Abstract
Advances in electrophysiology occurring in the middle of the twentieth century provided a nonintrusive means of studying the bioelectrical activity associated with behavior in humans and the first method for assessing the activity of the brain. Early psychophysiological research was typically crude and plagued with methodological problems related to various technical limitations (e.g., Angell and Thompson [1]). Nevertheless, a foundation was established for the investigation of the physiological manifestations of cognition. Although methodological complexities continue to present an interpretive problem in experiments, there is now abundant evidence that both central and peripheral bioelectrical activity reflect behavioral and cognitive processes. The observation of this physiological activity led to the concept of arousal, which became an important part of many theories of attention.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Angell, J., & Thompson, H. B. (1899). A study of the relations between certain synaptic processes and consciousness. Psychological Review, 6, 32–39.
James, W. (1884). What is an emotion? Mind, 9, 188–204.
James, W. (1922). What is emotion? In K. Dunlap (Ed.), In the emotions. Baltimore: William and Wilkins.
Cannon, W. B. (1929). Bodily changes in pain, horror, fear and rage (2nd ed.). New York: Appleton.
Duffy, E. (1962). Activation and behavior. New York: Wiley.
Duffy, E. (1972). Activation. In N. S. Greenfield & R. A. Sternbach (Eds.), Handbook of psychophysiology. New York: Holt, Rhinehart & Winston.
Schachter, S., & Singer, J. E. (1962). Cognitive, social and physiological determinants of emotional state. Psychological Review, 69, 379–399.
Ax, A. F. (1953). The physiological differentiation between fear and anger in humans. Psychosomatic Medicine, 15, 433–442.
May, J. R., & Johnson, H. J. (1973). Physiological activity to internally elicited arousal and inhibitory thoughts. Journal of Abnormal Psychology, 82, 239–245.
Schwartz, G. E. (1988). Emotion and psychophysiological organization: A systems approach. In M. G. H. Coles, E. Donchin, & S. W. Porges (Eds.), Psychophysiology: Systems, processes, and applications (pp. 354–377). New York: The Guilford Press.
Schwartz, G. E., & Weinberger, D. A. (1980). Patterns of emotional responses to affective situations: Relations among happiness, sadness, anger, fear, depression and anxiety. Motivation and Emotion, 4, 175–191.
Roberts, R. J., & Weerts, T. C. (1982). Cardiovascular responding during anger and fear imagery. Psychological Reports, 50(1), 219–230.
Roberts, R. J., & Weerts, T. C. (1984). Forearm blood flow responding prior to voluntary isometric contraction. Psychophysiology, 21(4), 363–370.
LeDoux, J. (1996). Emotional networks and motor control: A fearful view. Progress in Brain Research, 107, 437–446.
LeDoux, J. (1998). Fear and the brain: Where have we been, and where are we going? Biological Psychiatry, 44(12), 1229–1238.
LeDoux, J. (2003). The emotional brain, fear, and the amygdala. Cellular and Molecular Neurobiology, 23(4–5), 727–738.
LeDoux, J. E., Thompson, M. E., Iadecola, C., Tucker, L. W., & Reis, D. J. (1983). Local cerebral blood flow increases during auditory and emotional processing in the conscious rat. Science, 221, 576–578.
LeDoux, J. E. (2000). Emotion circuits in the brain. Annual Review of Neuroscience, 23, 155–184.
LeDoux, J. E., & Hirst, W. (1986). Mind and brain: Dialogues in cognitive neuroscience. Cambridge [Cambridgeshire]. New York: Cambridge University Press.
Ledoux, J. E., & Muller, J. (1997). Emotional memory and psychopathology. Philosophical Transactions of the Royal Society of London, 352(1362), 1719–1726.
Ledoux, J. E., Sakaguchi, A., & Reis, D. J. (1983). Strain differences in fear between spontaneously hypertensive and normotensive rats. Brain Research, 277(1), 137–143.
LeDoux, J. E., Sakaguchi, A., & Reis, D. J. (1984). Subcortical efferent projections of the medial geniculate nucleus mediate emotional responses conditioned to acoustic stimuli. The Journal of Neuroscience, 4(3), 683–698.
Cohen, R. A., Paul, R., Zawacki, T. M., Moser, D. J., Sweet, L., & Wilkinson, H. (2001). Emotional and personality changes following cingulotomy. Emotion, 1(1), 38–50.
Kerns, J. G., Cohen, J. D., MacDonald, A. W., III, Cho, R. Y., Stenger, V. A., & Carter, C. S. (2004). Anterior cingulate conflict monitoring and adjustments in control. Science, 303(5660), 1023–1026.
Botvinick, M. M., Braver, T. S., Barch, D. M., Carter, C. S., & Cohen, J. D. (2001). Conflict monitoring and cognitive control. Psychological Review, 108(3), 624–652.
Damasio, A. R. (1994). Descartes’ error. New York: Harper Collins.
Damasio, A. R. (2010). Self comes to mind: Constructing the conscious brain. New York: Random House.
Bosse, T., Jonker, C. M., & Treur, J. (2008). Formalization of Damasio’s theory of emotion, feeling and core consciousness. Consciousness and Cognition, 17(1), 94–113.
Moruzzi, G., & Magoun, H. W. (1949). Brain stem reticular formation and activation of the EEG. Electroencephalography and Clinical Neurophysiology, 1, 455–473.
Kotliar, B. E. (1983). Neural mechanism of conditioning. New York, NY: Pergamon Press.
Kotliar B.I., Eroshenko, T. (1971). Hypothalamic gluceroceptors: the phenomenon of plasticity. physiol Behav 1971, Vol.7.
Yerkes, R., & Dodson, J. D. (1908). he relation of strength of stimulus to rapidity of habit formation. Journal of Comparative Neurology and Psychology, 18, 459–482.
Easterbrook, J. A. (1959). The effect of emotion on cue utilization and the organization of behavior. Psychological Review, 66(3), 183–201.
Broadbent, D. E. (1958). Perception and communication. London: Pergamon Press.
Kempton, S., Vance, A., Maruff, P., Luk, E., Costin, J., & Pantelis, C. (1999). Executive function and attention deficit hyperactivity disorder: Stimulant medication and better executive function performance in children. Psychological Medicine, 29(3), 527–538.
Loo, S. K., Teale, P. D., & Reite, M. L. (1999). EEG correlates of methylphenidate response among children with ADHD: A preliminary report. Biological Psychiatry, 45(12), 1657–1660.
McKetin, R., & Solowij, N. (1999). Event-related potential indices of auditory selective attention in dependent amphetamine users. Biological Psychiatry, 45(11), 1488–1497.
Solanto, M. V. (1997). Does methylphenidate influence cognitive performance? Journal of the American Academy of Child and Adolescent Psychiatry, 36(10), 1323–1325.
Pelham, W. E., Hoza, B., Kipp, H. L., Gnagy, E. M., & Trane, S. T. (1997). Effects of methylphenidate and expectancy of ADHD children’s performance, self-evaluations, persistence, and attributions on a cognitive task. Experimental and Clinical Psychopharmacology, 5(1), 3–13.
Lufi, D., Parish-Plass, J., & Gai, E. (1997). The effect of methylphenidate on the cognitive and personality functioning of ADHD children. The Israel Journal of Psychiatry and Related Sciences, 34(3), 200–209.
Geisler, M. W., Sliwinski, M., Coyle, P. K., Masur, D. M., Doscher, C., & Krupp, L. B. (1996). The effects of amantadine and pemoline on cognitive functioning in multiple sclerosis. Archives of Neurology, 53(2), 185–188.
Vos, P. J., Folgering, H. T., & van Herwaarden, C. L. (1995). Visual attention in patients with chronic obstructive pulmonary disease. Biological Psychology, 41(3), 295–305.
Herning, R. I., Jones, R. T., Hooker, W. D., & Tulunay, F. C. (1985). Information processing components of the auditory event related potential are reduced by cocaine. Psychopharmacology, 87(2), 178–185.
Flacker, J. M., & Lipsitz, L. A. (1999). Serum anticholinergic activity changes with acute illness in elderly medical patients. The Journals of Gerontology. Series A, Biological Sciences and Medical Sciences, 54(1), M12–M16.
Liu, J. L., & Su, S. N. (1993). The role of acetylcholine in the cognitive function of frontal neurons in monkeys. Science in China, 36(12), 1510–1517.
Trzepacz, P. T., Leavitt, M., & Ciongoli, K. (1992). An animal model for delirium. Psychosomatics, 33(4), 404–415.
Callaway, E., & Band, R. I. (1958). Some psychopharmacological effects of atropine; preliminary investigation of broadened attention. A.M.A. Archives of Neurology and Psychiatry, 79(1), 91–102.
Hockey, G. R. J. (1970). Effect of loud noise on attentional selectivity. Quarterly Journal of Experimental Psychology, 22, 28–36.
Broadbent, D. E., & Gregory, M. (1965). Effects of noise and of signal rate upon vigilance analysed by means of decision theory. Human Factors, 7(2), 155–162.
Corcoran, D. W. J., Mullin, J., Rainey, M. T., & Frith, G. (1977). The effects of raised signal and noise amplitude during the course of vigilance tasks. New York: Academic Press.
Adams, R. D., & Victor, M. (1981). Principles of neurology (2nd ed.). New York: McGraw-Hill.
Ropper, A., & Samuels, M. (2009). Adams and victor’s principles of neurology (9th ed.). New York: McGraw-Hill.
Lacey, B. C., & Lacey, J. I. (1978). Two way communications between the heart and the brain. American Psychologist, 33, 99–113.
Kahneman, D. (1973). Attention and effort. Englewood Cliffs: Prentice-Hall.
Pribram, K., & McGuinness, D. (1975). Arousal, activation, and effort in the control of attention. Psychological Review, 82(2), 116–149.
Cohen, R. A., & Waters, W. (1985). Psychophysiological correlates of levels and states of cognitive processing. Neuropsychologia, 23(2), 243–256.
Ohman, A. (1979). The orienting response, attention, and learning: An information-processing perspective. In H. D. Kimmel, E. H. van Olst, & J. F. Orlebeke (Eds.), The orienting reflex in humans (pp. 443–471). The Hague: Mouton.
Pillsbury, W. B. (1908). Attention. New York: Macmillan.
Woodworth, R. S. (1938). Experimental psychology. New York: H. Holt and company.
Maltzman, I. (1955). Thinking: From a behavioristic point of view. Psychological Review, 62, 275–286.
Maltzman, I. (1968). Theoretical conceptions of semantic conditioning and generalization. In T. R. Dixon & D. L. Horton (Eds.), Verbal behavior and general behavior theory (pp. 291–339). Englewood Cliffs: Prentice-Hall.
Maltzman, I. (1979). Orienting reflexes and classical conditioning in humans. In H. D. Kimmel, E. H. van Olst, & J. F. Orlebeke (Eds.), The orienting reflex in humans (pp. 323–352). Hillsdale: Erlbaum.
Darrow, C. W. (1929). Differences in the physiological reaction to sensory and ideational stimuli. Psychological Bulletin, 26, 185–201.
Lacey, J. I. (1959). Psychophysiological approaches to the evaluation of phsychotherapeutic process and outcome. In E. A. Rubinstein & M. B. Parloff (Eds.), Research in psychotherapy (pp. 160–208). Washington: American Psychological Association.
Lacey, J. I. (1967). Somatic response patterning and stress: Some revisions of activation theory. In M. H. Appley & R. Trumbull (Eds.), Psychological stress: Issues in research. New York: Appleton-Century-Crofts.
Lacey, J. I., & Lacey, B. C. (1958). Verification and extension of the principle of autonomic response-stereotypy. The American Journal of Psychology, 71(1), 50–73.
Graham, F. K., Clifton, R. K., & Hatton, H. M. (1968). Habituation of heart rate response to repeated auditory stimulation during the first five days of life. Child Development, 39(1), 35–52.
Graham, F. K., & Clifton, R. K. (1966). Heart-rate change as a component of the orienting response. Psychological Bulletin, 65, 305–320.
Jennings, J. R. (1986). Bodily changes during attending. In M. G. H. Coles, E. Donchin, & S. W. Porges (Eds.), Psychophysiology: Systems, processes, and applications (pp. 268–289). New York: The Guilford Press.
Jennings, J. R. (1986). Memory, thought, and bodily response. In M. G. H. Coles, E. Donchin, & S. Porges (Eds.), Psychophysiology: Systems, processes, and applications (pp. 290–308). New York: The Guilford Press.
Jennings, J. R., & Hall, S. W., Jr. (1980). Recall, recognition, and rate: Memory and the heart. Psychophysiology, 17, 37–46.
Jennings, J. R., Lawrence, B. E., & Kasper, P. (1978). Changes in alertness and processing capacity in a serial learning task. Memory and Cognition, 6, 45–63.
Graham, F. K. (1979). Distinguishing among orienting, defense, and startle reflexes. In H. D. Kimmel, E. H. van Olst, & J. F. Orlebeke (Eds.), The orienting reflex in humans. Hillsdale: Erlbaum.
Obrist, P. A. (1981). Cardiovascular psychophysiology: A perspective. New York: Plenum Press.
Obrist, P. A. (2008). Cardiovascular psychophysiology: Current issues in response mechanisms, biofeedback and methodology. New Brunswick: AldineTransaction.
Lacey, J. I., Kagan, J., Lacey, B. C., & Moss, H. A. (1963). The visceral level: Situational determinants and behavioural correlates of autonomic response patterns. In P. Knapp (Ed.), Expression of the emotions in man (pp. 161–196). New York: International Universities Press.
Jennings, J. R. (1971). Cardiac reactions and different developmental levels of cognitive functioning. Psychophysiology, 8(4), 433–450.
Kahneman, D., Tursky, B., Shapiro, D., & Crider, A. (1969). Pupillary, heart rate and skin resistance changes during a mental task. Journal of Experimental Psychology, 79, 164–167.
Tursky, B., Schwartz, G. E., & Crider, A. (1970). Differential patterns of heart rate and skin resistance during a digit-transformation task. Journal of Experimental Psychology, 83(3), 451–457.
Jennings, J. R., Averill, R. J., Opton, M. E., & Lazarus, R. S. (1980). Some parameters of heart rate change: Perceptual versus motor task requirements, noxiousness, and uncertainty. Psychophysiology, 7, 194–212.
Coles, M. G., & Duncan-Johnson, C. C. (1975). Cardiac activity and information processing: The effects of stimulus significance, and detection and response requirements. Journal of Experimental Psychology. Human Perception and Performance, 1(4), 418–428.
Schwartz, G. E., & Higgins, J. D. (1971). Cardiac activity preparatory to overt and covert behavior. Science, 173, 1144–1145.
Shangi, L. M., Das, J. P., & Mulcahy, R. (1978). Heart rate, recall, and reaction-time measures of levels of processing. Perceptual and Motor Skills, 46(1), 187–198.
Adan, A., & Sanchez-Turet, M. (1996). Cardiac reactivity during task performance: Influence of time of day. Neuroreport, 8(1), 129–132.
Spence, D. P., & Beyda, D. R. (1980). Heart-rate change as a measure of verbal storage and retrieval. British Journal of Psychology, 71(2), 283–293.
Somsen, R. J., Van der Molen, M. W., Jennings, J. R., & van Beek, B. (2000). Wisconsin Card Sorting in adolescents: Analysis of performance, response times and heart rate. Acta Psychologica, 104(2), 227–257.
Ramirez, I., Guerra, P., Munoz, M. A., Perakakis, P., Anllo-Vento, L., & Vila, J. (2010). The dynamics of cardiac defense: From attention to action. Psychophysiology, 47(5), 879–887.
Sosnowski, T., Krzywosz-Rynkiewicz, B., & Roguska, J. (2004). Program running versus problem solving: Mental task effect on tonic heart rate. Psychophysiology, 41(3), 467–475.
Sosnowski, T., & Rynkiewicz, A. (2008). RUN/EDIT information processing mode and phasic cardiac acceleration. Psychophysiology, 45(6), 1079–1085.
Kahneman, D., & Beatty, J. (1966). Pupil diameter and load on memory. Science, 154(756), 1583–1585.
Beatty, J. (1979). Pupillometric methods of workload evaluation: Present status and future possibilities. In R. Auffret (Ed.), Survey of methods to assess workload. Neuilly Sur Seine: Advisory Group for Aerospace Research and Development, North Atlantic Treaty Organization.
Beatty, J. (1982). Task-evoked pupillary responses, processing load, and the structure of processing resources. Psychological Bulletin, 91(2), 276–292.
Beatty, J., & Wagoner, B. L. (1978). Pupillometric signs of brain activation vary with level of cognitive processing. Science, 199(4334), 1216–1218.
Beatty, J., & Wagoner, B. L. (1978). Pupillometric signs of brain activation vary with level of cognitive processing. Science, 199(4334), 1216–1218.
Kahneman, D., Beatty, J., & Pollack, I. (1967). Perceptual deficit during a mental task. Science, 157(3785), 218–219.
Watson, J. B. (1925). Behaviorism. New York: The People’s Institute.
Jacobsen, E. (1938). Progressive relaxation (revised edition). Chicago: University of Chicago Press.
Cacioppo, J. T., & Petty, R. E. (1981). Electromyograms as measures of extent and affectivity of information processing. American Psychologist, 36(5), 441–456.
Cacioppo, J. T., & Petty, R. E. (1981). Electromyographic specificity during covert information processing. Psychophysiology, 18(5), 518–523.
McGuigan, F. (1978). Imagery and thinking: Covert functioning of the motor system. In G. E. Schwartz & D. Shapiro (Eds.), Consciousness and self-regulation: Advances in research and theory (Vol. 2). New York: Plenum Press.
Taub, E., Williams, M., Barro, G., & Steiner, S. S. (1978). Comparison of the performance of deafferented and intact monkeys on continuous and fixed ration schedules of reinforcement. Experimental Neurology, 58(1), 1–13.
Locke, L. J., & Fehr, F. S. (1970). Young children’s use of the speech code in a recall task. Journal of Experimental Child Psychology, 10, 367–373.
Glassman, W. E. (1972). Subvocal activity and acoustic confusions in short-term memory. Journal of Experimental Psychology, 96(1), 164–169.
Kleinsmith, L. J., & Kaplan, S. (1963). Paired-associate learning as a function of arousal and interpolated interval. Journal of Experimental Psychology, 65, 190–193.
Craik, F. I. M., & Blankstein, K. R. (1975). Psychophysiology and human memory. In P. H. Venables & M. J. Christie (Eds.), Research in psychophysiology (pp. 388–417). London: Wiley.
Broadbent, D. E. (1971). Decision and stress. London: Academic.
Hamilton, P., Hockey, G. R. J., & Quinn, J. G. (1972). Information selection, arousal, and memory. The British Journal of Psychiatry, 63, 181–189.
Jones, D. M., Smith, A. P., & Broadbent, D. E. (1979). Effects of moderate intensity noise on the Bakan vigilance task. The Journal of Applied Psychology, 64(6), 627–634.
Smith, A., Jones, D. M., & Broadbent, D. E. (1981). The effects of noise on recall of categorized lists. British Journal of Psychology, 72, 299–316.
Poulton, E. C. (1979). Composite model for human performance in continuous noise. Psychological Review, 86, 361–375.
Hockey, G. R. J. (1970). Signal probability and spatial location as possible bases for increased selectivity in noise. Quarterly Journal of Experimental Psychology, 22, 37–42.
Hockey, G. R. J. (1979). Stress and the cognitive components of skilled performance. In V. Hamilton & D. M. Warburton (Eds.), Human stress and cognition. Chichester: Wiley.
Revelle, W., Humphreys, M. S., Simon, L., & Gilliland, K. (1980). The interactive effect of personality, time of day, and caffeine: A test of the arousal model. Journal of Experimental Psychology. General, 109(1), 1–31.
Humphreys, M. S., & Revelle, W. (1984). Personality, motivation, and performance: A theory of the relationship between individual differences and information processing. Psychological Review, 91(2), 153–184.
Cacioppo, J. T. (1979). Effects of exogenous changes in heart rate on facilitation of thought and resistance to persuasion. Journal of Personality and Social Psychology, 37(4), 489–498.
Hoth, K. F., Nash, J., Poppas, A., Ellison, K. E., Paul, R. H., & Cohen, R. A. (2008). Effects of cardiac resynchronization therapy on health-related quality of life in older adults with heart failure. Clinical Interventions in Aging, 3(3), 553–560.
Folkard, S., & Greeman, A. L. (1974). Salience induced muscle tension, and the ability to ignore irrelevant information. Quarterly Journal of Experimental Psychology, 26, 360–367.
Folkard, S. (1979). Changes in immediate memory strategy under induced muscle tension and with time of day. Quarterly Journal of Experimental Psychology, 31, 621–633.
Folkard, S. (1979). Time of day and level of processing. Memory and Cognition, 7, 247–252.
Starr, A., Amlie, R. N., Martin, W. H., & Sanders, S. (1977). Development of auditory function in newborn infants revealed by auditory brainstem potentials. Pediatrics, 60(6), 831–839.
Munson, R., Ruchkin, D. S., Ritter, W., Sutton, S., & Squires, N. K. (1984). The relation of P3b to prior events and future behavior. Biological Psychology, 19(1), 1–29.
Sutton, S., & Ruchkin, D. S. (1984). The late positive complex. Advances and new problems. Annals of the New York Academy of Sciences, 425, 1–23.
Hillyard, S. A., Hink, R. F., Schwent, V. L., & Picton, T. W. (1973). Electrical signs of selective attention in the human brain. Science, 182, 177–180.
Hillyard, S. A., & Hansen, J. C. (1986). Attention: Electrophysiological approaches. In M. G. H. Coles, E. Donchin, & S. W. Porges (Eds.), Psychophysiology; systems, processes and applications. New York: Guilford.
Hillyard, S. A., & Hansen, J. C. (1986). Attention: Electrophysiological approaches. In M. G. H. Coles, E. Donchin, & S. W. Porges (Eds.), Psychophysiology: Systems, processes, and applications (pp. 227–243). New York: The Guilford Press.
Naatanen, R. (1982). Processing negativity: An evoked potential reflection of selective attention. Psychological Bulletin, 92, 605–640.
Deutsch, J. A., & Deutsch, D. (1963). Attention: Some theoretical considerations. Psychological Review, 70, 80–90.
Posner, M. I., Snyder, C. R., & Davidson, B. J. (1980). Attention and the detection of signals. Journal of Experimental Psychology. General, 109, 160–174.
Downing, C. J., & Pinker, S. (1975). The spatial structure of visual attention. In M. I. Posner & O. S. A. M. Martin (Eds.), Mechanisms of attention: Attention and performance (Vol. xi, pp. 171–187). Hillsdale: Erlbaum.
Magnun, G. R., & Hillyard, S. A. (1987). The spatial allocation of visual attention as indexed by event-related brain potentials. Human Factors, 29, 195–212.
Magnun, G. R., & Hillyard, S. A. (1988). Spatial gradients of visual attention: Behavioral and electrophysiological evidence. Electroencephalography and Clinical Neurophysiology, 70, 417–428.
Hillyard, S. A., & Minnte, T. F. (1984). Selective attention to color and location: An analysis with event-related potentials. Perception & Psychophysics, 36, 185–198.
Harter, M. R., Aine, C., & Schroeder, C. (1982). Hemispheric differences in the neural processing of stimulus location and type: Effects of selective attention on visual evoked potentials. Neuropsychologia, 20, 42–438.
Zouridakis, G., & Boutros, N. N. (1992). Stimulus parameter effects on the P50 evoked response. Biological Psychiatry, 32(9), 839–841.
Guterman, Y., Josiassen, R. C., & Bashore, T. R., Jr. (1992). Attentional influence on the P50 component of the auditory event-related brain potential. International Journal of Psychophysiology, 12(2), 197–209.
Waldo, M. C., & Freedman, R. (1986). Gating of auditory evoked responses in normal college students. Psychiatry Research, 19(3), 233–239.
Freedman, R., Adler, L. E., Gerhardt, G. A., et al. (1987). Neurobiological studies of sensory gating in schizophrenia. Schizophrenia Bulletin, 13(4), 669–678.
Kathmann, N., & Engel, R. R. (1990). Sensory gating in normals and schizophrenics: A failure to find strong P50 suppression in normals. Biological Psychiatry, 27(11), 1216–1226.
Boutros, N., Zouridakis, G., Rustin, T., Peabody, C., & Warner, D. (1993). The P50 component of the auditory evoked potential and subtypes of schizophrenia. Psychiatry Research, 47(3), 243–254.
Clementz, B. A., Geyer, M. A., & Braff, D. L. (1997). P50 suppression among schizophrenia and normal comparison subjects: A methodological analysis. Biological Psychiatry, 41(10), 1035–1044.
Olincy, A., Ross, R. G., Harris, J. G., et al. (2000). The P50 auditory event-evoked potential in adult attention-deficit disorder: Comparison with schizophrenia. Biological Psychiatry, 47(11), 969–977.
Jessen, F., Kucharski, C., Fries, T., et al. (2001). Sensory gating deficit expressed by a disturbed suppression of the P50 event-related potential in patients with Alzheimer’s disease. The American Journal of Psychiatry, 158(8), 1319–1321.
Bender, S., Schall, U., Wolstein, J., Grzella, I., Zerbin, D., & Oades, R. D. (1999). A topographic event-related potential follow-up study on ‘prepulse inhibition’ in first and second episode patients with schizophrenia. Psychiatry Research, 90(1), 41–53.
Woods, A. J., Mennemeier, M., Garcia-Rill, E., et al. (2012). Improvement in arousal, visual neglect, and perception of stimulus intensity following cold pressor stimulation. Neurocase, 18(2), 115–122.
Rauss, K. S., Pourtois, G., Vuilleumier, P., & Schwartz, S. (2009). Attentional load modifies early activity in human primary visual cortex. Human Brain Mapping, 30(5), 1723–1733.
Miller, J. M., Dobie, R. A., Pfingst, B. E., & Hienz, R. D. (1980). Electrophysiologic studies of the auditory cortex in the awake monkey. American Journal of Otolaryngology, 1(2), 119–130.
Alho, K., Woods, D. L., Algazi, A., & Naatanen, R. (1992). Intermodal selective attention. II. Effects of attentional load on processing of auditory and visual stimuli in central space. Electroencephalography and Clinical Neurophysiology, 82(5), 356–368.
Berman, R. A., & Colby, C. L. (2002). Auditory and visual attention modulate motion processing in area MT+. Brain Research, 14(1), 64–74.
Bundesen, C., Larsen, A., Kyllingsbaek, S., Paulson, O. B., & Law, I. (2002). Attentional effects in the visual pathways: A whole-brain PET study. Experimental Brain Research. Experimentelle Hirnforschung, 147(3), 394–406.
Ghose, G. M. (2009). Attentional modulation of visual responses by flexible input gain. Journal of Neurophysiology, 101(4), 2089–2106.
Ito, M., & Gilbert, C. D. (1999). Attention modulates contextual influences in the primary visual cortex of alert monkeys. Neuron, 22(3), 593–604.
Lee, J., & Maunsell, J. H. (2010). Attentional modulation of MT neurons with single or multiple stimuli in their receptive fields. The Journal of Neuroscience, 30(8), 3058–3066.
Montero, V. M. (2000). Attentional activation of the visual thalamic reticular nucleus depends on ‘top-down’ inputs from the primary visual cortex via corticogeniculate pathways. Brain Research, 864(1), 95–104.
Neri, P. (2004). Attentional effects on sensory tuning for single-feature detection and double-feature conjunction. Vision Research, 44(26), 3053–3064.
Reynolds, J. H., & Chelazzi, L. (2004). Attentional modulation of visual processing. Annual Review of Neuroscience, 27, 611–647.
Reynolds, J. H., Chelazzi, L., & Desimone, R. (1999). Competitive mechanisms subserve attention in macaque areas V2 and V4. The Journal of Neuroscience, 19(5), 1736–1753.
Rinne, T., Stecker, G. C., Kang, X., Yund, E. W., Herron, T. J., & Woods, D. L. (2007). Attention modulates sound processing in human auditory cortex but not the inferior colliculus. Neuroreport, 18(13), 1311–1314.
Safford, A. S., Hussey, E. A., Parasuraman, R., & Thompson, J. C. (2010). Object-based attentional modulation of biological motion processing: Spatiotemporal dynamics using functional magnetic resonance imaging and electroencephalography. The Journal of Neuroscience, 30(27), 9064–9073.
Schwartz, S., Vuilleumier, P., Hutton, C., Maravita, A., Dolan, R. J., & Driver, J. (2005). Attentional load and sensory competition in human vision: Modulation of fMRI responses by load at fixation during task-irrelevant stimulation in the peripheral visual field. Cerebral Cortex, 15(6), 770–786.
Treue, S., & Maunsell, J. H. (1999). Effects of attention on the processing of motion in macaque middle temporal and medial superior temporal visual cortical areas. The Journal of Neuroscience, 19(17), 7591–7602.
Vidyasagar, T. R. (2005). Attentional gating in primary visual cortex: A physiological basis for dyslexia. Perception, 34(8), 903–911.
Yamagishi, N., Callan, D. E., Anderson, S. J., & Kawato, M. (2008). Attentional changes in pre-stimulus oscillatory activity within early visual cortex are predictive of human visual performance. Brain Research, 1197, 115–122.
Yamagishi, N., Callan, D. E., Goda, N., Anderson, S. J., Yoshida, Y., & Kawato, M. (2003). Attentional modulation of oscillatory activity in human visual cortex. NeuroImage, 20(1), 98–113.
Sutton, S., Braren, M., Zubin, J., & John, E. R. (1965). Evoked-potential correlates of stimulus uncertainty. Science, 150(700), 1187–1188.
Squires, K. C., Squires, N. K., & Hillyard, S. A. (1975). Decision-related cortical potentials during an auditory signal detection task with cued observation intervals. Journal of Experimental Psychology. Human Perception and Performance, 1(3), 268–279.
Simson, R., Vaughan, H. G., & Ritter, W. (1976). The scalp topography of potentials associated with missing visual or auditory stimuli. Electroencephalography and Clinical Neurophysiology, 40, 33–42.
Simson, R., Vaughan, H. G., & Ritter, W. (1977). The scalp topography of potentials in auditory and visual discrimination tasks. Electroencephalography and Clinical Neurophysiology, 42, 528–535.
Okada, Y. C., Kaufman, L., & Williamson, S. J. (1983). The hippocampal formation as a source of the slow endogenous potentials. Electroencephalography and Clinical Neurophysiology, 55, 417–426.
Goodin, D. S., & Aminoff, M. J. (1984). The relationship between the evoked potential and brain events in sensory discrimination and motor response. Brain, 107, 241–251.
Halgren, E., Stapleton, J. M., Smith, M., & Altafullah, I. (1986). Generators of the human scalp P3(s). In R. Q. Cracco & I. Bodis-Wollner (Eds.), Evoked potentials (pp. 269–284). New York: Alan Liss.
Paller, K. A., Zola-Morgan, S., Squire, L. R., & Hillyard, S. A. (1988). P3-like brain waves in normal monkeys and in monkeys with medial temporal lesions. Behavioral Neuroscience, 102, 714–725.
Stapleton, J. M., & Halgren, E. (1987). Endogenous potentials evoked in simple cognitive tasks: Depth components and task correlates. Electroencephalography and Clinical Neurophysiology, 67(1), 44–52.
Stapleton, J. M., Halgren, E., & Moreno, K. A. (1987). Endogenous potentials after anterior temporal lobectomy. Neuropsychologia, 25(3), 549–557.
O’Donnell, B. F., Cohen, R. A., Hokama, H., et al. (1993). Electrical source analysis of auditory ERPs in medial temporal lobe amnestic syndrome. Electroencephalography and Clinical Neurophysiology, 87(6), 394–402.
Sutton, S., Tueting, P., Zubin, J., & John, E. R. (1967). Information delivery and the sensory evoked potential. Science, 155(768), 1436–1439.
Duncan-Johnson, C., & Donchin, E. (1977). On quantifying surprise: The variation of event-related potentials with subjective probability. Psychophysiology, 14, 456–467.
Courchesne, E., Hillyard, S. A., & Galambos, R. (1975). Stimulus novelty, task relevance and the visual evoked potentials in man. Electroencephalography and Clinical Neurophysiology, 39, 131–143.
Campbell, K. B., Courchesne, E., Picton, T. W., & Squires, K. C. (1979). Evoked potential correlates of human information processing. Biological Psychology, 8(1), 45–68.
Friedman, D., Cycowicz, Y. M., & Gaeta, H. (2001). The novelty P3: An event-related brain potential (ERP) sign of the brain’s evaluation of novelty. Neuroscience and Biobehavioral Reviews, 25(4), 355–373.
Friedman, D. B., Hakaarem, G., Sutton, S., & Fleiss, J. L. (1973). Effect of stimulus uncertainty on the pupillary dilatation response and the vertex evoked potential. Electroencephalography and Clinical Neurophysiology, 34, 475–484.
Rohrbaugh, J. W., Varner, J. L., Paige, S. R., Eckardt, M. J., & Ellingson, R. J. (1989). Event-related perturbations in an electrophysiological measure of auditory function: A measure of sensitivity during orienting? Biological Psychology, 29(3), 247–271.
Rohrbaugh, J. W., Varner, J. L., Paige, S. R., Eckardt, M. J., & Ellingson, R. J. (1990). Event-related perturbations in an electrophysiological measure of auditory sensitivity: Effects of probability, intensity and repeated sessions. International Journal of Psychophysiology, 10(1), 17–32.
Squires, K. C., Wickens, C., Squires, N. K., & Donchin, E. (1976). The effect of stimulus sequence on the waveform of the cortical event-related potential. Science, 193(4258), 1142–1146.
Duncan, C. C. (1988). Event-related brain potentials: A window on information processing in schizophrenia. Schizophrenia Bulletin, 14(2), 199–203.
Pourtois, G., De Pretto, M., Hauert, C. A., & Vuilleumier, P. (2006). Time course of brain activity during change blindness and change awareness: Performance is predicted by neural events before change onset. Journal of Cognitive Neuroscience, 18(12), 2108–2129.
Sessa, P., Luria, R., Verleger, R., & Dell’Acqua, R. (2007). P3 latency shifts in the attentional blink: Further evidence for second target processing postponement. Brain Research, 1137(1), 131–139.
Smith, J. L., Smith, E. A., Provost, A. L., & Heathcote, A. (2010). Sequence effects support the conflict theory of N2 and P3 in the Go/NoGo task. International Journal of Psychophysiology, 75(3), 217–226.
Verleger, R., & Berg, P. (1991). The waltzing oddball. Psychophysiology, 28(4), 468–477.
Dimoska, A., & Johnstone, S. J. (2008). Effects of varying stop-signal probability on ERPs in the stop-signal task: Do they reflect variations in inhibitory processing or simply novelty effects? Biological Psychology, 77(3), 324–336.
Martens, S., Elmallah, K., London, R., & Johnson, A. (2006). Cuing and stimulus probability effects on the P3 and the AB. Acta Psychologica, 123(3), 204–218.
Ehlers, C. L., & Somes, C. (2002). Long latency event-related potentials in mice: Effects of stimulus characteristics and strain. Brain Research, 957(1), 117–128.
O’Donnell, B. F., Hokama, H., McCarley, R. W., et al. (1994). Auditory ERPs to non-target stimuli in schizophrenia: Relationship to probability, task-demands, and target ERPs. International Journal of Psychophysiology, 17(3), 219–231.
Polich, J., Eischen, S. E., & Collins, G. E. (1994). P300 from a single auditory stimulus. Electroencephalography and Clinical Neurophysiology, 92(3), 253–261.
Polich, J. (1990). P300, probability, and interstimulus interval. Psychophysiology, 27(4), 396–403.
Sandman, C. A., Donnelly, J. F., O’Halloran, J. P., & Isenhart, R. (1990). Age-related change in P3 amplitude as a function of predictable and unpredictable rare events. The International Journal of Neuroscience, 52(3–4), 189–199.
Papanicolaou, A. C., Loring, D. W., Raz, N., & Eisenberg, H. M. (1985). Relationship between stimulus intensity and the P300. Psychophysiology, 22, 326–329.
McCarthy, G., & Donchin, E. (1981). A comparison of P300 latency and reaction time. Science, 211, 77–80.
Squires, N. K., Donchin, E., Squires, K. C., & Grossberg, S. (1977). Bisensory stimulation: Inferring decision-related processes from P300 component. Journal of Experimental Psychology, 3(2), 299–315.
Walton, P., Callaway, E., Halliday, R., & Naylor, H. (1987). Stimulus intensity, contrast, and complexity have additive effects on P300 latency. Electroencephalography and Clinical Neurophysiology. Supplement, 40, 284–292.
Ilan, A. B., & Polich, J. (1999). P300 and response time from a manual Stroop task. Clinical Neurophysiology, 110(2), 367–373.
Atkinson, C. M., Drysdale, K. A., & Fulham, W. R. (2003). Event-related potentials to Stroop and reverse Stroop stimuli. International Journal of Psychophysiology, 47(1), 1–21.
Rosenfeld, J. P., & Skogsberg, K. R. (2006). P300-based Stroop study with low probability and target Stroop oddballs: The evidence still favors the response selection hypothesis. International Journal of Psychophysiology, 60(3), 240–250.
Kutas, M., McCarthy, G., & Donchin, E. (1977). Augmenting mental chronometry: The P300 as a measure of stimulus evaluation time. Science, 197, 792–795.
Ritter, W., Simson, R., Vaughan, H. G., Jr., & Friedman, D. (1979). A brain event related to the making of a sensory discrimination. Science, 203(4387), 1358–1361.
Squires, K. C., Donchin, E., Herning, R. I., & McCarthy, G. (1977). On the influence of task relevance and stimulus probability on event-related-potential components. Electroencephalography and Clinical Neurophysiology, 42(1), 1–14.
Sutton, S., Ruchkin, D. S., Munson, R., Kietzman, M. L., & Hammer, M. (1982). Event-related potentials in a two-interval forced-choice detection task. Perception & Psychophysics, 32(4), 360–374.
Larson, M. J., Kelly, K. G., Stigge-Kaufman, D. A., Schmalfuss, I. M., & Perlstein, W. M. (2007). Reward context sensitivity impairment following severe TBI: An event-related potential investigation. Journal of the International Neuropsychological Society, 13(4), 615–625.
Bakay, E. P., Marton, M., Rigo, P., & Balazs, L. (1998). Responses to irrelevant probes during task-induced negative and positive shifts. International Journal of Psychophysiology, 28(3), 249–261.
Gratton, G., Coles, M. G., Sirevaag, E. J., Eriksen, C. W., & Donchin, E. (1988). Pre- and poststimulus activation of response channels: A psychophysiological analysis. Journal of Experimental Psychology, 14(3), 331–344.
Dunning, J. P., & Hajcak, G. (2007). Error-related negativities elicited by monetary loss and cues that predict loss. Neuroreport, 18(17), 1875–1878.
Fukushima, H., & Hiraki, K. (2006). Perceiving an opponent’s loss: Gender-related differences in the medial-frontal negativity. Social Cognitive and Affective Neuroscience, 1(2), 149–157.
Goyer, J. P., Woldorff, M. G., & Huettel, S. A. (2008). Rapid electrophysiological brain responses are influenced by both valence and magnitude of monetary rewards. Journal of Cognitive Neuroscience, 20(11), 2058–2069.
Holroyd, C. B., Hajcak, G., & Larsen, J. T. (2006). The good, the bad and the neutral: Electrophysiological responses to feedback stimuli. Brain Research, 1105(1), 93–101.
Mennes, M., Wouters, H., van den Bergh, B., Lagae, L., & Stiers, P. (2008). ERP correlates of complex human decision making in a gambling paradigm: Detection and resolution of conflict. Psychophysiology, 45(5), 714–720.
Toyomaki, A., & Murohashi, H. (2005). Discrepancy between feedback negativity and subjective evaluation in gambling. Neuroreport, 16(16), 1865–1868.
Yang, J., Li, H., Zhang, Y., Qiu, J., & Zhang, Q. (2007). The neural basis of risky decision-making in a blackjack task. Neuroreport, 18(14), 1507–1510.
Posner, M. I., & Snyder, C. R. R. (1975). Attention and cognitive control. In R. L. Solso (Ed.), Information processing and cognition: The Loyola Symposium (pp. 55–84). Hillsdale: Erlbaum.
Kramer, A. F., Wickens, C. D., & Donchin, E. (1983). An analysis of the processing requirements of a complex perceptual-motor task. Human Factors, 25(6), 597–621.
Kramer, A. F., Wickens, C. D., & Donchin, E. (1985). Processing of stimulus properties: Evidence for dual-task integrality. Journal of Experimental Psychology. Human Perception and Performance, 11(4), 393–408.
Wickens, C., Kramer, A., Vanasse, L., & Donchin, E. (1983). Performance of concurrent tasks: A psychophysiological analysis of the reciprocity of information-processing resources. Science, 221(4615), 1080–1082.
Wickens, C. D., Kramer, A. F., & Donchin, E. (1984). The event-related potential as an index of the processing demands of a complex target acquisition task. Annals of the New York Academy of Sciences, 425, 295–299.
Israel, J. B., Chesney, G. L., Wickens, C. D., & Donchin, E. (1980). P300 and tracking difficulty: Evidence for multiple resources in dual-task performance. Psychophysiology, 17, 259–273.
Israel, J. B., Wickens, C. D., Chesney, G. L., & Donchin, E. (1980). The event-related brain potential as an index of display-monitoring workload. Human Factors, 22, 211–224.
Schneider, W. S., & Shiffrin, R. M. (1977). Controlled and automatic human information processing: I. Detection, search, and attention. Psychological Review, 84, 1–66.
Shiffrin, R. M., & Schneider, W. (1977). Controlled and automatic human information processing: II. Perceptual learning, automatic attending and a general theory. Psychological Review, 84, 127–190.
Kramer, A., Schneiderf, W., Fisk, A., & Donchin, E. (1986). The effects of practice and task structure on the components of the event-related brain potential. Psychophysiology, 23, 33–47.
Praamstra, P., Kourtis, D., & Nazarpour, K. (2009). Simultaneous preparation of multiple potential movements: Opposing effects of spatial proximity mediated by premotor and parietal cortex. Journal of Neurophysiology, 102(4), 2084–2095.
Song, W., Ramakrishnan, A., Udoekwere, U. I., & Giszter, S. F. (2009). Multiple types of movement-related information encoded in hindlimb/trunk cortex in rats and potentially available for brain-machine interface controls. IEEE Transactions on Biomedical Engineering, 56(11 Pt 2), 2712–2716.
Hill, H. (2009). An event-related potential evoked by movement planning is modulated by performance and learning in visuomotor control. Experimental Brain Research. Experimentelle Hirnforschung, 195(4), 519–529.
Dirnberger, G., Reumann, M., Endl, W., Lindinger, G., Lang, W., & Rothwell, J. C. (2000). Dissociation of motor preparation from memory and attentional processes using movement-related cortical potentials. Experimental Brain Research. Experimentelle Hirnforschung, 135(2), 231–240.
Fallgatter, A. J., Esienack, S. S., Neuhauser, B., Aranda, D., Scheuerpflug, P., & Herrmann, M. J. (2000). Stability of late event-related potentials: Topographical descriptors of motor control compared with the P300 amplitude. Brain Topography, 12(4), 255–261.
Chen, R., & Hallett, M. (1999). The time course of changes in motor cortex excitability associated with voluntary movement. The Canadian Journal of Neurological Sciences, 26(3), 163–169.
Terada, K., Ikeda, A., Yazawa, S., Nagamine, T., & Shibasaki, H. (1999). Movement-related cortical potentials associated with voluntary relaxation of foot muscles. Clinical Neurophysiology, 110(3), 397–403.
Ikeda, A., Yazawa, S., Kunieda, T., et al. (1999). Cognitive motor control in human pre-supplementary motor area studied by subdural recording of discrimination/selection-related potentials. Brain, 122(Pt 5), 915–931.
Lehtokoski, A., Kujala, T., Naatanen, R., & Alho, K. (1998). Enhanced brain activity preceding voluntary movement in early blind humans. Neuroscience Letters, 253(3), 155–158.
Flor, H., Birbaumer, N., Roberts, L. E., et al. (1996). Slow potentials, event-related potentials, “gamma-band” activity, and motor responses during aversive conditioning in humans. Experimental Brain Research. Experimentelle Hirnforschung, 112(2), 298–312.
Tarkka, I. M., Massaquoi, S., & Hallett, M. (1993). Movement-related cortical potentials in patients with cerebellar degeneration. Acta Neurologica Scandinavica, 88(2), 129–135.
Cheron, G., & Borenstein, S. (1992). Mental movement simulation affects the N30 frontal component of the somatosensory evoked potential. Electroencephalography and Clinical Neurophysiology, 84(3), 288–292.
Nativ, A. (1991). Brain potentials associated with movement in traumatic brain injury. Physical Therapy, 71(1), 48–59.
Singh, J., & Knight, R. T. (1990). Frontal lobe contribution to voluntary movements in humans. Brain Research, 531(1–2), 45–54.
Adler, L. E., Pecevich, M., & Nagamoto, H. (1989). Bereitschaftspotential in tardive dyskinesia. Movement Disorders, 4(2), 105–112.
Neshige, R., Luders, H., Friedman, L., & Shibasaki, H. (1988). Recording of movement-related potentials from the human cortex. Annals of Neurology, 24(3), 439–445.
Leung, L. W., & Borst, J. G. (1987). Electrical activity of the cingulate cortex. I. Generating mechanisms and relations to behavior. Brain Research, 407(1), 68–80.
Bromm, B., & Treede, R. D. (1987). Human cerebral potentials evoked by CO2 laser stimuli causing pain. Experimental Brain Research. Experimentelle Hirnforschung., 67(1), 153–162.
Lee, B. I., Luders, H., Lesser, R. P., Dinner, D. S., & Morris, H. H., III. (1986). Cortical potentials related to voluntary and passive finger movements recorded from subdural electrodes in humans. Annals of Neurology, 20(1), 32–37.
Haagh, S. A., & Brunia, C. H. (1985). Anticipatory response-relevant muscle activity, CNV amplitude and simple reaction time. Electroencephalography and Clinical Neurophysiology, 61(1), 30–39.
Thickbroom, G. W., Mastaglia, F. L., Carroll, W. M., & Davies, H. D. (1985). Cerebral potentials accompanying visually triggered finger movement in man. Electroencephalography and Clinical Neurophysiology, 62(3), 209–218.
Dietz, V., Quintern, J., Berger, W., & Schenck, E. (1985). Cerebral potentials and leg muscle e.m.g. responses associated with stance perturbation. Experimental Brain Research. Experimentelle Hirnforschung., 57(2), 348–354.
Woodward, S. H., Ford, J. M., & Hammett, S. C. (1993). N4 to spoken sentences in young and older subjects. Electroencephalography and Clinical Neurophysiology, 87(5), 306–320.
Halgren, E., Baudena, P., Heit, G., et al. (1994). Spatio-temporal stages in face and word processing. 2. Depth-recorded potentials in the human frontal and Rolandic cortices. Journal of Physiology, Paris, 88(1), 51–80.
Kirsch, W., & Hennighausen, E. (2010). ERP correlates of linear hand movements: Distance dependent changes. Clinical Neurophysiology, 121(8), 1285–1292.
Kirsch, W., Hennighausen, E., & Rosler, F. (2010). ERP correlates of linear hand movements in a motor reproduction task. Psychophysiology, 47(3), 486–500.
Qiu, J., Li, H., Luo, Y., Zhang, Q., & Tu, S. (2009). The neural basis of syllogistic reasoning: An event-related potential study. Brain Research, 1273, 106–113.
Roopesh, B. N., Rangaswamy, M., Kamarajan, C., et al. (2009). Priming deficiency in male subjects at risk for alcoholism: The N4 during a lexical decision task. Alcoholism, Clinical and Experimental Research, 33(12), 2027–2036.
Ceponiene, R., Torki, M., Alku, P., Koyama, A., & Townsend, J. (2008). Event-related potentials reflect spectral differences in speech and non-speech stimuli in children and adults. Clinical Neurophysiology, 119(7), 1560–1577.
Ceponiene, R., Lepisto, T., Alku, P., Aro, H., & Naatanen, R. (2003). Event-related potential indices of auditory vowel processing in 3-year-old children. Clinical Neurophysiology, 114(4), 652–661.
Schapkin, S. A., Gusev, A. N., & Kuhl, J. (2000). Categorization of unilaterally presented emotional words: An ERP analysis. Acta Neurobiologiae Experimentalis, 60(1), 17–28.
Chao, L. L., & Knight, R. T. (1997). Age-related prefrontal alterations during auditory memory. Neurobiology of Aging, 18(1), 87–95.
Chao, L. L., Nielsen-Bohlman, L., & Knight, R. T. (1995). Auditory event-related potentials dissociate early and late memory processes. Electroencephalography and Clinical Neurophysiology, 96(2), 157–168.
Frund, I., Busch, N. A., Schadow, J., Korner, U., & Herrmann, C. S. (2007). From perception to action: Phase-locked gamma oscillations correlate with reaction times in a speeded response task. BMC Neuroscience, 8, 27.
Pourtois, G., Delplanque, S., Michel, C., & Vuilleumier, P. (2008). Beyond conventional event-related brain potential (ERP): Exploring the time-course of visual emotion processing using topographic and principal component analyses. Brain Topography, 20(4), 265–277.
Lee, W. H., Liu, Z., Mueller, B. A., Lim, K., & He, B. (2009). Influence of white matter anisotropic conductivity on EEG source localization: Comparison to fMRI in human primary visual cortex. Clinical Neurophysiology, 120(12), 2071–2081.
Lelic, D., Gratkowski, M., Valeriani, M., Arendt-Nielsen, L., & Drewes, A. M. (2009). Inverse modeling on decomposed electroencephalographic data: A way forward? Journal of Clinical Neurophysiology, 26(4), 227–235.
Lew, S., Wolters, C. H., Anwander, A., Makeig, S., & MacLeod, R. S. (2009). Improved EEG source analysis using low-resolution conductivity estimation in a four-compartment finite element head model. Human Brain Mapping, 30(9), 2862–2878.
Genetti, M., Khateb, A., Heinzer, S., Michel, C. M., & Pegna, A. J. (2009). Temporal dynamics of awareness for facial identity revealed with ERP. Brain and Cognition, 69(2), 296–305.
Bobes, M. A., Garcia, Y. F., Lopera, F., et al. (2010). ERP generator anomalies in presymptomatic carriers of the Alzheimer’s disease E280A PS-1 mutation. Human Brain Mapping, 31(2), 247–265.
De Pascalis, V., Varriale, V., & D’Antuono, L. (2010). Event-related components of the punishment and reward sensitivity. Clinical Neurophysiology, 121(1), 60–76.
Kayser, J., Tenke, C. E., Gil, R., & Bruder, G. E. (2010). ERP generator patterns in schizophrenia during tonal and phonetic oddball tasks: Effects of response hand and silent count. Clinical EEG and Neuroscience, 41(4), 184–195.
Lee, P. S., Chen, Y. S., Hsieh, J. C., Su, T. P., & Chen, L. F. (2010). Distinct neuronal oscillatory responses between patients with bipolar and unipolar disorders: A magnetoencephalographic study. Journal of Affective Disorders, 123(1–3), 270–275.
Stancak, A., Polacek, H., & Bukovsky, S. (2010). Bursts of 15–30 Hz oscillations following noxious laser stimulus originate in posterior cingulate cortex. Brain Research, 1317, 69–79.
Wibral, M., Turi, G., Linden, D. E., Kaiser, J., & Bledowski, C. (2008). Decomposition of working memory-related scalp ERPs: Crossvalidation of fMRI-constrained source analysis and ICA. International Journal of Psychophysiology, 67(3), 200–211.
Baumgartner, U., Vogel, H., Ellrich, J., Gawehn, J., Stoeter, P., & Treede, R. D. (1998). Brain electrical source analysis of primary cortical components of the tibial nerve somatosensory evoked potential using regional sources. Electroencephalography and Clinical Neurophysiology, 108(6), 588–599.
Tarkka, I. M., Stokic, D. S., Basile, L. F., & Papanicolaou, A. C. (1995). Electric source localization of the auditory P300 agrees with magnetic source localization. Electroencephalography and Clinical Neurophysiology, 96(6), 538–545.
Pantev, C., Bertrand, O., Eulitz, C., et al. (1995). Specific tonotopic organizations of different areas of the human auditory cortex revealed by simultaneous magnetic and electric recordings. Electroencephalography and Clinical Neurophysiology, 94(1), 26–40.
Bayle, D. J., & Taylor, M. J. (2010). Attention inhibition of early cortical activation to fearful faces. Brain Research, 1313, 113–123.
Chait, M., de Cheveigne, A., Poeppel, D., & Simon, J. Z. (2010). Neural dynamics of attending and ignoring in human auditory cortex. Neuropsychologia, 48(11), 3262–3271.
Dale, C. L., Findlay, A. M., Adcock, R. A., et al. (2010). Timing is everything: Neural response dynamics during syllable processing and its relation to higher-order cognition in schizophrenia and healthy comparison subjects. International Journal of Psychophysiology, 75(2), 183–193.
Haegens, S., Osipova, D., Oostenveld, R., & Jensen, O. (2010). Somatosensory working memory performance in humans depends on both engagement and disengagement of regions in a distributed network. Human Brain Mapping, 31(1), 26–35.
Henaff, M. A., Bayle, D., Krolak-Salmon, P., & Fonlupt, P. (2010). Cortical dynamics of a self driven choice: A MEG study during a card sorting task. Clinical Neurophysiology, 121(4), 508–515.
Luo, H., Liu, Z., & Poeppel, D. (2010). Auditory cortex tracks both auditory and visual stimulus dynamics using low-frequency neuronal phase modulation. PLoS Biology, 8(8), e1000445.
Xiang, J., Simon, J., & Elhilali, M. (2010). Competing streams at the cocktail party: Exploring the mechanisms of attention and temporal integration. The Journal of Neuroscience, 30(36), 12084–12093.
Luo, Q., Mitchell, D., Cheng, X., et al. (2009). Visual awareness, emotion, and gamma band synchronization. Cerebral Cortex, 19(8), 1896–1904.
Milde, T., Haueisen, J., Witte, H., & Leistritz, L. (2009). Modelling of cortical and thalamic 600 Hz activity by means of oscillatory networks. Journal of Physiology, Paris, 103(6), 342–347.
Nahum, M., Renvall, H., & Ahissar, M. (2009). Dynamics of cortical responses to tone pairs in relation to task difficulty: A MEG study. Human Brain Mapping, 30(5), 1592–1604.
van Gerven, M., & Jensen, O. (2009). Attention modulations of posterior alpha as a control signal for two-dimensional brain-computer interfaces. Journal of Neuroscience Methods, 179(1), 78–84.
Talvitie, S. S., Matilainen, L. E., Pekkonen, E., Alku, P., May, P. J., & Tiitinen, H. (2010). The effects of cortical ischemic stroke on auditory processing in humans as indexed by transient brain responses. Clinical Neurophysiology, 121(6), 912–920.
de Pasquale, F., Della Penna, S., Snyder, A. Z., et al. (2010). Temporal dynamics of spontaneous MEG activity in brain networks. Proceedings of the National Academy of Sciences of the United States of America, 107(13), 6040–6045.
Draganova, R., Wollbrink, A., Schulz, M., Okamoto, H., & Pantev, C. (2009). Modulation of auditory evoked responses to spectral and temporal changes by behavioral discrimination training. BMC Neuroscience, 10, 143.
Lee, L. C., Andrews, T. J., Johnson, S. J., et al. (2010). Neural responses to rigidly moving faces displaying shifts in social attention investigated with fMRI and MEG. Neuropsychologia, 48(2), 477–490.
Garagnani, M., Shtyrov, Y., & Pulvermuller, F. (2009). Effects of attention on what is known and what is not: MEG evidence for functionally discrete memory circuits. Frontiers in Human Neuroscience, 3, 10.
Tanaka, E., Kida, T., Inui, K., & Kakigi, R. (2009). Change-driven cortical activation in multisensory environments: An MEG study. NeuroImage, 48(2), 464–474.
Itier, R. J., & Batty, M. (2009). Neural bases of eye and gaze processing: The core of social cognition. Neuroscience and Biobehavioral Reviews, 33(6), 843–863.
Klimesch, W. (1996). Memory processes, brain oscillations and EEG synchronization. International Journal of Psychophysiology, 24(1–2), 61–100.
Klimesch, W. (1999). EEG alpha and theta oscillations reflect cognitive and memory performance: A review and analysis. Brain Research. Brain Research Reviews, 29(2–3), 169–195.
Landfield, P. W., McGaugh, J. L., & Tusa, R. J. (1972). Theta rhythm: A temporal correlate of memory storage processes in the rat. Science, 175(17), 87–89.
Nitz, D. A., & McNaughton, B. L. (1999). Hippocampal EEG and unit activity responses to modulation of serotonergic median raphe neurons in the freely behaving rat. Learning & Memory, 6(2), 153–167.
O’Keefe, J. (1993). Hippocampus, theta, and spatial memory. Current Opinion in Neurobiology, 3(6), 917–924.
Schacter, D. L. (1977). EEG theta waves and psychological phenomena: A review and analysis. Biological Psychology, 5(1), 47–82.
Staubli, U., & Lynch, G. (1987). Stable hippocampal long-term potentiation elicited by ‘theta’ pattern stimulation. Brain Research, 435(1–2), 227–234.
Cartling, B. (1994). Generation of associative processes in a neural network with realistic features of architecture and units. International Journal of Neural Systems, 5(3), 181–194.
Skrebitsky, V. G., & Chepkova, A. N. (1998). Hebbian synapses in cortical and hippocampal pathways. Reviews in the Neurosciences, 9(4), 243–264.
Bush, D., Philippides, A., Husbands, P., & O’Shea, M. (2010). Dual coding with STDP in a spiking recurrent neural network model of the hippocampus. PLoS Computational Biology, 6, e1000839.
Etevenon, P., Tortrat, D., & Benkelfat, C. (1985). Electroencephalographic cartography. II. By means of statistical group studies-activation by visual attention. Neuropsychobiology, 13(3), 141–146.
Saletu, B., & Grunberger, J. (1985). Memory dysfunction and vigilance: Neurophysiological and psychopharmacological aspects. Annals of the New York Academy of Sciences, 444, 406–427.
Koenig, L. J., & Gustafson, J. W. (1979). Hippocampal function in distractibility: An electroencephalographic investigation. Physiology & Behavior, 22(2), 305–310.
Halgren, E., Babb, T. L., & Crandall, P. H. (1978). Human hippocampal formation EEG desynchronizes during attentiveness and movement. Electroencephalography and Clinical Neurophysiology, 44(6), 778–781.
Klemm, W. R. (1976). Hippocampal EEG, and information processing: A special role for theta rhythm. Progress in Neurobiology, 7(3), 197–214.
Bennett, T. L., Hebert, P. N., & Moss, D. E. (1973). Hippocampal theta activity and the attention component of discrimination learning. Behavioral Biology, 8(2), 173–181.
Daniel, R. S. (1967). Alpha and theta EEG in vigilance. Perceptual and Motor Skills, 25(3), 697–703.
Sainsbury, R. S. (1998). Hippocampal theta: A sensory-inhibition theory of function. Neuroscience and Biobehavioral Reviews, 22(2), 237–241.
Liberman, T., Velluti, R. A., & Pedemonte, M. (2009). Temporal correlation between auditory neurons and the hippocampal theta rhythm induced by novel stimulations in awake guinea pigs. Brain Research, 1298, 70–77.
Palva, J. M., Monto, S., Kulashekhar, S., & Palva, S. (2010). Neuronal synchrony reveals working memory networks and predicts individual memory capacity. Proceedings of the National Academy of Sciences of the United States of America, 107(16), 7580–7585.
Palva, J. M., Palva, S., & Kaila, K. (2005). Phase synchrony among neuronal oscillations in the human cortex. Journal of Neuroscience, 25, 3962–3972.
Paul, R. H., Clark, C. R., Lawrence, J., Goldberg, E., Williams, L. M., Cooper, N., et al. (2005). Age-dependent change in executive function and gamma 40 Hz phase synchrony. Journal of Integrative Neuroscience, 4, 63–76.
Pfefferbaum, A., Ford, J. M., Roth, W. T., & Kopell, B. S. (1980). Age differences in P3-reaction time associations. Electroencephalography and Clinical Neurophysiology, 49, 257–265.
Pfefferbaum, A., Wenegrat, B. G., Ford, J. M., Roth, W. T., & Kopell, B. S. (1984). Clinical application of the P3 component of the event-related potentials. II. Dementia, Depression and Schizophrenia. Electroencephalography and Clinical Neurophysiology, 59, 104–124.
Syndulko, K., Hansch, E. C., Cohen, S. N., et al. (1982). Long-latency event-related potentials in normal aging and dementia. Advances in Neurology, 32, 279–285.
Goodin, D. S., Squires, K. C., Henderson, B. H., & Starr, A. (1978). An early event-related cortical potential. Psychophysiology, 15(4), 360–365.
Squires, N. K., & Ollo, C. (1999). Comparison of endogenous event-related potentials in attend and non-attend conditions: Latency changes with normal aging. Clinical Neurophysiology, 110(3), 564–574.
Loring, D. W., Levin, H. S., Papanicolaou, A. C., Larrabee, G. J., & Eisenberg, H. M. (1984). Auditory evoked potentials in senescent forgetfulness. The International Journal of Neuroscience, 24(2), 133–141.
Van der Wal, E. A., & Sandman, C. A. (1992). Evidence for terminal decline in the event-related potential of the brain. Electroencephalography and Clinical Neurophysiology, 83(3), 211–216.
Friedman, D., Kazmerski, V., & Fabiani, M. (1997). An overview of age-related changes in the scalp distribution of P3b. Electroencephalography and Clinical Neurophysiology, 104(6), 498–513.
O’Donnell, B. F., Friedman, S., Swearer, J. M., & Drachman, D. A. (1992). Active and passive P3 latency and psychometric performance: Influence of age and individual differences. International Journal of Psychophysiology, 12(2), 187–195.
Pollock, V. E., & Schneider, L. S. (1992). P3 from auditory stimuli in healthy elderly subjects: Hearing threshold and tone stimulus frequency. International Journal of Psychophysiology, 12(3), 237–241.
Woods, D. L. (1992). Auditory selective attention in middle-aged and elderly subjects: An event-related brain potential study. Electroencephalography and Clinical Neurophysiology, 84(5), 456–468.
Naatanen, R., Pakarinen, S., Rinne, T., & Takegata, R. (2004). The mismatch negativity (MMN): Towards the optimal paradigm. Clinical Neurophysiology, 115(1), 140–144.
Naatanen, R., & Winkler, I. (1999). The concept of auditory stimulus representation in cognitive neuroscience. Psychological Bulletin, 125(6), 826–859.
Kok, A. (2000). Age-related changes in involuntary and voluntary attention as reflected in components of the event-related potential (ERP). Biological Psychology, 54(1–3), 107–143.
McEvoy, L. K., Pellouchoud, E., Smith, M. E., & Gevins, A. (2001). Neurophysiological signals of working memory in normal aging. Brain Research. Cognitive Brain Research, 11(3), 363–376.
West, R., & Travers, S. (2008). Differential effects of aging on processes underlying task switching. Brain and Cognition, 68(1), 67–80.
Gazzaley, A., Cooney, J. W., McEvoy, K., Knight, R. T., & D’Esposito, M. (2005). Top-down enhancement and suppression of the magnitude and speed of neural activity. Journal of Cognitive Neuroscience, 17(3), 507–517.
Goodin, D. S., Squires, K. C., & Starr, A. (1978). Long latency event-related components of the auditory evoked potential in dementia. Brain, 101, 635–648.
Hansch, E. C., Syndulko, K., Cohen, S. N., Goldberg, Z. I., Potvin, A. R., & Tourtellotte, W. W. (1982). Cognition in Parkinson disease: An event-related potential perspective. Annals of Neurology, 11(6), 599–607.
O’Donnell, B. F., Squires, N. K., Martz, M. J., Chen, J. R., & Phay, A. J. (1987). Evoked potential changes and neuropsychological performance in Parkinson’s disease. Biological Psychology, 24, 23–37.
Polich, J., Ehlers, C. L., Otis, S., Mandell, A. J., & Bloom, F. E. (1986). P300 latency reflects the degree of cognitive decline in dementing illness. Electroencephalography and Clinical Neurophysiology, 63(2), 138–144.
Polich, J., Ladish, C., & Bloom, F. E. (1990). P300 assessment of early Alzheimer’s disease. Electroencephalography and Clinical Neurophysiology, 77(3), 179–189.
de Brionne, M. H., Gueguen, B., Bourdel, M. C., et al. (1991). [Topographical analysis of endogenous evoked potentials in depressed old people and in patients with Alzheimer’s type dementia]. Neurophysiologie Clinique = Clinical Neurophysiology, 21(5–6), 449–458.
Naatanen, R. (2003). Mismatch negativity: Clinical research and possible applications. International Journal of Psychophysiology, 48(2), 179–188.
Kazmerski, V. A., Friedman, D., & Ritter, W. (1997). Mismatch negativity during attend and ignore conditions in Alzheimer’s disease. Biological Psychiatry, 42(5), 382–402.
Sumi, N., Nan’no, H., Fujimoto, O., Ohta, Y., & Takeda, M. (2000). Interpeak latency of auditory event-related potentials (P300) in senile depression and dementia of the Alzheimer type. Psychiatry and Clinical Neurosciences, 54(6), 679–684.
Cohen, R. A., O’Donnell, B. F., Meadows, M. E., Moonis, M., Stone, W. F., & Drachman, D. A. (1995). ERP indices and neuropsychological performance as predictors of functional outcome in dementia. Journal of Geriatric Psychiatry and Neurology, 8(4), 217–225.
Yamaguchi, S., Tsuchiya, H., Yamagata, S., Toyoda, G., & Kobayashi, S. (2000). Event-related brain potentials in response to novel sounds in dementia. Clinical Neurophysiology, 111(2), 195–203.
Munte, T. F., Ridao-Alonso, M. E., Preinfalk, J., et al. (1997). An electrophysiological analysis of altered cognitive functions in Huntington disease. Archives of Neurology, 54(9), 1089–1098.
Syndulko, K., Gilden, E. R., Hansch, E. C., Potvin, A. R., Tourtellotte, W. W., & Potvin, J. H. (1981). Decreased verbal memory associated with anticholinergic treatment in Parkinson’s disease patients. The International Journal of Neuroscience, 14(1–2), 61–66.
Tsuchiya, H., Yamaguchi, S., & Kobayashi, S. (2000). Impaired novelty detection and frontal lobe dysfunction in Parkinson’s disease. Neuropsychologia, 38(5), 645–654.
Lopez-Azcarate, J., Tainta, M., Rodriguez-Oroz, M. C., et al. (2010). Coupling between beta and high-frequency activity in the human subthalamic nucleus may be a pathophysiological mechanism in Parkinson’s disease. The Journal of Neuroscience, 30(19), 6667–6677.
Sannita, W. G., Carozzo, S., Orsini, P., et al. (2009). ‘Gamma’ band oscillatory response to chromatic stimuli in volunteers and patients with idiopathic Parkinson’s disease. Vision Research, 49(7), 726–734.
Colloca, L., Benedetti, F., Bergamasco, B., et al. (2006). Electroencephalographic responses to intraoperative subthalamic stimulation. Neuroreport, 17(14), 1465–1468.
Marsden, J. F., Limousin-Dowsey, P., Ashby, P., Pollak, P., & Brown, P. (2001). Subthalamic nucleus, sensorimotor cortex and muscle interrelationships in Parkinson’s disease. Brain, 124(Pt 2), 378–388.
Mima, T., & Hallett, M. (1999). Corticomuscular coherence: A review. Journal of Clinical Neurophysiology, 16(6), 501–511.
Spencer, K. M., Niznikiewicz, M. A., Nestor, P. G., Shenton, M. E., & McCarley, R. W. (2009). Left auditory cortex gamma synchronization and auditory hallucination symptoms in schizophrenia. BMC Neuroscience, 10, 85.
Beste, C., Konrad, C., Saft, C., et al. (2009). Alterations in voluntary movement execution in Huntington’s disease are related to the dominant motor system: Evidence from event-related potentials. Experimental Neurology, 216(1), 148–157.
Beste, C., Saft, C., Andrich, J., Gold, R., & Falkenstein, M. (2008). Response inhibition in Huntington’s disease-a study using ERPs and sLORETA. Neuropsychologia, 46(5), 1290–1297.
Beste, C., Saft, C., Andrich, J., Gold, R., & Falkenstein, M. (2008). Stimulus–response compatibility in Huntington’s disease: A cognitive-neurophysiological analysis. Journal of Neurophysiology, 99(3), 1213–1223.
Uc, E. Y., Skinner, R. D., Rodnitzky, R. L., & Garcia-Rill, E. (2003). The midlatency auditory evoked potential P50 is abnormal in Huntington’s disease. Journal of Neurological Sciences, 212(1–2), 1–5.
Jackson, C. E., & Snyder, P. J. (2008). Electroencephalography and event-related potentials as biomarkers of mild cognitive impairment and mild Alzheimer’s disease. Alzheimer’s & Dementia, 4(1 Suppl 1), S137–S143.
Callaway, E., & Halliday, R. (1982). The effect of attentional effort on visual evoked potential N1 latency. Psychiatry Research, 7(3), 299–308.
Halliday, R., Callaway, E., & Naylor, H. (1983). Visual evoked potential changes induced by methylphenidate in hyperactive children: Dose/response effects. Electroencephalography and Clinical Neurophysiology, 55(3), 258–267.
Satterfield, J. H., Schell, A. M., Nicholas, T. W., Satterfield, B. T., & Freese, T. E. (1990). Ontogeny of selective attention effects on event-related potentials in attention-deficit hyperactivity disorder and normal boys. Biological Psychiatry, 28(10), 879–903.
Duncan, C. C., Rumsey, J. M., Wilkniss, S. M., Denckla, M. B., Hamburger, S. D., & Odou-Potkin, M. (1994). Developmental dyslexia and attention dysfunction in adults: Brain potential indices of information processing. Psychophysiology, 31(4), 386–401.
Harter, M. R., Anllo-Vento, L., Wood, F. B., & Schroeder, M. M. (1988). Separate brain potential characteristics in children with reading disability and attention deficit disorder: Color and letter relevance effects. Brain and Cognition, 7(1), 115–140.
Harter, M. R., Diering, S., & Wood, F. B. (1988). Separate brain potential characteristics in children with reading disability and attention deficit disorder: Relevance-independent effects. Brain and Cognition, 7(1), 54–86.
Novak, G. P., Solanto, M., & Abikoff, H. (1995). Spatial orienting and focused attention in attention deficit hyperactivity disorder. Psychophysiology, 32(6), 546–559.
Strandburg, R. J., Marsh, J. T., Brown, W. S., et al. (1996). Continuous-processing—Related event-related potentials in children with attention deficit hyperactivity disorder. Biological Psychiatry, 40(10), 964–980.
Perchet, C., Revol, O., Fourneret, P., Mauguiere, F., & Garcia-Larrea, L. (2001). Attention shifts and anticipatory mechanisms in hyperactive children: An ERP study using the Posner paradigm. Biological Psychiatry, 50(1), 44–57.
Jonkman, L. M., Kemner, C., Verbaten, M. N., et al. (1997). Effects of methylphenidate on event-related potentials and performance of attention-deficit hyperactivity disorder children in auditory and visual selective attention tasks. Biological Psychiatry, 41(6), 690–702.
Jonkman, L. M., Kemner, C., Verbaten, M. N., et al. (1997). Event-related potentials and performance of attention-deficit hyperactivity disorder: Children and normal controls in auditory and visual selective attention tasks. Biological Psychiatry, 41(5), 595–611.
Winsberg, B. G., Javitt, D. C., & Silipo, G. S. (1997). Electrophysiological indices of information processing in methylphenidate responders. Biological Psychiatry, 42(6), 434–445.
Hermens, D. F., Cooper, N. J., Kohn, M., Clarke, S., & Gordon, E. (2005). Predicting stimulant medication response in ADHD: Evidence from an integrated profile of neuropsychological, psychophysiological and clinical factors. Journal of Integrative Neuroscience, 4(1), 107–121.
Hermens, D. F., Williams, L. M., Clarke, S., Kohn, M., Cooper, N., & Gordon, E. (2005). Responses to methylphenidate in adolescent AD/HD: evidence from concurrently recorded autonomic (EDA) and central (EEG and ERP) measures. International Journal of Psychophysiology, 58(1), 21–33.
Steger, J., Imhof, K., Steinhausen, H., & Brandeis, D. (2000). Brain mapping of bilateral interactions in attention deficit hyperactivity disorder and control boys. Clinical Neurophysiology, 111(7), 1141–1156.
Dimoska, A., Johnstone, S. J., Barry, R. J., & Clarke, A. R. (2003). Inhibitory motor control in children with attention-deficit/hyperactivity disorder: Event-related potentials in the stop-signal paradigm. Biological Psychiatry, 54(12), 1345–1354.
Smith, J. L., Johnstone, S. J., & Barry, R. J. (2004). Inhibitory processing during the Go/NoGo task: An ERP analysis of children with attention-deficit/hyperactivity disorder. Clinical Neurophysiology, 115(6), 1320–1331.
Johnstone, S. J., Barry, R. J., Markovska, V., Dimoska, A., & Clarke, A. R. (2009). Response inhibition and interference control in children with AD/HD: A visual ERP investigation. International Journal of Psychophysiology, 72(2), 145–153.
Liotti, M., Pliszka, S. R., Higgins, K., Perez, R., III, & Semrud-Clikeman, M. (2010). Evidence for specificity of ERP abnormalities during response inhibition in ADHD children: A comparison with reading disorder children without ADHD. Brain and Cognition, 72(2), 228–237.
Wiersema, J. R., van der Meere, J. J., & Roeyers, H. (2009). ERP correlates of error monitoring in adult ADHD. Journal of Neural Transmission, 116(3), 371–379.
Brown, C. R., Clarke, A. R., Barry, R. J., McCarthy, R., Selikowitz, M., & Magee, C. (2005). Event-related potentials in attention-deficit/hyperactivity disorder of the predominantly inattentive type: An investigation of EEG-defined subtypes. International Journal of Psychophysiology, 58(1), 94–107.
Levit, R. A., Sutton, S., & Zubin, J. (1973). Evoked potential correlates of information processing in psychiatric patients. Psychological Medicine, 3, 487–494.
Roth, W. T., & Kopell, B. S. (1973). P 300—An orienting reaction in the human auditory evoked response. Perceptual and Motor Skills, 36(1), 219–225.
Baribeau-Braun, J., Picton, T. W., & Gosselin, J. Y. (1983). Schizophrenia: A neurophysiological evaluation of abnormal information processing. Science, 219(4586), 874–876.
Brecher, M., Porjesz, B., & Begleiter, H. (1987). The N2 component of the event-related potential in schizophrenic patients. Electroencephalography and Clinical Neurophysiology, 66, 369–375.
Duncan-Johnson, C. C., Roth, W., & Koppell, B. S. (1984). Effects of stimulus sequence on P300 and reaction time in schizophrenics. In R. Karrer, J. Cohen, & P. Tueting (Eds.), Brain and information: Event-related potentials (Vol. 425, pp. 570–577). New York: Annals of the New York Academy of Sciences.
O’Donnell, B. F., Hetrick, W. P., Vohs, J. L., Krishnan, G. P., Carroll, C. A., & Shekhar, A. (2004). Neural synchronization deficits to auditory stimulation in bipolar disorder. Neuroreport, 15(8), 1369–1372.
O’Donnell, B. F., Faux, S. F., McCarley, R. W., et al. (1995). Increased rate of P300 latency prolongation with age in schizophrenia. Electrophysiological evidence for a neurodegenerative process. Archives of General Psychiatry, 52(7), 544–549.
Kayser, J., Tenke, C. E., Gates, N. A., Kroppmann, C. J., Gil, R. B., & Bruder, G. E. (2006). ERP/CSD indices of impaired verbal working memory subprocesses in schizophrenia. Psychophysiology, 43(3), 237–252.
McCarley, R. W., Shenton, M. E., O’Donnell, B. F., & Nestor, P. G. (1993). Uniting Kraepelin and Bleuler: The psychology of schizophrenia and the biology of temporal lobe abnormalities. Harvard Review of Psychiatry, 1(1), 36–56.
Polich, J., Howard, L., & Starr, A. (1983). P300 latency correlates with digit span. Psychophysiology, 20(6), 665–669.
Kraiuhin, C., Gordon, E., Meares, R., & Howson, A. (1986). Psychometrics and event-related potentials in the diagnosis of dementia. Journal of Gerontology, 41, 154–162.
Ritter, W., Vaughan, H. G., Jr., & Costa, L. D. (1968). Orienting and habituation to auditory stimuli: A study of short term changes in average evoked responses. Electroencephalography and Clinical Neurophysiology, 25(6), 550–556.
Ruchkin, D. S., Munson, R., & Sutton, S. (1982). P300 and slow wave in a message consisting of two events. Psychophysiology, 19(6), 629–642.
Ruchkin, D. S., & Sutton, S. (1978). Emmitted P300 potentials and temporal uncertainty. Electroencephalography and Clinical Neurophysiology, 45(2), 268–277.
Donchin, E. (1981). Presidential address, 1980. Surprise!…Surprise? Psychophysiology, 18(5), 493–513.
Grossberg, S. (1988). Neural networks and natural intelligence. Cambridge: MIT Press.
Galletly, C., Clark, C. R., McFarlane, A. C., & Weber, D. L. (2001). Working memory in posttraumatic stress disorder—An event-related potential study. Journal of Traumatic Stress, 14(2), 295–309.
Kok, A. (2001). On the utility of P3 amplitude as a measure of processing capacity. Psychophysiology, 38(3), 557–577.
Kranczioch, C., Debener, S., & Engel, A. K. (2003). Event-related potential correlates of the attentional blink phenomenon. Brain Research. Cognitive Brain Research, 17(1), 177–187.
Serrien, D. J., Pogosyan, A. H., & Brown, P. (2004). Influence of working memory on patterns of motor related cortico-cortical coupling. Experimental Brain Research. Experimentelle Hirnforschung, 155(2), 204–210.
Smolnik, R., Perras, B., Molle, M., Fehm, H. L., & Born, J. (2000). Event-related brain potentials and working memory function in healthy humans after single-dose and prolonged intranasal administration of adrenocorticotropin 4–10 and desacetyl-alpha-melanocyte stimulating hormone. Journal of Clinical Psychopharmacology, 20(4), 445–454.
Vogel, E. K., & Luck, S. J. (2002). Delayed working memory consolidation during the attentional blink. Psychonomic Bulletin & Review, 9(4), 739–743.
Courchesne, E., Courchesne, R. Y., & Hillyard, S. A. (1978). The effect of stimulus deviation on P3 waves to easily recognized stimuli. The International Journal of Neuroscience, 29, 199–204.
Polich, J. (1989). P300 from a passive auditory paradigm. Electroencephalography and Clinical Neurophysiology, 74(4), 312–320.
James, W. (1892). Attention. In W. James (Ed.), Psychology (pp. 217–238). New York: Henry Holt and Company.
Meador, K. J., Loring, D. W., Gallagher, B. B., et al. (1992). Differential effects of left versus right seizure focus on human hippocampal evoked responses. The International Journal of Neuroscience, 66(1–2), 87–91.
Meador, K. J., Loring, D. W., Huh, K., King, D. W., & Gallagher, B. B. (1990). Long-latency evoked potentials during aura of temporal lobe origin. The International Journal of Neuroscience, 50(1–2), 127–130.
Meador, K. J., Loring, D. W., Huh, K., et al. (1988). Spectral analysis of sphenoidal evoked potentials predicts epileptic focus. Epilepsia, 29(4), 434–439.
Meador, K. J., Loring, D. W., King, D. W., et al. (1988). Spectral power of human limbic evoked potentials: Relationship to seizure onset. Annals of Neurology, 23(2), 145–151.
Meador, K. J., Loring, D. W., King, D. W., et al. (1988). Cholinergic modulation of human limbic evoked potentials. The International Journal of Neuroscience, 38(3–4), 407–414.
Meador, K. J., Loring, D. W., King, D. W., et al. (1987). Limbic evoked potentials predict site of epileptic focus. Neurology, 37(3), 494–497.
Garcia-Marin, V., & Gonzalez-Feria, L. (2000). Depth electroencephalography in selection of refractory epilepsy for surgery. Our experience with the suboccipital approach. Neurologia i Neurochirurgia Polska, 34(Suppl 8), 31–39.
Marossero, F., Ettorre, G., Franzini, A., & Motti, D. F. (1978). Chronic depth electrodes study of one case of bitemporal epilepsy due to glial tumour. Some physiopathological considerations. Acta Neurochirurgica, 45(1–2), 123–131.
Laitinen, L., & Toivakka, E. (1972). Locating brain tumours through depth EEG probes. Confinia Neurologica, 34(2), 101–105.
Miatton, M., Van Roost, D., Thiery, E., et al. (2011). The cognitive effects of amygdalohippocampal deep brain stimulation in patients with temporal lobe epilepsy. Epilepsy & Behavior, 22(4), 759–764.
Bollimunta, A., Mo, J., Schroeder, C. E., & Ding, M. (2011). Neuronal mechanisms and attentional modulation of corticothalamic alpha oscillations. The Journal of Neuroscience, 31(13), 4935–4943.
Hajcak, G., Anderson, B. S., Arana, A., et al. (2010). Dorsolateral prefrontal cortex stimulation modulates electrocortical measures of visual attention: Evidence from direct bilateral epidural cortical stimulation in treatment-resistant mood disorder. Neuroscience, 170(1), 281–288.
Nikulin, V. V., Marzinzik, F., Wahl, M., et al. (2008). Anticipatory activity in the human thalamus is predictive of reaction times. Neuroscience, 155(4), 1275–1283.
Klostermann, F., Wahl, M., Marzinzik, F., Schneider, G. H., Kupsch, A., & Curio, G. (2006). Mental chronometry of target detection: Human thalamus leads cortex. Brain, 129(Pt 4), 923–931.
Lado, F. A. (2006). Chronic bilateral stimulation of the anterior thalamus of kainate-treated rats increases seizure frequency. Epilepsia, 47(1), 27–32.
Gobbele, R., Waberski, T. D., Kuelkens, S., Sturm, W., Curio, G., & Buchner, H. (2000). Thalamic and cortical high-frequency (600 Hz) somatosensory-evoked potential (SEP) components are modulated by slight arousal changes in awake subjects. Experimental Brain Research. Experimentelle Hirnforschung, 133(4), 506–513.
Bruin, K. J., Kenemans, J. L., Verbaten, M. N., & Van der Heijden, A. H. (1998). Localization of spatial attention processes with the aid of a probe technique. Electroencephalography and Clinical Neurophysiology, 108(2), 110–122.
Feindel, W. (1982). The contributions of Wilder Penfield to the functional anatomy of the human brain. Human Neurobiology, 1(4), 231–234.
Penfield, W. (1958). Some mechanisms of consciousness discovered during electrical stimulation of the brain. Proceedings of the National Academy of Sciences of the United States of America, 44(2), 51–66.
Sochurkova, D., Rektor, I., Jurak, P., & Stancak, A. (2006). Intracerebral recording of cortical activity related to self-paced voluntary movements: A Bereitschaftspotential and event-related desynchronization/synchronization. SEEG study. Experimental Brain Research. Experimentelle Hirnforschung, 173(4), 637–649.
Rusnakova, S., Daniel, P., Chladek, J., Jurak, P., & Rektor, I. (2011). The executive functions in frontal and temporal lobes: A flanker task intracerebral recording study. Journal of Clinical Neurophysiology, 28(1), 30–35.
Nager, W., Munte, T. F., Bohrer, I., et al. (2007). Automatic and attentive processing of sounds in cochlear implant patients—Electrophysiological evidence. Restorative Neurology and Neuroscience, 25(3–4), 391–396.
Bidet-Caulet, A., Fischer, C., Besle, J., Aguera, P. E., Giard, M. H., & Bertrand, O. (2007). Effects of selective attention on the electrophysiological representation of concurrent sounds in the human auditory cortex. The Journal of Neuroscience, 27(35), 9252–9261.
Ekstrom, A. D., Caplan, J. B., Ho, E., Shattuck, K., Fried, I., & Kahana, M. J. (2005). Human hippocampal theta activity during virtual navigation. Hippocampus, 15(7), 881–889.
Ding, L., Lai, Y., & He, B. (2005). Low resolution brain electromagnetic tomography in a realistic geometry head model: A simulation study. Physics in Medicine and Biology, 50(1), 45–56.
Kukleta, M., Brazdil, M., Roman, R., & Jurak, P. (2003). Identical event-related potentials to target and frequent stimuli of visual oddball task recorded by intracerebral electrodes. Clinical Neurophysiology, 114(7), 1292–1297.
Author information
Authors and Affiliations
Rights and permissions
Copyright information
© 2014 Springer Science+Business Media New York
About this chapter
Cite this chapter
Cohen, R.A. (2014). Electrophysiology of Attention. In: The Neuropsychology of Attention. Springer, Boston, MA. https://doi.org/10.1007/978-0-387-72639-7_9
Download citation
DOI: https://doi.org/10.1007/978-0-387-72639-7_9
Published:
Publisher Name: Springer, Boston, MA
Print ISBN: 978-0-387-72638-0
Online ISBN: 978-0-387-72639-7
eBook Packages: MedicineMedicine (R0)