Functional imaging with cellular resolution reveals precise micro-architecture in visual cortex

Neurons in the cerebral cortex are organized into anatomical columns, with ensembles of cells arranged from the surface to the white matter. Within a column, neurons often share functional properties, such as selectivity for stimulus orientation; columns with distinct properties, such as different preferred orientations, tile the cortical surface in orderly patterns. This functional architecture was discovered with the relatively sparse sampling of microelectrode recordings. Optical imaging of membrane voltage or metabolic activity elucidated the overall geometry of functional maps, but is averaged over many cells (resolution >100 µm). Consequently, the purity of functional domains and the precision of the borders between them could not be resolved. Here, we labelled thousands of neurons of the visual cortex with a calcium-sensitive indicator in vivo. We then imaged the activity of neuronal populations at single-cell resolution with two-photon microscopy up to a depth of 400 µm. In rat primary visual cortex, neurons had robust orientation selectivity but there was no discernible local structure; neighbouring neurons often responded to different orientations. In area 18 of cat visual cortex, functional maps were organized at a fine scale. Neurons with opposite preferences for stimulus direction were segregated with extraordinary spatial precision in three dimensions, with columnar borders one to two cells wide. These results indicate that cortical maps can be built with single-cell precision.

[1]  V. Mountcastle Modality and topographic properties of single neurons of cat's somatic sensory cortex. , 1957, Journal of neurophysiology.

[2]  D. Hubel,et al.  Receptive fields, binocular interaction and functional architecture in the cat's visual cortex , 1962, The Journal of physiology.

[3]  Z. Wiesenfeld,et al.  Receptive fields of single cells in the visual cortex of the hooded rat , 1975, Brain Research.

[4]  T. Wiesel,et al.  Morphology and intracortical projections of functionally characterised neurones in the cat visual cortex , 1979, Nature.

[5]  B. R. Payne,et al.  Organization of direction preferences in cat visual cortex , 1981, Brain Research.

[6]  Chia‐Sheng Lin,et al.  Receptive field properties of neurons in the visual cortex of the rat , 1981, Neuroscience Letters.

[7]  D. Whitteridge,et al.  The relationship of receptive field properties to the dendritic shape of neurones in the cat striate cortex. , 1984, The Journal of physiology.

[8]  A. Grinvald,et al.  Real-time optical imaging of naturally evoked electrical activity in intact frog brain , 1984, Nature.

[9]  G. Blasdel,et al.  Voltage-sensitive dyes reveal a modular organization in monkey striate cortex , 1986, Nature.

[10]  T. Wiesel,et al.  Functional architecture of cortex revealed by optical imaging of intrinsic signals , 1986, Nature.

[11]  B R Payne,et al.  Organization of orientation and direction selectivity in areas 17 and 18 of cat cerebral cortex. , 1987, Journal of neurophysiology.

[12]  M. Cynader,et al.  Surface organization of orientation and direction selectivity in cat area 18 , 1987, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[13]  Roger Y. Tsien,et al.  Fluorescence measurement and photochemical manipulation of cytosolic free calcium , 1988, Trends in Neurosciences.

[14]  D. Ts'o,et al.  Functional organization of primate visual cortex revealed by high resolution optical imaging. , 1990, Science.

[15]  Prof. Dr. Valentino Braitenberg,et al.  Anatomy of the Cortex , 1991, Studies of Brain Function.

[16]  Rafael Yuste,et al.  Control of postsynaptic Ca2+ influx in developing neocortex by excitatory and inhibitory neurotransmitters , 1991, Neuron.

[17]  Amiram Grinvald,et al.  Iso-orientation domains in cat visual cortex are arranged in pinwheel-like patterns , 1991, Nature.

[18]  T. M. Mayhew,et al.  Anatomy of the Cortex: Statistics and Geometry. , 1991 .

[19]  R. Yuste,et al.  Neuronal domains in developing neocortex. , 1992, Science.

[20]  A. Peters,et al.  Neuronal organization in area 17 of cat visual cortex. , 1993, Cerebral cortex.

[21]  R. Reid,et al.  Specificity of monosynaptic connections from thalamus to visual cortex , 1995, Nature.

[22]  D. Fitzpatrick,et al.  A systematic map of direction preference in primary visual cortex , 1996, Nature.

[23]  A. Grinvald,et al.  Functional Organization for Direction of Motion and Its Relationship to Orientation Maps in Cat Area 18 , 1996, The Journal of Neuroscience.

[24]  T Bonhoeffer,et al.  Orientation selectivity in pinwheel centers in cat striate cortex. , 1997, Science.

[25]  D. Kleinfeld,et al.  In vivo dendritic calcium dynamics in neocortical pyramidal neurons , 1997, Nature.

[26]  V. Mountcastle Perceptual Neuroscience: The Cerebral Cortex , 1998 .

[27]  D S Kim,et al.  Geometrical and topological relationships between multiple functional maps in cat primary visual cortex. , 1999, Neuroreport.

[28]  R. Lund,et al.  Receptive field properties of single neurons in rat primary visual cortex. , 1999, Journal of neurophysiology.

[29]  Y Matsuda,et al.  Arrangement of orientation pinwheel centers around area 17/18 transition zone in cat visual cortex. , 2000, Cerebral cortex.

[30]  R. Yuste,et al.  Dynamics of Spontaneous Activity in Neocortical Slices , 2001, Neuron.

[31]  D. L. Adams,et al.  Capricious expression of cortical columns in the primate brain , 2003, Nature Neuroscience.

[32]  Karel Svoboda,et al.  ScanImage: Flexible software for operating laser scanning microscopes , 2003, Biomedical engineering online.

[33]  W. Webb,et al.  Nonlinear magic: multiphoton microscopy in the biosciences , 2003, Nature Biotechnology.

[34]  J. A. Hirsch Synaptic physiology and receptive field structure in the early visual pathway of the cat. , 2003, Cerebral cortex.

[35]  C. Stosiek,et al.  In vivo two-photon calcium imaging of neuronal networks , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[36]  B. Sakmann,et al.  Molecular Supralinear Ca 2 Influx into Dendritic Tufts of Layer 2 / 3 Neocortical Pyramidal Neurons In Vitro and In Vivo , 2003 .

[37]  R. Reid,et al.  Efficacy of Retinal Spikes in Driving Cortical Responses , 2003, The Journal of Neuroscience.

[38]  Bert Sakmann,et al.  Supralinear Ca2+ Influx into Dendritic Tufts of Layer 2/3 Neocortical Pyramidal Neurons In Vitro and In Vivo , 2003, The Journal of Neuroscience.

[39]  F. Helmchen,et al.  Sulforhodamine 101 as a specific marker of astroglia in the neocortex in vivo , 2004, Nature Methods.

[40]  C. Blakemore,et al.  An analysis of orientation selectivity in the cat's visual cortex , 1974, Experimental Brain Research.

[41]  G. Buzsáki,et al.  Calcium Dynamics of Cortical Astrocytic Networks In Vivo , 2004, PLoS biology.

[42]  K. Fujita [Two-photon laser scanning fluorescence microscopy]. , 2007, Tanpakushitsu kakusan koso. Protein, nucleic acid, enzyme.