Neuropixels 2.0: A miniaturized high-density probe for stable, long-term brain recordings

Steinmetz, Nicholas A.; Aydın, Çağatay; Лебедева, А. Ю.; Okun, Michael; Pachitariu, Marius; Bauža, Marius; Beau, Maxime; Bhagat, Jai; Böhm, Claudia; Broux, Martijn; Chen, Susu; Colonell, Jennifer; Gardner, Richard J.; Karsh, Bill; Kostadinov, Dimitar; López, Carolina Mora; Park, Junchol; Putzeys, Jan; Sauerbrei, Britton; Daal, Rik van; Vollan, Abraham Z.; Welkenhuysen, Marleen; Z, Ye; Dudman, Joshua T.; Dutta, B.; Hantman, Adam W.; Harris, Kenneth D. M.; Lee, Albert K.; Moser, Edvard I; O’Keefe, John; Renart, Alfonso; Svoboda, Karel; Häusser, Michael; Haesler, Sebastian; Carandini, Matteo; Harris, T. D.

doi:10.1101/2020.10.27.358291

Cited by 132 publications

(207 citation statements)

References 72 publications

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“…Ongoing advances in neural interfacing technologies are enabling simultaneous monitoring of the activity of large neural populations across a wide array of brain areas and behaviors (1)(2)(3)(4)(5). Such technologies may fundamentally change the questions we can address about computations within a neural population, allowing neuroscientists to shift focus from understanding how individual neurons' activity relates to externally-measurable or controllable parameters, toward understanding how neurons within a network coordinate their activity to perform computations underlying those behaviors.…”

Section: Introductionmentioning

confidence: 99%

A large-scale neural network training framework for generalized estimation of single-trial population dynamics

Keshtkaran

Sedler

Chowdhury

et al. 2021

Preprint

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Large-scale recordings of neural activity are providing new opportunities to study network-level dynamics. However, the sheer volume of data and its dynamical complexity are critical barriers to uncovering and interpreting these dynamics. Deep learning methods are a promising approach due to their ability to uncover meaningful relationships from large, complex, and noisy datasets. When applied to high-D spiking data from motor cortex (M1) during stereotyped behaviors, they offer improvements in the ability to uncover dynamics and their relation to subjects’ behaviors on a millisecond timescale. However, applying such methods to less-structured behaviors, or in brain areas that are not well-modeled by autonomous dynamics, is far more challenging, because deep learning methods often require careful hand-tuning of complex model hyperparameters (HPs). Here we demonstrate AutoLFADS, a large-scale, automated model-tuning framework that can characterize dynamics in diverse brain areas without regard to behavior. AutoLFADS uses distributed computing to train dozens of models simultaneously while using evolutionary algorithms to tune HPs in a completely unsupervised way. This enables accurate inference of dynamics out-of-the-box on a variety of datasets, including data from M1 during stereotyped and free-paced reaching, somatosensory cortex during reaching with perturbations, and frontal cortex during cognitive timing tasks. We present a cloud software package and comprehensive tutorials that enable new users to apply the method without needing dedicated computing resources.

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Section: Introductionmentioning

confidence: 99%

A large-scale neural network training framework for generalized estimation of single-trial population dynamics

Keshtkaran

Sedler

Chowdhury

et al. 2021

Preprint

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“…However, recent advances in silicon processing enable much higher recording site densities and as such thin silicon probes with hundreds of recording sites per shanks have been reported [ 56 , 57 ]. For example, the Neuropixels 1.0 and 2.0 contain respectively 966 and 1280 recording sites per shank (70 µm x 20 µm), of which 384 can be read out simultaneously [ 58 , 59 , 60 ]. Additionally, due to their high electrode density, they have shown to be capable of recording and tracking hundreds of individual neurons for multiple weeks.…”

Section: Neural Activity Monitoringmentioning

confidence: 99%

Technological Challenges in the Development of Optogenetic Closed-Loop Therapy Approaches in Epilepsy and Related Network Disorders of the Brain

et al. 2020

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Epilepsy is a chronic, neurological disorder affecting millions of people every year. The current available pharmacological and surgical treatments are lacking in overall efficacy and cause side-effects like cognitive impairment, depression, tremor, abnormal liver and kidney function. In recent years, the application of optogenetic implants have shown promise to target aberrant neuronal circuits in epilepsy with the advantage of both high spatial and temporal resolution and high cell-specificity, a feature that could tackle both the efficacy and side-effect problems in epilepsy treatment. Optrodes consist of electrodes to record local field potentials and an optical component to modulate neurons via activation of opsin expressed by these neurons. The goal of optogenetics in epilepsy is to interrupt seizure activity in its earliest state, providing a so-called closed-loop therapeutic intervention. The chronic implantation in vivo poses specific demands for the engineering of therapeutic optrodes. Enzymatic degradation and glial encapsulation of implants may compromise long-term recording and sufficient illumination of the opsin-expressing neural tissue. Engineering efforts for optimal optrode design have to be directed towards limitation of the foreign body reaction by reducing the implant’s elastic modulus and overall size, while still providing stable long-term recording and large-area illumination, and guaranteeing successful intracerebral implantation. This paper presents an overview of the challenges and recent advances in the field of electrode design, neural-tissue illumination, and neural-probe implantation, with the goal of identifying a suitable candidate to be incorporated in a therapeutic approach for long-term treatment of epilepsy patients.

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“…A small craniotomy (diameter, 0.5 -1 mm) was made over the recording sites one the day prior to the first recording session. Extracellular spikes were recorded using Janelia silicon probes (HH-2) with two shanks (32 channels each, 25 µm interval between channel, 250 µm between shanks), or Neuropixels probes (Jun et al, 2017b;Steinmetz et al, 2020;Liu et al, 2020). For the HH-2 probe, 64 channel voltage signals were multiplexed, recorded on a PCI6133 board (National instrument), and digitized at 400 kHz (14 bit).…”

Section: Extracellular Electrophysiologymentioning

confidence: 99%

A midbrain - thalamus - cortex circuit reorganizes cortical dynamics to initiate planned movement

Inagaki

Chen

et al. 2020

Preprint

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Motor behaviors are often planned long before execution, but only released after specific sensory events. Planning and execution are each associated with distinct patterns of motor cortex activity. Key questions are how these dynamic activity patterns are generated and how they relate to behavior. Here we investigate the multi-regional neural circuits that link an auditory ‘go cue’ and the transition from planning to execution of directional licking. Ascending glutamatergic neurons in the midbrain reticular and pedunculopontine nuclei show short-latency and phasic changes in spike rate that are selective for the go cue. This signal is transmitted via the thalamus to the motor cortex, where it triggers a rapid reorganization of motor cortex state from planning-related activity to a motor command, which in turn drives appropriate movement. Our studies show how brainstem structures can control cortical dynamics via the thalamus for rapid and precise motor behavior.

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Neuropixels 2.0: A miniaturized high-density probe for stable, long-term brain recordings

Cited by 132 publications

References 72 publications

A large-scale neural network training framework for generalized estimation of single-trial population dynamics

A large-scale neural network training framework for generalized estimation of single-trial population dynamics

Technological Challenges in the Development of Optogenetic Closed-Loop Therapy Approaches in Epilepsy and Related Network Disorders of the Brain

A midbrain - thalamus - cortex circuit reorganizes cortical dynamics to initiate planned movement

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