Complex vibratory patterns in an elephant larynx

Ct, Herbst; Švec, Jan G.; Lohscheller, Jörg; Frey, Roland; Gumpenberger, Michaela; Stoeger, Angela S.; Wt, Fitch

doi:10.1242/jeb.091009

Cited by 23 publications

(27 citation statements)

References 54 publications

(60 reference statements)

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“…Focusing on species that vocalize at these two extremes of the frequency range relevant in the animal realm, researchers found evidence that the production of infrasonic and ultrasonic vocalizations could be explained by the same mechanisms as those used in the human voice. For instance, Herbst and colleagues showed that infrasonic elephant rumbles result from MEAD-generated vocal fold oscillation, and that the infrasonic character of these oscillations is causally linked to the size and three-dimensional movements of these vocal folds (Herbst et al, 2012(Herbst et al, , 2013b. A similar conclusion was drawn regarding the production of ultrasonic vocalizations in rats by using ELE (Johnson et al, 2010) and intratracheal pressure and airflow measurements in anesthetized animals (Riede, 2011).…”

Section: Progressive Use Of Excised Larynx Experimentation In a Paralmentioning

confidence: 81%

“…To investigate such cases through ELE, special attention should be paid to avoid removing inner laryngeal tissue, in order to identify potential vibrating sources (e.g. Herbst et al (2013b) identified a 1:1 phase-locked vibration of vocal folds and ventricular folds in a elephant larynx). Another study using ELE on two red deer larynges documented increased glottal efficiency for non-regular vocal fold vibration regimes at high subglottal pressures, hypothetically suggesting an energetic advantage in animal vocal communication when converting metabolic to acoustic energy in this species (Herbst, 2014).…”

Section: Progressive Use Of Excised Larynx Experimentation In a Paralmentioning

confidence: 99%

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Excised larynx experimentation: history, current developments, and prospects for bioacoustic research

Garcia

Herbst

2018

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The study of sound production mechanisms is a crucial, yet understudied, aspect of vocal communication research in vertebrates. In excised larynx experimentation (ELE), phonation is simulated ex vivo by forcing air through a larynx specimen mounted on a laboratory bench. The method provides unique insights into vocal production and allows inference of in vivo conditions. Here, we provide a historical overview of how this technique has been implemented, from antiquity to current state-of-theart setups. We review the advances made by applying ELE to human voice and biophysics research. We then highlight the promising research output resulting from ELE in animal bioacoustics, a research field that has largely overlooked the use of this method until very recently, but is now increasingly relying on this tool. We continue by discussing the limitations of ELE, depending on the focus of investigation. Finally, we suggest how this approach should be implemented and can be applied to various research questions. We conclude by underlining the value that ELE contributes to the comprehension of human voice as well as mammalian and avian vocal communication within an interdisciplinary approach.

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Section: Progressive Use Of Excised Larynx Experimentation In a Paralmentioning

confidence: 81%

Section: Progressive Use Of Excised Larynx Experimentation In a Paralmentioning

confidence: 99%

Excised larynx experimentation: history, current developments, and prospects for bioacoustic research

Garcia

Herbst

2018

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“…Experimental data testing these hypotheses directly on real air sacs are currently lacking. One possible area of research, which is likely to prove fruitful, is ex-vivo investigation of the effects of air sacs on call acoustics in excised larynx experiments (see Titze et al, 2010;Klemuk et al, 2011;Herbst et al, 2012Herbst et al, , 2013Bowling et al, 2017;Garcia et al, 2017). Another exciting area, which would provide data on vocal-fold vibration during natural vocalizations (thus accounting for the 'source' of the sound, and allowing for the 'filter' to be analysed -Fant, 1960;Chiba and Kajiyama, 1941), is invivo electroglottography (Brown and Cannito, 1995;Herbst and Dunn, 2018).…”

Section: The Function Of Air Sacs In Primate Vocal Communicationmentioning

confidence: 99%

Sexual selection and the loss of laryngeal air sacs during the evolution of speech

Dunn

2018

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One noteworthy, but unexplained, aspect of the evolution of human speech is the loss of laryngeal air sacs during hominin evolution. Very little is known about the adaptive significance of this curious trait, or the selection pressures that may have driven the evolution of air sacs among primates, and their later loss in Homo. Here, I review the literature on the loss of laryngeal air sacs during the evolution of speech, and argue that sexual selection may have been a key factor. Although air sacs do not fossilize, the presence or absence of air sacs appears to be correlated with the anatomy of the hyoid bone, and fossil hyoid evidence suggests that air sacs were lost in hominins between 3.3 million and 530000 years ago. Air sacs are hypothesized to have an acoustic function, and some authors have argued that hominins may have lost their air sacs because they would make speech less clear. In other primates, such as gorillas and howler monkeys, air sacs appear to play a role in acoustic size exaggeration and may be linked to reproductive competition. I explore the hypothesis that changes in social organization and mating system towards reduced male-male competition may have relaxed the selection pressure maintaining loud, low-frequency calls in hominins, making air sacs obsolete. While much of the above will remain hypothetical until more concrete data are gathered, we can speculate by saying that air sacs may not have been necessary for the type of quiet vocal interaction that typifies human communication. Perhaps more recent Homo species, with lower levels of sexual dimorphism and increased social tolerance and complexity, began to communicate in a more complex way, eventually leading to spoken language.

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“…Such relationships between structure and behavior can be analyzed with the phase diagram (also called phase plot, phase space, or structure-behavior diagram) (Sterman, 2000). A phase diagram plots two variables on a two-dimensional graph (Herbst et al, 2013) with independent and dependent variables plotted on the X and Y axes, respectively. Since understanding structurebehavior associations is an important prerequisite for designing policies (Davidsen, 1992), the dynamic relationships were explored between key variables in the model and their policy implications were analyzed.…”

Section: Structure-behavior Analysismentioning

confidence: 99%

Renewable energy technology diffusion: an analysis of photovoltaic-system support schemes in Medellín, Colombia

Radomes

Arango

2015

Journal of Cleaner Production

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Complex vibratory patterns in an elephant larynx

Cited by 23 publications

References 54 publications

Excised larynx experimentation: history, current developments, and prospects for bioacoustic research

Excised larynx experimentation: history, current developments, and prospects for bioacoustic research

Sexual selection and the loss of laryngeal air sacs during the evolution of speech

Renewable energy technology diffusion: an analysis of photovoltaic-system support schemes in Medellín, Colombia

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