Sage Journals: Discover world-class research

Abstract

Introduction:

Music tempo has strong clinical maneuverability and positive emotional effect in music therapy, which can directly evoke multiple emotions and dynamic neural changes in the whole brain. However, the precise relationship between music tempo and its emotional effects remains unclear. The present study aimed to investigate the dynamic network connectivity (dFNC) associated with emotions elicited by music at different tempi.

Materials and Methods:

We obtained emotion ratings of fast-tempo (155–170 beats per minute [bpm]), middle-tempo (90 bpm), and slow-tempo (50–60 bpm) piano music from 40 participants both during and after functional magnetic resonance imaging (fMRI). Group independent component analysis (ICA), sliding time window correlations, and k-means clustering were used to assess the dFNC of fMRI data. Paired t-tests were conducted to compare the difference of neural networks.

Results:

(1) Fast music was associated with higher ratings of emotional valence and arousal, which were accompanied with increasing dFNC between somatomotor (SM) and cingulo-opercular (CO) networks and decreasing dFNC between frontoparietal and SM networks. (2) Even with stronger activation in auditory (AUD) networks, slow music was associated with weaker emotion than fast music, with decreasing functional network connectivity across the brain and the participation of default mode (DM). (3) Middle-tempo music elicited moderate emotional activation with the most stable dFNC in the whole brain.

Conclusion:

Faster music increases neural activity in the SM and CO regions, increasing the intensity of the emotional experience. In contrast, slower music was associated with decreasing engagement of AUD and stable engagement of DM, resulting in a weak emotional experience. These findings suggested that the time-varying aspects of functional connectivity can help to uncover the dynamic neural substrates of tempo-evoked emotion while listening to music.

Impact statement

Music tempo is helpful in clarifying the neural process of music-evoked emotional processes with the activation of multiple neural networks. By investigating the dynamic network connectivity (dFNC) associated with emotions elicited by music at different tempi, this study found that faster music increased neural activity in the somatomotor and cingulo-opercular regions with increasing emotional experience. Slower music was associated with decreasing engagement of auditory and stable engagement of default mode with calm emotion. The time-varying aspects of dFNC in musical emotion evoked by three typical tempi provided the first whole-brain characterization of regional differences in functional connectivity (FC) variability and distinction of discrete FC states.

Get full access to this article

View all access options for this article.

References

Allen

, Damaraju

, Plis

, et al. 2014. Tracking whole-brain connectivity dynamics in the resting state. Cereb Cortex, 24:663–676.

Balasubramanian

, Kanagasabai

, Mohan

, et al. 2018. Music induced emotion using wavelet packet decomposition—an EEG study. Biomed Signal Proc Control, 42:115–128.

Balch

, Lewis

. 1996. Music-dependent memory: the roles of tempo change and mood mediation. J Exp Psychol, 22:1354.

Bashwiner

, Bacon

, Wertz

, et al. 2020. Resting state functional connectivity underlying musical creativity. Neuroimage, 218:116940.

Bell

, Sejnowski

. 1995. An information-maximization approach to blind separation and blind deconvolution. Neural Comput, 7:1129–1159.

Bishop

, Wright

, Karageorghis

. 2014. Tempo and intensity of pre-task music modulate neural activity during reactive task performance. Psychol Music, 42:714–727.

Cohen

, Fair

, Dosenbach

, et al. 2008. Defining functional areas in individual human brains using resting functional connectivity MRI. Neuroimage, 41:45–57.

De Witte

, Lindelauf

, Moonen

, et al. 2020a. Music therapy interventions for stress reduction in adults with mild intellectual disabilities: perspectives from clinical practice. Front Psychol, 11:572549.

De Witte

, Pinho

ADS

, Stams

, et al. 2020b. Music therapy for stress reduction: a systematic review and meta-analysis. Health Psychol Rev. 1–26.

10.

Dean

, Robinson

, Harper

, et al. 2008. Rapid neural adaptation to sound level statistics. J Neurosci, 28:6430–6438.

11.

Feiss

, Kostrna

, Scruggs

, et al. 2021. Effects of music tempo on perceived exertion, attention, affect, heart rate, and performance during isometric strength exercise. J Sports Sci, 39:161–169.

12.

Fernández-Sotos

, Fernández-Caballero

, Latorre

. 2016. Influence of tempo and rhythmic unit in musical emotion regulation. Front Comput Neurosci, 10:80.

13.

Friedman

, Hastie

, Tibshirani

. 2008. Sparse inverse covariance estimation with the graphical lasso. Biostatistics, 9:432–441.

14.

Garza-Villarreal

, Jiang

, Vuust

, et al. 2015. Music reduces pain and increases resting state fMRI BOLD signal amplitude in the left angular gyrus in fibromyalgia patients. Front Psychol, 6:1051.

15.

Ghahari

, Farahani

, Fatemizadeh

, et al. 2020. Investigating time-varying functional connectivity derived from the Jackknife Correlation method for distinguishing between emotions in fMRI data. Cogn Neurodyn, 14:457–471.

16.

Grootswagers

, Kennedy

, Most

, et al. 2020. Neural signatures of dynamic emotion constructs in the human brain. Neuropsychologia, 145:106535.

17.

Harvey

AR.

2020. Links between the neurobiology of oxytocin and human musicality. Front Hum Neurosci, 14:350.

18.

Himberg

, Hyvarinen

Icasso: Software for Investigating the Reliability of ICA Estimates by Clustering and Visualization. In 2003 IEEE XIII Workshop on Neural Networks for Signal Processing, Toulouse, France, 2003, pp. 259–268.

19.

Husain

, Thompson

, Schellenberg

. 2002. Effects of musical tempo and mode on arousal, mood, and spatial abilities. Music Percept, 20:151–171.

20.

Iwanaga

1995. Relationship between heart rate and preference for tempo of music. Percept Motor Skills, 81:435–440.

21.

Juslin

PN.

2019. Musical Emotions Explained: Unlocking the Secrets of Musical Affect. USA: Oxford University. Press.

22.

Kamenetsky

, Hill

, Trehub

. 1997. Effect of tempo and dynamics on the perception of emotion in music. Psychol Music, 25:149–160.

23.

Kaneshiro

, Nguyen

, Norcia

, et al. 2020. Natural music evokes correlated EEG responses reflecting temporal structure and beat. Neuroimage, 214:116559.

24.

Karageorghis

, Cheek

, Simpson

, et al. 2018. Interactive effects of music tempi and intensities on grip strength and subjective affect. Scand. J Med Sci Sports, 28:1166–1175.

25.

Koelsch

, Fritz

, Cramon

, et al. 2006. Investigating emotion with music: an fMRI study. Hum Brain Mapp, 27:239–250.

26.

Koelsch

, Skouras

. 2014. Functional centrality of amygdala, striatum and hypothalamus in a “small-world” network underlying joy: an fMRI study with music. Hum Brain Mapp, 35:3485–3498.

27.

, Chen

, Zhang

. 2019. Effect of music tempo on long-distance driving: which tempo is the most effective at reducing fatigue?. Iperception, 10:2041669519861982.

28.

, Adali

, Calhoun

. Sample Dependence Correction for Order Selection in fMRI Analysis. In 3rd IEEE International Symposium on Biomedical Imaging: Nano to Macro, Arlington, VA, USA, 2006, pp. 1072–1075.

29.

Lin

, Duann

, Feng

, et al. 2014. Revealing spatio-spectral electroencephalographic dynamics of musical mode and tempo perception by independent component analysis. J Neuroeng Rehabil, 11:18.

30.

Liu

, Liu

, Wei

, et al. 2018. Effects of musical tempo on musicians' and non-musicians' emotional experience when listening to music. Front Psychol, 9:2118.

31.

Liu

, Tang

, Zhao

, et al. 2020. Neural activation of different music styles during emotion-evoking. Psychol Music. 0305735620968260.

32.

Lloyd

1982. Least squares quantization in PCM. IEEE Trans Inform Theory. 28:129–137.

33.

Matsunaga

, Kawamichi

, Koike

, et al. 2016. Structural and functional associations of the rostral anterior cingulate cortex with subjective happiness. Neuroimage, 134:132–141.

34.

McAuley

, Miller

. 2007. Picking up the pace: effects of global temporal context on sensitivity to the tempo of auditory sequences. Percept Psychophys, 69:709–718.

35.

Mitterschiffthaler

, Fu

, Dalton

, et al. 2007. A functional MRI study of happy and sad affective states induced by classical music. Hum Brain Mapp, 28:1150–1162.

36.

Nicolaou

, Malik

, Daly

, et al. 2017. Directed motor-auditory EEG connectivity is modulated by music tempo. Front Hum Neurosci, 11:502.

37.

Park

, Gutyrchik

, Bao

, et al. 2014. Differences between musicians and non-musicians in neuro-affective processing of sadness and fear expressed in music. Neurosci Lett, 566:120–124.

38.

Rachakonda

, Egolf

, Correa

, et al. 2007. Group ICA of fMRI toolbox (GIFT) manual. Dostupnez [cit. 2011-11-5].

39.

Raz

, Touroutoglou

, Wilson-Mendenhall

, et al. 2016. Functional connectivity dynamics during film viewing reveal common networks for different emotional experiences. Cogn Affect Behav Neurosci, 16:709–723.

40.

Repp

BH.

2001. Processes underlying adaptation to tempo changes in sensorimotor synchronization. Hum Mov Sci, 20:277–312.

41.

Sachs

, Habibi

, Damasio

, et al. 2020. Dynamic intersubject neural synchronization reflects affective responses to sad music. Neuroimage, 218:116512.

42.

Savage

, Loui

, Tarr

, et al. 2020. Music as a coevolved system for social bonding. Behav Brain Sci. 1–42.

43.

Singer

, Jacoby

, Lin

, et al. 2016. Common modulation of limbic network activation underlies musical emotions as they unfold. Neuroimage, 141:517–529.

44.

Sloboda

, Juslin

. 2001. Psychological perspectives on music and emotion. In: Juslin PN, Sloboda JA (eds.) Music and Emotion. Oxford University Press; pp. 71–104.

45.

Smith

, Miller

, Salimi-Khorshidi

, et al. 2011. Network modelling methods for FMRI. Neuroimage, 54:875–891.

46.

Taruffi

, Pehrs

, Skouras

, et al. 2017. Effects of sad and happy music on mind-wandering and the default mode network. Sci Rep, 7:1–10.

47.

Thaut

, Trimarchi

, Parsons

. 2014. Human brain basis of musical rhythm perception: common and distinct neural substrates for meter, tempo, and pattern. Brain Sci, 4:428–452.

48.

Thomas

, Huber

, Stecker

, et al. 2015. Population receptive field estimates of human auditory cortex. Neuroimage, 105:428–439.

49.

Trochidis

, Bigand

. 2013. Investigation of the effect of mode and tempo on emotional responses to music using EEG power asymmetry. J Psychophysiol, 27:142.

50.

Van der Steen

, Jacoby

, et al. 2015. Sensorimotor synchronization with tempo-changing auditory sequences: modeling temporal adaptation and anticipation. Brain Res, 1626:66–87.

51.

Vuoskoski

, Thompson

, McIlwain

, et al. 2011. Who enjoys listening to sad music and why?. Music Percept, 29:311–317.

52.

Webster

, Weir

. 2005. Emotional responses to music: interactive effects of mode, texture, and tempo. Motiv Emot, 29:19–39.

53.

Yoon

, Verona

, Schlauch

, et al. 2020. Why do depressed people prefer sad music?. Emotion, 20:613.

54.

Yuan

, Lai

, Wu

, et al. 2009. A study on melody tempo with EEG. J Electron Sci Technol, 7:88–91.

55.

Zhu

, Liu

, Mathiak

, et al. 2019. Deriving electrophysiological brain network connectivity via tensor component analysis during freely listening to music. IEEE Trans Neural Syst Rehabil Eng, 28:409–418.

56.

Zuk

, Carney

, Lalor

. 2018. Preferred tempo and low-audio-frequency bias emerge from simulated sub-cortical processing of sounds with a musical beat. Front Neurosci, 12:349.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.41 MB

0.01 MB

0.02 MB

Dynamic Functional Network Connectivity Associated with Musical Emotions Evoked by Different Tempi