Music-selective neural populations arise without musical training.

Advanced Search

Dana Boebinger, Sam V Norman-Haignere, Josh H McDermott, Nancy Kanwisher

Author Information

Dana Boebinger: Speech and Hearing Bioscience and Technology, Harvard University, Cambridge, Massachusetts. ORCID
Sam V Norman-Haignere: Laboratoire des Sytèmes Perceptifs, Département d'Études Cognitives, École Normale Supérieure, PSL Research University, CNRS, Paris France. ORCID
Josh H McDermott: Speech and Hearing Bioscience and Technology, Harvard University, Cambridge, Massachusetts.
Nancy Kanwisher: Brain and Cognitive Sciences, Massachusetts Institute of Technology, Cambridge, Massachusetts.

PMID: 33596723 DOI: 10.1152/jn.00588.2020

Recent work has shown that human auditory cortex contains neural populations anterior and posterior to primary auditory cortex that respond selectively to music. However, it is unknown how this selectivity for music arises. To test whether musical training is necessary, we measured fMRI responses to 192 natural sounds in 10 people with almost no musical training. When voxel responses were decomposed into underlying components, this group exhibited a music-selective component that was very similar in response profile and anatomical distribution to that previously seen in individuals with moderate musical training. We also found that musical genres that were less familiar to our participants (e.g., Balinese ) produced strong responses within the music component, as did drum clips with rhythm but little melody, suggesting that these neural populations are broadly responsive to music as a whole. Our findings demonstrate that the signature properties of neural music selectivity do not require musical training to develop, showing that the music-selective neural populations are a fundamental and widespread property of the human brain. We show that music-selective neural populations are clearly present in people without musical training, demonstrating that they are a fundamental and widespread property of the human brain. Additionally, we show music-selective neural populations respond strongly to music from unfamiliar genres as well as music with rhythm but little pitch information, suggesting that they are broadly responsive to music as a whole.

auditory cortex decomposition expertise fMRI music

Neuroimage. 2020 Apr 15;210:116558 [PMID: 31962174]
Neurobiol Learn Mem. 2010 Feb;93(2):229-39 [PMID: 19853056]
Front Neurosci. 2019 Oct 30;13:1165 [PMID: 31736698]
Cortex. 2013 Nov-Dec;49(10):2822-33 [PMID: 23706955]
PLoS Biol. 2018 Dec 3;16(12):e2005127 [PMID: 30507943]
Science. 2020 Feb 28;367(6481):1043-1047 [PMID: 32108113]
Neuroimage. 2012 Apr 15;60(3):1902-12 [PMID: 22348885]
Cereb Cortex. 2013 Feb;23(2):249-54 [PMID: 22314043]
Cortex. 2011 Oct;47(9):1126-37 [PMID: 21665201]
Neuroimage. 2002 Apr;15(4):870-8 [PMID: 11906227]
J Neurosci. 2016 Mar 9;36(10):2986-94 [PMID: 26961952]
J Neurosci. 2006 May 3;26(18):4970-82 [PMID: 16672673]
Cognition. 2006 May;100(1):100-30 [PMID: 16412412]
Science. 2019 Nov 22;366(6468): [PMID: 31753969]
Hum Brain Mapp. 2009 Jan;30(1):267-75 [PMID: 18072277]
Curr Opin Neurobiol. 2005 Aug;15(4):470-7 [PMID: 16009546]
J Acoust Soc Am. 2003 Dec;114(6 Pt 1):3394-411 [PMID: 14714819]
J Neurosci. 2010 Jun 2;30(22):7604-12 [PMID: 20519535]
Neuron. 2006 Oct 19;52(2):371-81 [PMID: 17046698]
Front Syst Neurosci. 2013 Apr 30;7:11 [PMID: 23641203]
J Neurosci. 2011 Mar 9;31(10):3843-52 [PMID: 21389239]
Hum Brain Mapp. 1999;7(3):213-23 [PMID: 10194620]
Proc Natl Acad Sci U S A. 2009 Aug 25;106(34):14611-6 [PMID: 19667199]
Nat Neurosci. 2015 Jun;18(6):903-11 [PMID: 25984889]
J Neurosci. 2003 Jul 2;23(13):5545-52 [PMID: 12843255]
Neuron. 2011 Sep 8;71(5):926-40 [PMID: 21903084]
J Neurosci. 2012 Aug 29;32(35):12251-7 [PMID: 22933806]
J Acoust Soc Am. 1971 Feb;49(2):Suppl 2:467+ [PMID: 5541744]
Psychol Rev. 2000 Oct;107(4):885-913 [PMID: 11089410]
J Neurosci. 2011 Mar 16;31(11):4213-20 [PMID: 21411662]
Brain. 2000 Dec;123 Pt 12:2400-6 [PMID: 11099443]
J Cogn Neurosci. 2005 Oct;17(10):1578-92 [PMID: 16269098]
Curr Biol. 2017 Feb 6;27(3):359-370 [PMID: 28065607]
Exp Brain Res. 2010 Jul;204(1):91-101 [PMID: 20508918]
Front Psychol. 2015 Aug 11;6:1138 [PMID: 26321976]
Nature. 2001 Jul 5;412(6842):79-83 [PMID: 11452310]
J Basic Clin Physiol Pharmacol. 2001;12(2 Suppl):125-43 [PMID: 11605682]
Proc Natl Acad Sci U S A. 1996 Oct 1;93(20):11219-24 [PMID: 8855336]
Nat Neurosci. 2003 Jul;6(7):669-73 [PMID: 12830157]
Med Image Anal. 2001 Jun;5(2):143-56 [PMID: 11516708]
J Cogn Neurosci. 2007 May;19(5):893-906 [PMID: 17488212]
Ann N Y Acad Sci. 2005 Dec;1060:100-10 [PMID: 16597757]
Proc Natl Acad Sci U S A. 1993 Mar 15;90(6):2394-8 [PMID: 8460150]
Proc Natl Acad Sci U S A. 2012 Feb 7;109(6):2144-9 [PMID: 22308415]
Am J Psychol. 1987 Fall-Winter;100(3-4):441-71 [PMID: 3322052]
Curr Biol. 2019 Oct 7;29(19):3229-3243.e12 [PMID: 31543451]
Restor Neurol Neurosci. 2007;25(3-4):399-410 [PMID: 17943015]
Neuroimage. 1999 Feb;9(2):179-94 [PMID: 9931268]
Neuroimage. 2020 Jul 1;214:116768 [PMID: 32217163]
Proc Natl Acad Sci U S A. 2007 May 22;104(21):9087-92 [PMID: 17502592]
Percept Psychophys. 1997 Oct;59(7):1098-107 [PMID: 9360482]
Cortex. 2014 Oct;59:126-37 [PMID: 25173956]
J Neurosci. 1993 Jan;13(1):87-103 [PMID: 8423485]
Eur J Neurosci. 2012 Feb;35(4):598-613 [PMID: 22304434]
J Cogn Neurosci. 2000 May;12(3):520-41 [PMID: 10931776]
Neuron. 2018 May 2;98(3):630-644.e16 [PMID: 29681533]
Hum Mov Sci. 2010 Apr;29(2):200-13 [PMID: 20074825]
Neuron. 2011 Apr 14;70(1):121-31 [PMID: 21482361]
J Neurosci. 2011 Oct 5;31(40):14067-75 [PMID: 21976491]
Neuroimage. 2010 Apr 15;50(3):1202-11 [PMID: 20096790]
Cereb Cortex. 2011 Apr;21(4):938-48 [PMID: 20829245]
Science. 2013 Apr 12;340(6129):216-9 [PMID: 23580531]
Neuropharmacology. 1998 Apr-May;37(4-5):633-55 [PMID: 9705003]
J Acoust Soc Am. 2005 Aug;118(2):887-906 [PMID: 16158645]
Nat Neurosci. 2002 Apr;5(4):356-63 [PMID: 11896400]
Nat Hum Behav. 2018 Jan;2(1):52-66 [PMID: 30221202]
Nat Commun. 2020 Jun 3;11(1):2786 [PMID: 32493923]
Curr Biol. 2018 Jun 18;28(12):1860-1871.e4 [PMID: 29861132]
J Neurosci. 2004 Jul 28;24(30):6810-5 [PMID: 15282286]
Cogn Sci. 2008 Mar;32(2):418-44 [PMID: 21635341]
Hear Res. 2006 Sep;219(1-2):36-47 [PMID: 16839723]
Neuroreport. 2001 Jan 22;12(1):169-74 [PMID: 11201080]
Science. 2002 Dec 13;298(5601):2167-70 [PMID: 12481131]
Science. 1992 Sep 4;257(5075):1412-5 [PMID: 1529342]
J Cogn Neurosci. 2004 Jul-Aug;16(6):1010-21 [PMID: 15298788]
PLoS Biol. 2018 Mar 6;16(3):e2004103 [PMID: 29509766]
J Neurophysiol. 2012 Dec;108(12):3289-300 [PMID: 23019005]
Proc Natl Acad Sci U S A. 2019 Dec 10;116(50):25355-25364 [PMID: 31754035]
Cereb Cortex. 2001 Aug;11(8):754-60 [PMID: 11459765]
Nat Neurosci. 2003 Nov;6(11):1216-23 [PMID: 14583754]
Neuroimage. 2009 Oct 15;48(1):63-72 [PMID: 19573611]
Neuroimage. 2016 Jan 1;124(Pt A):898-905 [PMID: 26436712]
J Exp Psychol Hum Percept Perform. 1997 Jun;23(3):808-22 [PMID: 9180045]
Proc Natl Acad Sci U S A. 2015 Nov 10;112(45):E6233-42 [PMID: 26504238]
J Acoust Soc Am. 2010 Oct;128(4):1943-51 [PMID: 20968366]
J Neurophysiol. 2010 Feb;103(2):887-903 [PMID: 20018831]
Proc Natl Acad Sci U S A. 2011 Dec 20;108(51):E1441-50 [PMID: 22114191]
Neuron. 2015 Dec 16;88(6):1281-1296 [PMID: 26687225]
Proc Natl Acad Sci U S A. 2001 Sep 25;98(20):11818-23 [PMID: 11573015]
Nat Hum Behav. 2022 Mar;6(3):455-469 [PMID: 35145280]
Nat Neurosci. 2007 Apr;10(4):420-2 [PMID: 17351633]
Spat Vis. 1997;10(4):433-6 [PMID: 9176952]
Neuron. 2002 Nov 14;36(4):767-76 [PMID: 12441063]
Nature. 2016 Jul 28;535(7613):547-50 [PMID: 27409816]
J Neurosci. 2013 Dec 11;33(50):19451-69 [PMID: 24336712]
PLoS Comput Biol. 2014 Jan;10(1):e1003412 [PMID: 24391486]
Hear Res. 2005 Aug;206(1-2):159-76 [PMID: 16081006]
Neurosci Biobehav Rev. 2017 Oct;81(Pt B):181-187 [PMID: 28212857]
Nat Neurosci. 2011 Feb;14(2):257-62 [PMID: 21217764]
Nature. 2016 Aug 11;536(7615):171-178 [PMID: 27437579]
J Neurosci. 2016 Feb 10;36(6):2014-26 [PMID: 26865624]
Nat Rev Neurosci. 2007 May;8(5):393-402 [PMID: 17431404]
J Neurophysiol. 2001 Jul;86(1):326-38 [PMID: 11431514]
Science. 2010 Dec 3;330(6009):1359-64 [PMID: 21071632]
Psychon Bull Rev. 2005 Dec;12(6):969-92 [PMID: 16615317]
Neuroimage. 2013 Jul 15;75:97-107 [PMID: 23470982]
Neuroimage. 2011 Jul 1;57(1):293-300 [PMID: 21315158]
Science. 1995 Apr 7;268(5207):111-4 [PMID: 7701330]
Proc Natl Acad Sci U S A. 2002 Jul 23;99(15):10114-9 [PMID: 12119383]
Proc Natl Acad Sci U S A. 2005 Sep 20;102(38):13664-9 [PMID: 16174754]
Neurosci Lett. 2015 Apr 23;593:35-9 [PMID: 25766754]
PLoS Comput Biol. 2012;8(7):e1002594 [PMID: 22807665]

DP1 HD091947/NICHD NIH HHS
R01 DC017970/NIDCD NIH HHS
BCS-1634050/National Science Foundation (NSF)
DP1HD091947/HHS | National Institutes of Health (NIH)

Adult

Auditory Cortex

Auditory Perception

Brain Mapping

Female

Humans

Magnetic Resonance Imaging

Male

Music

Practice, Psychological

Young Adult

Journal Article

[Music perception, EEG and musical training].Musical ability, music training, and language ability in childhood.Music and Lyrics: Musical Training for Aural Rehabilitation.Music-reading training alleviates crowding with musical notation.Change detection in multi-voice music: the role of musical structure, musical training, and task demands.Influence of musical expertise and musical training on pitch processing in music and language.[Musical hallucinations: perpetual music].[Music and musical instruments].Musicians at the Cocktail Party: Neural Substrates of Musical Training During Selective Listening in Multispeaker Situations.Selective musical processing deficits in brain damaged populations.

Music in Noise: Neural Correlates Underlying Noise Tolerance in Music-Induced Emotion.Rostro-caudal networks for sound processing in the primate brain.Spontaneous emergence of rudimentary music detectors in deep neural networks.A neural population selective for song in human auditory cortex.Encoding of melody in the human auditory cortex.Subcortical responses to music and speech are alike while cortical responses diverge.Speech and music recruit frequency-specific distributed and overlapping cortical networks.Musical Sophistication and Speech Auditory-Motor Coupling: Easy Tests for Quick Answers.Vowel and formant representation in the human auditory speech cortex.Preserved functional organization of auditory cortex in two individuals missing one temporal lobe from infancy.

See all "Cited by" articles

OpenLB
Open Library of Bioscience