SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2091516658> ?p ?o ?g. }

Showing items 1 to 100 of ±123 with 100 items per page.

W2091516658 endingPage "221" @default.
W2091516658 startingPage "191" @default.
W2091516658 abstract "1. We measured the response of macaque ganglion cells to sinusoidally modulated red and green lights as the relative phase, theta, of the lights was varied. 2. At low frequencies, red-green ganglion cells of the parvocellular (PC-) pathway with opponent inputs from middle-wavelength sensitive (M-) and long-wavelength sensitive (L-) cones were minimally sensitive to luminance modulation (theta = 0 deg) and maximally sensitive to chromatic modulation (theta = 180 deg). With increasing frequency, the phase, theta, of minimal amplitude gradually changed, in opposite directions for cells with M- and L-cone centres. 3. At high frequencies (at and above 20 Hz), phasic cells of the magnocellular (MC-) pathway were maximally responsive when theta approximately 0 deg and minimally responsive when theta approximately 180 deg, as expected from an achromatic mechanism. At lower frequencies, the phase of minimal response shifted, for both on- and off-centre cells, to values of theta intermediate between 0 and 180 deg. This phase asymmetry was absent if the centre alone was stimulated with a small field. 4. For PC-pathway cells, it was possible to provide an account of response phase as a function of theta, using a model involving three parameters; phases of the L- and M-cone mechanisms and a L/M cone weighting term. For red-green cells, the phase parameters were monotonically related to temporal frequency and revealed a centre-surround phase difference. The phase difference was linear with a slope of 1-3 deg Hz-1. If this represents a latency difference, it would be 3-8 ms. Otherwise, temporal properties of the M- and L-cones appeared similar if not identical. By addition of a scaling term, the model could be extended to give an adequate account of the amplitude of responses. 5. We were able to activate selectively the surrounds of cells with short-wavelength (S-) cone input to their centres, and so were able to assess L/M cone weighting to the surround. M- and L-cone inputs added linearly for most cells. On average, the weighting corresponded to the Judd modification of the luminosity function although there was considerable inter-cell variability. 6. To account for results from MC-pathway cells, it was necessary to postulate a cone-opponent, chromatic input to their surrounds. We developed a receptive field model with linear summation of M- and L-cones to centre and surround, and with an additional M,L-cone opponent input to the surround.(ABSTRACT TRUNCATED AT 400 WORDS)" @default.
W2091516658 created "2016-06-24" @default.
W2091516658 creator A5030030562 @default.
W2091516658 creator A5036791302 @default.
W2091516658 creator A5040105108 @default.
W2091516658 creator A5041722871 @default.
W2091516658 creator A5060671251 @default.
W2091516658 date "1992-12-01" @default.
W2091516658 modified "2023-10-12" @default.
W2091516658 title "Responses of macaque ganglion cells to the relative phase of heterochromatically modulated lights." @default.
W2091516658 cites W1829900417 @default.
W2091516658 cites W1967762840 @default.
W2091516658 cites W1977097752 @default.
W2091516658 cites W1979871543 @default.
W2091516658 cites W1980400157 @default.
W2091516658 cites W1980434042 @default.
W2091516658 cites W1982447763 @default.
W2091516658 cites W1982467657 @default.
W2091516658 cites W1983647398 @default.
W2091516658 cites W1984722025 @default.
W2091516658 cites W1996822428 @default.
W2091516658 cites W1997325262 @default.
W2091516658 cites W1999985738 @default.
W2091516658 cites W2013517793 @default.
W2091516658 cites W2017329461 @default.
W2091516658 cites W2017623030 @default.
W2091516658 cites W2019217993 @default.
W2091516658 cites W2021096150 @default.
W2091516658 cites W2042895963 @default.
W2091516658 cites W2048697105 @default.
W2091516658 cites W2052462144 @default.
W2091516658 cites W2052655046 @default.
W2091516658 cites W2054266716 @default.
W2091516658 cites W2054283707 @default.
W2091516658 cites W2057546802 @default.
W2091516658 cites W2059376746 @default.
W2091516658 cites W2070292803 @default.
W2091516658 cites W2080295246 @default.
W2091516658 cites W2089338590 @default.
W2091516658 cites W2093726002 @default.
W2091516658 cites W2109019860 @default.
W2091516658 cites W2127238314 @default.
W2091516658 cites W2132731445 @default.
W2091516658 cites W2153053400 @default.
W2091516658 cites W2155170674 @default.
W2091516658 cites W2163318787 @default.
W2091516658 cites W2164833011 @default.
W2091516658 cites W2395399125 @default.
W2091516658 doi "https://doi.org/10.1113/jphysiol.1992.sp019413" @default.
W2091516658 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/1175151" @default.
W2091516658 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/1302264" @default.
W2091516658 hasPublicationYear "1992" @default.
W2091516658 type Work @default.
W2091516658 sameAs 2091516658 @default.
W2091516658 citedByCount "194" @default.
W2091516658 countsByYear W20915166582012 @default.
W2091516658 countsByYear W20915166582013 @default.
W2091516658 countsByYear W20915166582014 @default.
W2091516658 countsByYear W20915166582015 @default.
W2091516658 countsByYear W20915166582016 @default.
W2091516658 countsByYear W20915166582017 @default.
W2091516658 countsByYear W20915166582018 @default.
W2091516658 countsByYear W20915166582019 @default.
W2091516658 countsByYear W20915166582020 @default.
W2091516658 countsByYear W20915166582021 @default.
W2091516658 countsByYear W20915166582022 @default.
W2091516658 countsByYear W20915166582023 @default.
W2091516658 crossrefType "journal-article" @default.
W2091516658 hasAuthorship W2091516658A5030030562 @default.
W2091516658 hasAuthorship W2091516658A5036791302 @default.
W2091516658 hasAuthorship W2091516658A5040105108 @default.
W2091516658 hasAuthorship W2091516658A5041722871 @default.
W2091516658 hasAuthorship W2091516658A5060671251 @default.
W2091516658 hasBestOaLocation W20915166581 @default.
W2091516658 hasConcept C120665830 @default.
W2091516658 hasConcept C121332964 @default.
W2091516658 hasConcept C121535716 @default.
W2091516658 hasConcept C121731113 @default.
W2091516658 hasConcept C169760540 @default.
W2091516658 hasConcept C180205008 @default.
W2091516658 hasConcept C19071747 @default.
W2091516658 hasConcept C2778950215 @default.
W2091516658 hasConcept C2780723820 @default.
W2091516658 hasConcept C44280652 @default.
W2091516658 hasConcept C62520636 @default.
W2091516658 hasConcept C73313986 @default.
W2091516658 hasConcept C86803240 @default.
W2091516658 hasConceptScore W2091516658C120665830 @default.
W2091516658 hasConceptScore W2091516658C121332964 @default.
W2091516658 hasConceptScore W2091516658C121535716 @default.
W2091516658 hasConceptScore W2091516658C121731113 @default.
W2091516658 hasConceptScore W2091516658C169760540 @default.
W2091516658 hasConceptScore W2091516658C180205008 @default.
W2091516658 hasConceptScore W2091516658C19071747 @default.
W2091516658 hasConceptScore W2091516658C2778950215 @default.
W2091516658 hasConceptScore W2091516658C2780723820 @default.
W2091516658 hasConceptScore W2091516658C44280652 @default.
W2091516658 hasConceptScore W2091516658C62520636 @default.