Paradoxical Rules of Spike Train Decoding Revealed at the Sensitivity Limit of Vision
暂无分享,去创建一个
Lina Smeds | Daisuke Takeshita | Tuomas Turunen | Jussi Tiihonen | Petri Ala-Laurila | Johan Westö | P. Ala-Laurila | D. Takeshita | N. Martyniuk | Tuomas Turunen | Lina Smeds | Jussi Tiihonen | Aarni Seppänen | J. Tiihonen
[1] M. Lavail,et al. Rods and cones in the mouse retina. I. Structural analysis using light and electron microscopy , 1979, The Journal of comparative neurology.
[2] Fred Rieke,et al. Network Variability Limits Stimulus-Evoked Spike Timing Precision in Retinal Ganglion Cells , 2006, Neuron.
[3] J. Sanes,et al. The types of retinal ganglion cells: current status and implications for neuronal classification. , 2015, Annual review of neuroscience.
[4] G. Fain,et al. Electrophysiological methods for measurement of activation of phototransduction by bleached visual pigment in salamander photoreceptors. , 2000, Methods in enzymology.
[5] F. Rieke,et al. Coincidence Detection of Single-Photon Responses in the Inner Retina at the Sensitivity Limit of Vision , 2014, Current Biology.
[6] A.-C. Aho,et al. Visual performance of the toad (Bufo bufo) at low light levels: retinal ganglion cell responses and prey-catching accuracy , 2004, Journal of Comparative Physiology A.
[7] Amyeo Jereen,et al. Single cell transcriptome profiling of retinal ganglion cells identifies cellular subtypes , 2018, Nature Communications.
[8] K. Donner,et al. In search of the visual pigment template , 2000, Visual Neuroscience.
[9] G. Field,et al. Inhibition Controls Receptive Field Size, Sensitivity, and Response Polarity of Direction Selective Ganglion Cells Near the Threshold of Vision , 2019, bioRxiv.
[10] P H Schiller,et al. Evidence for only depolarizing rod bipolar cells in the primate retina , 1989, Visual Neuroscience.
[11] R. Masland,et al. The Major Cell Populations of the Mouse Retina , 1998, The Journal of Neuroscience.
[12] E. Chichilnisky,et al. Detection Sensitivity and Temporal Resolution of Visual Signals near Absolute Threshold in the Salamander Retina , 2022 .
[13] P. Ala-Laurila,et al. Processing of single-photon responses in the mammalian On and Off retinal pathways at the sensitivity limit of vision , 2017, Philosophical Transactions of the Royal Society B: Biological Sciences.
[14] Peter H. Schiller,et al. The ON and OFF channels of the visual system , 1992, Trends in Neurosciences.
[15] B. Boycott,et al. Functional architecture of the mammalian retina. , 1991, Physiological reviews.
[16] Peter H. Schiller,et al. Parallel information processing channels created in the retina , 2010, Proceedings of the National Academy of Sciences.
[17] P. Sieving,et al. The electroretinogram of the rhodopsin knockout mouse , 1999, Visual Neuroscience.
[18] Georgios Tzimiropoulos,et al. Human Pose Estimation via Convolutional Part Heatmap Regression , 2016, ECCV.
[19] A. Aho,et al. Retinal origins of the temperature effect on absolute visual sensitivity in frogs. , 1993, The Journal of physiology.
[20] Adam Bleckert,et al. Visual Space Is Represented by Nonmatching Topographies of Distinct Mouse Retinal Ganglion Cell Types , 2014, Current Biology.
[21] Fred Rieke,et al. Nonlinear Spatiotemporal Integration by Electrical and Chemical Synapses in the Retina , 2016, Neuron.
[22] Y. Bar-Shalom,et al. The probabilistic data association filter , 2009, IEEE Control Systems.
[23] A. Fairhall,et al. Timescales of Inference in Visual Adaptation , 2009, Neuron.
[24] Andrew J. King,et al. Measuring the Performance of Neural Models , 2016, Front. Comput. Neurosci..
[25] K. Donner,et al. Chromophore switch from 11‐cis‐dehydroretinal (A2) to 11‐cis‐retinal (A1) decreases dark noise in salamander red rods , 2007, The Journal of physiology.
[26] S. Hecht,et al. ENERGY, QUANTA, AND VISION , 1942, The Journal of general physiology.
[27] T. M. Esdaille,et al. Dark Light, Rod Saturation, and the Absolute and Incremental Sensitivity of Mouse Cone Vision , 2010, The Journal of Neuroscience.
[28] Marie E. Burns,et al. Dynamics of Cyclic GMP Synthesis in Retinal Rods , 2002, Neuron.
[29] K. Yau,et al. Quantal noise from human red cone pigment , 2008, Nature Neuroscience.
[30] F. Rieke,et al. Mechanisms of single-photon detection in rod photoreceptors. , 2000, Methods in enzymology.
[31] Matthias Bethge,et al. The functional diversity of retinal ganglion cells in the mouse , 2015, Nature.
[32] Kevin L. Briggman,et al. Structural and functional diversity of a dense sample of retinal ganglion cells , 2017 .
[33] F. Rieke,et al. Single-Photon Absorptions Evoke Synaptic Depression in the Retina to Extend the Operational Range of Rod Vision , 2008, Neuron.
[34] Maneesh Sahani,et al. How Linear are Auditory Cortical Responses? , 2002, NIPS.
[35] Hannah L Payne,et al. Magnetic eye tracking in mice , 2017, eLife.
[36] Guigang Zhang,et al. Deep Learning , 2016, Int. J. Semantic Comput..
[37] Anthony W. Azevedo,et al. C-terminal threonines and serines play distinct roles in the desensitization of rhodopsin, a G protein-coupled receptor , 2015, eLife.
[38] William N. Grimes,et al. The Synaptic and Circuit Mechanisms Underlying a Change in Spatial Encoding in the Retina , 2014, Neuron.
[39] F. Rieke,et al. Electrical Synaptic Input to Ganglion Cells Underlies Differences in the Output and Absolute Sensitivity of Parallel Retinal Circuits , 2011, The Journal of Neuroscience.
[40] Maneesh Sahani,et al. A Head-Mounted Camera System Integrates Detailed Behavioral Monitoring with Multichannel Electrophysiology in Freely Moving Mice , 2018, Neuron.
[41] Edward N. Pugh,et al. From candelas to photoisomerizations in the mouse eye by rhodopsin bleaching in situ and the light-rearing dependence of the major components of the mouse ERG , 2004, Vision Research.
[42] David Fitzpatrick,et al. Topology of ON and OFF inputs in visual cortex enables an invariant columnar architecture , 2016, Nature.
[43] F. Rieke,et al. Retinal processing near absolute threshold: from behavior to mechanism. , 2005, Annual review of physiology.
[44] H. Wässle,et al. Receptive field properties of ON- and OFF-ganglion cells in the mouse retina , 2009, Visual Neuroscience.
[45] K. Donner,et al. Low retinal noise in animals with low body temperature allows high visual sensitivity , 1988, Nature.
[46] J. Stahl,et al. Eye orientation during static tilts and its relationship to spontaneous head pitch in the laboratory mouse , 2008, Brain Research.
[47] Anthony W. Azevedo,et al. Experimental Protocols Alter Phototransduction: The Implications for Retinal Processing at Visual Threshold , 2011, The Journal of Neuroscience.
[48] H. Sompolinsky,et al. Benefits of Pathway Splitting in Sensory Coding , 2014, The Journal of Neuroscience.
[49] D. Baylor,et al. The membrane current of single rod outer segments , 1979, Vision Research.
[50] John H. R. Maunsell,et al. Functions of the ON and OFF channels of the visual system , 1986, Nature.
[51] J. T. Henriksson,et al. Ultraviolet radiation transmittance of the mouse eye and its individual media components. , 2010, Experimental eye research.
[52] John S Stahl,et al. Using eye movements to assess brain function in mice , 2004, Vision Research.
[53] P. E. Hallett,et al. A schematic eye for the mouse, and comparisons with the rat , 1985, Vision Research.
[54] P. H. Schiller. Central connections of the retinal ON and OFF pathways , 1982, Nature.
[55] J. Hayes,et al. Elevated dark-adapted thresholds in hypopigmented mice measured with a water maze screening apparatus , 1993, Behavior genetics.