October 11, 2020
This paper presentation will describe a semester-long interdisciplinary research experience for university-level student composers and biologists that is co-taught by a music professor and a biology professor. A part of the Mutational Music Project, this unique beyond-the-classroom experience integrates scientific research in genetics with creative activity in music technology. Composers use techniques from the fields of sonification, algorithmic composition, and data-driven music to assist the biologists in the sonic realization of their projects. Working in groups that pair composers with biologists, the students are asked to create a project that addresses the following question: In what way(s) can basic processes of genetics and evolutionary biology (especially mutation) be effectively represented through musical processes? The presentation will provide an overview of the course and discussion of the technological tools and methodologies employed, as well as selected project examples.
Presentation Handout (pdf)
DUDYCHA BIOL 599
Topics in Biology: Chords and Codons, MW 2:20-3:35 pm
Coker Life Science Building, R202
Syllabus: pdf
| Jeff
Dudycha, Professor Department of Biological Sciences College of Arts and Sciences University of South Carolina dudycha@biol.sc.edu Website: www.tangledbank.org |
Reginald
Bain, Professor Composition & Theory School of Music University of South Carolina rbain@mozart.sc.edu Website: reginaldbain.com |
The schedule below lists the combined activities from BIOL 599 & MUSC 540/(737). For a complete listing of activities see the Spring 2020 BIOL 599 and MUSC 540 syllabi (above), respectively.
SPRING 2020
| Introductory Lectures/Activities | |
| Mon., Jan. 13 | Bio 1: Course Introduction |
| Wed., Jan. 15 | Music 1: Music as Organized Sound |
| Wed., Jan. 22 | Bio 2: Genetics Review |
| Mon., Jan. 27 | Music 2: Sonification and Data-Driven Music |
| Wed., Jan. 29 | Bio 3: Mutation |
| Mon., Feb. 3 | Music 3: Mutational Music Project Ideas |
| Meet the Composers | |
| Wed., Feb. 5 | Meet the Composers |
| Project Brainstorming | |
| Mon., Feb. 17 | Project Brainstorming |
| Wed., Feb. 19 | Bio Group 1-5 Consultations |
| Feb. 20 - March 3 | Bio-Music Group 1-5 Meetings |
The biologists and composers meet in their assigned groups from this point forward.
| Project Work, Progress Reports, and Consultations | |
| Wed., March 4 | Bio Group 1-5 Status Reports |
| Wed., March 18 | Written Progress Reports/Consultations |
| Wed., March 25 | Written Progress Reports/Consultations |
| Mon., April 6 | Written Progress Reports/Consultations |
| Mon., April 13 | Written Progress Reports/Consultations |
| Presentation | |
| Mon., May 4 | Bio Group 1-5 Project Presentations |
Final Report (Due: Wed., May 6, at noon)
The three music lectures covered:
Lecture 1: Music as Organized Sound
Lecture 2: Sonification and Data-Driven Music
Lecture 3: Mutational Music Project Ideas
The research experience was offered during the Spring 2018 and Spring 2020 terms. The collaborative biologist-composer research groups produced the following projects:
| Group | Biologists | Composers | Project Title |
| 1 | Libby Davenport Patrick Lawson |
Ian Jones Jacob Wylie |
The Harmonic Balance of Eat or Be Eaten |
| 2 | Kate Bothe Michelle St. John |
Bryce Owens Graeme Rosner |
Algorithmically-derived jazz from amino acid data |
| 3 | Jacob Brock Dexter Reasons |
Elizabeth Greener Hunter Vowell |
Mutations Sonified in a Fugue |
| 4 | Rishi Suresh Frank Webb |
Andrew Gretzinger
Peter Underhill |
SoniPhylogenies: Cytochrome B Sonification using BLOSUM |
| 5 | Abby Askins Jack Gabel |
Te-Wei Huang Jesse Kaiser |
What Does Parkinson's Sound Like? |
| Group | Biologists | Composers | Project Title (or Description) |
| 1 | Lauren Huffmire Kathryn Metts |
Thomas Palmer Morgan Soard |
A genetic sequence is directly mapped to a chord progression while implementing the properties of various mutations |
| 2 | Zach Spicer Matthew Waller |
Ryan Williams | Waltz Toward Disaster: A Representation of the Accumulation of Mutations Over Time |
| 3 | Rachel May Joel Strom |
Michael VanBuhler Robert Wilkinson |
A familiar melody is altered according to the rules of genetic mutation |
| 4 | Lexi Dickson Olivia Harris |
Jacob Wylie | Hearing the Silent: Musically Expressing Intronic Mutations |
The software tools used to create these projects include:
EXAMPLE 1. Algorithmically-derived jazz from
amino acid data
by biologists Kate Bothe & Michelle St. John, and composers Bryce
Owens & Graeme Rosner
Video description:
One of two jazz compositions produced for this project, the following
blues by Graeme Rosner was created from the AVPR1A gene, a gene associated
with musical creativity. {YouTube: https://youtu.be/oEARsVYB1mk}
Paul Rosner, drums
Nate Lee, trombone
Graeme Rosner, flügelhorn
You can learn more about the composer's process at:
https://www.graemerosner.com/avpr1a-blues
Data credit:
UniProt.org, UniProtKB - P37288 (V1AR_HUMAN), Protein: Vasopressin V1a
receptor; Gene: AVPR1A;
Available at: https://www.uniprot.org/uniprot/P37288#sequences
EXAMPLE 2. EEG
Sonification: What Does Parkinson's Sound Like?
by biologists Abby Askins & Jack Gabel, and composers Te-Wei
Huang & Jesse Kaiser
Audio recording description:
"This piece is a sonification of brain activity from five patients with
Parkinson's disease and five healthy controls. You are hearing a composite
of ten EEGs, with the pitch of the gamelan clustered for the two groups.
Differences in the pitch represent the 'freezing of gait' that each of
these Parkinson's patients experienced. This symptom has been shown to
attenuate theta-band power and increase beta-band power at the Cz
electrode during pedaling exercise. The audio is based on voltage measured
from the Cz electrode and only sonifies a small portion of the total data
displayed in the graphs."
Excerpt: A mp3 recording of the first 20 sec. of the 30 min. sonification
Data Credit:
EEG data obtained from: Singh, A., Cole, R. C., Espinoza, A. I., Brown,
D., Cavanagh, J. F., & Narayanan, N. (2020). "Frontal theta and beta
oscillations during lower-limb movement in Parkinson’s disease." Clinical
Neurophysiology.
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Special thanks to all of the students who participated in the Spring 2018 and Spring 2020 interdisciplinary research experiences.
The Mutational Music Project is the broader impact component of the National Science Foundation (NSF) grant Mutational variance of the transcriptome and the origins of phenotypic plasticity (NSF award #1556645), Jeff Dudycha, principle investigator. Reginald Bain is the other senior person on the grant.
