The Effect of Makassar Folk Music on Cerebral Hemodynamics Measured by Transcranial Doppler
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Asian Institute of Research, Journal Publication, Journal Academics, Education Journal, Asian Institute
Asian Institute of Research, Journal Publication, Journal Academics, Education Journal, Asian Institute

Journal of Health and Medical Sciences

ISSN 2622-7258

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Published: 25 January 2022

The Effect of Makassar Folk Music on Cerebral Hemodynamics Measured by Transcranial Doppler

Andi Kurnia Bintang, David Gunawan, Jimmy

Hasanuddin University, Indonesia

journal of social and political sciences
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doi

10.31014/aior.1994.05.01.201

Pages: 1-7

Keywords: Cerebral Hemodynamics, Mean Flow Velocity, Music, Transcranial Doppler

Abstract

This study aimed to evaluate the effect of Makassar folk music on cerebral hemodynamics using transcranial doppler (TCD). This was an experimental study with a pre- and post-test design. The study was conducted on 30 subjects at the Sonology clinic of Wahidin Sudirohusodo Hospital, Makassar from August to September 2019. The subjects listened to either rock, classical, or Makassar folk music and cerebral hemodynamic parameters before and after listening were assessed using TCD. The results of the study show that there were significant changes in both the left and the right middle cerebral artery (MCA) mean flow velocity (MFV) after listening to three genres, with a p-value < 0.0001 for each genre. There was no significant difference between the changes observed in left MFV MCA compared to the one on the right side. The value of MFV change was not significantly different across genres. The results indicate that Makassar folk music has the same effect on increasing cerebral hemodynamics as classical music and rock music.

References

  1. Altenmuller, E., Marco-Pallares, J., Munte, T., & Schneider, S. (2009). Neural reorganization underlies improvement in stroke-induced motor dysfunction by music-supported therapy. Annals of the New York Academy of Sciences, 1169(1), 395–405.

  2. Antić, S., Jensen, U., Lovrenčić-Huzjan, A., Vuković, V., Mukhtarova, R., Verónica, S., Sáo, F., González Treviño, R., Jurašić, M.-J., & Santos, S. (2006). Changes of cerebral hemodynamics during music perception: A functional transcranial doppler study. Acta Clinica Croatica, 45(4), 301–307.

  3. Antić, S., Morović, S., Bašić Kes, V., Zavoreo, I., Jurašić, M. J., & Demarin, V. (2012). Enhancement of stroke recovery by music. Periodicum Biologorum, 114(3), 397–401.

  4. Bernardi, L., Porta, C., & Sleight, P. (2006). Cardiovascular, cerebrovascular, and respiratory changes induced by different types of music in musicians and non-musicians: The importance of silence. Heart, 92(4), 445–452.

  5. Carod Artal, F. J., Cabrera, C. V., & Horan, T. A. (2004). Lateralization of cerebral blood flow velocity changes during auditory stimulation: A functional transcranial Doppler study. Applied Neuropsychology, 11(3), 167–174.

  6. Chanda, M. L., & Levitin, D. J. (2013). The neurochemistry of music. Trends in Cognitive Sciences, 17(4), 179–193.

  7. Csiba, L., & Baracchini, C. (2016). Manual of neurosonology. Cambridge University Press.

  8. Hsu, W.-C., & Lai, H.-L. (2004). Effects of music on major depression in psychiatric inpatients. Archives of Psychiatric Nursing, 18(5), 193–199.

  9. Koelsch, S. (2010). Towards a neural basis of music-evoked emotions. Trends in Cognitive Sciences, 14(3), 131–137.

  10. Marinoni, M., Grassi, E., Latorraca, S., Caruso, A., & Sorbi, S. (2000). Music and cerebral hemodynamics. Journal of Clinical Neuroscience, 7(5), 425–428.

  11. Matteis, M., Silvestrini, M., Troisi, E., Cupini, L. M., & Caltagirone, C. (1997). Transcranial doppler assessment of cerebral flow velocity during perception and recognition of melodies. Journal of the Neurological Sciences, 149(1), 57–61.

  12. Merrett, D. L., & Wilson, S. J. (2012). Music and Neural plasticity.

  13. Osuch, E. A., Bluhm, R. L., Williamson, P. C., Théberge, J., Densmore, M., & Neufeld, R. W. (2009). Brain activation to favorite music in healthy controls and depressed patients. Neuroreport, 20(13), 1204–1208.

  14. Raglio, A., Attardo, L., Gontero, G., Rollino, S., Groppo, E., & Granieri, E. (2015). Effects of music and music therapy on mood in neurological patients. World Journal of Psychiatry, 5(1), 68.

  15. Rickard, N. S., & McFerran, K. (2012). Lifelong engagement with music: Benefits for mental health and well-being. Nova Science Publishers.

  16. Rossini, P., Altamura, C., Ferretti, A., Vernieri, F., Zappasodi, F., Caulo, M., Pizzella, V., Del Gratta, C., Romani, G., & Tecchio, F. (2004). Does cerebrovascular disease affect the coupling between neuronal activity and local haemodynamics? Brain, 127(1), 99–110.

  17. Schöning, M., Scheel, P., Holzer, M., Fretschner, R., & Will, B. E. (2005). Volume measurement of cerebral blood flow: Assessment of cerebral circulatory arrest. Transplantation, 80(3), 326–331.

  18. Valdueza, J. (2017). Neurosonology and Neuroimaging of Stroke, a comprehensive reference. Fortschr Neurol Psychiatr, 85, 514.

  19. Vingerhoets, G., & Stroobant, N. (1999). Between-task habituation in functional transcranial Doppler ultrasonography. Neuroreport, 10(15), 3185–3189.

  20. Vollmer-Haase, J., Finke, K., Hartje, W., & Bulla-Hellwig, M. (1998). Hemispheric dominance in the processing of JS Bach fugues: A transcranial Doppler sonography (TCD) study with musicians. Neuropsychologia, 36(9), 857–867.

  21. Wang, S., & Agius, M. (2018). The neuroscience of music; a review and summary. Psychiatria Danubina, 30(7), 588–594.

  22. Webb, A. J. (2019). Effects of vasodilating medications on cerebral haemodynamics in health and disease: Systematic review and meta-analysis. Journal of Hypertension, 37(6), 1119.

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