{"id":1619,"date":"2021-04-08T11:13:41","date_gmt":"2021-04-08T11:13:41","guid":{"rendered":"http:\/\/www.demo.onlypixels.com\/iisc-phy-anil\/?page_id=1619"},"modified":"2026-02-27T09:04:44","modified_gmt":"2026-02-27T09:04:44","slug":"publications","status":"publish","type":"page","link":"https:\/\/cns.iisc.ac.in\/sray\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"<style id=\"kt-blocks_b55540-bc\">.kt-tabs-id_b55540-bc > .kt-tabs-content-wrap > .wp-block-kadence-tab {border-width:1px 0px 0px 0px;border-color:#eeeeee;background:#ffffff;}.wp-block-kadence-tabs .kt-tabs-id_b55540-bc > .kt-tabs-title-list li {margin:0px 8px 0px 0px;}.wp-block-kadence-tabs .kt-tabs-id_b55540-bc > .kt-tabs-title-list li .kt-tab-title, .wp-block-kadence-tabs .kt-tabs-id_b55540-bc > .kt-tabs-content-wrap > .kt-tabs-accordion-title .kt-tab-title {font-size:1.1em;line-height:1.4em;border-width:0px 0px 4px 0px ;border-radius:4px 4px 0px 0px ;padding:8px 20px 8px 20px ;border-color:#ffffff;color:#555555;background:#ffffff;}.wp-block-kadence-tabs .kt-tabs-id_b55540-bc > .kt-tabs-title-list li .kt-tab-title:hover, .wp-block-kadence-tabs .kt-tabs-id_b55540-bc > .kt-tabs-content-wrap > .kt-tabs-accordion-title .kt-tab-title:hover {border-color:#eeeeee;color:#555555;background:#ffffff;}.wp-block-kadence-tabs .kt-tabs-id_b55540-bc > .kt-tabs-title-list li.kt-tab-title-active .kt-tab-title, .wp-block-kadence-tabs .kt-tabs-id_b55540-bc > .kt-tabs-content-wrap > .kt-tabs-accordion-title.kt-tab-title-active .kt-tab-title  {border-color:#0a6689;color:#0a6689;background:#ffffff;}<\/style>\n<div class=\"wp-block-kadence-tabs alignnone\"><div class=\"kt-tabs-wrap kt-tabs-id_b55540-bc kt-tabs-has-4-tabs kt-active-tab-1 kt-tabs-layout-tabs kt-tabs-tablet-layout-inherit kt-tabs-mobile-layout-inherit kt-tab-alignment-center \" style=\"max-width:none\"><ul class=\"kt-tabs-title-list\"><li id=\"tab-peer-reviewedarticlesandreviews\" class=\"kt-title-item kt-title-item-1 kt-tabs-svg-show-always kt-tabs-icon-side-right kt-tab-title-active\"><a href=\"#tab-peer-reviewedarticlesandreviews\" data-tab=\"1\" class=\"kt-tab-title kt-tab-title-1 \"><span class=\"kt-title-text\">Peer-reviewed Articles and Reviews<\/span><\/a><\/li><li id=\"tab-preprints\" class=\"kt-title-item kt-title-item-2 kt-tabs-svg-show-always kt-tabs-icon-side-right kt-tab-title-inactive\"><a href=\"#tab-preprints\" data-tab=\"2\" class=\"kt-tab-title kt-tab-title-2 \"><span class=\"kt-title-text\">Preprints<\/span><\/a><\/li><li id=\"tab-books\" class=\"kt-title-item kt-title-item-3 kt-tabs-svg-show-always kt-tabs-icon-side-right kt-tab-title-inactive\"><a href=\"#tab-books\" data-tab=\"3\" class=\"kt-tab-title kt-tab-title-3 \"><span class=\"kt-title-text\">Books<\/span><\/a><\/li><li id=\"tab-bookchapters\" class=\"kt-title-item kt-title-item-4 kt-tabs-svg-show-always kt-tabs-icon-side-right kt-tab-title-inactive\"><a href=\"#tab-bookchapters\" data-tab=\"4\" class=\"kt-tab-title kt-tab-title-4 \"><span class=\"kt-title-text\">Book chapters<\/span><\/a><\/li><\/ul><div class=\"kt-tabs-content-wrap\">\n<div class=\"wp-block-kadence-tab kt-tab-inner-content kt-inner-tab-1 kt-inner-tab_ee32c1-f7\"><div class=\"kt-tab-inner-content-inner\">\n<p>[51] Biswas A, Aggarwal S, Sharma K and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2026) <em>Simultaneous enhancement of stimulus-induced and stimulus-free gamma in open-eye meditators.<\/em> <strong>Imaging Neuroscience. <\/strong>4: IMAG.a.1145 <\/p>\n\n\n\n<p>[50] Aggarwal S, and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2025) <em>Changes in Higuchi\u2019s fractal dimension across age in healthy human EEG are anti-correlated with changes in oscillatory power and 1\/f slope.<\/em> <strong><strong>European Journal of Neuroscience.<\/strong> <\/strong>62(2): e70193.<\/p>\n\n\n\n<p>[49] Anand A, Murthy CM<strong><sup>\u2020<\/sup><\/strong>, and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2025) <em>Burst Estimation through Atomic Decomposition (BEAD): A Toolbox to find Oscillatory Bursts in Brain Signals.<\/em> <strong>Imaging Neuroscience.<\/strong> 3: IMAG.a.86<\/p>\n\n\n\n<p>[48] Biswas A#, Kumar WS#, Sharma K# and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2025) <em>Stimulus-induced gamma sources reduce in power but not in spatial extent with healthy aging in human EEG.<\/em> <strong>European Journal of Neuroscience. <\/strong>61(10):e70138; doi: 10.1111\/ejn.70138 (# indicates joint first author)<\/p>\n\n\n\n<p>[47] Krishnakumaran R, Pavuluri A, and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2025) <em>Delayed accumulation of inhibitory input explains gamma frequency variation with changing contrast in an Inhibition Stabilized Network. <\/em><strong>Journal of Neuroscience. <\/strong>45 (5):e1279242024; https:\/\/doi.org\/10.1523\/JNEUROSCI.1279-24.2024<\/p>\n\n\n\n<p>[46] Prakash SS, Mayo JP and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2024) <em>Dissociation of attentional state and behavioral outcome using local field potentials. <\/em><strong>eNeuro.<\/strong> 11(11): ENEURO.0327-24.2024<\/p>\n\n\n\n<p>[45] Kanth and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2024) <em>Gamma responses to colored natural stimuli can be predicted from local low-level stimulus features. <\/em><strong>eNeuro. <\/strong>11(7): ENEURO.0417-23.2024<\/p>\n\n\n\n<p>[44] Gulati D and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2024) <em>Auditory and visual gratings elicit distinct gamma responses.<strong> <\/strong><\/em><strong>eNeuro. <\/strong>11(4): ENEURO.0116-24.2024<\/p>\n\n\n\n<p>[43] Das A, Nandi N and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2024) <em>Alpha and SSVEP power outperforms Gamma power in capturing Attentional Modulation in Human EEG. <\/em><strong>Cerebral Cortex.<\/strong> 34(1), bhad412.<\/p>\n\n\n\n<p>[42] Kumar WS and<strong> Ray S<sup>\u2020<\/sup><\/strong> (2023)<em> Healthy aging and cognitive impairment alter EEG functional connectivity in distinct frequency bands. <\/em><strong>European Journal of Neuroscience.<\/strong> 58:3432-49<\/p>\n\n\n\n<p>[41] Krishnakumaran R and<strong> Ray S<sup>\u2020<\/sup><\/strong> (2023) <em>Temporal characteristics of gamma rhythm constrain properties of noise in an inhibition-stabilized network model. <\/em><strong>Cerebral Cortex.<\/strong> 33, 10108-10121<\/p>\n\n\n\n<p>[40] Aggarwal S and<strong> Ray S<sup>\u2020<\/sup><\/strong> (2023) <em>Slope of the power spectral density flattens at low frequencies (&lt;150 Hz) with healthy aging but also steepens at higher frequency (&gt;200 Hz) in human electroencephalogram. <\/em><strong>Cerebral Cortex Communications.<\/strong> 4(2):tgad011.<\/p>\n\n\n\n<p>[39] Pattisapu S and<strong> Ray S<sup>\u2020<\/sup><\/strong> (2023) <em>Stimulus-induced narrow-band gamma oscillations in humans can be recorded using open-hardware low-cost EEG amplifier. <\/em><strong>PLoS One.<\/strong> 18(1):e0279881.<\/p>\n\n\n\n<p>[38] Shirhatti V, Ravishankar P and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2022) <em>Gamma oscillations in primate primary visual cortex are severely attenuated by small stimulus discontinuities<\/em>. <strong>PLoS Biology. <\/strong>20(6):e3001666.<\/p>\n\n\n\n<p>[37*] Prakash SS, Mayo JP and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2022) <em>Decoding of attentional state using local field potential<\/em>. <strong>Current Opinion in Neurobiology. <\/strong>76:102589.<\/p>\n\n\n\n<p>[36] Liza K and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2022) <em>Local interactions between steady-state visually evoked potentials at nearby flickering frequencies. <\/em><strong>Journal of Neuroscience. <\/strong>42(19):3965-74.<\/p>\n\n\n\n<p>[35*] <strong>Ray S<sup>\u2020<\/sup><\/strong> (2022) <em>Spikes-Gamma phase relationship in visual cortex. <\/em><strong>Annual Review of Vision Sciences<em>. <\/em><\/strong>Accepted.<\/p>\n\n\n\n<p>[34] Murty DVPS<strong><sup>\u2020<\/sup><\/strong> and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2022) <em>Stimulus-induced robust narrow-band gamma oscillations in human EEG using cartesian gratings.<\/em> <strong>Bio-protocol<em>. <\/em><\/strong>12(7):e4379.<\/p>\n\n\n\n<p>[33] Krishnakumaran R, Raees M, <strong>Ray S<\/strong><strong><sup>\u2020<\/sup><\/strong> (2022) <em>Shape analysis of gamma rhythm supports a superlinear inhibitory regime in an inhibition-stabilized network.<\/em> <strong>PLoS Computational Biology<em>.<\/em> <\/strong>18:e1009886.<\/p>\n\n\n\n<p>[32] Kumar WS, Manikandan K, Murty DVPS, Ramesh RG, Purokayastha S, Javali M, Rao NP and <strong>Ray S<\/strong>\u2020 (2022) <em>Stimulus-induced narrowband gamma oscillations are test-retest reliable in healthy elderly in human EEG. <\/em><strong>Cerebral Cortex Communications<\/strong>. Vol 3(1):tgab066.<\/p>\n\n\n\n<p>[31] Murty DVPS, Manikandan K, Kumar WS, Ramesh RG, Purokayastha S, Nagendra B, Abhishek ML, Balakrishnan A, Javali M, Rao NP and <strong>Ray S<\/strong>\u2020 (2021) <em>Stimulus-induced Gamma rhythms are weaker in human elderly with Mild Cognitive Impairment and Alzheimer&#8217;s Disease. <\/em><strong>eLife<\/strong>. 10:e61666.<br><br>[30] Prakash SS, Das A, Kanth ST, Mayo JP,&nbsp;<strong>Ray S<\/strong>\u2020 (2021)<em> Decoding of attentional state using high-frequency local field potential is as accurate as using spikes. <\/em><strong>Cerebral Cortex<\/strong>. Vol 31(9): 4314-28.<br><br>[29] Das A and <strong>Ray S<\/strong>\u2020 (2021) <em>Effect of cross-orientation normalization on different neural measures in macaque primary visual cortex. <\/em><strong>Cerebral Cortex Communications<\/strong>. Vol 2(1), Article tgab009.<br><br>[28] Murty DVPS, Manikandan K, Kumar WS, Ramesh RG, Purokayastha S, Javali M, Rao NP and <strong>Ray S<\/strong>\u2020 (2020) <em>Gamma oscillations weaken with age in healthy elderly in human EEG. <\/em><strong>Neuroimage<\/strong>. Vol 215, Article 116826.<br><br>[27] Salelkar S and <strong>Ray S<\/strong>\u2020 (2020) <em>Interaction between steady-state visually evoked potentials at nearby flicker frequencies.<\/em> <strong>Scientific Reports<\/strong>. 10, Article 5344.<br><br>[26] Dubey A and <strong>Ray S<\/strong>\u2020 (2020) <em>Comparison of tuning properties of gamma and high-gamma power in local field potential (LFP) versus electrocorticogram (ECoG) in visual cortex. <\/em><strong>Scientific Reports<\/strong>. 10, Article 5422.<br><br>[25] Kanth ST and <strong>Ray S<\/strong>\u2020 (2020) <em>Electrocorticogram (ECoG) is highly informative in primate visual cortex. <\/em><strong>Journal of Neuroscience<\/strong>. 40(12):2430-2444.<br><br>[24] Biswas A and <strong>Ray S<\/strong>\u2020 (2019) <em>Alpha feedback has a positive effect for participants who are unable to sustain their alpha activity. <\/em><strong>eNeuro<\/strong>. 6(4):ENEURO.0498-18.2019.<br><br>[23] Dubey A and <strong>Ray S<\/strong>\u2020 (2019) <em>Cortical Electrocorticogram (ECoG) is a local signal. <\/em><strong>Journal of Neuroscience<\/strong>. 39(22):4299-4311.<br><br>[22] Das A and <strong>Ray S<\/strong>\u2020 (2018) <em>Effect of stimulus contrast and visual attention on spike gamma phase relationship in macaque primary visual cortex.&nbsp;<\/em><strong>Frontiers in Computational Neuroscience<\/strong>.&nbsp;Vol 12, Article 66.<br><br>[21] Salelkar S, Somasekhar GM and <strong>Ray S<\/strong>\u2020 (2018) <em>Distinct frequency bands in the local field potential are differently tuned to stimulus drift rate. <\/em><strong>Journal of Neurophysiology<\/strong>.&nbsp;120(2):681-692.<br><br>[20] Shirhatti V and <strong>Ray S<\/strong>\u2020 (2018)&nbsp;<em>Long wavelength (reddish) hues induce unusually large gamma oscillations in the primate primary visual cortex. <\/em><strong>Proceedings of the National Academy of Sciences<\/strong>. 115(17):4489-94.<br><br>[19] Murty DVPS#, Shirhatti V#, Ravishankar P# and <strong>Ray S<\/strong>\u2020 (2018) <em>Large visual stimuli induce two distinct gamma oscillations in primate visual cortex. <\/em><strong>Journal of Neuroscience<\/strong>. 38(11):2730-44.<br><br>[18] Subhash Chandran KS, Seelamantula CS, and <strong>Ray S<\/strong>\u2020 (2018) <em>Duration Analysis Using Matching Pursuit Algorithm Reveals Longer Bouts of Gamma Rhythm. <\/em><strong>Journal of Neurophysiology<\/strong>. 119(3): 808-821.<br><br>[17*] Biswas A and <strong>Ray S<\/strong>\u2020 (2017) <em>Control of alpha rhythm (8-13 Hz) using neurofeedback.<\/em> <strong>Journal of the Indian Institute of Science<\/strong>. Vol 97:4: 527-531.<br><br>[16] Dubey A and <strong>Ray S<\/strong>\u2020 (2016) <em>Spatial Spread of local field potential is band-pass in the primate visual cortex.<\/em> <strong>Journal of Neurophysiology<\/strong>. Oct 1; 116(4):1986-99.<br><br>[15] Shirhatti V, Borthakur A, and <strong>Ray S<\/strong>\u2020 (2016) <em>Effect of Reference Scheme on Power and Phase of the Local Field Potential. <\/em><strong>Neural Computation<\/strong>.&nbsp; Vol 28, No. 5:882-913. doi:10.1162\/NECO_a_00827.<br><br>[14*] Subhash Chandran K S, Mishra A#, Shirhatti V# and <strong>Ray S<\/strong>\u2020 (2016) <em>Comparison of Matching Pursuit algorithm with other signal processing techniques for computation of the time-frequency power spectrum of brain signals.<\/em> <strong>Journal of Neuroscience<\/strong>. March 23; 36(12): 3399-3408.<br><br>[13*] <strong>Ray S<\/strong>\u2020 (2015) <em>Challenges in the quantification and interpretation of spike-LFP relationships. <\/em><strong>Current Opinion in Neurobiology<\/strong>. April 30; 31: 111-118.<br><br>[12*] <strong>Ray S<\/strong> and Maunsell, JHR\u2020 (2015) <em>Do gamma oscillations play a role in cerebral cortex?<\/em> <strong>Trends in Cognitive Sciences<\/strong>. Vol. 19(2): 78-85.<br><br>[11] Srinath R and <strong>Ray S<\/strong>\u2020 (2014) <em>Effect of Amplitude Correlations on Coherence in the Local Field Potential. <\/em><strong>Journal of Neurophysiology<\/strong>. Aug 15; 112(4):741-51.<br><br>[10] <strong>Ray S<\/strong>\u2020, Ni AM and Maunsell JHR (2013) <em>Strength of Gamma Rhythm depends on Normalization. <\/em><strong>PLoS Biology<\/strong>. 11(2):e1001477.<br><br>[9] Ni AM, <strong>Ray S<\/strong> and Maunsell JHR\u2020 (2012) <em>Tuned Normalization Explains the Size of Attention Modulations. <\/em><strong>Neuron<\/strong>. Feb 23; 73(4):803-813.<br><br>[8] <strong>Ray S<\/strong>\u2020 and Maunsell JHR (2011) <em>Network rhythms influence the relationship between spike-triggered local field potential and functional connectivity.<\/em> <strong>Journal of Neuroscience<\/strong>. Aug 31; 31(35):12674-82.<br><br>[7] <strong>Ray S<\/strong>\u2020 and Maunsell JHR (2011) <em>Different origins of gamma rhythm and high-gamma activity in macaque visual cortex.<\/em> <strong>PLoS Biology<\/strong>. Apr; 9(4):e1000610.<br><br>[6] <strong>Ray S<\/strong>\u2020 and Maunsell JHR (2010) <em>Differences in gamma frequencies across visual cortex restrict their possible use in computation. <\/em><strong>Neuron<\/strong>. Sep 9; 67:885-896.<br><br>[5] <strong>Ray S<\/strong>\u2020, Crone NE, Niebur E, Franaszczuk PJ and Hsiao SS (2008) <em>Neural correlates of high-gamma oscillations (60-200 Hz) in macaque local field potentials and their potential implications in electrocorticography. <\/em><strong>Journal of Neuroscience<\/strong>. Nov 5; 28(45):11526-36.<br><br>[4] <strong>Ray S<\/strong>\u2020, Hsiao SS, Crone NE, Franaszczuk PJ and Niebur E (2008) <em>Effect of stimulus intensity on the spike-local field potential relationship in the secondary somatosensory cortex.<\/em> <strong>Journal of Neuroscience<\/strong>. Jul 16; 28(29): 7334-43.<br><br>[3] <strong>Ray S<\/strong>, Niebur E, Hsiao SS, Sinai A and Crone NE\u2020 (2008) <em>High-frequency gamma activity (80-150 Hz) is increased in human cortex during selective attention.<\/em> <strong>Clinical Neurophysiology<\/strong>. Jan; 119(1):116-33.<br><br>[2] Muniak MA, <strong>Ray S<\/strong>, Hsiao SS, Dammann JF, Bensmaia SJ\u2020 (2007) <em>The neural coding of stimulus intensity: linking the population response of mechanoreceptive afferents with psychophysical behavior.<\/em> <strong>Journal of Neuroscience<\/strong>. Oct 24; 27(43):11687-99.<br><br>[1] <strong>Ray S<\/strong>\u2020, Jouny CC, Crone NE, Boatman D, Thakor NV, Franaszczuk PJ (2003) <em>Human ECoG analysis during speech perception using matching pursuit: a comparison between stochastic and dyadic dictionaries.<\/em> <strong>IEEE Transactions in Biomedical Engineering<\/strong>. 50:1371-1373.<\/p>\n<\/div><\/div>\n\n\n\n<div class=\"wp-block-kadence-tab kt-tab-inner-content kt-inner-tab-2 kt-inner-tab_f81113-ae\"><div class=\"kt-tab-inner-content-inner\">\n<p>Biswas A and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2026) <em>Gamma oscillations across recording scales show a preference for saturated long-wavelength (reddish) hues in the primate visual cortex.<\/em> <strong>bioRxiv. <\/strong>https:\/\/doi.org\/10.64898\/2026.01.22.701022<\/p>\n\n\n\n<p>V Raju and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2025) <em>Differential Burst dynamics of Slow and Fast gamma rhythms in Macaque primary visual cortex.<\/em><strong> bioRxiv. <\/strong>https:\/\/doi.org\/10.1101\/2025.10.01.679813<\/p>\n\n\n\n<p>Gulati D and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2025) <em>Slow-varying normalization explains auditory steady-state masking interactions in human EEG. <\/em><strong>bioRxiv.<\/strong> <a href=\"https:\/\/doi.org\/10.1101\/2025.08.25.672175\">https:\/\/doi.org\/10.1101\/2025.08.25.672175<\/a><\/p>\n\n\n\n<p>Gulati D and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2025) <em>Slow-varying normalization explains diverse temporal frequency masking interactions in the macaque primary visual cortex. <\/em><strong>bioRxiv.<\/strong> <a href=\"https:\/\/doi.org\/10.1101\/2025.03.11.642541\"><\/a><a href=\"https:\/\/doi.org\/10.1101\/2025.03.11.642541\">https:\/\/doi.org\/10.1101\/2025.03.11.642541<\/a><\/p>\n\n\n\n<p>Prabhu P<strong><sup>\u2020<\/sup> <\/strong>and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2024) <em>Slow and fast gamma oscillations show phase-amplitude coupling with distinct high-frequency bands in macaque primary visual cortex.<\/em> <strong>bioRxiv. <\/strong><a href=\"https:\/\/doi.org\/10.1101\/2024.11.20.624422\">https:\/\/doi.org\/10.1101\/2024.11.20.624422<\/a><\/p>\n\n\n\n<p>Bhargava Gautham<strong><sup>\u2020<\/sup> <\/strong>and <strong>Ray S<sup>\u2020<\/sup><\/strong> (2024) <em>Simultaneously induced slow and fast gamma waves travel independently in primate primary visual cortex.<\/em><strong> <\/strong><strong>bioRxiv<\/strong>. &nbsp;<a href=\"https:\/\/doi.org\/10.1101\/2024.11.06.622198\">https:\/\/doi.org\/10.1101\/2024.11.06.622198<\/a><\/p>\n\n\n\n<p><\/p>\n\n\n\n<p><\/p>\n<\/div><\/div>\n\n\n\n<div class=\"wp-block-kadence-tab kt-tab-inner-content kt-inner-tab-3 kt-inner-tab_fe8353-cb\"><div class=\"kt-tab-inner-content-inner\">\n<p><strong>Ray S<\/strong> (2008) Linking Spikes with Neuronal Oscillations. ISBN-13: 978-3639097986. Publisher: VDM Verlag Dr. Mueller e.K.<\/p>\n<\/div><\/div>\n\n\n\n<div class=\"wp-block-kadence-tab kt-tab-inner-content kt-inner-tab-4 kt-inner-tab_63479e-5a\"><div class=\"kt-tab-inner-content-inner\">\n<p><strong>Ray S.<\/strong><em> <\/em><em>How do local field potentials measured with microelectrodes differ from iEEG activity? <\/em>In: Axmacher N (2023) Intracranial EEG: A Guide for Cognitive Neuroscientists. ISBN: 978-3-031-20909-3. Publisher: Springer Nature.<\/p>\n\n\n\n<p>Crone NE, Korzeniewska A, <strong>Ray S<\/strong>, Franaszczuk PJ. Cortical Function Mapping with Intracranial EEG. In: Tong, S, Thakor, NV. (2009) <strong>Quantitative EEG Analysis Methods and Clinical Applications<\/strong> (Engineering in Medicine &amp; Biology). ISBN-13: 978-1-59693-204-3. Publisher: Artech House, Inc.<\/p>\n<\/div><\/div>\n<\/div><\/div><\/div>\n\n\n\n<p><\/p>\n","protected":false},"excerpt":{"rendered":"","protected":false},"author":6,"featured_media":0,"parent":0,"menu_order":5,"comment_status":"closed","ping_status":"closed","template":"","meta":{"kt_blocks_editor_width":""},"_links":{"self":[{"href":"https:\/\/cns.iisc.ac.in\/sray\/wp-json\/wp\/v2\/pages\/1619"}],"collection":[{"href":"https:\/\/cns.iisc.ac.in\/sray\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/cns.iisc.ac.in\/sray\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/cns.iisc.ac.in\/sray\/wp-json\/wp\/v2\/users\/6"}],"replies":[{"embeddable":true,"href":"https:\/\/cns.iisc.ac.in\/sray\/wp-json\/wp\/v2\/comments?post=1619"}],"version-history":[{"count":60,"href":"https:\/\/cns.iisc.ac.in\/sray\/wp-json\/wp\/v2\/pages\/1619\/revisions"}],"predecessor-version":[{"id":2434,"href":"https:\/\/cns.iisc.ac.in\/sray\/wp-json\/wp\/v2\/pages\/1619\/revisions\/2434"}],"wp:attachment":[{"href":"https:\/\/cns.iisc.ac.in\/sray\/wp-json\/wp\/v2\/media?parent=1619"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}