Contribution of cells in the posterior parietal cortex to the planning of visually guided locomotion in the cat: Effects of temporary visual interruption

Journal of Neurophysiology

Volumn 105, Issue 5, 2011, Pages 2457-2470

  Marigold, Daniel S ^b   Drew, Trevor ^a  

^a UNIVERSITÉ DE MONTRÉAL   (Canada)

^b SIMON FRASER UNIVERSITY   (Canada)

Author keywords

Gait modification; Internal model; Online corrections

Indexed keywords

ANIMAL EXPERIMENT; ANIMAL TISSUE; ARTICLE; BRAIN FUNCTION; CAT; CONTROLLED STUDY; FOREFOOT; GAIT; LOCOMOTION; MALE; NONHUMAN; POSTERIOR PARIETAL CORTEX; PRIORITY JOURNAL; TASK PERFORMANCE; VISION; VISUOMOTOR COORDINATION; VOLUNTARY MOVEMENT;

ANIMALS; CATS; EXERCISE TEST; INTENTION; LOCOMOTION; MALE; PARIETAL LOBE; PHOTIC STIMULATION; PSYCHOMOTOR PERFORMANCE; TIME FACTORS; VISUAL PERCEPTION; WALKING;

EID: 79956272793     PISSN: 00223077     EISSN: 15221598     Source Type: Journal    
DOI: 10.1152/jn.00992.2010     Document Type: Article

References (44)

1. Andersen RA, Buneo CA. Intentional maps in posterior parietal cortex. Annu Rev Neurosci 25: 189-220, 2002.
2. Andujar JE, Lajoie K, Drew T. A contribution of area 5 of the posterior parietal cortex to the planning of visually guided locomotion: limb-specific and limb-independent effects. J Neurophysiol 103: 986-1006, 2010.
3. Beloozerova IN, Sirota MG. Integration of motor and visual information in parietal area 5 during locomotion. J Neurophysiol 90: 961-971, 2003.
4. Buneo CA, Andersen RA. The posterior parietal cortex: sensorimotor interface for the planning and online control of visually guided movements. Neuropsychologia 44: 2594-2606, 2006.
5. Cerminara NL, Apps R, Marple-Horvat DE. An internal model of a moving visual target in the lateral cerebellum. J Physiol 587: 429-442, 2009.
6. Cui H, Andersen RA. Posterior parietal cortex encodes autonomously selected motor plans. Neuron 56: 552-559, 2007.
7. Desmurget M, Epstein CM, Turner RS, Prablanc C, Alexander GE, Grafton ST. Role of the posterior parietal cortex in updating reaching movements to a visual target. Nat Neurosci 2: 563-567, 1999.
8. Drew T. Motor cortical activity during voluntary gait modifications in the cat. I. Cells related to the forelimbs. J Neurophysiol 70: 179-199, 1993.
9. Drew T, Andujar JE, Lajoie K, Yakovenko S. Cortical mechanisms involved in visuomotor coordination during precision walking. Brain Res Rev 57: 199-211, 2008.
10. Drew T, Doucet S. Application of circular statistics to the study of neuronal discharge during locomotion. J Neurosci Methods 38: 172-182, 1991.
11. Drew T, Marigold DS. The effect of manipulation of visual input on the discharge activity of cells in the posterior parietal cortex during voluntary gait modifications in the cat. Soc Neurosci Abstr 860.172-6, 2008.
12. Dubner R, Rutledge LT. Recording and analysis of converging input upon neurons in cat association cortex. J Neurophysiol 27: 620-634, 1964.
13. Eskandar EN, Assad JA. Dissociation of visual, motor and predictive signals in parietal cortex during visual guidance. Nat Neurosci 2: 88-93, 1999.
14. Gnadt JW, Andersen RA. Memory related motor planning activity in posterior cortex of macaque. Exp Brain Res 70: 216-220, 1988
15. Hollands MA, Marple-Horvat DE. Visually guided stepping under conditions of step cycle-related denial of visual information. Exp Brain Res 109: 343-356, 1996.
16. Kalaska JF. Parietal cortex area 5 and visuomotor behavior. Can J Physiol Pharmacol 74: 483-498, 1996.
17. Lajoie K, Andujar JE, Pearson KG, Drew T. Neurons in area 5 of the posterior parietal cortex in the cat contribute to interlimb coordination during visually guided locomotion: a role in working memory. J Neurophysiol 103: 2234-2254, 2010.
18. Lajoie K, Drew T. Lesions of area 5 of the posterior parietal cortex in the cat produce errors in the accuracy of paw placement during visually guided locomotion. J Neurophysiol 97: 2339-2354, 2007.
19. Lee DN, Lishman JR, Thomson JA. Regulation of gait in long jumping. J Exp Psychol Hum Percept Perform 8: 448-459, 1982.
20. Lipski J. Antidromic activation of neurones as an analytic tool in the study of the central nervous system. J Neurosci Methods 4: 1-32, 1981.
21. Maimon G, Assad JA. A cognitive signal for the proactive timing of action in macaque LIP. Nat Neurosci 9: 948-955, 2006a.
22. Maimon G, Assad JA. Parietal area 5 and the initiation of self-timed movements versus simple reactions. J Neurosci 26: 2487-2498, 2006b.
23. Marigold DS, Andujar JE, Lajoie K, Drew T. Motor planning of locomotor adaptations on the basis of vision: the role of the posterior parietal cortex. Prog Brain Res 188: 83-100, 2011.
24. McVea DA, Taylor AJ, Pearson KG. Long-lasting working memories of obstacles established by foreleg stepping in walking cats require area 5 of the posterior parietal cortex. J Neurosci 29: 9396-9404, 2009.
25. Mountcastle VB, Lynch JC, Georgopoulos A, Sakata H, Acuna C. Posterior parietal association cortex of the monkey: command functions for operation within extrapersonal space. J Neurophysiol 38: 871-908, 1975.
26. Mulliken GH, Musallam S, Andersen RA. Forward estimation of movement state in posterior parietal cortex. Proc Natl Acad Sci USA 105: 8170-8177, 2008.
27. Murata A, Gallase V, Kaseda M, Sakata H. Parietal neurons related to memory-guided hand manipulation. J Neurophysiol 75: 2180-2186, 1996.
28. Palmer C. A microwire technique for recording single neurons in unrestrained animals. Brain Res Bull 3: 285-289, 1978.
29. Patla AE. Understanding the roles of vision in the control of human locomotion. Gait Posture 5: 54-69, 1997.
30. Patla AE. How is human gait controlled by vision? Ecol Psychol 10: 287-302, 1998.
31. Patla AE, Adkin A, Martin C, Holden R, Prentice S. Characteristics of voluntary visual sampling of the environment for safe locomotion over different terrains. Exp Brain Res 112: 513-522, 1996.
32. Patla AE, Greig MA. Any way you look at it, successful obstacle negotiation needs visually guided on-line foot placement regulation during the approach phase. Neurosci Lett 397: 110-114, 2006.
33. Pham QC, Hicheur H. On the open-loop and feedback processes that underlie the formation of trajectories during visual and nonvisual locomotion in humans. J Neurophysiol 102: 2800-2815, 2009.
34. Reynolds RF, Day BL. Visual guidance of the human foot during a step. J Physiol 569: 677-684, 2005.
35. Rice NJ, Tunik E, Grafton ST. The anterior intraparietal sulcus mediates grasp execution, independent of requirement to update: new insights from transcranial magnetic stimulation. J Neurosci 26: 8176-8182, 2006.
36. Rietdyk S, Rhea CK. Control of adaptive locomotion: effect of visual obstruction and visual cues in the environment. Exp Brain Res 169: 272-278, 2006.
37. Shadmehr R, Krakauer JW. A computational neuroanatomy for motor control. Exp Brain Res 185: 359-381, 2008.
38. Snyder LH, Batista AP, Andersen RA. Coding of intention in the posterior parietal cortex. Nature 386: 167-170, 1997.
39. Thomson JA. How do we use visual information to control locomotion? Trends Neurosci 3: 247-250, 1980.
40. Thomson JA. Is continuous visual monitoring necessary in visually guided locomotion? J Exp Psychol Hum Percept Perform 9: 427-443, 1983.
41. Tunik E, Frey SH, Grafton ST. Virtual lesions of the anterior intraparietal area disrupt goal-dependent on-line adjustments of grasp. Nat Neurosci 8: 505-511, 2005.
42. Udo M, Kamei H, Matsukawa K, Tanaka K. Intralimb coordination in cat locomotion investigated with perturbation. II. Correlates in neuronal activity of Deiter's cells of decerebrate walking cats. Exp Brain Res 46: 438-447, 1982.
43. Wilkinson EJ, Sherk H. The use of visual information for planning accurate steps in a cluttered environment. Behav Brain Res 164: 270-274, 2005.
44. Wolpert DM, Goodbody SJ, Husain M. Maintaining internal representations: the role of the human superior parietal lobe. Nat Neurosci 1: 529-533, 1998.