Neural response dynamics of spiking and local field potential activity depend on CRT monitor refresh rate in the tree shrew primary visual cortex.

Entrainment of neural activity to luminance impulses during the refresh of cathode ray tube monitor displays has been observed in the primary visual cortex (V1) of humans and macaque monkeys. This entrainment is of interest because it tends to temporally align and thus synchronize neural responses at the millisecond timescale. Here we show that, in tree shrew V1, both spiking and local field potential activity are also entrained at cathode ray tube refresh rates of 120, 90, and 60 Hz, with weakest but still significant entrainment even at 120 Hz, and strongest entrainment occurring in cortical input layer IV. For both luminance increments ("white" stimuli) and decrements ("black" stimuli), refresh rate had a strong impact on the temporal dynamics of the neural response for subsequent luminance impulses. Whereas there was rapid, strong attenuation of spikes and local field potential to prolonged visual stimuli composed of luminance impulses presented at 120 Hz, attenuation was nearly absent at 60-Hz refresh rate. In addition, neural onset latencies were shortest at 120 Hz and substantially increased, by ∼15 ms, at 60 Hz. In terms of neural response amplitude, black responses dominated white responses at all three refresh rates. However, black/white differences were much larger at 60 Hz than at higher refresh rates, suggesting a mechanism that is sensitive to stimulus timing. Taken together, our findings reveal many similarities between V1 of macaque and tree shrew, while underscoring a greater temporal sensitivity of the tree shrew visual system.

[1]  Donald I A MacLeod,et al.  Imperceptibly rapid contrast modulations processed in cortex: Evidence from psychophysics. , 2010, Journal of vision.

[2]  P. Whittle Increments and decrements: Luminance discrimination , 1986, Vision Research.

[3]  R. Shapley,et al.  Generation of Black-Dominant Responses in V1 Cortex , 2010, The Journal of Neuroscience.

[4]  A Pantle,et al.  Flicker adaptation. I. Effect on visual sensitivity to temporal fluctuations of light intensity. , 1971, Vision research.

[5]  H. Spitzer,et al.  Temporal encoding of two-dimensional patterns by single units in primate inferior temporal cortex. I. Response characteristics. , 1987, Journal of neurophysiology.

[6]  R. Shapley,et al.  Temporal-frequency selectivity in monkey visual cortex , 1996, Visual Neuroscience.

[7]  S. Shipp The brain circuitry of attention , 2004, Trends in Cognitive Sciences.

[8]  Tom H. Pringle,et al.  Molecular and Genomic Data Identify the Closest Living Relative of Primates , 2007, Science.

[9]  D. Snodderly,et al.  A Dissociation Between Brain Activity and Perception: Chromatically Opponent Cortical Neurons Signal Chromatic Flicker that is not Perceived , 1997, Vision Research.

[10]  A. Kohn Visual adaptation: physiology, mechanisms, and functional benefits. , 2007, Journal of neurophysiology.

[11]  François Mauguière,et al.  Human lateral geniculate nucleus and visual cortex respond to screen flicker , 2003, Annals of neurology.

[12]  Daniel E. Wollman,et al.  Phase locking of neuronal responses to the vertical refresh of computer display monitors in cat lateral geniculate nucleus and striate cortex , 1995, Journal of Neuroscience Methods.

[13]  Stephen D. Van Hooser,et al.  Orientation Selectivity without Orientation Maps in Visual Cortex of a Highly Visual Mammal , 2005, The Journal of Neuroscience.

[14]  K. H. Mild,et al.  Steady-state visual evoked potentials to computer monitor flicker. , 1998, International journal of psychophysiology : official journal of the International Organization of Psychophysiology.

[15]  Georgios A Keliris,et al.  Neurons in macaque area V4 acquire directional tuning after adaptation to motion stimuli , 2005, Nature Neuroscience.

[16]  R. Shapley,et al.  “Black” Responses Dominate Macaque Primary Visual Cortex V1 , 2009, The Journal of Neuroscience.

[17]  B. Richmond,et al.  Latency: another potential code for feature binding in striate cortex. , 1996, Journal of neurophysiology.

[18]  B J Richmond,et al.  Temporal encoding of two-dimensional patterns by single units in primate inferior temporal cortex. II. Quantification of response waveform. , 1987, Journal of neurophysiology.

[19]  Ke Zhou,et al.  Human visual cortex responds to invisible chromatic flicker , 2007, Nature Neuroscience.

[20]  M W Oram,et al.  The temporal resolution of neural codes: does response latency have a unique role? , 2002, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[21]  James Gordon,et al.  Entrainment to Video Displays in Primary Visual Cortex of Macaque and Humans , 2004, The Journal of Neuroscience.

[22]  John Krauskopf,et al.  Discrimination and detection of changes in luminance , 1980, Vision Research.

[23]  K. Grieve,et al.  The primate pulvinar nuclei: vision and action , 2000, Trends in Neurosciences.

[24]  Joel Pokorny,et al.  Sawtooth contrast sensitivity: Decrements have the edge , 1989, Vision Research.

[25]  L. Optican,et al.  Temporal encoding of two-dimensional patterns by single units in primate inferior temporal cortex. III. Information theoretic analysis. , 1987, Journal of neurophysiology.

[26]  D. Fitzpatrick,et al.  Spatial coding of position and orientation in primary visual cortex , 2002, Nature Neuroscience.

[27]  W. Murphy,et al.  Resolution of the Early Placental Mammal Radiation Using Bayesian Phylogenetics , 2001, Science.

[28]  Jon H Kaas,et al.  Architectonic Subdivisions of Neocortex in the Tree Shrew (Tupaia belangeri) , 2009, Anatomical record.

[29]  M. Oram Contrast induced changes in response latency depend on stimulus specificity , 2010, Journal of Physiology-Paris.

[30]  R. Shapley,et al.  Spatial Spread of the Local Field Potential and its Laminar Variation in Visual Cortex , 2009, The Journal of Neuroscience.

[31]  Michael M. Miyamoto,et al.  Molecular and Morphological Supertrees for Eutherian (Placental) Mammals , 2001, Science.

[32]  K. Grill-Spector,et al.  fMR-adaptation: a tool for studying the functional properties of human cortical neurons. , 2001, Acta psychologica.

[33]  A. Short,et al.  Decremental and incremental visual thresholds , 1966, The Journal of physiology.

[34]  B J Richmond,et al.  Temporal encoding of two-dimensional patterns by single units in primate primary visual cortex. II. Information transmission. , 1990, Journal of neurophysiology.

[35]  J. Victor,et al.  Nature and precision of temporal coding in visual cortex: a metric-space analysis. , 1996, Journal of neurophysiology.

[36]  Gregor Rainer Localizing Cortical Computations during Visual Selection , 2008, Neuron.

[37]  P. H. Schiller,et al.  Spatial frequency and orientation tuning dynamics in area V1 , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[38]  D. Kerzel,et al.  Visual flicker in the gamma-band range does not draw attention. , 2010, Journal of neurophysiology.

[39]  J. Kaas,et al.  Cortical connections of area 17 in tree shrews , 1984, The Journal of comparative neurology.

[40]  F. Mechler,et al.  Temporal coding of contrast in primary visual cortex: when, what, and why. , 2001, Journal of neurophysiology.

[41]  A. Buchner,et al.  Text – background polarity affects performance irrespective of ambient illumination and colour contrast , 2007, Ergonomics.

[42]  H. M. Petry,et al.  Psychophysical measurement of temporal modulation sensitivity in the tree shrew (Tupaia belangeri) , 2000, Vision Research.