Biology:Mismatch negativity

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The mismatch negativity (MMN) or mismatch field (MMF) is a component of the event-related potential (ERP) to an odd stimulus in a sequence of stimuli. It arises from electrical activity in the brain and is studied within the field of cognitive neuroscience and psychology. It can occur in any sensory system, but has most frequently been studied for hearing and for vision, in which case it is abbreviated to vMMN.[1] The (v)MMN occurs after an infrequent change in a repetitive sequence of stimuli (sometimes the entire sequence is called an oddball sequence.) For example, a rare deviant (d) stimulus can be interspersed among a series of frequent standard (s) stimuli (e.g., s s s s s s s s s d s s s s s s d s s s d s s s s...). In hearing, a deviant sound can differ from the standards in one or more perceptual features such as pitch, duration, loudness, or location.[2] The MMN can be elicited regardless of whether someone is paying attention to the sequence.[3] During auditory sequences, a person can be reading or watching a silent subtitled movie, yet still show a clear MMN. In the case of visual stimuli, the MMN occurs after an infrequent change in a repetitive sequence of images. MMN refers to the mismatch response in electroencephalography (EEG); MMF or MMNM refer to the mismatch response in magnetoencephalography (MEG).

History

The auditory MMN was discovered in 1978 by Risto Näätänen, A. W. K. Gaillard, and S. Mäntysalo at the Institute for Perception, TNO in The Netherlands.[4]

The first report of a visual MMN was in 1990 by Rainer Cammer.[5] For a history of the development of the visual MMN, see Pazo-Alvarez et al. (2003).[6]

Characteristics

The MMN is a response to a deviant within a sequence of otherwise regular stimuli; thus, in an experimental setting, it is produced when stimuli are presented in a many-to-one ratio; for example, in a sequence of sounds s s s s s s s d s s s s d s s s..., the d is the deviant or oddball stimulus, and will elicit an MMN response. The mismatch negativity occurs even if the subject is not consciously paying attention to the stimuli.[4] Processing of sensory stimulus features is essential for humans in determining their responses and actions. If behaviourally relevant aspects of the environment are not correctly represented in the brain, then the organism's behaviour cannot be appropriate. Without these representations our ability to understand spoken language, for example, would be seriously impaired. Cognitive neuroscience has consequently emphasised the importance of understanding brain mechanisms of sensory information processing, that is, the sensory prerequisites of cognition. Most of the data obtained, unfortunately, do not allow the objective measurement of the accuracy of these stimulus representations.[7] In addition, recent cognitive neuroscience seems to have succeeded in extracting such a measure, however. This is the mismatch negativity (MMN), a component of the event-related potential (ERP), first reported by Näätänen, Gaillard, and Mäntysalo (1978).[4] An in-depth review of MMN research can be found in Näätänen (1992)[7] while other recent reviews also provide information on the generator mechanisms of MMN,[8] its magnetic counterpart, MMNm (Näätänen, Ilmoniemi & Alho, 1994),[9] and its clinical applicability.[10]

The auditory MMN can occur in response to deviance in pitch, intensity, or duration. The auditory MMN is a fronto-central negative potential with sources in the primary and non-primary auditory cortex and a typical latency of 150-250 ms after the onset of the deviant stimulus. Sources could also include the inferior frontal gyrus, and the insular cortex.[11][12][13] The amplitude and latency of the MMN is related to how different the deviant stimulus is from the standard. Large deviances elicit MMN at earlier latencies. For very large deviances, the MMN can even overlap the N100.[14]

The visual MMN can occur in response to deviance in such aspects as color, size, or duration. The visual MMN is an occipital negative potential with sources in the primary visual cortex and a typical latency of 150-250 ms after the onset of the deviant stimulus.

Neurolinguistics

As kindred phenomena have been elicited with speech stimuli, under passive conditions that require very little active attention to the sound, a version of MMN has been frequently used in studies of neurolinguistic perception, to test whether or not these participants neurologically distinguish between certain kinds of sounds.[15] The MMN response has been used to study how fetuses and newborns discriminate speech sounds.[16][17] In addition to these kinds of studies focusing on phonological processing, some research has implicated the MMN in syntactic processing.[18] Some of these studies have attempted to directly test the automaticity of the MMN, providing converging evidence for the understanding of the MMN as a task-independent and automatic response.[19]

For basic stimulus features

MMN is evoked by an infrequently presented stimulus ("deviant"), differing from the frequently-occurring stimuli ("standards") in one or several physical parameters like duration, intensity, or frequency.[7] In addition, it is generated by a change in spectrally complex stimuli like phonemes, in synthesised instrumental tones, or in the spectral component of tone timbre. Also the temporal order reversals elicit an MMN when successive sound elements differ either in frequency, intensity, or duration. The MMN is not elicited by stimuli with deviant stimulus parameters when they are presented without the intervening standards. Thus, the MMN has been suggested to reflect change detection when a memory trace representing the constant standard stimulus and the neural code of the stimulus with deviant parameter(s) are discrepant.

Vs. auditory sensory memory

The MMN data can be understood as providing evidence that stimulus features are separately analysed and stored in the vicinity of auditory cortex (for a discussion, please see the theory section below). The close resemblance of the behaviour of the MMN to that of the previously behaviourally observed "echoic" memory system strongly suggests that the MMN provides a non-invasive, objective, task-independently measurable physiological correlate of stimulus-feature representations in auditory sensory memory.

Relationship to attentional processes

The experimental evidence suggests that the auditory sensory memory index MMN provides sensory data for attentional processes, and, in essence, governs certain aspects of attentive information processing. This is evident in the finding that the latency of the MMN determines the timing of behavioural responses to changes in the auditory environment.[20] Furthermore, even individual differences in discrimination ability can be probed with the MMN. The MMN is a component of the chain of brain events causing attention switches to changes in the environment. Attentional instructions also affect MMN.[21][22][23][24][25]

In clinical research

The MMN has been documented in a number of studies to disclose neuropathological changes. Presently, the accumulated body of evidence suggests that while the MMN offers unique opportunities to basic research of the information processing of a healthy brain, it might be useful in tapping neurodegenerative changes as well.

MMN, which is elicited irrespective of attention, provides an objective means for evaluating possible auditory discrimination and sensory-memory anomalies in such clinical groups as dyslexics and patients with aphasia, who have a multitude of symptoms including attentional problems. Recent results suggest that a major problem underlying the reading deficit in dyslexia might be an inability of the dyslexics' auditory cortex to adequately model complex sound patterns with fast temporal variation.[26] According to the results of an ongoing study, MMN might also be used in the evaluation of auditory perception deficits in aphasia.

Alzheimer's patients demonstrate decreased amplitude of MMN, especially with long inter-stimulus intervals; this is thought to reflect reduced span of auditory sensory memory. Parkinsonian patients do demonstrate a similar deficit pattern, whereas alcoholism would appear to enhance the MMN response. This latter, seemingly contradictory, finding could be explained by hyperexcitability of CNS neurones resulting from neuroadaptive changes taking place during a heavy drinking bout.

While the results obtained thus far seem encouraging, several steps need to be taken before the MMN can be used as a clinical tool in patient treatment. A focus of research in the late 1990s aimed to tackle some of the key signal-analysis problems encountered in development of clinical use of MMN and challenges still remain. Nevertheless, as it stands, clinical research employing the MMN has already produced significant knowledge on the CNS functional changes related to cognitive decline in the aforementioned clinical disorders.

A 2010 study found that MMN durations were reduced in a group of schizophrenia patients who later went on to have psychotic episodes, suggesting that MMN durations may predict future psychosis.[27] Recent research advocates for the use of MMN in clinical intervention, because MMN can predict treatment response for patients with schizophrenia in the context of pro-cognitive therapeutics.[28]

Theory

The mainstream "memory trace" interpretation of MMN is that it is elicited in response to violations of simple rules governing the properties of information. It is thought to arise from violation of an automatically formed, short-term neural model or memory trace of physical or abstract environmental regularities.[29][30] However, other than MMN, there is no other neurophysiological evidence for the formation of the memory representation of those regularities.[citation needed]

Integral to this memory trace view is that there are: i) a population of sensory afferent neuronal elements that respond to sound, and; ii) a separate population of memory neuronal elements that build a neural model of standard stimulation and respond more vigorously when the incoming stimulation violates that neural model, eliciting an MMN.

An alternative "fresh afferent" interpretation[7][31] is that there are no memory neuronal elements, but the sensory afferent neuronal elements that are tuned to properties of the standard stimulation respond less vigorously upon repeated stimulation. Thus when a deviant activates a distinct new population of neuronal elements that is tuned to the different properties of the deviant rather than the standard, these fresh afferents respond more vigorously, eliciting an MMN.

A third view is that the sensory afferents are the memory neurons.[32][33]

See also


References

  1. Stefanics, G; Kremláček, J; Czigler, I (2014). "Visual mismatch negativity: A predictive coding view". Frontiers in Human Neuroscience 8 (666): 666. doi:10.3389/fnhum.2014.00666. PMID 25278859. 
  2. "Attention and mismatch negativity". Psychophysiology 30 (5): 436–50. September 1993. doi:10.1111/j.1469-8986.1993.tb02067.x. PMID 8416070. 
  3. "Musical scale properties are automatically processed in the human auditory cortex". Brain Research 1117 (1): 162–74. October 2006. doi:10.1016/j.brainres.2006.08.023. PMID 16963000. http://www.brainmusic.org/EducationalActivitiesFolder/Brattico_pitch2006.pdf. 
  4. 4.0 4.1 4.2 "Early selective-attention effect on evoked potential reinterpreted". Acta Psychologica 42 (4): 313–29. July 1978. doi:10.1016/0001-6918(78)90006-9. PMID 685709. 
  5. "Is there no MMN in the visual modality?". Behavioral and Brain Sciences 13 (2): 234–235. 1990. doi:10.1017/s0140525x00078420. 
  6. "MMN in the visual modality: a review". Biological Psychology 63 (3): 199–236. July 2003. doi:10.1016/s0301-0511(03)00049-8. PMID 12853168. 
  7. 7.0 7.1 7.2 7.3 Näätänen, Risto (1992). Attention and brain function. Hillsdale, N.J: L. Erlbaum. ISBN 978-0-8058-0984-8. OCLC 25832590. https://www.questia.com/PM.qst?a=o&d=14362952. 
  8. "Cerebral generators of mismatch negativity (MMN) and its magnetic counterpart (MMNm) elicited by sound changes". Ear and Hearing 16 (1): 38–51. February 1995. doi:10.1097/00003446-199502000-00004. PMID 7774768. 
  9. "Magnetoencephalography in studies of human cognitive brain function". Trends in Neurosciences 17 (9): 389–95. September 1994. doi:10.1016/0166-2236(94)90048-5. PMID 7529443. 
  10. "Mismatch negativity--a unique measure of sensory processing in audition". The International Journal of Neuroscience 80 (1–4): 317–37. 1995. doi:10.3109/00207459508986107. PMID 7775056. 
  11. "Subdural recordings of the mismatch negativity (MMN) in patients with focal epilepsy". Brain 128 (Pt 4): 819–28. April 2005. doi:10.1093/brain/awh442. PMID 15728656. 
  12. "Convergent evidence for hierarchical prediction networks from human electrocorticography and magnetoencephalography". Cortex; A Journal Devoted to the Study of the Nervous System and Behavior 82: 192–205. September 2016. doi:10.1016/j.cortex.2016.05.001. PMID 27389803. 
  13. "Auditory deviance detection in the human insula: An intracranial EEG study". Cortex; A Journal Devoted to the Study of the Nervous System and Behavior 121: 189–200. December 2019. doi:10.1016/j.cortex.2019.09.002. PMID 31629197. https://www.biorxiv.org/content/10.1101/487306v1. 
  14. "N1 and the mismatch negativity are spatiotemporally distinct ERP components: disruption of immediate memory by auditory distraction can be related to N1". Psychophysiology 44 (4): 530–40. July 2007. doi:10.1111/j.1469-8986.2007.00529.x. PMID 17532805. 
  15. "Auditory cortex accesses phonological categories: an MEG mismatch study". Journal of Cognitive Neuroscience 12 (6): 1038–55. November 2000. doi:10.1162/08989290051137567. PMID 11177423. 
  16. Schmidt, Louis A.; Segalowitz, Sidney J (2008). Developmental psychophysiology: theory, systems, and methods. Cambridge: Cambridge University Press. ISBN 978-0-511-49979-1. OCLC 190792301. 
  17. "Sound frequency change detection in fetuses and newborns, a magnetoencephalographic study". NeuroImage 28 (2): 354–61. November 2005. doi:10.1016/j.neuroimage.2005.06.011. PMID 16023867. 
  18. "The mismatch negativity as an objective tool for studying higher language functions". Automaticity and Control in Language Processing. Advances in Behavioural Brain Science. 2007. pp. 217–242. doi:10.4324/9780203968512. ISBN 978-0-203-96851-2. 
    Specific experimental studies include the following:
  19. "Syntax as a reflex: neurophysiological evidence for early automaticity of grammatical processing". Brain and Language 104 (3): 244–53. March 2008. doi:10.1016/j.bandl.2007.05.002. PMID 17624417. 
  20. "Attentive novelty detection in humans is governed by pre-attentive sensory memory". Nature 372 (6501): 90–2. November 1994. doi:10.1038/372090a0. PMID 7969425. Bibcode1994Natur.372...90T. 
  21. "The effects of channel-selective attention on the mismatch negativity wave elicited by deviant tones". Psychophysiology 28 (1): 30–42. January 1991. doi:10.1111/j.1469-8986.1991.tb03384.x. PMID 1886962. 
  22. "Magnetoencephalographic recordings demonstrate attentional modulation of mismatch-related neural activity in human auditory cortex". Psychophysiology 35 (3): 283–92. May 1998. doi:10.1017/s0048577298961601. PMID 9564748. 
  23. "Mismatch negativity (MMN) is altered by directing attention". NeuroReport 6 (8): 1187–90. May 1995. doi:10.1097/00001756-199505300-00028. PMID 7662904. http://cogprints.org/1182/2/Neuroreport.pdf. 
  24. "Attention-dependent allocation of auditory processing resources as measured by mismatch negativity". NeuroReport 10 (18): 3749–53. December 1999. doi:10.1097/00001756-199912160-00005. PMID 10716203. 
  25. "Task instructions modulate the attentional mode affecting the auditory MMN and the semantic N400". Frontiers in Human Neuroscience 8: 654. 2014. doi:10.3389/fnhum.2014.00654. PMID 25221494. 
  26. "Basic auditory dysfunction in dyslexia as demonstrated by brain activity measurements". Psychophysiology 37 (2): 262–6. March 2000. doi:10.1111/1469-8986.3720262. PMID 10731777. https://www.cambridge.org/core/journals/psychophysiology/article/basic-auditory-dysfunction-in-dyslexia-as-demonstrated-by-brain-activity-measurements/6D671B9289C62183C9C4EFDDF3306D22. 
  27. "Prediction of psychosis by mismatch negativity". Biological Psychiatry 69 (10): 959–66. May 2011. doi:10.1016/j.biopsych.2010.09.057. PMID 21167475. 
  28. Hochberger, William C.; Joshi, Yash B.; Thomas, Michael L.; Zhang, Wendy; Bismark, Andrew W.; Treichler, Emily B. H.; Tarasenko, Melissa; Nungaray, John et al. (February 2019). "Neurophysiologic measures of target engagement predict response to auditory-based cognitive training in treatment refractory schizophrenia" (in en). Neuropsychopharmacology 44 (3): 606–612. doi:10.1038/s41386-018-0256-9. ISSN 1740-634X. PMID 30377381. 
  29. "The mismatch negativity (MMN) in basic research of central auditory processing: a review". Clinical Neurophysiology 118 (12): 2544–90. December 2007. doi:10.1016/j.clinph.2007.04.026. PMID 17931964. 
  30. "The concept of auditory stimulus representation in cognitive neuroscience". Psychological Bulletin 125 (6): 826–59. November 1999. doi:10.1037/0033-2909.125.6.826. PMID 10589304. 
  31. "Human posterior auditory cortex gates novel sounds to consciousness". Proceedings of the National Academy of Sciences of the United States of America 101 (17): 6809–14. April 2004. doi:10.1073/pnas.0303760101. PMID 15096618. Bibcode2004PNAS..101.6809J. 
  32. Ulanovsky N (February 2004). Neuronal Adaptation in Cat Auditory Cortex (PDF) (Ph.D. thesis). Hebrew University. Archived from the original (PDF) on 11 June 2016.
  33. "Short-term plasticity in auditory cognition". Trends in Neurosciences 30 (12): 653–61. December 2007. doi:10.1016/j.tins.2007.09.003. PMID 17981345. 

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