Two-photon imaging of cerebral hemodynamics and neural activity in awake and anesthetized marmosets

Santisakultarm, Thom P.; Kersbergen, Calvin J.; Bandy, Daryl K.; Ide, David C.; Choi, Sangho; Silva, Afonso C.

doi:10.1016/j.jneumeth.2016.07.003

Cited by 45 publications

(30 citation statements)

References 53 publications

(83 reference statements)

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“…We used an AAV1-GCaMP5G construct injected into S1, and an intravascular fluorescent dye to visualize individual neurons and blood vessels located up to 500 mm below the cortical surface. We observed task-induced vascular responses and neural activity for over 5 months before optical quality of the cranial window deteriorated (Santisakultarm et al, 2016). The use of optical methods for direct visualization of neural activity in the brain of awake behaving marmosets is a major future direction that significantly boosts the value of this species to neuroscience research.…”

Section: Future Directions and Conclusionmentioning

confidence: 92%

Anatomical and functional neuroimaging in awake, behaving marmosets

Silva

2016

Developmental Neurobiology

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The common marmoset (Callithrix jacchus) is a small New World monkey that has gained significant recent interest in neuroscience research, due in great part for its compatibility with gene editing techniques, but also due to its tremendous versatility as an experimental animal model. Neuroimaging modalities, including anatomical (MRI) and functional magnetic resonance imaging (fMRI), complemented by two-photon laser scanning microscopy and electrophysiology, have been at the forefront of unraveling the anatomical and functional organization of the marmoset brain. High resolution anatomical MRI of the marmoset brain can be obtained with remarkable cytoarchitectonic detail. Functional MRI of the marmoset brain has been used to study various sensory systems, including somatosensory, auditory and visual pathways, while resting-state fMRI studies have unraveled functional brain networks that bear great correspondence to those previously described in humans. Two-photon laser scanning microscopy of the marmoset brain has enabled the simultaneous recording of neuronal activity from thousands of neurons with single cell spatial resolution. In this article, we aim to review the main results obtained by our group and our colleagues in applying neuroimaging techniques to study the marmoset brain.

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Section: Future Directions and Conclusionmentioning

confidence: 92%

Anatomical and functional neuroimaging in awake, behaving marmosets

Silva

2016

Developmental Neurobiology

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“…One of the most promising aspects of the marmoset as a model system for neuroscience derives from its potential for genetic manipulation, since the initial demonstration of transgenic marmosets expressing enhanced green fluorescent protein (Sasaki et al, 2009;Cyranoski, 2014;Sasaki, 2015). More recently there have been demonstrations of using viral strategies to introduce genes for expressing calcium indicators which have allowed for in vivo calcium imaging in anesthetized marmosets (Sadakane et al, 2015;Santisakultarm et al, 2016). Successful optogenetic stimulation has also recently been reported (MacDougall et al, 2016).…”

Section: Working With Marmosets To Study the Motor Systemmentioning

confidence: 99%

The marmoset as a model system for studying voluntary motor control

Walker

MacLean

Hatsopoulos

2016

Developmental Neurobiology

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The common marmoset has recently gained interest as an animal model for systems and behavioral neuroscience. This is due in part to the advent of transgenic marmosets, which affords the possibility of combining genetic manipulations with physiological recording and behavioral monitoring to study neural systems. In this review, they will argue that the marmoset provides a unique opportunity to study the neural basis of voluntary motor control from an integrative perspective. First, as an intermediate animal model, the marmoset represents an important bridge in motor system function between other primates, including humans, and rodents. Second, due to the marmoset's small brain size and lissencephalic cortex, novel electrophysiological and optical recording technologies will allow an integrative study of cortical function at multiple spatial scales beyond that afforded by other non-human primate models. Finally, as a primate expressing an ancestral state of corticospinal organization, the marmoset offers the possibility of understanding the integrative function of cortical and spinal interneuron circuitry in isolation of more recent corticomotoneuronal elaborations. If the potential of the marmoset as a model species is to be realized, they will need to learn to work with their natural behavioral repertoire. They have concluded by considering practical aspects of studying motor systems with marmosets. © 2016 Wiley Periodicals, Inc. Develop Neurobiol 77: 273-285, 2017.

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“…New kinds of detectors like GaAsP photomultipliers or hybrid avalanche photodiodes allow detection of dimmer signals. Also, promising advances in the miniaturization of two-photon microscopes are enabling simultaneous recordings of neural circuit activity in freely moving animals (Yu et al 2015; Zong et al 2017) while avoiding the side effects associated with the use of anesthetics (Tran and Gordon 2015; Santisakultarm et al 2016). …”

Section: Introductionmentioning

confidence: 99%

Two-photon probes for in vivo multicolor microscopy of the structure and signals of brain cells

Ricard

Arroyo

et al. 2018

Brain Struct Funct

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Imaging the brain of living laboratory animals at a microscopic scale can be achieved by two-photon microscopy thanks to the high penetrability and low phototoxicity of the excitation wavelengths used. However, knowledge of the two-photon spectral properties of the myriad fluorescent probes is generally scarce and, for many, non-existent. In addition, the use of different measurement units in published reports further hinders the design of a comprehensive imaging experiment. In this review, we compile and homogenize the two-photon spectral properties of 280 fluorescent probes. We provide practical data, including the wavelengths for optimal two-photon excitation, the peak values of two-photon action cross section or molecular brightness, and the emission ranges. Beyond the spectroscopic description of these fluorophores, we discuss their binding to biological targets. This specificity allows in vivo imaging of cells, their processes, and even organelles and other subcellular structures in the brain. In addition to probes that monitor endogenous cell metabolism, studies of healthy and diseased brain benefit from the specific binding of certain probes to pathology-specific features, ranging from amyloid-β plaques to the autofluorescence of certain antibiotics. A special focus is placed on functional in vivo imaging using two-photon probes that sense specific ions or membrane potential, and that may be combined with optogenetic actuators. Being closely linked to their use, we examine the different routes of intravital delivery of these fluorescent probes according to the target. Finally, we discuss different approaches, strategies, and prerequisites for two-photon multicolor experiments in the brains of living laboratory animals.

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Two-photon imaging of cerebral hemodynamics and neural activity in awake and anesthetized marmosets

Cited by 45 publications

References 53 publications

Anatomical and functional neuroimaging in awake, behaving marmosets

Anatomical and functional neuroimaging in awake, behaving marmosets

The marmoset as a model system for studying voluntary motor control

Two-photon probes for in vivo multicolor microscopy of the structure and signals of brain cells

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