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Holmes NP (2017) Moving towards barely-visible targets: Help! Vision Research Group Seminar, School of Psychology, University of Nottingham, 14th December  
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1. Alstermark B, Eide E, Górska T, Lundberg A, Pettersson L' (1984) Visually guided switching of forelimb target reaching in cats. Acta Physiologica Scandinavica, 120(1):151-153
      [NBArticle #31126] [Cites 2] [CitedBy 23] [Delete citation]
2. Blanchard CCV, McGlashan HL, French B, Sperring RJ, Petrocochino B, Holmes NP (2017) Online control of prehension predicts performance on a standardised motor assessment test in 8-12 year old children. Frontiers in Psychology, 8:374
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3. Carlton LG (1981) Processing visual feedback information for movement control. Journal of Experimental Psychology: Human Perception and Performance, 7(5):1019-1030
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4. Hall NJ, Colby CL (2016) Express saccades and superior colliculus responses are sensitive to short-wavelength cone contrast. Proceedings of the National Academy of Sciences USA, 113(24):6743-6748
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5. Herter TM, Takei T, Munoz DP, Scott SH (2015) Neurons in red nucleus and primary motor cortex exhibit similar responses to mechanical perturbations applied to the upper-limb during posture. Frontiers in Integrative Neuroscience, :29
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6. Holmes NP, Dakwar A (2015) Online control of reaching and pointing to visual, auditory, and multimodal targets: Effects of target modality and method of determining correction latency. Vision Research, 117:105-116
        [NBArticle #34083] [Cites 34] [CitedBy 15] [Delete citation]
7. Paulignan Y, MacKenzie C, Marteniuk RG, Jeannerod M (1991a) Selective perturbation of visual input during prehension movements. 1. The effects of changing object position. Experimental Brain Research, 83(3):502-512
    [NBArticle #10579] [Cites 16] [CitedBy 169] [Delete citation]
8. Petersen SE, Robinson DL (1985) Pulvinar nuclei of the behaving rhesus monkey: Visual responses and their modulation. Journal of Neurophysiology, 54:867-886
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9. Pruszynski JA, King GL, Boisse L, Scott SH, Flanagan JR, Munoz DP (2010) Stimulus-locked responses on human arm muscles reveal a rapid neural pathway linking visual input to arm motor output. European Journal of Neuroscience, 32(6):1049-1057
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10. Schmolesky MT, Wang Y, Hanes DP, Thompson KG, Leutgeb S, Schall JD, Leventhal AG (1998) Signal timing across the macaque visual system. Journal of Neurophysiology, 79(6):3272-3278
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11. Schwartz AS, Cheney C (1966) Neural mechanisms involved in the critical flicker frequency of the cat. Brain Research, 1(4):369-380
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12. Scott SH (2004) Optimal feedback control and the neural basis of volitional motor control. Nature Reviews Neuroscience, 5(7):534-546
  [NBArticle #12018] [Cites 1] [CitedBy 4] [Delete citation]
13. Takeichi N, Kaneko CRS, Fuchs AF (2005) Discharge of monkey nucleus reticularis tegmenti pontis neurons changes during saccade adaptation. Journal of Neurophysiology, 94(3):1938-1951
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14. Veerman MM, Brenner E, Smeets JBJ (2008) The latency for correcting a movement depends on the visual attribute that defines the target. Experimental Brain Research, 187(2):219-228
    [NBArticle #21677] [Cites 24] [CitedBy 36] [Delete citation]
15. Warren WG (2017b) Online-control of movement: testing motor cortex involvement with paired-pulse transcranial magnetic stimulation. Thesis, , 20pp.
  [NBArticle #48425] [Cites 28] [CitedBy 2] [Delete citation]
16. Warren WG, Blanchard CCV, Fialek S, Zeni S, Holmes NP (2017) Early and spatially-selective responses in proximal arm muscles during visual control of reaching: transcranial magnetic stimulation over primary motor cortex and cerebellum. Journal of Neurophysiology, :
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17. Watson AB, Pelli DG (1983) QUEST: A Bayesian adaptive psychometric method. Perception & Psychophysics, 33(2):113-120
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