Dr Alison Lane, BSc, MA, PhD
(email at firstname.lastname@example.org)
I completed my undergraduate degree, Masters degree and PhD all at Durham University, here in the Psychology department. I then worked as a post-doctoral research associate on a project examining the neural mechanisms of visuo-spatial attention with Dr Ellison. Throughout these positions I began to specialise in the clinical neuropsychology of vision, which remains my main area of interest.
My main research interest is in clinical neuropsychology, specifically vision and spatial attention. I am involved in research examining compensatory interventions for people with visual field defects and I am mainly interested in the role which attention plays in such rehabilitation. As part of this work we have developed Durham Reading and Exploration (DREX) training which is free app for the rehabilitation of partial visual loss. More information can be found at:
My additional research involves examining the neural mechanisms of visual attention, with focus on the roles of areas such as posterior parietal cortex and frontal eye fields. Transcranial magnetic stimulation (TMS) and transcranial direct current stimulation (tDCS) are the primary techniques that I employ in this area.
More broadly I am also interested in mental health and wellbeing, particularly issues like stress and stigma. This includes an interest in how factors such as this could also influence successful rehabilitation following neurological injury.
- Visual Field Defects
- Visuospatial attention
- Lane, Alison R., Ball, Keira & Ellison, Amanda (2015). Dissociating the neural mechanisms of distance and spatial reference frames. Neuropsychologia 74: 42-49.
- Aimola, Lina, Lane, Alison R., Smith, Daniel T., Kerkhoff, Georg, Ford, Gary A. & Schenk, Thomas (2014). Efficacy and feasibility of home-based training for individuals with homonymous visual field defects. Neurorehabilitation and Neural Repair 28(3): 207-218.
- Ellison, A., Ball, K.L., Moseley, P., Dowsett, J., Smith, D.T., Weis, S. & Lane, A.R. (2014). Functional Interaction between Right Parietal and Bilateral Frontal Cortices during Visual Search Tasks Revealed Using Functional Magnetic Imaging and Transcranial Direct Current Stimulation. PLoS ONE 9(4): e93767.
- Lane, A.R., Ball, K., Smith, D.T. , Schenk, T & Ellison, A. (2013). Near and far space: understanding the neural mechanisms of spatial attention. Human Brain Mapping 34(2): 356-366.
- Ball, K., Lane, A. R., Smith, D. T. & Ellison, A. (2013). Site-Dependent Effects of tDCS Uncover Dissociations in the Communication Network Underlying the Processing of Visual Search. Brain Stimulation 6(6): 959-965.
- Hesse, C, Lane, AR, Aimola, L & Schenk, T (2012). Pathways involved in human conscious vision contribute to obstacle-avoidance behaviour. European Journal of Neuroscience 36(3): 2383-2390.
- Lane, A.R., Smith, D.T., Schenk, T. & Ellison, A. (2012). The involvement of posterior parietal cortex and frontal eye fields in spatially primed visual search. Brain Stimulation 5(1): 11-17.
- Ball, K., Lane, A., Ellison, A. & Schenk, T. (2011). Spatial priming in visual search: memory for body-centred information. Experimental Brain Research 212(3): 477-485.
- Lane, A.R., Smith, D.T., Schenk, T. & Ellison, A. (2011). The involvement of posterior parietal cortex in feature and conjunction visuomotor search. Journal of Cognitive Neuroscience 23(8): 1964-1972.
- Lane, A. R. , Smith, D. T., Ellison, A. & Schenk, T. (2010). Visual exploration training is no better than attention training for treating hemianopia. Brain 133(6): 1717-1728.
- Smith, D.T., Lane, A.R. & Schenk, T. (2008). Arm position does not attenuate visual loss in patients with homonymous field deficits. Neuropsychologia 46(9): 2320-2325.
- Lane, A.R., Smith, D.T. & Schenk, T. (2008). Clinical treatment options for patients with homonymous visual field defects. Clinical Opthalmology 2(1): 93-102.
- Ellison, A., Lane, A. R. & Schenk, T. (2007). The interaction of brain regions during visual search processing as revealed by transcranial magnetic stimulation. Cerebral Cortex 17(11): 2579-2584.
- Dr Thomas Schenk