An optical approach for mapping functional connectivity at single-cell resolution in brain circuits.
Publication
, Journal Article
Roy, S; Field, GD
Published in: Cell Rep Methods
August 22, 2022
In the current issue of Cell Reports Methods, Spampinato et al. demonstrate a multiplexed system combining holographic photo-stimulation and functional imaging that may offer a generalizable approach for revealing how signals interact in complex neural circuits.
Duke Scholars
Published In
Cell Rep Methods
DOI
EISSN
2667-2375
Publication Date
August 22, 2022
Volume
2
Issue
8
Start / End Page
100272
Location
United States
Related Subject Headings
- Retina
- Mice
- Holography
- Brain Mapping
- Brain
- Animals
Citation
APA
Chicago
ICMJE
MLA
NLM
Roy, S., & Field, G. D. (2022). An optical approach for mapping functional connectivity at single-cell resolution in brain circuits. Cell Rep Methods, 2(8), 100272. https://doi.org/10.1016/j.crmeth.2022.100272
Roy, Suva, and Greg D. Field. “An optical approach for mapping functional connectivity at single-cell resolution in brain circuits.” Cell Rep Methods 2, no. 8 (August 22, 2022): 100272. https://doi.org/10.1016/j.crmeth.2022.100272.
Roy S, Field GD. An optical approach for mapping functional connectivity at single-cell resolution in brain circuits. Cell Rep Methods. 2022 Aug 22;2(8):100272.
Roy, Suva, and Greg D. Field. “An optical approach for mapping functional connectivity at single-cell resolution in brain circuits.” Cell Rep Methods, vol. 2, no. 8, Aug. 2022, p. 100272. Pubmed, doi:10.1016/j.crmeth.2022.100272.
Roy S, Field GD. An optical approach for mapping functional connectivity at single-cell resolution in brain circuits. Cell Rep Methods. 2022 Aug 22;2(8):100272.
Published In
Cell Rep Methods
DOI
EISSN
2667-2375
Publication Date
August 22, 2022
Volume
2
Issue
8
Start / End Page
100272
Location
United States
Related Subject Headings
- Retina
- Mice
- Holography
- Brain Mapping
- Brain
- Animals