In vivo voltage-sensitive dye imaging of mouse cortical activity with mesoscopic optical tomography

Tang, Qinggong; Tsytsarev, Vassiliy; Feng, Yan; Wang, Chen; Erzurumlu, Reha S.; Chen, Yu

doi:10.1117/1.nph.7.4.041402

Cited by 5 publications

(2 citation statements)

References 122 publications

(220 reference statements)

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“…Advances in imaging technologies that brought us cameras of high spatial and temporal resolution have made imaging neural population activity with fluorescent probes accessible. Voltage sensitive dyes (VSDs) have been used in mice to image neural activity in the barrel cortex ( Davis et al, 2011 ; Tsytsarev et al, 2017 ; Margalit and Slovin, 2018 ), frontal cortex ( Nagasaka et al, 2017 ), insular cortex ( Fujita et al, 2017 ), sensory cortex ( Gollnick et al, 2016 ), sensorimotor cortex ( Luhmann, 2017 ; Sreenivasan et al, 2017 ; Kunori and Takashima, 2019 ; Tang et al, 2020 ), and the motor cortex ( Kunori et al, 2014 ; Kunori and Takashima, 2016 ) in vivo . In case of the motor cortex, the researchers imaged the neural activity of the M1 and M2 motor cortex 200–300 μm below the cortical surface using the VSD and were able to observe spread of neural activity from M2 to M1 following forelimb-related sensory-evoked M2 activity.…”

Section: Discussionmentioning

confidence: 99%

Visualizing Oscillations in Brain Slices With Genetically Encoded Voltage Indicators

Rhee

Iwamoto²,

Baker

2021

Front. Neuroanat.

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Genetically encoded voltage indicators (GEVIs) expressed pan-neuronally were able to optically resolve bicuculline induced spontaneous oscillations in brain slices of the mouse motor cortex. Three GEVIs were used that differ in their timing of response to voltage transients as well as in their voltage ranges. The duration, number of cycles, and frequency of the recorded oscillations reflected the characteristics of each GEVI used. Multiple oscillations imaged in the same slice never originated at the same location, indicating the lack of a “hot spot” for induction of the voltage changes. Comparison of pan-neuronal, Ca2+/calmodulin-dependent protein kinase II α restricted, and parvalbumin restricted GEVI expression revealed distinct profiles for the excitatory and inhibitory cells in the spontaneous oscillations of the motor cortex. Resolving voltage fluctuations across space, time, and cell types with GEVIs represent a powerful approach to dissecting neuronal circuit activity.

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Section: Discussionmentioning

confidence: 99%

Visualizing Oscillations in Brain Slices With Genetically Encoded Voltage Indicators

Rhee

Iwamoto²,

Baker

2021

Front. Neuroanat.

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“…Advances in imaging technologies that brought us cameras of high spatial and temporal resolution have made imaging neural population activity with fluorescent probes accessible. Voltage sensitive dyes (VSDs) have been used in mice to image neural activity in the barrel cortex (Davis et al, 2011;Tsytsarev et al, 2017;Margalit and Slovin, 2018), frontal cortex (Nagasaka et al, 2017), insular cortex (Fujita et al, 2017), sensory cortex (Gollnick et al, 2016), sensorimotor cortex (Luhmann, 2017;Sreenivasan et al, 2017;Kunori and Takashima, 2019;Tang et al, 2020), and the motor cortex (Kunori et al, 2014;FIGURE 6 | Investigating common neural substrates of oscillations. For each 10 s recording containing more than one oscillation, pairwise correlations of each unmasked pixel and the reference pixel were calculated.…”

Section: Discussionmentioning

confidence: 99%

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Diffuse Fluorescence Tomography

Faulkner

Ochoa

Nizam

et al. 2021

Biomedical Optical Imaging

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This chapter discusses the field of diffuse fluorescence tomography in terms of fluorescence diffuse optical tomography (FDOT) and fluorescence molecular tomography (FMT). A brief overview of the forward photon propagation model is given. In addition, the techniques and challenges associated with solving the inverse problem, required for successful reconstruction, are discussed. Moreover, special attention is given to the different instrumentation used in diffuse fluorescence tomography. This includes the instrumentation associated with adequate illumination of the sample as well as efficient detection. Furthermore, the diverse applications of diffuse fluorescence tomography are explored, ranging from its use in biomarkers to preclinical applications and translational imaging. Finally, the chapter looks at the emerging technologies, which will shape the field in the near future.

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In vivo voltage-sensitive dye imaging of mouse cortical activity with mesoscopic optical tomography

Cited by 5 publications

References 122 publications

Visualizing Oscillations in Brain Slices With Genetically Encoded Voltage Indicators

Visualizing Oscillations in Brain Slices With Genetically Encoded Voltage Indicators

Presentation_1.pptx

Diffuse Fluorescence Tomography

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