DE | EN
 
 
 
 
 
 
 
 
 
   
 

15: Attention in sense of touch

Bauer M, Oostenveld R, Peeters M, Fries P (2006) Tactile spatial attention enhances gamma-band activity in somatosensory cortex and reduces low-frequency activity in parieto-occipital areas. J Neuroscience 26(2): 490-501

Buchner H, Reinartz U, Waberski TD, Gobbele R, Noppeney U, Scherg M (1999) Sustained attention modulates the immediate effect of de-afferentation on the cortical representation of the digits: Source localization of somatosensory evoked potentials in humans. Neurosci Lett 260: 57-60

Burton H, Abend NS, MacLeod AMK, Sinclair RJ, Snyder AZ, Raichle ME (1999) Tactile attention tasks enhance activation in somatosensory regions of parietal cortex: a positron emission tomography study. Cerebral Cortex 9: 662-674

Burton H, Sinclair RJ (2000) Tactile-spatial and cross-modal attention effects in the primary somatosensory cortical areas 3b and 1-2 of rhesus monkeys. Somatosensory and Motor Research 17: 213-228

Burton H, Sinclair RJ, Hong SY, Pruett JR, Whang KC (1997) Tactile-spatial and cross-modal attention effects in the second somatosensory and 7b cortical areas of rhesus monkeys. Somatosensory and Motor Research 14: 237-267

Chapman CE, Meftah EM (2005) Independent controls of attentional influences in primary and secondary somatosensory cortex. J Neurophysiology 94: 4094-4107

Driver J (2001) A selective review of selective attention research from the past century. Br J Psychology 92: 53-78

Driver J, Grossenbacher PinG (1996) Multimodal spatial constraints on tactile selective attention. In: JL McClelland (ed): Attention and performance XVI. MIT Press, Cambridge, MA

Duncan J, Ward R, Shapiro K (1994) Direct measurement of attentional dwell time in human vision. Nature 369: 313-315

Eimer M, Forster B (2003) Modulations of early somatosensory ERP components by transient and sustained attention. Exp Brain Res 151: 24-31

Forster B, Eimer M (2004) The attentional selection of spatial and non-spatial attributes in touch: ERP evidence for parallel and independent processes. Biological Psychology 66: 1-20

Fries P, Reynolds JH, Rorie AE, Desimone R (2001) Modulation of oscillatory neural synchronization by selective visual attention. Science 291: 1560-1563

Giabbiconi CM, Dancer C, Zopf R, Gruber T, Müller MM (2004) Selective spatial attention to left or right hand flutter sensation modulates the steadystate somatosensory evoked potential. Cognitive Brain Research 20: 58-66

Giabbiconi CM, Trujillo-Barreto NJ, Gruber T, Müller MM (2007) Sustained spatial attention to vibration is mediated in primary somatosensory cortex. NeuroImage 35: 255-262

Goff GD (1967) Differential discrimination of frequency of cutaneous mechanical vibration. J Exp Psychology 74: 294-299

Gruber T, Müller MM, Keil A, Elbert T (1999) Selective visual-spatial attention alters induced gamma band responses in the human EEG. Clin Neurophysiol 110: 2074-2085

Hansen JC, Hillyard SA (1980) Endogenous brain potentials associated with selective auditory attention. Electroencephalography and Clinical Neurophysiology 49: 277-290

Hansson T, Brismar T (1999) Tactile stimulation of the hand causes bilateral cortical activation: a functional magnetic resonance study in humans. Neurosci Lett 271: 29-32

Harrington GS, Hunter Downs III J (2001) fMRI mapping of the somatosensory cortex with vibratory stimuli. Is there a dependency on stimulus frequency? Brain Research 897: 188-192

Hillyard SA, Anllo-Vento L (1998) Event-related brain potentials in the study of visual selective attention. PNAS 95: 781-787

Hillyard SA, Mangun GR, Woldorff MG, Luck SJ (1995) Neural systems mediating selective attention. In: MS Gazzaniga (eds): The cognitive neurosciences. MIT Press, Cambridge

Hollins M, Goble AK, Whitsel BL, Tommerdahl M (1990) Time course and actionspectrum of vibrotactile adaptation. Somatosensory and Motor Research 2: 205-221

Hsiao SS, O’Shaughnessy DM, Johnson KO (1993) Effects of selective attention on spatial form processing in monkey primary and secondary cortex. J Neurophysiology 70: 444-447

Hsiao SS, Vega-Bermudez F (2002) Attention in the somatosensory system. In: RJ Nelson (ed): The somatosensory system: Deciphering the brain’s own body image. CRC Press, Boca Raton

Hämäläinen H, Kekoni J, Sams M, Reinikainen K, Näätänen R (1990) Human somatosensory evoked potentials to mechanical pulses and vibration: contributions of SI and SII somatosensory cortices to P50 and P100 components. Electroencephalography and Clin Neurophysiol 75(2): 13-21

Iguchi Y, Hoshi Y, Hashimoto I (2001) Selective spatial attention induces short-term plasticity in human somatosensory cortex. Neuroreport 12: 3133-3136

Ishiko N, Hanamori T, Murayama N (1980) Spatial distribution of somatosensory responses evoked by tapping the tongue and finger in man. Electroencephalography and Clin Neurophysiol 50: 1-10

James W (1890) Principles of Psychology. Henry Holt, New York

Johannsen-Berg H, Llyoyd D (2000) The physiology and psychology of selective attention to touch. Frontiers in Bioscience 5: 894-904

Kandel ER, Jessel TM (1991) Touch. In: TM Jessell (ed): Principles of neural science. Prentice Hall International, London

Kelly EF, Folger SE (1999) EEG evidence of stimulus- directed response dynamics in human somatosensory cortex. Brain Research 815: 326-336

Kelly EF, Trulsson M, Folger SE (1997) Periodic microstimulation of single mechanoreceptive afferents produces frequency-following responses in human EEG. J Neurophysiology 77: 137-144

Kida T, Nishihira Y, Wasaka T, Nakata H, Sakamoto M (2004) Differential modulation of temporal and frontal components of the somatosensory N410 and the effect of interstimulus interval in a selective attention task. Cognitive Brain Research 19: 33-39

Kida T, Nishihira Y, Wasaka T, Nakata H, Sakamoto M (2004) Passive enhancement of the somatosensory P100 and N140 in an active attention task using deviant alone condition. Clin Neurophysiol 115: 871-879

Kida T, Wasaka T, Nakata H, Akatsuka K, Kakigi R (2006) Active attention modulates passive attention- related neural responses to sudden somatosensory input against a silent background. Exp Brain Research 175: 609-617

Lakatos S, Shepard R (1997) Time-distance relations in shifting attention between locations on one’s body. Perception & Psychophysics 59: 557-566

LaMotte RH, Mountcastle VB (1975) Capacities of humans and monkeys to discriminate between vibratory stimuli of different frequency and amplitude: a correlation between neural events and psychophysical measurements. J Neurophysiology 38: 539-559

Macaluso E, Frith CD, Driver J (2000) Selective spatial attention in vision and touch: unimodal and multimodal mechanisms revealed by PET. J Neurophysiology 83: 3062-3075

Martin JH, Jessel TM (1991) Modality coding in the somatic sensory system. In: TM Jessell (eds): Principles of neural science. Prentice Hall International, London

Mima T, Nagamine T, Nakamura K, Shibasaki H (1998) Attention modulates both primary and secondary somatosensory cortical activites in humans: A magnetoencephalogrpahic study. J Neurophysiology 80: 2215-2221

Mountcastle VB, Steinmetz MA, Romo R (1990) Frequency discrimination in the sense of flutter: psychophysical measurements correlated with postcentral events in behaving monkeys. J Neuroscience 10: 3032-3044

Mountcastle VB, Talbot WH, Sakata H, Hyvarinen J (1969) Cortical mechanisms in flutter vibration studied in unanesthetized monkeys. J Neurophysiology 32: 453-484

Müller MM, Gruber T (2001) Induced gamma-band responses in the human EEG are related to attentional information processing. Visual Cognition 8: 579-592

Müller MM, Teder-Sälejärvi W, Hillyard SA (1998) The time course of cortical facilitation during cued shifts of spatial attention. Nature Neuroscience 1: 631-634

Nakajima Y, Imamura N (2000) Probability and interstimulus interval effects on the N140 and the P300 components of somatosensory ERPs. Int J Neurosci 104: 75-91

Niebur E, Hsiao SS, Johnson KO (2002) Synchrony: a neural mechanism for attentional selection? Curr Opin Neurobiol 12: 190-194

Niebur E, Koch C, Rosin C (1993) An oscillationbased model for the neuronal basis of attention. Vision Research 33: 2789-2802

Niebur E, Krieger Z (2002) Electrophysiological correlates of synchronous neural activity and attention: a short review. Biosystems 67: 157-166

Posner MI (1980) Orienting of attention. Quarterly J Exp Psychology 32: 3-25

Salinas E, Hernandez A, Zainos A, Romo R (2000) Periodicity and firing rate as candidate neural codes for the frequency of vibrotactile stimuli. J Neuroscience 20(14): 5503-5515

Snyder AZ (1992) Steady-state vibration evoked potentials: description of technique and characterization of responses. Electroenceph Clin Neurophysiol 84: 257-268

Sperling G, Reeves A (1980) Measuring the reaction time of a shift of visual attention. In: RS Nickerson (ed): Attention and performance. VIII. Erlbaum, Hillsdale

Staines WR, Graham SJ, Black SE, McIlroy WE (2002) Task-relevant modulation of contralateral and ipsilateral primary somatosensory cortex and the role of a prefrontal-cortical sensory gating system. NeuroImage 15: 190-199

Steinmetz PN, Roy A, Fitzgerald PJ, Hsiao SS, Johnson KO, Niebur E (2000) Attention modulates synchronized neuronal firing in primate somatosensory cortex. Nature 404(6774): 187-190

Taylor-Clarke M, Kennett S, Haggard P (2002) Vision modulates somatosensory cortical processing. Current Biology 12(3): 233-236

Tobimatsu S, Zhang YM, Kato M (1999) Steadystate vibration somatosensory evoked potentials: physiological characteristics and tuning function. Clin Neurophysiol 110: 1953-1958

Tobimatsu S, Zhang YM, Suga R, Kato M (2000) Differential temporal coding in vibratory sense in the hand and foot in man. Clin Neurophysiol 111: 398-404

Tommerdahl M, Delemos KA, Whitsel BL, Favorov OV, Metz CB (1999) Response of anterior parietal cortex to cutaneous flutter versus vibration. J Neurophysiology 82: 16-33

Tommerdahl M, Whitsel BL, Favorov OV, Metz CB, O’Quinn BL (1999) Response of contralateral SI and SII in cat to same-site cutaneous flutter versus vibration. J Neurophysiology 82: 1982-1992

von der Malsburg C, Schneider W (1986) A neural cocktail-party processor. Biological Cybernetics 54: 29-40

Weichselgartner E, Sperling G (1987) Dynamics of automatic controlled visual attention. Science 238: 778-780

Yantis S, Johnson DN (1990) Mechanisms of attentional priority. J Exper Psychol Hum Percept Perform 16: 812-825

Zimmermann M (1990) Das somatoviscerale sensorische System. In: G Thews (ed): Physiologie des Menschen. Springer-Verlag, Berlin

Zopf R, Giabbiconi CM, Gruber T, Müller MM (2004) Attentional modulation of the human somatosensory evoked potential in a trial-by-trial spatial cueing and sustained spatial attention task measured with high density 128 channels EEG. Cognitive Brain Research 20: 491-509

<link>Ref: « Implicit and explicit memory effects in haptic perception
<link>Ref: » Haptic object identification
<link>references: chapters, <link>all

<link>contents «Human Haptic Perception», Grunwald (Ed.)