Individual vocal identity is enhanced by the enlarged external nose in male proboscis monkeys (Nasalis larvatus)

Yoshitani, Tomoki1; Miyazaki, Rintaro1; Seino, Satoru2; Edamura, Kazuya3; Murata, Koichi4; Matsuda, Ikki5; Nishimura, Takeshi 6 ; Tokuda, Isao1

Published Jul 01, 2025 on Dryad. https://doi.org/10.5061/dryad.5qfttdzj3

Data files

Jul 01, 2025 version files 1.01 GB

CTscans.zip
827.41 MB
README.md
4.11 KB
STL.zip
16.84 MB
SweeptoneMeasurement_ed02.zip
161.90 MB

Abstract

Adult male proboscis monkeys, Nasalis larvatus, develop an enlarged external nose. Males often produce loud, long-distance calls filtered through the nasal passage. The enlarged nose likely functions as a visual badge of social status and a visual key representing the owner’s physical and sexual quality and thus is useful for females in selecting mates. In addition to such visual signaling, a larger external nose enhances the lower frequencies in calls, possibly exaggerating acoustic signals related to body size. Here, we used computational simulations with three-dimensional models of the nasal passage to show how the external nose modifies the acoustic property, indicating that the external nose develops to enhance lower frequencies in adults but varies in a specific formant position among adult males. This finding suggests that the external nose generates acoustic signals about physical–sexual maturity in adult males and individual identity among them. The unusual features of the social organisation in this species, a patrilineality of a multilevel community consisting of one-male-multi-female units, may reinforce the functional importance of individual male recognition for males and females to monitor the location of both their own units and those of other males.

Dataset DOI: 10.5061/dryad.5qfttdzj3

Description of the data and file structure

CT scans, STL data of 3D model, and acoustic property calculated

Files and variables

File: CTscans.zip

Description: Frozen specimens of two male proboscis monkeys (adult Jaka and juvenile Niko) were thawed and scanned using a 320-row area detector CT scanner (Aquilion One™, Canon Medical Systems Corporation, Otawara, Japan) at Nihon University in Fujisawa, Japan, in 2016. The scans are in DICOM format. The scanning and reconstruction parameters are described in the header of each file.

File: STL.zip

Description: The nasal passage from the posterior and anterior naris area was extracted from each CT scans and the extracted area was transformed into a three-dimensional surface image in stereolithography (STL) format. The left and right nasal passages of each proboscis were computationally separated, and the side with few water and tissues was used for study after smoothing rough surfaces.

File: SweeptoneMeasurement.zip

Description: The acoustic properties of a replica model of the nasal passage which was created from the STL data were measured based on the method of Kitamura et al. (2009). The models were based on the geometric data used for computational estimation and created by a three-dimensional printer using acrylonitrile–butadiene–styrene resin. A sweep tone sound was generated from a loudspeaker (W3-881SJ; TB Speaker, Taipei, Taiwan) with an amplifier (PC200USB-HR; Fostex, Tokyo) and was inputted from the external nostril side. The distance between the loudspeaker and the external nose was set to 30 mm. The nasopharyngeal side was covered with a silicone plate (Smooth-Sil 940; Smooth-On, Macungie, USA), into which a probe microphone (Type 4182; Brüel & Kjaer, Naerum, Denmark) was inserted through a small hole and linked to a Nexus conditioning amplifier (Brüel & Kjaer). By covering the output, direct injection of the source sound into the microphone was avoided. Acoustic effects below the posterior nostril, such as the ventricle and the vocal tract, were also avoided so that only the acoustic effect of the nasal passage was measured.

Before measurement, the sweep tone sound was recorded externally to the nasal passage. To minimize environmental effects (e.g., frequency response and directivity of the microphone, reverberation, and room reflection), the input signal was corrected so that the sweep tone sound was generated with equal power at all frequencies. The corrected signal was applied to the nasal passage, and the output sound was recorded by a digital recorder with a sampling frequency of 44.1 kHz.

air_f.csv: Original sweep tone sound generated from a loudspeaker (W3-881SJ; TB Speaker, Taipei, Taiwan) with an amplifier (PC200USB-HR; Fostex, Tokyo). The frequency was increased from 100 Hz to 6000 Hz in 120 seconds. This sound was recorded by a probe microphone (Type 4182; Brüel & Kjær, Naerum, Denmark) in the absence of the replica model of the nasal cavity. The sampling frequency is 44.1 kHz. The physical unit for the recording time is seconds, whereas that of the microphone signal is voltage.

air_f.wav: Sound file converted from “air_f.csv.”

jaka.csv: Output sound recorded from the replica model of Jaka by the probe microphone (Type 4182; Brüel & Kjær, Naerum, Denmark). The sweep tone sound was input to the replica model from the external nostril side. The sampling frequency is 44.1 kHz. The physical unit for the recording time is seconds, whereas that of the microphone signal is voltage.

niko.csv: Output sound recorded from the replica model of Niko by the probe microphone (Type 4182; Brüel & Kjær, Naerum, Denmark). The sweep tone sound was input to the replica model from the external nostril side. The sampling frequency is 44.1 kHz. The physical unit for the recording time is seconds, whereas that of the microphone signal is voltage.