PUBLICATIONS

Name Headline Link
Grinvald A, Bonhoeffer T, Vanzetta I, et al. High-resolution functional optical imaging: from the neocortex to the eye. Ophthalmol Clin North Am. Mar 2004;17(1):53-67.  link icon
Nelson DA, Krupsky S, Pollack A, et al. Special report: Noninvasive multi-parameter functional optical imaging of the eye. Ophthalmic Surg Lasers Imaging. Jan-Feb 2005;36(1):57-66.  link icon
Landa G, Garcia PM, Rosen RB. Correlation between Retina Blood Flow Velocity Assessed by Retinal Function Imager and Retina Thickness Estimated by Scanning Laser Ophthalmoscopy/Optical Coherence Tomography. Ophthalmologica. Jan 12 2009;223(3):155-161. link icon
Izhaky D, Nelson DA, Burgansky-Eliash Z, Grinvald A. Functional Imaging Using the Retinal Function Imager: Direct Imaging of Blood Velocity, achieving Fluorescein Angiography-like Images Without any Contrast Agent, Qualitative Oximetry and Functional Metabolic Signals. Japanese Journal of Ophthalmology. 2009 53:345-351. link icon
Landa G, Rosen RB. New Patterns of Retinal Collateral Circulation are Exposed by the Retinal Functional Imager (RFI). Br J Ophthalmol. 2010;94:54-58.  link icon
Landa G, Rosen RB. A New Vascular Pattern for Idiopathic Juxtafoveal Telangiectasia Revealed by the Retinal Function Imager. Ophthalmic Surg Lasers Imaging. Jan-Feb 2010;41(3). link icon
Burgansky-Eliash Z, Nelson DA, Bar-Tal Pupko O, Lowenstein A, Grinvald A, Barak A. Reduced Retinal Blood Flow Velocity in Diabetic Retinopathy. Retina 2010: 30(5):765-773. link icon
Landa G, Amde W, Haileselassie Y, Rosen RB.  Cilioretinal arteries in diabetic eyes are associated with increased retinal blood flow velocity and occurrence of diabetic macular edema. Retina. 2011 Feb;31(2):304-11.  link icon
Burgansky-Eliash Z, Barash H, Nelson DA, et al.  Retinal Function Imager Measurements of Retinal Blood Flow Velocity in Patients with Early Diabetes Mellitus.Retina in press link icon
Darin A. Nelson, Amit Ruf, Oaknin Jacob, Zvia Burgansky-Eliash, Hila Barash, David Izhaky, Anat Lowenstein, Adiel Barak, Elisha Bartov, Tali Rock, Amiram Grinvald. High-Resolution Imaging of Perfused Capillaries Without the Use of Contrast Agent. Submitted. link icon
Barash H, Burgansky-Eliash Z, Nelson DA, Izhaky D, Barak A, Lowenstein A, Neuderfer M, Kesler A, Grinvald A. Retinal Function Imager Measurements of Retinal Blood Flow Velocity and their Relationship to Various Physiological Parameters. Submitted. link icon
Adiel Barak, Zvia Burgansky-Eliash, Hila Barash, Darin A. Nelson, Amiram Grinvald, Anat Lowenstein. The Effect of Intravitreal Bevacizumab (Avastin) Injection on Retinal Blood Flow Velocity. Submitted link icon
Beutelspacher SC. Serbecic N. Barash H. Burgansky-Eliash Z. Grinvald A. Jonas JB (2011) Central serous chorioretinopathy shows reduced retinal circulation in retinal function imaging (RFI) Acta Ophthalmologica 23 DOI: 10.1111/j.1755-3768 link icon
Name Headline Link
Palagina G, Eysel UT and Jancke D (2009) Strengthening of lateral activation in adult rat visual cortex after retinal lesions captured with voltage-sensitive dye imaging in vivo, PNAS 106 (21):1743-1747. link icon
MacEvoy, SP, Tucker TR and Fitzpatrick D (2009) A precise form of divisive suppression supports population coding in the primary visual cortex, Nature Neuroscience 12 (5): 637-645. link icon
Livneh Y, Feinstein N, Klein M and Mizrahi A (2009) Sensory Input Enhances Synaptogenesis of Adult-Born Neurons, Journal of Neuroscience 29 (1): 86? 97. link icon
Li Y, Van Hooser SD, Mazurek M, White LE and Fitzpatrick D (2008) Experience with moving visual stimuli drives the early development of cortical direction selectivity, Nature 456 (7224): 952-956. link icon
Chen G, Lu HD and Roe AW (2008) A Map for Horizontal Disparity in Monkey V2, Neuron 58 (3):442-450. link icon
Nauhaus I., Benucci A, Carandini M and Ringach DL (2008) Neuronal Selectivity and Local Map Structure in Visual Cortex, Neuron 57 (5): 673-679.  link icon
Kerr JND,de Kock CPJ, Greenberg DS, Bruno RM, Sakmann B. and Helmchen F (2007) Spatial Organization of Neuronal Population Responses in Layer 2/3 of Rat Barrel Cortex, Journal of Neuroscience 27 (48): 13316-13328. link icon
Chen LM, Turner GH, Friedman RM, Zhang N, Gore JC, Roe AW and Avison MJ (2007) High-Resolution Maps of Real and Illusory Tactile Activation in Primary Somatosensory Cortex in Individual Monkeys with Functional Magnetic Resonance Imaging and Optical Imaging, Journal of Neuroscience 27 (34): 9181-9191. link icon
Accolla R, Bathellier B, Petersen CCH and Carleton Alan (2007) Differential Spatial Representation of Taste Modalities in the Rat Gustatory Cortex, Journal of Neuroscience 27 (6): 1396-1404. link icon
Xu X, Collins CE, Khaytin I, Kaas JH and Casagrande VA (2006) Unequal representation of cardinal vs. oblique orientations in the middle temporal visual area, PNAS 103 (46): 17490-17495.  link icon
Chen Y, Geisle WS and Seidemann E (2006) Optimal decoding of correlated neural population responses in the primate visual cortex, Nature Neuroscience 9 (11): 1412?1420.  link icon
Ohki K, Chung S, Kara, P, Hubener M, Bonhoeffer T and Reid RC (2006) Highly ordered arrangement of single neurons in orientation pinwheels, Nature 442 (7105): 925-928.  link icon
Lin DY, Shea SD, Katz LC (2006) Representation of Natural Stimuli in the Rodent Main Olfactory Bulb, Neuron 50 (6): 937-949.  link icon
Hofer SB, Mrsic-Flogel TD, Bonhoeffer T and Hübener M (2005) Prior experience enhances plasticity in adult visual cortex, Nature Neuroscience 9 (1): 127-132.  link icon
Roe AW, Lu HD and Hung CP (2005) Cortical processing of a brightness illusion, PNAS 2005 102 (10): 3869-3874.  link icon
Van Hooser SD, Heimel, JAF, Chung S, Nelson SB and Toth LJ (2005) Orientation Selectivity without Orientation Maps in Visual Cortex of a Highly Visual Mammal, Journal of Neuroscience 25 (1): 19-28.  link icon
Vanzetta I, Slovin H, Omer DB, et al. Columnar resolution of blood volume and oximetry functional maps in the behaving monkey: Implications for fMRI Neuron42 (5): 843-854 jun 10 2004  link icon
Eysel UT. Illusions and perceived images in the primate brain Science 302 (5646): 789-791 oct 31 2003  link icon
Petersen CCH, Grinvald A, Sakmann B. Spatiotemporal dynamics of sensory responses in layer 2/3 of rat barrel cortex measured in vivo by voltage-sensitive dye imaging combined with whole-cell voltage recordings and neuron reconstructions. Journal Of Neuroscience 23 (4): 1298-1309 feb 15 2003  link icon
Tucker TR, Katz LC. Spatiotemporal patterns of excitation and inhibition evoked by the horizontal network in layer 2/3 of ferret visual cortex. JOURNAL OF NEUROPHYSIOLOGY 89 (1): 488-500 JAN 2003  link icon
Bosking WH, Crowley JC, Fitzpatrick D (2002). Spatial coding of position and orientation in primary visual cortex. Nat Neuroscience, 5:874-882.  link icon
Luo M, Katz LC (2001). Response correlation maps of neurons in the mammalian olfactory bulb. Neuron, 32: 1165-1179.  link icon
Schwartz TH, Bonhoeffer T (2001). In vivo optical mapping of epileptic foci and surround inhibition in ferret cerebral cortex. Nature Med, 7:1063-1067.  link icon
Dragoi V, Rivadulla C, Sur M (2001). cortical processing of a brightness illusion, PNAS 2005 102 (10): 3869-3874.  link icon
Rubin BD, Katz LC (2001). Spatial coding of enantiomers in the rat olfactory bulb. Nature Neurosci, 4: 355-6.  link icon
Uchida N, Takahashi YK, Tanifuji M, Mori K (2000). Odor maps in the mammalian olfactory bulb: domain organization and odorant structural features. Nature Neurosci, 3:1035-43.  link icon
von Melchner L, Pallas SL, Sur M (2000). Visual behaviour mediated by retinal projections directed to the auditory pathway. Nature, 404:871-6.  link icon
Grinvald A, Slovin H, Vanzetta I (2000). Non-invasive visualization of cortical columns by fMRI (2000). Nature Neurosci, 3:105-7.  link icon
Crowley JC, Katz LC. (2000). Early development of ocular dominance columns.  Science. 2000 290(5495):1321-4.  link icon
Sharma J, Angelucci A, Sur M (2000). Induction of visual orientation modules in auditory cortex (2000). Nature, 404: 841-7.  link icon
Das A, Gilbert CD (1999). Topography of contextual modulations mediated by short-range interactions in primary visual cortex. Nature, 399: 655-61.  link icon
Vanzetta I, Grinvald A (1999). Increased cortical oxidative metabolism due to sensory stimulation: implications for functional brain imaging. Science, 286: 1555-8.  link icon
Das A, and Gilbert CD (1997). Distortions of visuotopic map match orientation singularities in primary visual cortex. Nature, 387:594-598.  link icon
Crair MC, Gillespie DC, Stryker MP (1998). The role of visual experience in the development of columns in cat visual cortex. Science, 279:566-70.  link icon
Weliky, M. and Katz LC (1997). Disruption of orientation tuning in visual cortex by artificially correlated neuronal activity Nature, 386:680-685.  link icon
Maldonado PE, Godecke I, Gray CM, Bonhoeffer T (1997). Orientation selectivity in pinwheel centers in cat striate cortex. Science, 276:1551-5.  link icon
Shoham, D, Hubener, M, Grinvald A and Bonhoeffer T (1997). Spatio-temporal frequency domains and their relationship to cytochrome oxidase staining in cat visual cortex. Nature, 385: 529-534.  link icon
Godecke I, Bonhoeffer T (1996). Development of Identical Orientation Maps for 2 Eyes without Common Visual Experience, Nature, 379: 251-254.  link icon
Weliky M, Bosking W, Fitzpatrick D (1996). A systematic map of direction preference in primary visual cortex. Nature 379: 725-728.  link icon
Malonek D, and Grinvald A (1996). Interactions between electrical cortical activity and the microcirculation revealed by imaging spectroscopy: Implications for functional brain mapping. Science 272: 551-554.  link icon
Wang G, Tanaka K and Tanifuji M (1996). Optical imaging of functional organization in the monkey inferotemporal cortex. Science, 272: 1665-1668.  link icon
Sheth BR, Sharma J, Rao SC, and Sur M (1996).  Orientation maps of subjective contours in visual cortex. Science 274: 2110-2115.  link icon
Das, A Gilbert, CD (1995). Long-range horizontal connections and their role in cortical reorganization revealed by optical recording of cat primary visual cortex. Nature, 375: 780.  link icon
Name Headline Link
White LE and Fitzpatrick D (2007) Vision and Cortical Map Development, Neuron 56 (2): 327-338.  link icon
Neuroscience Research. Windhorst U and Johansson H (Editors) Springer Verlag, pp 893-969.
Hubener M, Bonhoeffer T. Visual cortex: Two-photon excitement Current Biology 15 (6): R205-R208 mar 29 2005
Grinvald A, Hildesheim R VSDI: A new era in functional imaging of cortical dynamics. Nature Reviews Neuroscience 5 (11): 874-885 nov 2004  link icon
Zapeda A, Arias C, Sengpiel F. Optical imaging of intrinsic signals: recent developments in the methodology and its applications. Journal Of Neuroscience Methods 136 (1): 1-21 jun 15 2004  link icon
Grinvald A, et al. (1999). In-vivo Optical Imaging of cortical Architecture and Dynamics. In Modern Techniques in Neuroscience Research. U. Windhorst and H. Johansson Springer, pp 893-969  link icon
Mrsic-Flogel T, Hubener M, Bonhoeffer T. Brain mapping: New wave optical Imaging. C urrent B iology 13 (19): R778-R780 SEP 30 2003  link icon
Grinvald A (1985). Real-time optical mapping of neuronal activity: from single growth cones to the intact mammalian brain. Ann Rev Neurosci, 8: 263-305.  link icon
Name Headline Link
Grinvald A, Salzberg BM and Cohen LB (1977). Simultaneous recording from several neurons in an invertebrate central nervous system. Nature, 268: 140.  link icon
Grinvald A, Cohen LB, Lesher S and Boyle MB (1981). Simultaneous optical monitoring of activity of many neurons in invertebrate ganglia using a 124-element photodiode array. J Neurophysiol, 45: 829-840.  link icon
Grinvald A and Farber I (1981). Optical recording of calcium action potentials from growth cones of cultured neurons using a laser microbeam. Science, 212: 1164-1166.  link icon
Grinvald A, Hildesheim R, Farber IC and Anglister L (1982). Better fluorescent probes for the measurements of rapid changes in membrane potential. Biophys J, 39: 301-308.
Grinvald A, Manker A and Segal M (1982). Visualization of the spread of electrical activity in rat hippocampal slices by voltage-sensitive optical probes. J Physiol, 333: 269-291.  link icon
Grinvald A, Anglister L, Freeman JA, Hildesheim R and Manker A (1984). Real time optical imaging of naturally evoked electrical activity in the intact frog brain. Nature, 308: 848-850.  link icon
Ts’o DY, Frostig RD, Lieke E and Grinvald A (1990). Functional architecture of primate visual cortex revealed by high resolution optical imaging. Science, 249: 417-420.
Bonhoeffer T and Grinvald A (1991). Iso-orientation domains in cat visual cortex are arranged in pinwheel-like patterns. Nature, 353: 429-431.  link icon
Arieli A, Sterkin A, Grinvald A and Aertsen A (1996). Dynamics of on-going activity: Explanation of the large variability in evoked cortical responses. Science, 273: 1868-1871.
Shoham D, Hubener M, Grinvald A and Bonhoeffer T (1997). Spatio-temporal frequency domains and their relationship to cytochrome oxidase staining in cat visual cortex. Nature, 385: 529-534.  link icon
Shoham, D, Glaser DE, Arieli A, Kenet T, Hildesheim R, and Grinvald A (1999). Imaging cortical architecture and dynamics at high spatial and temporal resolution with new voltage-sensitive dyes. Neuron, 24: 1-12
Tsodyks M, Kenet T, Grinvald A and Arieli A (1999). The spontaneous activity of single cortical neuron depends the underlying global functional architecture . Science, 286: 1943-1946.  link icon
Name Headline Link
Malonek D and Grinvald A (1996). Interactions between electrical activity and cortical microcirculation revealed by imaging spectroscopy; implications for functional brain imaging. Science, 272: 551-554.  link icon
Frostig RD, Lieke E, Ts’o DY and Grinvald A (1990). Cortical functional architecture and local coupling between neuronal activity and the microcirculation revealed by in vivo high resolution optical imaging of intrinsic signals in cat and monkey visual cortex. Proc Natl Acad Sci USA, 87: 6082-6086.  link icon
Grinvald A, Lieke E, Frostig R, Gilbert CD and Wiesel TN (1986). Functional architecture of cortex revealed by optical imaging of intrinsic signals. Nature, 324: 361-364.  link icon
Name Headline Link
Shien Wei Ng B, Grabska-Barwinska A, Gunturkun O and Jancke D (2010) Dominant Vertical Orientation Processing without Clustered Maps: Early Visual Brain Dynamics Imaged with Voltage-Sensitive Dye in the Pigeon Visual Wulst, Journal of Neuroscience 30 (19): 6713? 6725.
Benucci A, Ringach DL and Carandini M (2009) Coding of stimulus sequences by population responses in visual cortex, Nature Neuroscience 12 (10):1317-1324.  link icon
Benucci A, Frazor RA and Carandini M (2007) Standing Waves and Traveling Waves Distinguish Two Circuits in Visual Cortex, Neuron 55 (1): 103-117.  link icon
Jancke D, Chavane F, Naaman S, Grinvald A (2004). Imaging cortical correlates of illusion in early visual cortex. Nature, 2004 Mar 25;428(6981):423-6.  link icon
Kenet T, Bibitchkov D, Tsodyks M, Grinvald A, Arieli A (2003). Spontaneously emerging cortical representations of visual attributes. Nature, 2003 Oct 30;425(6961):954-6.  link icon
Derdikman D, Hildesheim R, Ahissar E, Arieli A, Grinvald A (2003). Imaging spatiotemporal dynamics of surround inhibition in the barrels somatosensory cortex. J Neurosci, 2003 Apr 15;23(8):3100-5.  link icon
Sharon D and Grinvald A (2002). Dynamics and constancy in cortical spatiotemporal patterns of orientation processing. Science, 295: 512-515.  link icon
Seidemann E, Arieli A, Grinvald A, Slovin H (2002). Dynamics of depolarization and hyperpolarization in the frontal cortex and saccade goal. Science, 295:862-865.  link icon
Spors H and Grinvald A (2002). Temporal dynamics of odor representations and coding by the mammalian olfactory bulb. Neuron, 34:1-20.
Slovin H., Arieli A, Hildesheim R, and Grinvald A (2002). Long-term voltage-sensitive dye imaging of cortical dynamics in the behaving monkey. J. Neurophys, In press.  link icon
Shoham, D, Glaser DE, Arieli A, Kenet T, Hildesheim R and Grinvald A (1999). Imaging cortical architecture and dynamics at high spatial and temporal resolution with new voltage-sensitive dyes. Neuron, 24:1-12.
Grinvald A, Lieke E, Frostig R, Gilbert CD and Wiesel TN (1986). Functional architecture of cortex revealed by optical imaging of intrinsic signals. Nature, 324: 361-364.  link icon
Grinvald A, Anglister L, Freeman JA, Hildesheim R and Manker A (1984). Real time optical imaging of naturally evoked electrical activity in the intact frog brain. Nature, 308:848-850.  link icon
Grinvald A., Fine A, Farber IC and Hildesheim R (1983). Fluorescence monitoring of electrical responses from small neurons and their processes. Biophys. J, 42:145-198.  link icon
Grinvald A, Manker A and Segal M (1982). Visualization of the spread of electrical activity in rat hippocampal slices by voltage-sensitive optical probes. J. Physiol, 333:269-291.  link icon
Carlson GC, Coulter DA (2008), In vitro functional imaging in brain slices using fast voltage-sensitive dye imaging combined with whole-cell patch recording, Nature Protocols 3 (2): 249-255 Jan 24 2008  link icon
Farkas E, Pratt R, Sengpiel F and Obrenovitch TP (2008) Direct, live imaging of cortical spreading depression and anoxic depolarisation using a fluorescent, voltage-sensitive dye,Journal of Cerebral Blood Flow & Metabolism 28, 251-262 2008  link icon
Ferezou I, Bolea S and Petersen CCH (2006) Visualizing the Cortical Representation of Whisker Touch: Voltage-Sensitive Dye Imaging in Freely Moving Mice, Neuron, 4 (50): 617-629 May 18 2006  link icon