CellExplorer: a graphical user interface and a standardized pipeline for visualizing and characterizing single neurons

Research output: Working paperPreprintResearch

Standard

CellExplorer : a graphical user interface and a standardized pipeline for visualizing and characterizing single neurons. / Petersen, Peter C.; Siegle, Joshua H.; Steinmetz, Nicholas A.; Mahallati, Sara; Buzsáki, György.

2020.

Research output: Working paperPreprintResearch

Harvard

Petersen, PC, Siegle, JH, Steinmetz, NA, Mahallati, S & Buzsáki, G 2020 'CellExplorer: a graphical user interface and a standardized pipeline for visualizing and characterizing single neurons'. https://doi.org/10.1101/2020.05.07.083436

APA

Petersen, P. C., Siegle, J. H., Steinmetz, N. A., Mahallati, S., & Buzsáki, G. (2020). CellExplorer: a graphical user interface and a standardized pipeline for visualizing and characterizing single neurons. https://doi.org/10.1101/2020.05.07.083436

Vancouver

Petersen PC, Siegle JH, Steinmetz NA, Mahallati S, Buzsáki G. CellExplorer: a graphical user interface and a standardized pipeline for visualizing and characterizing single neurons. 2020. https://doi.org/10.1101/2020.05.07.083436

Author

Petersen, Peter C. ; Siegle, Joshua H. ; Steinmetz, Nicholas A. ; Mahallati, Sara ; Buzsáki, György. / CellExplorer : a graphical user interface and a standardized pipeline for visualizing and characterizing single neurons. 2020.

Bibtex

@techreport{1ed169b7dd7840b1acc83da97fe7b1ed,
title = "CellExplorer: a graphical user interface and a standardized pipeline for visualizing and characterizing single neurons",
abstract = "The large diversity of neuron types of the brain, characterized by a unique set of electrophysiological characteristics, provides the means by which cortical circuits perform complex operations. To quantify, compare, and visualize the functional features of single neurons, we have developed the open-source framework, CellExplorer. It consists of three components: a processing module that calculates standardized physiological metrics, performs neuron type classification and detects putative monosynaptic connections, a flexible data structure, and a powerful graphical interface. The graphical interface makes it possible to explore any combination of pre-computed features at the speed of a mouse click. The CellExplorer framework allows users to process and relate their data to a growing collection of “ground truth” neurons from different genetic lines, as well as to tens of thousands of single neurons collected across our labs. We believe CellExplorer will accelerate the linking of physiological properties of single neurons in the intact brain to genetically identified types.",
author = "Petersen, {Peter C.} and Siegle, {Joshua H.} and Steinmetz, {Nicholas A.} and Sara Mahallati and Gy{\"o}rgy Buzs{\'a}ki",
year = "2020",
doi = "10.1101/2020.05.07.083436",
language = "English",
type = "WorkingPaper",

}

RIS

TY - UNPB

T1 - CellExplorer

T2 - a graphical user interface and a standardized pipeline for visualizing and characterizing single neurons

AU - Petersen, Peter C.

AU - Siegle, Joshua H.

AU - Steinmetz, Nicholas A.

AU - Mahallati, Sara

AU - Buzsáki, György

PY - 2020

Y1 - 2020

N2 - The large diversity of neuron types of the brain, characterized by a unique set of electrophysiological characteristics, provides the means by which cortical circuits perform complex operations. To quantify, compare, and visualize the functional features of single neurons, we have developed the open-source framework, CellExplorer. It consists of three components: a processing module that calculates standardized physiological metrics, performs neuron type classification and detects putative monosynaptic connections, a flexible data structure, and a powerful graphical interface. The graphical interface makes it possible to explore any combination of pre-computed features at the speed of a mouse click. The CellExplorer framework allows users to process and relate their data to a growing collection of “ground truth” neurons from different genetic lines, as well as to tens of thousands of single neurons collected across our labs. We believe CellExplorer will accelerate the linking of physiological properties of single neurons in the intact brain to genetically identified types.

AB - The large diversity of neuron types of the brain, characterized by a unique set of electrophysiological characteristics, provides the means by which cortical circuits perform complex operations. To quantify, compare, and visualize the functional features of single neurons, we have developed the open-source framework, CellExplorer. It consists of three components: a processing module that calculates standardized physiological metrics, performs neuron type classification and detects putative monosynaptic connections, a flexible data structure, and a powerful graphical interface. The graphical interface makes it possible to explore any combination of pre-computed features at the speed of a mouse click. The CellExplorer framework allows users to process and relate their data to a growing collection of “ground truth” neurons from different genetic lines, as well as to tens of thousands of single neurons collected across our labs. We believe CellExplorer will accelerate the linking of physiological properties of single neurons in the intact brain to genetically identified types.

U2 - 10.1101/2020.05.07.083436

DO - 10.1101/2020.05.07.083436

M3 - Preprint

BT - CellExplorer

ER -

ID: 356962760