Publications by Steve Heinen
A covered eye fails to follow an object moving in depth. Scientific Reports, 11. http://doi.org/https://doi.org/10.1038/s41598-021-90371-8. (2021).
Human Eye Movements Reveal Video Frame Importance. Computer, 52(5), 48–57. http://doi.org/10.1109/MC.2019.2903246. (2019).
A common mechanism modulates saccade timing during pursuit and fixation. Journal Of Neurophysiology .. (2019).
Foveated convolutional neural networks for video summarization. Multimedia Tools And Applications, 77(22), 29245-29267. http://doi.org/https://doi.org/10.1007/s11042-018-5953-1. (2018).
Choosing a foveal goal recruits the saccadic system during smooth pursuit. Journal Of Neurophysiology , 120(2), 489-496. http://doi.org/ 10.1152/jn.00418.2017. (2018).
A Subconscious Interaction between Fixation and Anticipatory Pursuit. Journal Of Neuroscience, 37(47), 11424-11430. http://doi.org/10.1523/JNEUROSCI.2186-17.2017. (2017).
Illusory motion reveals velocity matching, not foveation, drives smooth pursuit of large objects. Journal Of Vision, 17(12).. (2017).
Monocular and Binocular Smooth Pursuit in Central Field Loss. Vision Research.. (2017).
Smooth pursuit eye movements in patients with macular degeneration. Journal Of Vision, 16, 1.. (2016).
A foveal target increases catch-up saccade frequency during smooth pursuit. Journal Of Neurophysiology, jn–00774.. (2015).
A mechanism for decision rule discrimination by supplementary eye field neurons. Experimental Brain Research, 233, 459–476.. (2015).
Allocation of attention during pursuit of large objects is no different than during fixation. Journal Of Vision, 15, 9–9.. (2015).
Different time scales of motion integration for anticipatory smooth pursuit and perceptual adaptation. Journal Of Vision, 15, 16.. (2015).
Contrasting the roles of the supplementary and frontal eye fields in ocular decision making. Journal Of Neurophysiology, 111, 2644–2655.. (2014).
Motion Integration for Ocular Pursuit Does Not Hinder Perceptual Segregation of Moving Objects. The Journal Of Neuroscience, 34, 5835–5841.. (2014).
Shared attention for smooth pursuit and saccades. Journal Of Vision, 13, 7.. (2013).
Flexibility of foveal attention during ocular pursuit. Journal Of Vision, 11, 9.. (2011).
Flexible interpretation of a decision rule by supplementary eye field neurons. Journal Of Neurophysiology, 106, 2992–3000.. (2011).
The default allocation of attention is broadly ahead of smooth pursuit. Journal Of Vision, 10, 7.. (2010).
The effects of microstimulation of the dorsomedial frontal cortex on saccade latency. Journal Of Neurophysiology, 99, 1857–1870.. (2008).
Storage of an oculomotor motion aftereffect. Vision Research, 47, 466–473.. (2007).
An oculomotor decision process revealed by functional magnetic resonance imaging. The Journal Of Neuroscience, 26, 13515–13522.. (2006).
Anticipatory movement timing using prediction and external cues. The Journal Of Neuroscience, 26, 4519–4525.. (2006).
Neuroscience: rewiring the adult brain. Nature, 438, E3–E3.. (2005).
Properties of saccades generated as a choice response. Experimental Brain Research, 162, 278–286.. (2005).
Timing and velocity randomization similarly affect anticipatory pursuit. Journal Of Vision, 5, 1.. (2005).
Trajectory interpretation by supplementary eye field neurons during ocular baseball. Journal Of Neurophysiology, 94, 1385–1391.. (2005).
Supplementary eye fields stimulation facilitates anticipatory pursuit. Journal Of Neurophysiology, 92, 1257–1262.. (2004).
Perceptual and oculomotor evidence of limitations on processing accelerating motion. Journal Of Vision, 3, 698-709.. (2003).
Smooth pursuit eye movements: Recent advances. The Visual Neurosciences (Chalupa Lm, Werner Js, Eds), 333–334.. (2003).
Facilitation of smooth pursuit initiation by electrical stimulation in the supplementary eye fields. Journal Of Neurophysiology, 86, 2413–2425.. (2001).
Human smooth pursuit direction discrimination. Vision Research, 39, 59–70.. (1999).
Spatial integration in human smooth pursuit. Vision Research, 38, 3785–3794.. (1998).
Single-neuron activity in the dorsomedial frontal cortex during smooth-pursuit eye movements to predictable target motion. Visual Neuroscience, 14, 853–865.. (1997).
The function of the cerebellar uvula in monkey during optokinetic and pursuit eye movements: single-unit responses and lesion effects. Experimental Brain Research, 110, 1–14.. (1996).
Single neuron activity in the dorsomedial frontal cortex during smooth pursuit eye movements. Experimental Brain Research, 104, 357–361.. (1995).
Adaptation of saccades and fixation to bilateral foveal lesions in adult monkey. Vision Research, 32, 365–373.. (1992).
Cerebellar uvula involvement in visual motion processing and smooth pursuit control in monkey. Annals Of The New York Academy Of Sciences, 656, 775–782.. (1992).
Characteristics of nystagmus evoked by electrical stimulation of the uvular/nodular lobules of the cerebellum in monkey. Journal Of Vestibular Research: Equilibrium & Orientation, 2, 235–245.. (1991).
Generation of smooth-pursuit eye movements: neuronal mechanisms and pathways. Neuroscience Research, 11, 79–107.. (1991).
Recovery of visual responses in foveal V1 neurons following bilateral foveal lesions in adult monkey. Experimental Brain Research, 83, 670–674.. (1991).
Gaze Changes from Binocular to Monocular Viewing during Smooth Pursuit in Macular Degeneration. Investigative Ophthalmology & Visual Science.. (2016).
Evaluation of Smooth Pursuit in Individuals with Central Field Loss. European Conference on Eye Movements. Vienna, Austria: Vienna, Austria.. (2015).
Patterns of eye movement adaptation to foveal lesions in adult primates. In Walker, M. F., FitzGibbon, E. J., & Goldberg, M. E. (1994). Contemporary Oculomotor and Vestibular Research: A Tribute to David A Robinson.. (1993).