A Versatile Method for Viral Transfection of Calcium Indicators in the Neonatal Mouse Brain

He, Cynthia X.; Arroyo, Erica D.; Cantu, Daniel A.; Goel, Anubhuti; Portera‐Cailliau, Carlos

doi:10.3389/fncir.2018.00056

Cited by 20 publications

(24 citation statements)

References 32 publications

(45 reference statements)

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“…scientific community. Aspects of certain modules of the EZcalcium toolbox have already been successfully implemented in several published studies (He et al, 2017(He et al, , 2018Goel et al, 2018), and the toolbox is freely available on GitHub 2 .…”

Section: Discussionmentioning

confidence: 99%

“…In particular, calcium imaging with two-photon microscopy (Svoboda and Yasuda, 2006;Mostany et al, 2015) and microendoscopy with miniscopes or fiber photometry (Ghosh et al, 2011;Liberti et al, 2017;Jacob et al, 2018;Aharoni et al, 2019;Zhang et al, 2019) have provided key insights, such as how developing cortical networks undergo drastic transitions (Golshani et al, 2009;Rochefort et al, 2009) or how large neuronal ensembles encode spatial navigation (Dombeck et al, 2010). Calcium imaging offers several distinct advantages over traditional electrode recording techniques (Grewe and Helmchen, 2009;Grienberger and Konnerth, 2012): (1) it can be combined with genetic approaches (e.g., Cre-Lox) to probe neuronal activity in specific sub-populations of neurons (Goel et al, 2018;Yaeger et al, 2019) and glia (Srinivasan et al, 2016), either in specific subcellular compartments (e.g., axon boutons, dendritic spines, glial microdomains; Cichon and Gan, 2015;Broussard et al, 2018) or in specific brain regions or cortical layers (Lacefield et al, 2019); (2) recordings can be carried out over periods of days or even weeks (Chen et al, 2013;He et al, 2018); (3) recordings can be made simultaneously in a large population of hundreds or thousands of neurons in multiple brain regions (e.g., an entire sub-network; Sofroniew et al, 2016); (4) calcium imaging can also be combined with optogenetic manipulations, which makes it possible to perform all-optical probing of circuit function (Packer et al, 2015); (5) recordings can be performed in freely moving animals, providing a key link between circuit activity and behavior (Lin and Schnitzer, 2016); and (6) calcium imaging is less invasive than traditional electrode recordings (e.g., tetrodes, silicon probes). Another advantage the technique offers is the ability to precisely map the relative spatial location of groups of neurons.…”

Section: Introductionmentioning

confidence: 99%

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EZcalcium: Open-Source Toolbox for Analysis of Calcium Imaging Data

Cantu

Wang

Gongwer

et al. 2020

Front. Neural Circuits

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Fluorescence calcium imaging using a range of microscopy approaches, such as two-photon excitation or head-mounted "miniscopes," is one of the preferred methods to record neuronal activity and glial signals in various experimental settings, including acute brain slices, brain organoids, and behaving animals. Because changes in the fluorescence intensity of genetically encoded or chemical calcium indicators correlate with action potential firing in neurons, data analysis is based on inferring such spiking from changes in pixel intensity values across time within different regions of interest. However, the algorithms necessary to extract biologically relevant information from these fluorescent signals are complex and require significant expertise in programming to develop robust analysis pipelines. For decades, the only way to perform these analyses was for individual laboratories to write their custom code. These routines were typically not well annotated and lacked intuitive graphical user interfaces (GUIs), which made it difficult for scientists in other laboratories to adopt them. Although the panorama is changing with recent tools like CaImAn, Suite2P, and others, there is still a barrier for many laboratories to adopt these packages, especially for potential users without sophisticated programming skills. As two-photon microscopes are becoming increasingly affordable, the bottleneck is no longer the hardware, but the software used to analyze the calcium data optimally and consistently across different groups. We addressed this unmet need by incorporating recent software solutions, namely NoRMCorre and CaImAn, for motion correction, segmentation, signal extraction, and deconvolution of calcium imaging data into an open-source, easy to use, GUI-based, intuitive and automated data analysis software package, which we named EZcalcium.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

EZcalcium: Open-Source Toolbox for Analysis of Calcium Imaging Data

Cantu

Wang

Gongwer

et al. 2020

Front. Neural Circuits

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“…The goal of this project was to develop an open source toolbox for analysis of calcium imaging data that could be freely disseminated across the broader scientific community. Aspects of certain modules of the EZcalcium toolbox have already been successfully implemented in several published studies He et al, 2018;He et al, 2017) and the toolbox is freely available on GitHub (https://github.com/porteralab/EZcalcium).…”

Section: Discussionmentioning

confidence: 99%

“…In particular, calcium imaging with 2-photon microscopy (Mostany et al, 2015;Svoboda and Yasuda, 2006) and micro-endoscopy with miniscopes or fiber photometry (Aharoni et al, 2019;Ghosh et al, 2011;Jacob et al, 2018;Liberti et al, 2017;Zhang et al, 2019) have provided key insights, such as how developing cortical networks undergo drastic transitions (Golshani et al, 2009;Rochefort et al, 2009) or how large neuronal ensembles encode spatial navigation (Dombeck et al, 2010). Calcium imaging offers several distinct advantages over traditional electrode recording techniques (Grewe and Helmchen, 2009;Grienberger and Konnerth, 2012): 1) it can be combined with genetic approaches (e.g., Cre-Lox) to probe neuronal activity in specific sub-populations of neurons Yaeger et al, 2019) and glia (Srinivasan et al, 2016), either in specific subcellular compartments (e.g., axon boutons, dendritic spines, glial microdomains) (Broussard et al, 2018;Cichon and Gan, 2015) or in specific brain regions or cortical layers (Lacefield et al, 2019); 2) recordings can be carried out over periods of days or even weeks He et al, 2018); 3) recordings can be made simultaneously in a large population of hundreds or thousands of neurons in multiple brain regions (e.g., an entire sub-network) (Sofroniew et al, 2016); 4) calcium imaging can also be combined with optogenetic manipulations, which makes it possible to perform all-optical probing of circuit function (Packer et al, 2015); 5) recordings can be performed in freely moving animals, providing a key link between circuit activity and behavior (Lin and Schnitzer, 2016); and 6) calcium imaging is less invasive than traditional electrode recordings (e.g., tetrodes, silicon probes). Another advantage the technique offers is the ability to precisely map the relative spatial location of groups of neurons.…”

Section: Introductionmentioning

confidence: 99%

EZcalcium: Open Source Toolbox for Analysis of Calcium Imaging Data

Cantu

Wang

Gongwer

et al. 2020

Preprint

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Fluorescence calcium imaging using a range of microscopy approaches, such as 2-photon excitation or head-mounted 'miniscopes', is one of the preferred methods to record neuronal activity and glial signals in various experimental settings, including acute brain slices, brain organoids, and behaving animals. Because changes in the fluorescence intensity of genetically encoded or chemical calcium indicators correlate with action potential firing in neurons, data analysis is based on inferring such spiking from changes in pixel intensity values across time within different regions of interest. However, the algorithms necessary to extract biologically relevant information from these fluorescent signals are complex and require significant expertise in programming to develop robust analysis pipelines. For decades, the only way to perform these analyses was for individual laboratories to write their own custom code. These routines were typically not well annotated and lacked intuitive graphical user interfaces (GUIs), which made it difficult for scientists in other laboratories to adopt them. Although the panorama is changing with recent tools like CaImAn, Suite2P and others, there is still a barrier for many laboratories to adopt these packages, especially for potential users without sophisticated programming skills. As 2-photon microscopes are becoming increasingly affordable, 2 the bottleneck is no longer the hardware, but the software used to analyze the calcium data in an optimal manner and consistently across different groups. We addressed this unmet need by incorporating recent software solutions for motion correction, segmentation, signal extraction and deconvolution of calcium imaging data into an open-source, easy to use, GUI-based, intuitive and automated data analysis software, which we named EZcalcium.

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“…Classical virus-mediated gene transfer approaches into pre-selected brain regions are mostly limited to adult animals via stereotactic injections (Cetin et al, 2007 ). For a global expression of transduced genes in the mouse brain, a neonatal rAAV delivery method was introduced and used successfully (Passini and Wolfe, 2001 ; Pilpel et al, 2009 ; Chakrabarty et al, 2013 ; Kim et al, 2013 , 2014 ; McLean et al, 2014 ; Ayers et al, 2015 ; He et al, 2018 ). As alternatives to this global, neonatal rAAV gene transduction, in utero electroporation (Saito, 2006 ; Huang and Carcagno, 2018 ), or systemic injection of rAAV into the tail vein of adult or adolescent mice (Foust et al, 2009 ; Stoica et al, 2013 ; Körbelin et al, 2016 ; Thomsen et al, 2017 ) achieved similar expression of transfected or transduced genes in the mouse brain.…”

Section: Introductionmentioning

confidence: 99%

Alternative Anesthesia of Neonatal Mice for Global rAAV Delivery in the Brain With Non-detectable Behavioral Interference in Adults

Tang

Zillmann

Sprengel

2020

Front. Behav. Neurosci.

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Viral-transduced gene expression is the current standard for cell-type-specific labeling and cell tacking in experimental neuroscience. To achieve widespread gene expression, a viral delivery method to neonatal rodents was introduced more than two decades ago. Most of those neonatal viral vector injection-based gene transduction methods in mice used deep hypothermia for anesthesia, which was reported to be associated with behavioral impairments. To explore other options for neonatal viral applications, we applied a combination of Medetomidine, Midazolam, and Fentanyl (MMF), each of which can be antagonized by a specific antagonist. Later in their adulthood, we found that adult mice, that received the MMF-induced anesthesia, combined with virus-injected into the brain at postnatal day 2, showed similar performance in all behavioral tasks tested, including tasks for motor coordination, anxiety-related tasks, and spatial memory when compared to adult naïve littermates. This demonstrates that MMF anesthesia could be safely applied to mice for neonatal viral transduction at P2.

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A Versatile Method for Viral Transfection of Calcium Indicators in the Neonatal Mouse Brain

Cited by 20 publications

References 32 publications

EZcalcium: Open-Source Toolbox for Analysis of Calcium Imaging Data

EZcalcium: Open-Source Toolbox for Analysis of Calcium Imaging Data

EZcalcium: Open Source Toolbox for Analysis of Calcium Imaging Data

Alternative Anesthesia of Neonatal Mice for Global rAAV Delivery in the Brain With Non-detectable Behavioral Interference in Adults

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