2024
Gauld OM, Packer AM, Russell LE, Dalgleish HWP, Iuga M, Sacadura F, Roth A, Clark BA, Häusser M. (2024). A latent pool of neurons silenced by sensory-evoked inhibition can be recruited to enhance perception. Neuron 8:S0896-6273(24)00276-9. doi: 10.1016/j.neuron.2024.04.015. (PDF)
Russell LE, Fişek M, Yang Z, Tan LP, Packer AM, Dalgleish HWP, Chettih SN, Harvey CD, Häusser M. (2024). The influence of cortical activity on perception depends on behavioral state and sensory context. Nature Communications 15(1):2456. (PDF)
2023
Fişek M, Herrmann D, Egea-Weiss A, Cloves M, Bauer L, Lee TY, Russell LE, Häusser M. (2023). Cortico-cortical feedback engages active dendrites in visual cortex. Nature 617(7962):769-776. (PDF)
2022
Buetfering C, Zhang Z, Pitsiani M, Smallridge J, Boven E, McElligott S, Häusser M. (2022). Behaviorally relevant decision coding in primary somatosensory cortex neurons. Nature Neuroscience 25(9):1225-1236. (PDF)
Russell L, Dalgleish H, Nutbrown R, Gauld OM, Herrmann D, Fisek M, Packer AM & Häusser M (2022). All-optical interrogation of neural circuits in awake behaving mice. Nature Protocols (PDF)
Kostadinov D & Häusser M (2022). Reward signals in the cerebellum: origins, targets, and functional implications. Neuron (PDF)
2021
Häusser, M (2021). Optogenetics: the might of light. New England Journal of Medicine 183: 1-14. [PDF]
Bicknell B and Häusser M (2021). A synaptic learning rule for exploiting nonlinear dendritic computation. Neuron (PDF)
Sezener E, Grabska-Barwińska A, Kostadinov D, Beau M, Krishnagopal S, Budden D, Hutter M, Veness J, Botvinick M, Clopath C, Häusser M, Latham PE (2021). A rapid and efficient learning rule for biological neural circuits. bioRxiv (PDF)
Simon A, Roth A, Sheridan A, Fişek M, Marra V, Racca C, Funke J, Staras K, Häusser M (2021). Ultrastructural readout of in vivo synaptic activity for functional connectomics. bioRxiv (PDF)
Russell, LE, Dalgleish, HPC, Nutbrown, R, Gauld, OM, Herrmann, D, Fisek, M, Packer, A, Häusser, M (2021). All-optical interrogation of neural circuits in behaving mice. bioRxiv [PDF]
Goetz, L, Roth, A, Häusser, M (2021). Active dendrites enable strong but sparse inputs to determine orientation selectivity. PNAS 118: e2017339118. [PDF]
International Brain Laboratory et al. (2021). Standardized and reproducible measurement of decision-making in mice. eLife doi: 10.7554/eLife.63711. [PDF]
Steinmetz et al. (2021). Neuropixels 2.0: A miniaturized high-density probe for stable, long-term brain recordings. Science doi: 10.1126/science.abf4588. [PDF]
2020
Robinson NTM, Descamps LAL, Russell LE, Buchholz M, Bicknell B, Antonov GK, Lau JYN, Nutbrown R, Schmidt-Hieber C, Häusser M (2020). Targeted activation of hippocampal place cells drives memory-guided spatial behavior. Cell 183: 1-14. [PDF]
Tsutsumi S, Chadney O, Yiu TL, Bäumler E, Faraggiana L, Beau M, Häusser M (2020). Purkinje cell activity determines the timing of sensory-evoked motor initiation. Cell Reports 33(12):108537. [PDF]
Dalgleish HWP, Russell LE, Packer AM, Roth A, Gauld OM, Greenstreet F, Thompson EJ, Häusser M (2020). How many neurons are sufficient for perception of cortical activity? eLife 8:e49872. [PDF]
Fişek M, Häusser M. (2020). Are human dendrites different? Trends in Cognitive Neuroscience 24(6):411-412. [PDF]
Arlt C, Häusser M. (2020). Microcircuit rules governing impact of single interneurons on Purkinje cell output in vivo. Cell Reports 30(9):3020-3035.e3.
2019
Cornford JH, Mercier MS, Leite M, Magloire V, Häusser M, Kullmann DM. (2019). Dendritic NMDA receptors in parvalbumin neurons enable strong and stable neuronal assemblies. eLife 8:e49872. [PDF]
Kostadinov D, Beau M, Pozo MB, Häusser M. (2019). Predictive and reactive reward signals conveyed by climbing fiber inputs to cerebellar Purkinje cells. Nature Neuroscience 22(6):950-962. [PDF]
Haq N, Schmidt-Hieber C, Sialana FJ, Ciani L, Heller JP, Stewart M, Bentley L, Wells S, Rodenburg RJ, Nolan PM, Forsythe E, Wu MC, Lubec G, Salinas P, Häusser M, Beales PL, Christou-Savina S. (2019). Loss of Bardet-Biedl syndrome proteins causes synaptic aberrations in principal neurons. PLoS Biology 17(9):e3000414. (PDF)
2018
Zhang Z, Russell LE, Packer AM, Gauld OM, Häusser M (2018). Closed-loop all-optical interrogation of neural circuits in vivo. Nature Methods 15(12):1037-1040. [PDF]
2017
Jun, J. et al. (2017). Fully integrated silicon probes for high-density recording of neural activity. Nature 551, 232–236. (PDF).
International Brain Laboratory (2017). An International Laboratory for Systems and Computational Neuroscience. Neuron 96(6):1213-1218. [PDF]
Schmidt-Hieber C, Toleikyte G, Aitchison L, Roth A, Clark BA, Branco T, Häusser M (2017). Active dendritic integration as a mechanism for robust and precise grid cell firing. Nature Neuroscience 20(8):1114-1121. [PDF]
2016
Mainen ZF, Häusser M, Pouget A (2016). A better way to crack the brain. Nature 539(7628):159-161. [PDF]
Neuro Cloud Consortium (2016). To the Cloud! A Grassroots Proposal to Accelerate Brain Science Discovery. Neuron. 2016 Nov 2;92(3):622-627. [PDF]
Buchin A, Rieubland S, Häusser M, Gutkin BS, Roth A (2016). Inverse stochastic resonance in cerebellar Purkinje cells. PLoS Comput Biology 12(8):e1005000.
van Welie I, Roth A, Ho SS, Komai S, Häusser M (2016). Conditional spike transmission mediated by electrical coupling ensures millisecond precision-correlated activity among interneurons in vivo. Neuron 90(4):810-23. [PDF]
Haider B, Schulz DP, Häusser M, Carandini M (2016). Millisecond coupling of local field potentials to synaptic currents in the awake visual cortex. Neuron 90(1):35-42.
Sato TK, Haider B, Häusser M, Carandini M (2016). An excitatory basis for divisive normalization in visual cortex. Nature Neuroscience 19(4):568-70.
2015
Emiliani V, Cohen AE, Deisseroth K, Häusser M (2015). All-optical interrogation of neural circuits.
Journal of Neuroscience 35(41):13917-26. [PDF]
Ishikawa T, Shimuta M, Häusser M. (2015). Multimodal sensory integration in single cerebellar granule cells in vivo. eLife 4. pii: e12916.
Duguid I, Branco T, Chadderton P, Arlt C, Powell K, Häusser M (2015). Control of cerebellar granule cell output by sensory-evoked Golgi cell inhibition. PNAS 112(42):13099-104. [PDF]
Goetz L, Roth A, Häusser M (2015). Dendritic inhibitory synapses punch above their weight.
Neuron 87(3):465-8.
Powell K, Mathy A, Duguid I, Häusser M (2015). Synaptic representation of locomotion in single cerebellar granule cells. eLife 17:4. doi: 10.7554/eLife.07290. [PDF]
Collot M, Wilms CD, Bentkhayet A, Marcaggi P, Couchman K, Charpak S, Dieudonné S, Häusser M, Feltz A, Mallet JM (2015). CaRuby-Nano: a novel high affinity calcium probe for dual color imaging.
eLife 31:4, doi: 10.7554/eLife.05808. [PDF]
Wilms CD, Häusser M. (2015). Reading out a spatiotemporal population code by imaging neighbouring parallel fibre axons in vivo. Nature Communications 6:6464. [PDF]
2014
Packer AM, Russell LE, Dalgleish HWP, Häusser M (2014). Simultaneous all-optical manipulation and recording of neural circuit activity with cellular resolution in vivo. Nature Methods 12(2):140-6. [PDF]
Häusser M (2014). Optogenetics: the age of light. Nature Methods 11: 1012 - 1014. [PDF]
Mathy A, Clark BA, Häusser M (2014). Synaptically induced long-term modulation of electrical coupling in the inferior olive. Neuron 81(6):1290 - 1296. [PDF]
Rieubland S, Roth A, Häusser M (2014). Structured connectivity in cerebellar inhibitory networks. Neuron 81(4):913 - 929. [PDF]
Sato TK, Häusser M, Carandini M (2014). Distal connectivity causes summation and division across mouse visual cortex. Nature Neuroscience 17:30-2. [PDF]
Wilms, C, Häusser M (2014). Twitching towards the ideal calcium sensor. Nature Methods 11: 139 - 40. [PDF]
Häusser M, Margrie TW (2014). Two-photon targeted patching and electroporation in vivo. Cold Spring Harbor Protocols doi: 10.1101/pdb.prot080143. [PDF]
2013
Smith S, Smith IT, Branco T, Häusser M (2013). Dendritic spikes enhance stimulus selectivity in cortical neurons in vivo. Nature 503: 115-20. [PDF]
Schmidt-Hieber C, Häusser M (2013). How to build a grid cell. Philosophical Transactions of the Royal Society B 369:20120520. [PDF]
Cottam JC, Smith SL, Häusser M (2013). Target-specific effects of somatostatin-expressing interneurons on neocortical visual processing. Journal of Neuroscience 33:19567-78. [PDF]
Haider B, Häusser M, Carandini M (2013). Inhibition dominates sensory responses in the awake cortex, Nature 493: 97-100.
Packer AM, Roska B, Häusser M (2013). Targeting neurons and photons for optogenetics. Nature Neuroscience 16:805-15. [PDF]
Schmidt-Hieber C, Häusser M (2013). Cellular mechanisms of spatial navigation in the medial entorhinal cortex. Nature Neuroscience 16:325-31. [PDF]
2012
Cuntz H, Mathy A, Häusser M (2012). A scaling law derived from optimal dendritic wiring. PNAS 109:11014-8.
Duguid I, Branco T, London M, Chadderton P, Häusser M (2012). Tonic inhibition enhances fidelity of sensory information transmission in the cerebellar cortex. J Neurosci. 32(32):11132-43.
Marra V, Burden JJ, Thorpe JR, Smith IT, Smith SL, Häusser M, Branco T, Staras K (2012) . A preferentially segregated recycling vesicle pool of limited size supports neurotransmission in native central synapses. Neuron 76:579-89.
Rieubland S, Roth A, Häusser M (2012). Dendritic ventriloquism: inhibitory synapses throw their voices. Neuron 75:190-3.
2011
Branco T, Häusser M (2011). Synaptic integration gradients in single cortical pyramidal cell dendrites. Neuron 69:885-92. [PDF]
Kitamura K, Häusser M (2011). Dendritic calcium signaling triggered by spontaneous and sensory-evoked climbing fiber input to cerebellar Purkinje cells in vivo. Journal of Neuroscience 31:10847-5.
H Cuntz, F Forstner, A Borst, M Häusser (2011). The TREES toolbox—probing the basis of axonal and dendritic branching. Neuroinformatics 9(1):91-6.
2010
Branco T, Clark BA and Häusser M. (2010) Dendritic Discrimination of Temporal Input Sequences in Cortical Neurons. Science, 329:1671-5. [PDF]
Branco T, Häusser M (2010). The single dendritic branch as a fundamental functional unit in the nervous system. Curr Opin Neurobiol. 20:494-502. [PDF]
Cuntz H, Forstner F, Borst A and Häusser M. (2010) One rule to grow them all: a general theory of neuronal branching and its practical application. PLoS Comput Biol. 6(8). [PDF]
London M, Roth A, Beeren L, Häusser M and Latham PE. (2010) Sensitivity to perturbations in vivo implies high noise and suggests rate coding in cortex. Nature 466:123-7. [PDF]
Smith SL and Häusser M. (2010) Parallel processing of visual space by neighboring neurons in mouse visual cortex . Nature Neuroscience 13:1144-9. [PDF]
Phoka E, Cuntz H, Roth A and Häusser M. (2010) A new approach for determining phase response curves reveals that Purkinje cells can act as perfect integrators. PLoS Comput Biol. 29;6(4). [PDF]
Palmer LM, Clark BA, Gründemann J, Roth A, Stuart GJ and Häusser M. (2010) Initiation of simple and complex spikes in cerebellar Purkinje cells. J Physiol. 588:1709-17. [PDF]
Selected PRE-2010 Publications:
Scanziani M and Häusser M. (2009) Electrophysiology in the age of light. Nature, 461:930-9. [PDF]
Mathy A, Ho SS, Davie JT, Duguid IC, Clark BA, Häusser M. (2009) Encoding of oscillations by axonal bursts in inferior olive neurons. Neuron, 62:388-99. [PDF]
Judkewitz B, Rizzi M, Kitamura K, Häusser M. (2009) Targeted single-cell electroporation of mammalian neurons in vivo. Nature Protocols, 4:862-9. [PDF]
Watt AJ, Cuntz H, Mori M, Nusser Z, Sjöström PJ, Häusser M. (2009) Traveling waves in developing cerebellar cortex mediated by asymmetrical Purkinje cell connectivity. Nature Neuroscience, 12:463-73. [PDF]
Kitamura K, Judkewitz B, Kano M, Denk W, Häusser M. (2008) Targeted patch-clamp recordings and single-cell electroporation of unlabeled neurons in vivo. Nature Methods, 5:61-7. [PDF]
Sjöström, PJ, Rancz EA, Roth A, and Häusser, M. (2008) Dendritic Excitability and Synaptic Plasticity. Physiological Reviews, 88:769-840. [PDF]
Rancz EA, Ishikawa T, Duguid I, Chadderton P, Mahon S, Häusser M. (2007) High-fidelity transmission of sensory information by single cerebellar mossy fibre boutons. Nature, 450:1245-8. [PDF]
Häusser M, Smith SL. (2007) Controlling neural circuits with light. Nature, 446:617-9. [PDF]