| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Charles A Hass, Juan M Angueyra, Zachary Lindbloom-Brown, Fred Rieke, Gregory D Horwit. Chromatic detection from cone photoreceptors to V1 neurons to behavior in rhesus monkeys. Journal of vision. vol 15. issue 15. 2016-02-25. PMID:26523737. |
populations of weakly correlated v1 neurons narrowly exceeded the monkeys' chromatic sensitivity but fell well short of the cones' chromatic sensitivity, suggesting that most of the behavior-limiting noise lies between the cone outer segments and the output of v1. |
2016-02-25 |
2023-08-13 |
monkey |
| Xiaobing Li, Yao Chen, Reza Lashgari, Yulia Bereshpolova, Harvey A Swadlow, Barry B Lee, Jose Manuel Alons. Mixing of Chromatic and Luminance Retinal Signals in Primate Area V1. Cerebral cortex (New York, N.Y. : 1991). vol 25. issue 7. 2016-02-19. PMID:24464943. |
mixing of chromatic and luminance retinal signals in primate area v1. |
2016-02-19 |
2023-08-12 |
Not clear |
| Xiaobing Li, Yao Chen, Reza Lashgari, Yulia Bereshpolova, Harvey A Swadlow, Barry B Lee, Jose Manuel Alons. Mixing of Chromatic and Luminance Retinal Signals in Primate Area V1. Cerebral cortex (New York, N.Y. : 1991). vol 25. issue 7. 2016-02-19. PMID:24464943. |
vision emerges from activation of chromatic and achromatic retinal channels whose interaction in visual cortex is still poorly understood. |
2016-02-19 |
2023-08-12 |
Not clear |
| Xiaobing Li, Yao Chen, Reza Lashgari, Yulia Bereshpolova, Harvey A Swadlow, Barry B Lee, Jose Manuel Alons. Mixing of Chromatic and Luminance Retinal Signals in Primate Area V1. Cerebral cortex (New York, N.Y. : 1991). vol 25. issue 7. 2016-02-19. PMID:24464943. |
to investigate this interaction, we recorded neuronal activity from retinal ganglion cells and v1 cortical cells in macaques and measured their visual responses to grating stimuli that had either luminance contrast (luminance grating), chromatic contrast (chromatic grating), or a combination of the two (compound grating). |
2016-02-19 |
2023-08-12 |
Not clear |
| Xiaobing Li, Yao Chen, Reza Lashgari, Yulia Bereshpolova, Harvey A Swadlow, Barry B Lee, Jose Manuel Alons. Mixing of Chromatic and Luminance Retinal Signals in Primate Area V1. Cerebral cortex (New York, N.Y. : 1991). vol 25. issue 7. 2016-02-19. PMID:24464943. |
as with parvocellular or koniocellular retinal ganglion cells, some v1 cells responded mostly to the chromatic contrast of the compound grating. |
2016-02-19 |
2023-08-12 |
Not clear |
| Xiaobing Li, Yao Chen, Reza Lashgari, Yulia Bereshpolova, Harvey A Swadlow, Barry B Lee, Jose Manuel Alons. Mixing of Chromatic and Luminance Retinal Signals in Primate Area V1. Cerebral cortex (New York, N.Y. : 1991). vol 25. issue 7. 2016-02-19. PMID:24464943. |
as with magnocellular retinal ganglion cells, other v1 cells responded mostly to the luminance contrast and generated a frequency-doubled response to equiluminant chromatic gratings. |
2016-02-19 |
2023-08-12 |
Not clear |
| Shay Zweig, Guy Zurawel, Robert Shapley, Hamutal Slovi. Representation of Color Surfaces in V1: Edge Enhancement and Unfilled Holes. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 35. issue 35. 2015-11-25. PMID:26338322. |
we used voltage-sensitive-dye imaging in fixating macaque monkeys to measure v1 population responses to spatially uniform chromatic (red, green, or blue) and achromatic (black or white) squares of different sizes (0.5°-8°) presented for 300 ms. |
2015-11-25 |
2023-08-13 |
monkey |
| Shay Zweig, Guy Zurawel, Robert Shapley, Hamutal Slovi. Representation of Color Surfaces in V1: Edge Enhancement and Unfilled Holes. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 35. issue 35. 2015-11-25. PMID:26338322. |
our results imply that uniform filled-in representations of surfaces in v1 are not required for the perception of uniform surfaces and that chromatic and achromatic squares are represented differently in v1. |
2015-11-25 |
2023-08-13 |
monkey |
| Henry Railo, Eki Andersson, Valtteri Kaasinen, Teemu Laine, Mika Koivist. Unlike in clinical blindsight patients, unconscious processing of chromatic information depends on early visual cortex in healthy humans. Brain stimulation. vol 7. issue 3. 2015-05-18. PMID:24698972. |
unlike in clinical blindsight patients, unconscious processing of chromatic information depends on early visual cortex in healthy humans. |
2015-05-18 |
2023-08-13 |
Not clear |
| Dajun Xing, Ahmed Ouni, Stephanie Chen, Hinde Sahmoud, James Gordon, Robert Shaple. Brightness-color interactions in human early visual cortex. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 35. issue 5. 2015-04-14. PMID:25653377. |
we localized the brightness-color interaction in human v1 by means of recording the chromatic visual-evoked potential. |
2015-04-14 |
2023-08-13 |
human |
| Dajun Xing, Ahmed Ouni, Stephanie Chen, Hinde Sahmoud, James Gordon, Robert Shaple. Brightness-color interactions in human early visual cortex. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 35. issue 5. 2015-04-14. PMID:25653377. |
the chromatic visual-evoked potential measurements decisively support the idea that brightness-color interaction arises in a recurrent inhibitory network in v1. |
2015-04-14 |
2023-08-13 |
human |
| Andreas Keil, Vladimir Miskovic, Michael J Gray, Jasna Martinovi. Luminance, but not chromatic visual pathways, mediate amplification of conditioned danger signals in human visual cortex. The European journal of neuroscience. vol 38. issue 9. 2014-06-20. PMID:23889165. |
luminance, but not chromatic visual pathways, mediate amplification of conditioned danger signals in human visual cortex. |
2014-06-20 |
2023-08-12 |
human |
| Andreas Keil, Vladimir Miskovic, Michael J Gray, Jasna Martinovi. Luminance, but not chromatic visual pathways, mediate amplification of conditioned danger signals in human visual cortex. The European journal of neuroscience. vol 38. issue 9. 2014-06-20. PMID:23889165. |
we conclude that sensory input conducted via the chromatic pathways into retinotopic visual cortex has limited access to the bi-directional connectivity with brain networks mediating the acquisition and expression of fear, such as the amygdaloid complex. |
2014-06-20 |
2023-08-12 |
human |
| Charles A Hass, Gregory D Horwit. V1 mechanisms underlying chromatic contrast detection. Journal of neurophysiology. vol 109. issue 10. 2013-11-25. PMID:23446689. |
v1 mechanisms underlying chromatic contrast detection. |
2013-11-25 |
2023-08-12 |
monkey |
| Charles A Hass, Gregory D Horwit. V1 mechanisms underlying chromatic contrast detection. Journal of neurophysiology. vol 109. issue 10. 2013-11-25. PMID:23446689. |
to elucidate the cortical mechanisms of color vision, we recorded from individual primary visual cortex (v1) neurons in macaque monkeys performing a chromatic detection task. |
2013-11-25 |
2023-08-12 |
monkey |
| Christian J Kellner, Thomas Wachtle. A distributed code for color in natural scenes derived from center-surround filtered cone signals. Frontiers in psychology. vol 4. 2013-10-07. PMID:24098289. |
in the retina of trichromatic primates, chromatic information is encoded in an opponent fashion and transmitted to the lateral geniculate nucleus (lgn) and visual cortex via parallel pathways. |
2013-10-07 |
2023-08-12 |
Not clear |
| Christian J Kellner, Thomas Wachtle. A distributed code for color in natural scenes derived from center-surround filtered cone signals. Frontiers in psychology. vol 4. 2013-10-07. PMID:24098289. |
in the visual cortex, however, the chromatic selectivities are more distributed, which is in accordance with a population code for color. |
2013-10-07 |
2023-08-12 |
Not clear |
| Christian J Kellner, Thomas Wachtle. A distributed code for color in natural scenes derived from center-surround filtered cone signals. Frontiers in psychology. vol 4. 2013-10-07. PMID:24098289. |
in contrast to previous analyses of linear transformations of cone signals, chromatic selectivities were not restricted to two main chromatic axes, but were more continuously distributed in color space, similar to the population code of color in the early visual cortex. |
2013-10-07 |
2023-08-12 |
Not clear |
| Claudia Lunghi, David C Burr, M Concetta Morron. Long-term effects of monocular deprivation revealed with binocular rivalry gratings modulated in luminance and in color. Journal of vision. vol 13. issue 6. 2013-09-30. PMID:23637272. |
we tested the residual plastic potential of the adult visual cortex for both achromatic and chromatic vision by measuring binocular rivalry in adult humans following 150 minutes of monocular patching. |
2013-09-30 |
2023-08-12 |
Not clear |
| Oleg Leontiev, Giedrius T Buracas, Christine Liang, Beau M Ances, Joanna E Perthen, Amir Shmuel, Richard B Buxto. Coupling of cerebral blood flow and oxygen metabolism is conserved for chromatic and luminance stimuli in human visual cortex. NeuroImage. vol 68. 2013-08-01. PMID:23238435. |
coupling of cerebral blood flow and oxygen metabolism is conserved for chromatic and luminance stimuli in human visual cortex. |
2013-08-01 |
2023-08-12 |
human |