Thoracic vibrations in stingless bees (<i>Melipona seminigra</i>):resonances of the thorax influence vibrations associated with flight but not those associated with sound production

Hrncir, Michael; Gravel, Anne-Isabelle; Schorkopf, Dirk Louis P.; Schmidt, Veronika; Zucchi, Ronaldo; Barth, Friedrich G.

doi:10.1242/jeb.013920

Cited by 38 publications

(72 citation statements)

References 31 publications

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“…Hymenopteran and coleopteran insects, which also contain asynchronous indirect flight muscles, show wing-related behaviors that are also suggestive of an actively controlled clutch. Bees thermoregulate by vibrating their thorax without moving their wings (Hrncir et al, 2008), and some beetles are capable of producing sound by vibrating their thorax with their wings folded (Leston et al, 1965). Both behaviors require insects to decouple their wings from the thorax, and are indicative of the presence of a clutch mechanism.…”

Section: Passive Mechanisms Coordinate Wing and Haltere Motionmentioning

confidence: 99%

Mechanics of the thorax in flies

Deora

Gundiah

Sane

2017

Journal of Experimental Biology

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Insects represent more than 60% of all multicellular life forms, and are easily among the most diverse and abundant organisms on earth. They evolved functional wings and the ability to fly, which enabled them to occupy diverse niches. Insects of the hyper-diverse orders show extreme miniaturization of their body size. The reduced body size, however, imposes steep constraints on flight ability, as their wings must flap faster to generate sufficient forces to stay aloft. Here, we discuss the various physiological and biomechanical adaptations of the thorax in flies which enabled them to overcome the myriad constraints of small body size, while ensuring very precise control of their wing motion. One such adaptation is the evolution of specialized myogenic or asynchronous muscles that power the high-frequency wing motion, in combination with neurogenic or synchronous steering muscles that control higher-order wing kinematic patterns. Additionally, passive cuticular linkages within the thorax coordinate fast and yet precise bilateral wing movement, in combination with an actively controlled clutch and gear system that enables flexible flight patterns. Thus, the study of thoracic biomechanics, along with the underlying sensory-motor processing, is central in understanding how the insect body form is adapted for flight.

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Section: Passive Mechanisms Coordinate Wing and Haltere Motionmentioning

confidence: 99%

Mechanics of the thorax in flies

Deora

Gundiah

Sane

2017

Journal of Experimental Biology

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“…; forager vibrations, 660·mm·s -1 ; average gain between thorax and wingtips: annoyance buzzing, 16.2·dB; forager vibrations, 17.9·dB) (Hrncir et al, 2008). The way that thoracic vibrations are transformed into airborne sounds, therefore, is very similar in these two types of vibrations.…”

Section: Materials and Methods Bees And Study Sitementioning

confidence: 91%

“…We therefore took the measurements (12 different measurement points above the bees or 24 different measurement points in the horizontal plane around the bees) in an arbitrary sequence to reduce any bias caused by potential differences in signalling due to increasing exhaustion of the bees along with the duration of a recording. Sling-tethered bees generated annoyance buzzing for about 10·min (Hrncir et al, 2008). In the present study, the recordings covered time periods between 3 and 5·min per investigated bee.…”

Section: Sound Field Generated By Vibrating Beesmentioning

confidence: 94%

“…Stingless bees Melipona seminigra Friese 1903 generate pulsed 'annoyance buzzing' when tethered with a sling around their neck (Hrncir et al, 2008). Although annoyance buzzing differed significantly with respect to both the main frequency component and the velocity amplitude from forager vibrations, the mechanism of generation is similar in these two types of vibrations.…”

Section: Materials and Methods Bees And Study Sitementioning

confidence: 99%

“…Whereas honey bees generate sounds with splayed wings during their dance movements, with the wing tips 5-9·mm apart (Michelsen, 2003), stingless bees generate thorax vibrations during both forager vibrations and annoyance buzzing with their wings closely folded over the abdomen (Lindauer and Kerr, 1958;Hrncir et al, 2006a;Hrncir et al, 2006b;Hrncir et al, 2008). Due to the folding of the wings, these are uncoupled from the indirect flight mechanism and, thus, their oscillation amplitude during 'buzzing' is strongly reduced compared to that during flight (Heinrich, 1993;King et al, 1996).…”

Section: Air Particle Movementmentioning

confidence: 99%

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The sound field generated by tethered stingless bees (Melipona scutellaris): inferences on its potential as a recruitment mechanism inside the hive

Hrncir

Schorkopf

Schmidt

et al. 2008

Journal of Experimental Biology

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SUMMARYIn stingless bees, recruitment of hive bees to food sources involves thoracic vibrations by foragers during trophallaxis. The temporal pattern of these vibrations correlates with the sugar concentration of the collected food. One possible pathway for transfering such information to nestmates is through airborne sound. In the present study, we investigated the transformation of thoracic vibrations into air particle velocity, sound pressure, and jet airflows in the stingless bee Melipona scutellaris. Whereas particle velocity and sound pressure were found all around and above vibrating individuals, there was no evidence for a jet airflow as with honey bees. The largest particle velocities were measured 5·mm above the wings (16.0±4.8·mm·s -1 ). Around a vibrating individual, we found maximum particle velocities of 8.6±3.0·mm·s -1 (horizontal particle velocity) in front of the beeʼs head and of 6.0±2.1·mm·s -1 (vertical particle velocity) behind its wings. Wing oscillations, which are mainly responsible for air particle movements in honey bees, significantly contributed to vertically oriented particle oscillations only close to the abdomen in M. scutellaris (distances р5·mm). Almost 80% of the hive bees attending trophallactic food transfers stayed within a range of 5·mm from the vibrating foragers. It remains to be shown, however, whether air particle velocity alone is strong enough to be detected by Johnstonʼs organ of the bee antenna. Taking the physiological properties of the honey beeʼs Johnstonʼs organ as the reference, M. scutellaris hive bees are able to detect the forager vibrations through particle movements at distances of up to 2·cm.

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Recruitment and Communication in Foraging

Grüter

2020

Stingless Bees

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Thoracic vibrations in stingless bees (Melipona seminigra):resonances of the thorax influence vibrations associated with flight but not those associated with sound production

Cited by 38 publications

References 31 publications

Mechanics of the thorax in flies

Mechanics of the thorax in flies

The sound field generated by tethered stingless bees (Melipona scutellaris): inferences on its potential as a recruitment mechanism inside the hive

Recruitment and Communication in Foraging

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