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  1. Spatial context non-uniformly modulates inter-laminar communication in the primary visual cortex. Xu*, X., Morton*, M.P., Nandy+, A.S.& Jadi+, M.P. (2024). Neuron

  2. Brain-state mediated modulation of inter-laminar dependencies in visual cortex. Das*, A., Sheffield*, A., Nandy A.S., Jadi, M.P. (2024). Nature Communications *=equal contribution

  3. Development of a Marmoset Apparatus for Automated Pulling (MarmoAAP) to Study Cooperative Behaviors. Meisner, O. C., Fagan, N. A., Shi, W., Greenwood, J., Jadi, M. P., Nandy, A. S., Chang, S. W. C. (2024). eLife.

  4. Focal vs Diffuse: Mechanisms of attention mediated performance enhancement in a hierarchical model of the visual system. Wang, X., Jadi, M. P.

  5. The orbitofrontal cortex: A goal-directed cognitive map framework for social and non-social behaviorsShi W, Meisner O, Blackmore S, Jadi M, Nandy A, Chang S. (2023). Neurobiology Of Learning And Memory

  6. Laminar compartmentalization of attention modulation in area V4 aligns with the demands of visual processing hierarchy in the cortex. Wang, X., Nandy, A. S., Jadi, M. P. (2023). Scientific Reports

  7. Cell-type specific deletions of Neuroligin 2 reveal a vital role of synaptic excitation-inhibition balance. Longley, C.M., Xu, X.,  Messier, J.E., Cai, Z., Park, J.W., Chen, H., Reznik, D.L., Jadi, M.P, Xue, M. 

  8. Laminar Mechanisms of Saccadic Suppression in Primate Visual Cortex. Denagamage, S., Morton, M. P., Reynolds, J.H., Jadi, M. P. & Nandy, A. S. (2023). Cell Reports 

  9. Brain state and cortical layer-specific mechanisms underlying perception at threshold. Morton, M. P., Denagamage, S., Reynolds, J.H., Jadi, M. P. & Nandy, A. S. (2023). eLife

  10. Tonic GABAergic activity facilitates dendritic calcium signaling and short-term plasticity. Chiu, C. Q., Morse, T.M., Nani, F.,  Knoflach, F., Hernandez, M., Jadi, M.P., Higley, M.J.

  11. Classical-contextual interactions in V1 may rely on dendritic computations. Jin, L., Behabadi, B., Jadi, M. P., Ramachandran, C. & Mel, B. W., (2022). Neuroscience

  12. Optogenetically induced low-frequency correlations impair perception. Nandy, A. S., Nassi, J. J., Jadi, M. P. & Reynolds, J. H. (2019). eLife

  13. Cortical gamma band synchronization through somatostatin neurons. Veit, J., Hakim, R., Jadi, M.P., Sejnowski, T.J., Adesnik, H. (2017). Nature Neuroscience, 20(7)
  14. Modulatory compartments in cortex and the local regulation of cholinergic tone. Coppola, J.J., Ward, N.J., Jadi, M.P., Disney, A. (2016). J. Physiology, 110(1-2)
  15. Neurons in macaque Area V4 are tuned for complex spatio-temporal patterns. Nandy, A.S., Mitchell, J.F., Jadi, M.P., Reynolds, J.H., (2016). Neuron, 91(4)
  16. Abnormal Gamma Oscillations in N-Methyl-D-Aspartate Receptor Hypofunction Models of Schizophrenia. Jadi, M.P., Behrens, M.M. & Sejnowski, T. J., (2016). Biological Psychiatry, 79(9).
  17. Regulating cortical oscillations in an inhibition-stabilized network. Jadi, M.P., & Sejnowski, T. J., (2014). Proceedings of the IEEE, 102(5). 
  18. Cortical oscillations arise from contextual interactions that regulate sparse coding. Jadi, M.P., & Sejnowski, T. J., (2014). Proceedings of the National Academy of Sciences, 111(18).
  19. An augmented 2-layer model captures nonlinear analog spatial integration effects in pyramidal neuron dendrites. Jadi, M.P., Behabadi, B., Polsky, A., Schiller, J. & Mel, B. W., (2014). Proceedings of the IEEE, 102(5).
  20. Location-dependent effects of inhibition on local spiking in pyramidal neuron dendrites. Jadi, M.*, Polsky, A.*, Schiller, J. & Mel, B. W., (2012). PLoS Comput Biol, 8(6), e1002550. *=equal contribution
  21. Location-dependent excitatory synaptic interactions in pyramidal neuron dendrites. Behabadi, B., Polsky, A., Jadi, M., Schiller, J. & Mel, B. W., (2012). PLoS Comput Biol, 8(7), e1002599. 
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