SNOW LAB

• Fairchild, G.T., Holler, D.E., Fabbri, S., Gomez, M.A., Snow, J.C. (2024) Naturalistic Object Representations Depend on Distance and Size Cues. bioRxiv https://doi.org/10.1101/2024.03.16.585308
• Gomez, M.A., Snow, J.C. (2024) How to construct liquid-crystal spectacles to control vision of real-world objects and environments. Behavior Research Methods 56(2), 563-576
• Snow, J.C. Gomez, M.A., Compton, M.T. (2023) Human memory for real-world solid objects is not predicted by responses to image displays. Journal of Experimental Psychology: General 152(10), 2703-2712
• Gurariy, G., Mruczek, R.E.B., Snow, J.C., Caplovitz, G.P. (2022) Using high-density electroencephalography to explore spatiotemporal representations of object categories in visual cortex. Journal of Cognitive Neuroscience 34(6), 967-987
• Fairchild, G.T., Marini, F., Snow, J.C. (2021) Graspability modulates the stronger EEG signature of motor preparation for real objects vs. pictures. Journal of Cognitive Neuroscience 33(12), 2477-2493
• Snow, J.C. & Culham, J.C. (2021) . The treachery of images: How realism influences brain and behaviour. Trends in Cognitive Sciences, 25(6), 506-519.
• Freud, E., Behrmann, M., & Snow, J.C. (2020). What does dorsal cortex contribute to perception? Open Mind: Discoveries in Cognitive Science, 4, 40-56.
• Holler, D., Fabbri, S., & Snow, J.C. (2020). Object responses are highly malleable, rather than invariant, with changes in object appearance. Scientific Reports, 10(1), 4654.
• Fairchild, G.T., & Snow, J.C. (2020). Physical Inference: How the brain represents mass. eLife, 9, e54373.
• Romero, C.A. & Snow, J.C (2019). Methods for presenting real-world objects under controlled laboratory conditions. Journal of Visualized Experiments, 148, e59762.
• Holler, D., Behrmann, M., & Snow, J.C. (2019). Real-world size coding of solid objects, but not 2-D or 3-D images, in visual agnosia patients with bilateral ventral lesions. Cortex, 119, 555-568.
• Marini, F., Breeding, K.A., & Snow, J.C. (2019). Distinct visuo-motor brain dynamics for real-world objects versus planar images. NeuroImage, 195, 232-242.
• Marini, F., Breeding, K.A., & Snow, J.C. (2019). Dataset of 24-subject EEG recordings during viewing of real-world objects and planar images of the same items. Data in Brief, 24, 103857.
• Buckingham, G., Holler, D., Michelakakis, E.E., & Snow, J.C. (2018). Preserved object weight processing after bilateral LOC lesions. Journal of Cognitive Neuroscience, 30(11), 1683-1690.
• Erlikhman, G., Caplovitz, G.P., Gurariy, G, Medina, J. & Snow, J.C. (2018). Towards a unified perspective of object shape and motion processing in human dorsal cortex. Consciousness and Cognition, 64, 106-120.
• Romero, C.A., Compton, M.T., Yang, Y., & Snow, J.C. (2018).The real deal: Willingness-to-pay and satiety expectations are greater for real foods versus their images. Cortex, 107, 78-91.
• Gomez, M.A., Skiba, R.M. & Snow, J.C. (2018). Graspable objects grab attention more than images do. Psychological Science, 29(2), 206-218.
• Gomez, M.A. & Snow, J.C. (2017). Action Properties of Object Images Facilitate Visual Search. Journal of Experimental Psychology: Human Perception and Performance, 43(6), 1115-1124.
• Chen, J., Snow, J.C., Culham, J.C., & Goodale, M.A. (2017). What Role Does "Elongation" Play in "Tool-Specific" Activation and Connectivity in the Dorsal and Ventral Visual Streams? Cerebral Cortex, 28(4), 1117-1131.
• Skiba, R.M. & Snow, J.C. (2016). Attentional Capture for Tool Images is Driven by the Head End of the Tool, not the Handle. Attention, Perception, & Psychophysics, 78(8), 2500-2514.
• Squires, S.D., Macdonald, S.N., Culham, J.C., & Snow, J.C. ( (2016). Priming tool actions: Are real objects more effective primes than pictures? Experimental Brain Research, 234(4), 963-976.
• Snow, J.C., Goodale, M.G., & Culham, J.C (2015). Preserved haptic shape processing after bilateral LOC lesions. Journal of Neuroscience, 35(40), 13745-13760.
• Barnett-Cowan, M., Snow, J.C., & Culham, J.C. (2015). Contribution of bodily and gravitational orientation cues to face and letter recognition. Multisensory Research, 28(5-6), 427-442.
• Snow, J.C., Skiba, R.M., Coleman, T.L., & Berryhill, M.E. (2014). Real-world objects are more memorable than photographs of objects. Frontiers in Human Neuroscience, 8(Article 837), 1-11.
• Snow, J.C., Strother, L., & Humphreys, G.W. (2014). Haptic shape representation in visual cortex. Journal of Cognitive Neuroscience, 26(5), 1154-1167.
• Podrebarac, S., Goodale, M.A., & Snow J.C. (2014). Are visual texture-selective areas recruited during haptic texture discrimination? NeuroImage, 94, 129-137.
• Podrebarac, S., Goodale, M.A., van der Zwan, R., & Snow, J.C. (2013). Gender-selective neural populations: evidence from event-related fMR repetition suppression. Experimental Brain Research, 226(2), 241-252.
• Snow, J.C., Miranda, R.R., & Humphreys, G.W. (2013). Impaired visual sensitivity within the ipsilesional hemifield following unilateral parietal damage. Cortex, 49(1), 158-171.
• Snow, J.C., Pettypiece, C.E., McAdam, T.D., McLean, A.D., Stroman, P.W., Goodale, M.A. & Culham, J.C. (2011). Bringing the real world into the fMRI scanner: Repetition effects for pictures versus real objects. Scientific Reports, 1(130)
• Snow, J.C., Allen, H.A., Rafal, R.D., & Humphreys, G.W. (2009). Impaired attentional selection following lesions to human pulvinar: Evidence for homology between human and monkey. Proceedings of the National Academy of Sciences of the USA, 106(10), 4054-4059.
• Snow, J.C, & Mattingley, J.B. (2008). Central perceptual load does not reduce ipsilesional flanker interference in parietal extinction Neuropsychology, 22(3), 371-382.
• Snow, J.C, & Mattingley, J.B. (2006). Goal-driven selective attention in patients with right hemisphere lesions: How intact is the ipsilesional field? Brain, 129(Pt 1), 168-181.
• Snow, J.C, & Mattingley, J.B. (2006). Stimulus- and goal-driven biases of selective attention following unilateral brain damage: Implications for rehabilitation of spatial neglect and extinction. Restorative Neurology and Neuroscience, 24(4-6), 233-245.