of spike trains from hundreds of neurons (or more). Currently, approaches to extracting spike times and labels from raw data are time consuming, lack standardization and involve manual intervention, making it difficult to maintain data provenance and assess the quality of scientific results. Here, we describe an automated clustering approach and associated software package that addresses these problems and provides novel cluster quality metrics. We show that our approach has accuracy comparable to or exceeding that achieved using manual or semi-manual techniques with desktop CPU runtimes faster than acquisition time for up to hundreds of electrodes. Moreover, a single choice of parameters in the algorithm is effective for a variety of electrode geometries and across multiple brain regions. This algorithm has the potential to enable reproducible and automated spike sorting of larger scale recordings than is currently possible.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Fully Automated Approach to Spike Sorting

Chung

Magland

Barnett

et al. 2017

Neuron

369

396

View full text Add to dashboard Cite

show abstract

“…A good example of this is filtering (Quian Quiroga and Panzeri, 2009), where the type of filter is shown to matter, and the use of spike shapes in spike sorting (Rossant et al, 2015). Workflows often include loops, whether for repeating an analysis across a number of datasets, or for repeating an analysis while varying some of the analysis parameters.…”

Section: Sharing Services and Workflowsmentioning

confidence: 98%

“…There is a huge and active literature on the analysis tools, whether for electrophysiology or other forms of neuroscience dataset (for example, Lewicki (1998), Harris et al (2000), Hulata et al (2002), Takahashi et al (2003), Pouzat et al (2004), Mizuseki et al (2014), Rossant et al (2015), to name but a few purely in the area of spike sorting). However, simply noting that a particular type of analysis (based on some equations in a paper, for example) has been carried out is not the same as sharing the analysis tools.…”

Section: Scientific and Clinical Reasonsmentioning

confidence: 99%

Why sharing matters for electrophysiological data analysis

Smith

2015

Brain Research Bulletin

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“…This same study also found as many as 24 single units in a virtual tetrode in the relatively sparse visual cortex. More recently, software algorithms that utilize precise spatial information as part of the sorting logic show great promise for improving both speed and accuracy 30,[80][81][82] . Investigating the optimal microelectrode size and pitch for speed and accuracy in spike sorting is an important research area.…”

Section: Recording Brain Activity Brief Historymentioning

confidence: 99%

State-of-the-art MEMS and microsystem tools for brain research

et al. 2017

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Mapping brain activity has received growing worldwide interest because it is expected to improve disease treatment and allow for the development of important neuromorphic computational methods. MEMS and microsystems are expected to continue to offer new and exciting solutions to meet the need for high-density, high-fidelity neural interfaces. Herein, the state-of-the-art in recording and stimulation tools for brain research is reviewed, and some of the most significant technology trends shaping the field of neurotechnology are discussed.

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Spike sorting for large, dense electrode arrays

Cited by 28 publications

References 39 publications

A Fully Automated Approach to Spike Sorting

A Fully Automated Approach to Spike Sorting

Why sharing matters for electrophysiological data analysis

State-of-the-art MEMS and microsystem tools for brain research

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