nach oben

Brain Topography

Erschienen in:

01.07.2014 | Review

The Mechanisms and Meaning of the Mismatch Negativity

verfasst von: Yonatan I. Fishman

Erschienen in: Brain Topography | Ausgabe 4/2014

Einloggen, um Zugang zu erhalten

Abstract

The mismatch negativity (MMN) is a pre-attentive auditory event-related potential (ERP) component that is elicited by a change in a repetitive acoustic pattern. It is obtained by subtracting responses evoked by frequent ‘standard’ sounds from responses evoked by infrequent ‘deviant’ sounds that differ from the standards along some acoustic dimension, e.g., frequency, intensity, or duration, or abstract feature. The MMN has been attributed to neural generators within the temporal and frontal lobes. The mechanisms and meaning of the MMN continue to be debated. Two dominant explanations for the MMN have been proposed. According to the “neural adaptation” hypothesis, repeated presentation of the standards results in adapted (i.e., attenuated) responses of feature-selective neurons in auditory cortex. Rare deviant sounds activate neurons that are less adapted than those stimulated by the frequent standard sounds, and thus elicit a larger ‘obligatory’ response, which yields the MMN following the subtraction procedure. In contrast, according to the “sensory memory” hypothesis, the MMN is a ‘novel’ (non-obligatory) ERP component that reflects a deviation between properties of an incoming sound and those of a neural ‘memory trace’ established by the preceding standard sounds. Here, we provide a selective review of studies which are relevant to the controversy between proponents of these two interpretations of the MMN. We also present preliminary neurophysiological data from monkey auditory cortex with potential implications for the debate. We conclude that the mechanisms and meaning of the MMN are still unresolved and offer remarks on how to make progress on these important issues.

Alain C, Woods DL (1997) Attention modulates auditory pattern memory as indexed by event-related brain potentials. Psychophysiology 34:534–546PubMed

Alain C, Woods DL, Ogawa KH (1994) Brain indices of automatic pattern processing. Neuroreport 6:140–144PubMed

Alho K, Winkler I, Escera C, Huotilainen M, Virtanen J, Jaaskelainen IP, Pekkonen E, Ilmoniemi RJ (1998) Processing of novel sounds and frequency changes in the human auditory cortex: magnetoencephalographic recordings. Psychophysiology 35:211–224PubMed

Althen H, Grimm S, Escera C (2011) Fast detection of unexpected sound intensity decrements as revealed by human evoked potentials. PLoS One 6:e28522PubMedCentralPubMed

Anderson LA, Christianson GB, Linden JF (2009) Stimulus-specific adaptation occurs in the auditory thalamus. J Neurosci 29:7359–7363PubMed

Arezzo J, Pickoff A, Vaughan HG Jr (1975) The sources and intracerebral distribution of auditory evoked potentials in the alert rhesus monkey. Brain Res 90:57–73PubMed

Arnal LH, Giraud AL (2012) Cortical oscillations and sensory predictions. Trends Cogn Sci 16:390–398PubMed

Arnott SR, Alain C (2002) Stepping out of the spotlight: MMN attenuation as a function of distance from the attended location. Neuroreport 13:2209–2212PubMed

Atencio CA, Blake DT, Strata F, Cheung SW, Merzenich MM, Schreiner CE (2007) Frequency-modulation encoding in the primary auditory cortex of the awake owl monkey. J Neurophysiol 98:2182–2195PubMed

Bartlett EL, Wang X (2005) Long-lasting modulation by stimulus context in primate auditory cortex. J Neurophysiol 94:83–104PubMed

Bekinschtein TA, Dehaene S, Rohaut B, Tadel F, Cohen L, Naccache L (2009) Neural signature of the conscious processing of auditory regularities. Proc Natl Acad Sci USA 106:1672–1677PubMedCentralPubMed

Bendixen A, Schroger E (2008) Memory trace formation for abstract auditory features and its consequences in different attentional contexts. Biol Psychol 78:231–241PubMed

Bendixen A, Schroger E, Winkler I (2009) I heard that coming: event-related potential evidence for stimulus-driven prediction in the auditory system. J Neurosci 29:8447–8451PubMed

Bendixen A, SanMiguel I, Schroger E (2012) Early electrophysiological indicators for predictive processing in audition: a review. Int J Psychophysiol 83:120–131PubMed

Bendor D, Wang X (2010) Neural coding of periodicity in marmoset auditory cortex. J Neurophysiol 103:1809–1822PubMedCentralPubMed

Brosch M, Schreiner CE (1997) Time course of forward masking tuning curves in cat primary auditory cortex. J Neurophysiol 77:923–943PubMed

Brugge JF, Volkov IO, Oya H, Kawasaki H, Reale RA, Fenoy A, Steinschneider M, Howard MA 3rd (2008) Functional localization of auditory cortical fields of human: click-train stimulation. Hear Res 238:12–24PubMed

Budd TW, Barry RJ, Gordon E, Rennie C, Michie PT (1998) Decrement of the N1 auditory event-related potential with stimulus repetition: habituation vs. refractoriness. Int J Psychophysiol 31:51–68PubMed

Campbell T, Neuvonen T (2007) Adaptation of neuromagnetic N1 without shifts in dipolar orientation. Neuroreport 18:377–380PubMed

Chennu S, Noreika V, Gueorguiev D, Blenkmann A, Kochen S, Ibanez A, Owen AM, Bekinschtein TA (2013) Expectation and attention in hierarchical auditory prediction. J Neurosci 33:11194–11205PubMedCentralPubMed

Cornella M, Leung S, Grimm S, Escera C (2012) Detection of simple and pattern regularity violations occurs at different levels of the auditory hierarchy. PLoS One 7:e43604PubMedCentralPubMed

Denham SL, Winkler I (2006) The role of predictive models in the formation of auditory streams. J Physiol Paris 100:154–170PubMed

Doeller CF, Opitz B, Mecklinger A, Krick C, Reith W, Schroger E (2003) Prefrontal cortex involvement in preattentive auditory deviance detection: neuroimaging and electrophysiological evidence. Neuroimage 20:1270–1282PubMed

Edwards E, Soltani M, Deouell LY, Berger MS, Knight RT (2005) High gamma activity in response to deviant auditory stimuli recorded directly from human cortex. J Neurophysiol 94:4269–4280PubMed

Elangovan S, Cranfordt JL, Walker L, Stuart A (2005) A comparison of the mismatch negativity and a differential waveform response. Int J Audiol 44:637–646PubMed

Farley BJ, Quirk MC, Doherty JJ, Christian EP (2010) Stimulus-specific adaptation in auditory cortex is an NMDA-independent process distinct from the sensory novelty encoded by the mismatch negativity. J Neurosci 30:16475–16484PubMed

Fishman YI, Steinschneider M (2009) Temporally dynamic frequency tuning of population responses in monkey primary auditory cortex. Hear Res 254:64–76PubMedCentralPubMed

Fishman YI, Steinschneider M (2012) Searching for the mismatch negativity in primary auditory cortex of the awake monkey: deviance detection or stimulus specific adaptation? J Neurosci 32:15747–15758PubMedCentralPubMed

Fishman YI, Reser DH, Arezzo JC, Steinschneider M (2001a) Neural correlates of auditory stream segregation in primary auditory cortex of the awake monkey. Hear Res 151:167–187PubMed

Fishman YI, Volkov IO, Noh MD, Garell PC, Bakken H, Arezzo JC, Howard MA, Steinschneider M (2001b) Consonance and dissonance of musical chords: neural correlates in auditory cortex of monkeys and humans. J Neurophysiol 86:2761–2788PubMed

Fishman YI, Arezzo JC, Steinschneider M (2004) Auditory stream segregation in monkey auditory cortex: effects of frequency separation, presentation rate, and tone duration. J Acoust Soc Am 116:1656–1670PubMed

Fishman YI, Micheyl C, Steinschneider M (2012) Neural mechanisms of rhythmic masking release in monkey primary auditory cortex: implications for models of auditory scene analysis. J Neurophysiol 107:2366–2382PubMedCentralPubMed

Friedman D, Cycowicz YM, Gaeta H (2001) The novelty P3: an event-related brain potential (ERP) sign of the brain’s evaluation of novelty. Neurosci Biobehav Rev 25:355–373PubMed

Friston K (2005) A theory of cortical responses. Philos Trans R Soc Lond B Biol Sci 360:815–836PubMedCentralPubMed

Friston K (2008) Hierarchical models in the brain. PLoS Comput Biol 4:e1000211PubMedCentralPubMed

Gaese BH, Ostwald J (1995) Temporal coding of amplitude and frequency modulation in the rat auditory cortex. Eur J Neurosci 7:438–450PubMed

Garrido MI, Kilner JM, Stephan KE, Friston KJ (2009) The mismatch negativity: a review of underlying mechanisms. Clin Neurophysiol 120:453–463PubMedCentralPubMed

Giard MH, Perrin F, Pernier J, Bouchet P (1990) Brain generators implicated in the processing of auditory stimulus deviance: a topographic event-related potential study. Psychophysiology 27:627–640PubMed

Gil-da-Costa R, Stoner GR, Fung R, Albright TD (2013) Nonhuman primate model of schizophrenia using a noninvasive EEG method. Proc Natl Acad Sci USA 110:15425–15430

Haenschel C, Vernon DJ, Dwivedi P, Gruzelier JH, Baldeweg T (2005) Event-related brain potential correlates of human auditory sensory memory-trace formation. J Neurosci 25:10494–10501PubMed

Hari R, Hamalainen M, Ilmoniemi R, Kaukoranta E, Reinikainen K, Salminen J, Alho K, Naatanen R, Sams M (1984) Responses of the primary auditory cortex to pitch changes in a sequence of tone pips: neuromagnetic recordings in man. Neurosci Lett 50:127–132PubMed

He J, Hashikawa T, Ojima H, Kinouchi Y (1997) Temporal integration and duration tuning in the dorsal zone of cat auditory cortex. J Neurosci 17:2615–2625PubMed

Heil P, Rajan R, Irvine DR (1992) Sensitivity of neurons in cat primary auditory cortex to tones and frequency-modulated stimuli. I: effects of variation of stimulus parameters. Hear Res 63:108–134PubMed

Horvath J, Czigler I, Sussman E, Winkler I (2001) Simultaneously active pre-attentive representations of local and global rules for sound sequences in the human brain. Brain Res Cogn Brain Res 12:131–144PubMed

Horvath J, Czigler I, Jacobsen T, Maess B, Schroger E, Winkler I (2008) MMN or no MMN: no magnitude of deviance effect on the MMN amplitude. Psychophysiology 45:60–69PubMed

Hsieh IH, Fillmore P, Rong F, Hickok G, Saberi K (2012) FM-selective networks in human auditory cortex revealed using fMRI and multivariate pattern classification. J Cogn Neurosci 24:1896–1907PubMed

Hughes HC, Darcey TM, Barkan HI, Williamson PD, Roberts DW, Aslin CH (2001) Responses of human auditory association cortex to the omission of an expected acoustic event. Neuroimage 13:1073–1089PubMed

Jaaskelainen IP, Ahveninen J, Bonmassar G, Dale AM, Ilmoniemi RJ, Levanen S, Lin FH, May P, Melcher J, Stufflebeam S, Tiitinen H, Belliveau JW (2004) Human posterior auditory cortex gates novel sounds to consciousness. Proc Natl Acad Sci USA 101:6809–6814PubMedCentralPubMed

Jacobsen T, Schroger E (2001) Is there pre-attentive memory-based comparison of pitch? Psychophysiology 38:723–727PubMed

Javitt DC (2000) Intracortical mechanisms of mismatch negativity dysfunction in schizophrenia. Audiol Neurootol 5:207–215PubMed

Javitt DC, Zukin SR (1991) Recent advances in the phencyclidine model of schizophrenia. Am J Psychiatry 148:1301–1308PubMed

Javitt DC, Schroeder CE, Steinschneider M, Arezzo JC, Vaughan HG Jr (1992) Demonstration of mismatch negativity in the monkey. Electroencephalogr Clin Neurophysiol 83:87–90PubMed

Javitt DC, Steinschneider M, Schroeder CE, Vaughan HG Jr, Arezzo JC (1994) Detection of stimulus deviance within primate primary auditory cortex: intracortical mechanisms of mismatch negativity (MMN) generation. Brain Res 667:192–200PubMed

Javitt DC, Steinschneider M, Schroeder CE, Arezzo JC (1996) Role of cortical N-methyl-D-aspartate receptors in auditory sensory memory and mismatch negativity generation: implications for schizophrenia. Proc Natl Acad Sci USA 93:11962–11967PubMedCentralPubMed

Javitt DC, Jayachandra M, Lindsley RW, Specht CM, Schroeder CE (2000) Schizophrenia-like deficits in auditory P1 and N1 refractoriness induced by the psychomimetic agent phencyclidine (PCP). Clin Neurophysiol 111:833–836PubMed

Jemel B, Achenbach C, Muller BW, Ropcke B, Oades RD (2002) Mismatch negativity results from bilateral asymmetric dipole sources in the frontal and temporal lobes. Brain Topogr 15:13–27PubMed

Korzyukov O, Alho K, Kujala A, Gumenyuk V, Ilmoniemi RJ, Virtanen J, Kropotov J, Naatanen R (1999) Electromagnetic responses of the human auditory cortex generated by sensory-memory based processing of tone-frequency changes. Neurosci Lett 276:169–172PubMed

Korzyukov OA, Winkler I, Gumenyuk VI, Alho K (2003) Processing abstract auditory features in the human auditory cortex. Neuroimage 20:2245–2258PubMed

Lanting CP, Briley PM, Sumner CJ, Krumbholz K (2013) Mechanisms of adaptation in human auditory cortex. J Neurophysiol 110:973–983

Lappe C, Steinstrater O, Pantev C (2013) A beamformer analysis of MEG data reveals frontal generators of the musically elicited mismatch negativity. PLoS One 8:e61296PubMedCentralPubMed

Lee TS, Mumford D (2003) Hierarchical Bayesian inference in the visual cortex. J Opt Soc Am A Opt Image Sci Vis 20:1434–1448PubMed

Liegeois-Chauvel C, Musolino A, Badier JM, Marquis P, Chauvel P (1994) Evoked potentials recorded from the auditory cortex in man: evaluation and topography of the middle latency components. Electroencephalogr Clin Neurophysiol 92:204–214PubMed

Lozano-Soldevilla D, Marco-Pallares J, Fuentemilla L, Grau C (2012) Common N1 and mismatch negativity neural evoked components are revealed by independent component model-based clustering analysis. Psychophysiology 49:1454–1463PubMed

Lutkenhoner B (2003) Magnetoencephalography and its achilles’ heel. J Physiol Paris 97:641–658PubMed

Macdonald M, Campbell K (2011) Effects of a violation of an expected increase or decrease in intensity on detection of change within an auditory pattern. Brain Cogn 77:438–445PubMed

Maess B, Jacobsen T, Schroger E, Friederici AD (2007) Localizing pre-attentive auditory memory-based comparison: magnetic mismatch negativity to pitch change. Neuroimage 37:561–571PubMed

Malmierca MS, Cristaudo S, Perez-Gonzalez D, Covey E (2009) Stimulus-specific adaptation in the inferior colliculus of the anesthetized rat. J Neurosci 29:5483–5493PubMedCentralPubMed

May P, Tiitinen H (2001) Human cortical processing of auditory events over time. Neuroreport 12:573–577PubMed

May PJ, Tiitinen H (2010) Mismatch negativity (MMN), the deviance-elicited auditory deflection, explained. Psychophysiology 47:66–122PubMed

May P, Tiitinen H, Ilmoniemi RJ, Nyman G, Taylor JG, Naatanen R (1999) Frequency change detection in human auditory cortex. J Comput Neurosci 6:99–120PubMed

Mendelson JR, Cynader MS (1985) Sensitivity of cat primary auditory cortex (AI) neurons to the direction and rate of frequency modulation. Brain Res 327:331–335PubMed

Mendelson JR, Schreiner CE, Sutter ML, Grasse KL (1993) Functional topography of cat primary auditory cortex: responses to frequency-modulated sweeps. Exp Brain Res 94:65–87PubMed

Micheyl C, Tian B, Carlyon RP, Rauschecker JP (2005) Perceptual organization of tone sequences in the auditory cortex of awake macaques. Neuron 48:139–148PubMed

Molholm S, Martinez A, Ritter W, Javitt DC, Foxe JJ (2005) The neural circuitry of pre-attentive auditory change-detection: an fMRI study of pitch and duration mismatch negativity generators. Cereb Cortex 15:545–551PubMed

Muckli L, Petro LS (2013) Network interactions: non-geniculate input to V1. Curr Opin Neurobiol 23:195–201PubMed

Muckli L, Petro LS, Smith FW (2013) Backwards is the way forward: feedback in the cortical hierarchy predicts the expected future. Behav Brain Sci 36:221PubMed

Naatanen R, Alho K (1995a) Mismatch negativity—a unique measure of sensory processing in audition. Int J Neurosci 80:317–337PubMed

Naatanen R, Alho K (1995b) Generators of electrical and magnetic mismatch responses in humans. Brain Topogr 7:315–320PubMed

Naatanen R, Escera C (2000) Mismatch negativity: clinical and other applications. Audiol Neurootol 5:105–110PubMed

Naatanen R, Picton T (1987) The N1 wave of the human electric and magnetic response to sound: a review and an analysis of the component structure. Psychophysiology 24:375–425PubMed

Naatanen R, Paavilainen P, Tiitinen H, Jiang D, Alho K (1993) Attention and mismatch negativity. Psychophysiology 30:436–450PubMed

Naatanen R, Tervaniemi M, Sussman E, Paavilainen P, Winkler I (2001) “Primitive intelligence” in the auditory cortex. Trends Neurosci 24:283–288PubMed

Naatanen R, Jacobsen T, Winkler I (2005) Memory-based or afferent processes in mismatch negativity (MMN): a review of the evidence. Psychophysiology 42:25–32PubMed

Naatanen R, Paavilainen P, Rinne T, Alho K (2007) The mismatch negativity (MMN) in basic research of central auditory processing: a review. Clin Neurophysiol 118:2544–2590PubMed

Naatanen R, Kujala T, Escera C, Baldeweg T, Kreegipuu K, Carlson S, Ponton C (2012) The mismatch negativity (MMN)—a unique window to disturbed central auditory processing in ageing and different clinical conditions. Clin Neurophysiol 123:424–458PubMed

Nordby H, Roth WT, Pfefferbaum A (1988) Event-related potentials to breaks in sequences of alternating pitches or interstimulus intervals. Psychophysiology 25:262–268PubMed

Nourski KV, Steinschneider M, Oya H, Kawasaki H, Jones RD, Howard MA (2012) Spectral organization of the human lateral superior temporal gyrus revealed by intracranial recordings. Cereb Cortex (in press)

Opitz B, Rinne T, Mecklinger A, von Cramon DY, Schroger E (2002) Differential contribution of frontal and temporal cortices to auditory change detection: FMRI and ERP results. Neuroimage 15:167–174PubMed

Paavilainen P (2013) The mismatch-negativity (MMN) component of the auditory event-related potential to violations of abstract regularities: a review. Int J Psychophysiol 88:109–123PubMed

Paavilainen P, Jaramillo M, Naatanen R, Winkler I (1999) Neuronal populations in the human brain extracting invariant relationships from acoustic variance. Neurosci Lett 265:179–182PubMed

Pelleg-Toiba R, Wollberg Z (1989) Tuning properties of auditory cortex cells in the awake squirrel monkey. Exp Brain Res 74:353–364PubMed

Pincze Z, Lakatos P, Rajkai C, Ulbert I, Karmos G (2001) Separation of mismatch negativity and the N1 wave in the auditory cortex of the cat: a topographic study. Clin Neurophysiol 112:778–784PubMed

Pincze Z, Lakatos P, Rajkai C, Ulbert I, Karmos G (2002) Effect of deviant probability and interstimulus/interdeviant interval on the auditory N1 and mismatch negativity in the cat auditory cortex. Brain Res Cogn Brain Res 13:249–253PubMed

Raij T, McEvoy L, Makela JP, Hari R (1997) Human auditory cortex is activated by omissions of auditory stimuli. Brain Res 745:134–143PubMed

Rao RP, Ballard DH (1999) Predictive coding in the visual cortex: a functional interpretation of some extra-classical receptive-field effects. Nat Neurosci 2:79–87PubMed

Recanzone GH, Guard DC, Phan ML (2000) Frequency and intensity response properties of single neurons in the auditory cortex of the behaving macaque monkey. J Neurophysiol 83:2315–2331PubMed

Rosburg T (2003) Left hemispheric dipole locations of the neuromagnetic mismatch negativity to frequency, intensity and duration deviants. Brain Res Cogn Brain Res 16:83–90PubMed

Rosburg T, Trautner P, Dietl T, Korzyukov OA, Boutros NN, Schaller C, Elger CE, Kurthen M (2005) Subdural recordings of the mismatch negativity (MMN) in patients with focal epilepsy. Brain 128:819–828PubMed

Rosburg T, Trautner P, Boutros NN, Korzyukov OA, Schaller C, Elger CE, Kurthen M (2006) Habituation of auditory evoked potentials in intracranial and extracranial recordings. Psychophysiology 43:137–144PubMed

Rosburg T, Zimmerer K, Huonker R (2010) Short-term habituation of auditory evoked potential and neuromagnetic field components in dependence of the interstimulus interval. Exp Brain Res 205:559–570PubMed

Russeler J, Altenmuller E, Nager W, Kohlmetz C, Munte TF (2001) Event-related brain potentials to sound omissions differ in musicians and non-musicians. Neurosci Lett 308:33–36PubMed

Saarinen J, Paavilainen P, Schoger E, Tervaniemi M, Naatanen R (1992) Representation of abstract attributes of auditory stimuli in the human brain. Neuroreport 3:1149–1151PubMed

Salisbury DF (2012) Finding the missing stimulus mismatch negativity (MMN): emitted MMN to violations of an auditory gestalt. Psychophysiology 49:544–548PubMedCentralPubMed

Sams M, Kaukoranta E, Hamalainen M, Naatanen R (1991) Cortical activity elicited by changes in auditory stimuli: different sources for the magnetic N100 m and mismatch responses. Psychophysiology 28:21–29PubMed

SanMiguel I, Widmann A, Bendixen A, Trujillo-Barreto N, Schröger E (2013) Hearing silences: human auditory processing relies on preactivation of sound-specific brain activity patterns. J Neurosci 33:8633–8639PubMed

Scherg M, Von Cramon D (1985) Two bilateral sources of the late AEP as identified by a spatio-temporal dipole model. Electroencephalogr Clin Neurophysiol 62:32–44PubMed

Scholl B, Gao X, Wehr M (2010) Nonoverlapping sets of synapses drive on responses and off responses in auditory cortex. Neuron 65:412–421PubMedCentralPubMed

Schroeder CE, Mehta AD, Givre SJ (1998) A spatiotemporal profile of visual system activation revealed by current source density analysis in the awake macaque. Cereb Cortex 8:575–592PubMed

Schroger E, Wolff C (1996) Mismatch response of the human brain to changes in sound location. Neuroreport 7:3005–3008PubMed

Schroger E, Bendixen A, Trujillo-Barreto NJ, Roeber U (2007) Processing of abstract rule violations in audition. PLoS One 2:e1131PubMedCentralPubMed

Sculthorpe LD, Campbell KB (2011) Evidence that the mismatch negativity to pattern violations does not vary with deviant probability. Clin Neurophysiol 122:2236–2245PubMed

Shamma SA, Fleshman JW, Wiser PR, Versnel H (1993) Organization of response areas in ferret primary auditory cortex. J Neurophysiol 69:367–383PubMed

Shelley AM, Silipo G, Javitt DC (1999) Diminished responsiveness of ERPs in schizophrenic subjects to changes in auditory stimulation parameters: implications for theories of cortical dysfunction. Schizophr Res 37:65–79PubMed

Sussman ES (2007) A new view on the MMN and attention debate: the role of context in processing auditory events. J Psychophysiol 21:164–175

Sussman ES, Gumenyuk V (2005) Organization of sequential sounds in auditory memory. Neuroreport 16:1519–1523PubMed

Sussman E, Ritter W, Vaughan HG Jr (1998) Predictability of stimulus deviance and the mismatch negativity. Neuroreport 9:4167–4170PubMed

Taaseh N, Yaron A, Nelken I (2011) Stimulus-specific adaptation and deviance detection in the rat auditory cortex. PLoS One 6:e23369PubMedCentralPubMed

Tervaniemi M, Maury S, Naatanen R (1994a) Neural representations of abstract stimulus features in the human brain as reflected by the mismatch negativity. Neuroreport 5:844–846PubMed

Tervaniemi M, Saarinen J, Paavilainen P, Danilova N, Naatanen R (1994b) Temporal integration of auditory information in sensory memory as reflected by the mismatch negativity. Biol Psychol 38:157–167PubMed

Tian B, Rauschecker JP (2004) Processing of frequency-modulated sounds in the lateral auditory belt cortex of the rhesus monkey. J Neurophysiol 92:2993–3013PubMed

Tiitinen H, Alho K, Huotilainen M, Ilmoniemi RJ, Simola J, Naatanen R (1993) Tonotopic auditory cortex and the magnetoencephalographic (MEG) equivalent of the mismatch negativity. Psychophysiology 30:537–540PubMed

Todorovic A, de Lange FP (2012) Repetition suppression and expectation suppression are dissociable in time in early auditory evoked fields. J Neurosci 32:13389–13395PubMed

Todorovic A, van Ede F, Maris E, de Lange FP (2011) Prior expectation mediates neural adaptation to repeated sounds in the auditory cortex: an MEG study. J Neurosci 31:9118–9123PubMed

Umbricht D, Schmid L, Koller R, Vollenweider FX, Hell D, Javitt DC (2000) Ketamine-induced deficits in auditory and visual context-dependent processing in healthy volunteers: implications for models of cognitive deficits in schizophrenia. Arch Gen Psychiatry 57:1139–1147PubMed

Ulanovsky N, Las L, Nelken I (2003) Processing of low-probability sounds by cortical neurons. Nat Neurosci 6:391–398

Vaughan HG Jr, Ritter W (1970) The sources of auditory evoked responses recorded from the human scalp. Electroencephalogr Clin Neurophysiol 28:360–367PubMed

von der Behrens W, Bauerle P, Kossl M, Gaese BH (2009) Correlating stimulus-specific adaptation of cortical neurons and local field potentials in the awake rat. J Neurosci 29:13837–13849PubMed

Wacongne C, Labyt E, van Wassenhove V, Bekinschtein T, Naccache L, Dehaene S (2011) Evidence for a hierarchy of predictions and prediction errors in human cortex. Proc Natl Acad Sci USA 108:20754–20759PubMedCentralPubMed

Wacongne C, Changeux JP, Dehaene S (2012) A neuronal model of predictive coding accounting for the mismatch negativity. J Neurosci 32:3665–3678PubMed

Walker LJ, Carpenter M, Downs CR, Cranford JL, Stuart A, Pravica D (2001) Possible neuronal refractory or recovery artifacts associated with recording the mismatch negativity response. J Am Acad Audiol 12:348–356PubMed

Watkins PV, Barbour DL (2011a) Rate-level responses in awake marmoset auditory cortex. Hear Res 275:30–42PubMedCentralPubMed

Watkins PV, Barbour DL (2011b) Level-tuned neurons in primary auditory cortex adapt differently to loud versus soft sounds. Cereb Cortex 21:178–190PubMedCentralPubMed

Winkler I (2007) Interpreting the mismatch negativity. J Psychophysiol 21:147–163

Winkler I, Czigler I (2012) Evidence from auditory and visual event-related potential (ERP) studies of deviance detection (MMN and vMMN) linking predictive coding theories and perceptual object representations. Int J Psychophysiol 83:132–143PubMed

Woldorff MG, Hillyard SA, Gallen CC, Hampson SR, Bloom FE (1998) Magnetoencephalographic recordings demonstrate attentional modulation of mismatch-related neural activity in human auditory cortex. Psychophysiology 35:283–292PubMed

Wood CC, Wolpaw JR (1982) Scalp distribution of human auditory evoked potentials. II. Evidence for overlapping sources and involvement of auditory cortex. Electroencephalogr Clin Neurophysiol 54:25–38PubMed

Yabe H, Tervaniemi M, Reinikainen K, Naatanen R (1997) Temporal window of integration revealed by MMN to sound omission. Neuroreport 8:1971–1974PubMed

Yamashiro K, Inui K, Otsuru N, Kida T, Kakigi R (2009) Automatic auditory off-response in humans: an MEG study. Eur J Neurosci 30:125–131PubMed

Yamashiro K, Inui K, Otsuru N, Kakigi R (2011) Change-related responses in the human auditory cortex: an MEG study. Psychophysiology 48:23–30PubMed

Yaron A, Hershenhoren I, Nelken I (2012) Sensitivity to complex statistical regularities in rat auditory cortex. Neuron 76:603–615PubMed

Yvert B, Fischer C, Bertrand O, Pernier J (2005) Localization of human supratemporal auditory areas from intracerebral auditory evoked potentials using distributed source models. Neuroimage 28:140–153PubMed

Titel: The Mechanisms and Meaning of the Mismatch Negativity
verfasst von: Yonatan I. Fishman
Publikationsdatum: 01.07.2014
Verlag: Springer US
Erschienen in: Brain Topography / Ausgabe 4/2014
Print ISSN: 0896-0267
Elektronische ISSN: 1573-6792
DOI: https://doi.org/10.1007/s10548-013-0337-3

Leitlinien kompakt für die Neurologie

Mit medbee Pocketcards sicher entscheiden.

^{Seit 2022 gehört die medbee GmbH zum Springer Medizin Verlag}

Kostenlos registrieren

Neu im Fachgebiet Neurologie

23.04.2024 | Demenz | Nachrichten

Update Neurologie

Bestellen Sie unseren Fach-Newsletter und bleiben Sie gut informiert.

Newsletter bestellen

Springer Medizin

The Mechanisms and Meaning of the Mismatch Negativity

Abstract

Leitlinien kompakt für die Neurologie

Neu im Fachgebiet Neurologie

Demenzkranke durch Antipsychotika vielfach gefährdet

Parkinson-Therapie im Wandel – aktuelle Leitlinie im Fokus

Auf diese Krankheiten bei Geflüchteten sollten Sie vorbereitet sein

Hustenstiller lindert Agitation bei Alzheimer

Update Neurologie

Springer Medizin

Abstract

Bitte loggen Sie sich ein, um Zugang zu diesem Inhalt zu erhalten

Weitere Artikel der Ausgabe 4/2014

Scalp Current Density Mapping in the Analysis of Mismatch Negativity Paradigms

Time–Frequency Analysis of Event-Related Potentials: A Brief Tutorial

MMN and Novelty P3 in Coma and Other Altered States of Consciousness: A Review

New Perspectives on the Mismatch Negativity (MMN) Component: An Evolving Tool in Cognitive Neuroscience

The Five Myths of MMN: Redefining How to Use MMN in Basic and Clinical Research

An Integrative Model of Subcortical Auditory Plasticity

Leitlinien kompakt für die Neurologie

Neu im Fachgebiet Neurologie

Demenzkranke durch Antipsychotika vielfach gefährdet

Parkinson-Therapie im Wandel – aktuelle Leitlinie im Fokus

Auf diese Krankheiten bei Geflüchteten sollten Sie vorbereitet sein

Hustenstiller lindert Agitation bei Alzheimer

Update Neurologie