Comparative Histological Study of the Mammalian Facial Nucleus

Furutani, Rui; Sugita, Shoei

doi:10.1292/jvms.70.367

Cited by 6 publications

(9 citation statements)

References 21 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…( F ) Facial nucleus neuron number in mammals. Species averages are given in black [dots data ( 5 ); triangles data ( 6 )]. In red, data are given for individual African and Asian elephant facial nuclei; filled symbols (cell counts), empty symbols (facial nerve fiber counts), squares (stillborn elephants), dots (adult elephants) (see fig.…”

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Elephant facial motor control

et al. 2022

View full text Add to dashboard Cite

We studied facial motor control in elephants, animals with muscular dexterous trunks. Facial nucleus neurons (~54,000 in Asian elephants, ~63,000 in African elephants) outnumbered those of other land-living mammals. The large-eared African elephants had more medial facial subnucleus neurons than Asian elephants, reflecting a numerically more extensive ear-motor control. Elephant dorsal and lateral facial subnuclei were unusual in elongation, neuron numerosity, and a proximal-to-distal neuron size increase. We suggest that this subnucleus organization is related to trunk representation, with the huge distal neurons innervating the trunk tip with long axons. African elephants pinch objects with two trunk tip fingers, whereas Asian elephants grasp/wrap objects with larger parts of their trunk. Finger “motor foveae” and a positional bias of neurons toward the trunk tip representation in African elephant facial nuclei reflect their motor strategy. Thus, elephant brains reveal neural adaptations to facial morphology, body size, and dexterity.

show abstract

Section: Resultsmentioning

confidence: 99%

“…4D, bottom). Such cell size heterogeneity is unusual in mammalian facial subnuclei, which typically encompass neurons of similar size (5,6) trunk innervation may drive this cell-size gradient. In Fig.…”

Section: Dorsal and Lateral Subnuclei Show Cell-size Gradients Possib...mentioning

confidence: 99%

Elephant facial motor control

et al. 2022

View full text Add to dashboard Cite

show abstract

“…This cone is subdivided on both sides into different muscle layers, the texture of which is more or less the same throughout the consecutive layers. Looking closer, it seems likely that single layers of the nasal muscles or parts of these layers are innervated by individual branches or fiber bundles of the facial nerve and that these axons belong to specific neuron populations of the facial motor nucleus in the brain stem as is true for various components of the facial muscles in other mammals (Papez, 1927; Breathnach, 1960; Voogd et al, 1998; Sherwood, 2005; Furutani and Sugita, 2008). This hypothesis has to be tested in the future by careful comparative investigations including ungulates and cetaceans.…”

Section: Discussionmentioning

confidence: 99%

Functional Morphology of the Nasal Complex in the Harbor Porpoise (Phocoena phocoena L.)

Huggenberger

Rauschmann

Vogl

et al. 2009

The Anatomical Record

View full text Add to dashboard Cite

Toothed whales (Odontoceti, Cetacea) are the only aquatic mammals known to echolocate, and probably all of them are able to produce click sounds and to synthesize their echoes into a three-dimensional ''acoustic image'' of their environment. In contrast to other mammals, toothed whales generate their vocalizations (i.e., echolocation clicks) by a pneumatically-driven process in their nasal complex. This study is dedicated to a better understanding of sound generation and emission in toothed whales based on morphological documentation and bioacoustic interpretation. We present an extensive description of the nasal morphology including the nasal muscles in the harbor porpoise (Phocoena phocoena) using macroscopical dissections, computer-assisted tomography, magnetic resonance imaging, and histological sections. In general, the morphological data presented here substantiate and extend the unified ''phonic lips'' hypothesis of sound generation in toothed whales suggested by Cranford et al. (J Morphol 1996;228:223-285). There are, however, some morphological peculiarities in the porpoise nasal complex which might help explain the typical polycyclic structure of the clicks emitted. We hypothesize that the tough connective tissue capsule (porpoise capsule) surrounding the sound generating apparatus is a structural prerequisite for the production of these high-frequency clicks. The topography of the deep rostral nasal air sacs (anterior nasofrontal and premaxillary sacs), narrowing the potential acoustic pathway from the phonic lips to the melon (a large fat body in front of the nasal passage), and the surrounding musculature should be crucial factors in the formation of focused narrowbanded sound beams in the harbor porpoise. Anat Rec, 292:902-920, 2009. 2009 Wiley-Liss, Inc.

show abstract

“…This musculature is thought to have evolved from the jaw-and gill slit-opening muscles of primitive aquatic tetrapods, with sometimes extensive remodeling (Baisden et al, 1987;Guest et al, 2018;Hinrichsen and Watson, 1984) to support adaptations, such as eyelid-closing muscles in terrestrial animals, somatosensory whisking in mammals, and facial expression in humans (Diogo et al, 2008;Grant et al, 2012). The adaptation of the relative sizes of facial subnuclei to specific evolutionary needs in different mammalian species (Furutani and Sugita, 2008) suggests they may serve as organizing centers for facial nerve branches, and multiple studies indicate that individual facial branches map to specific subnuclei to varying extents (Baisden et al, 1987;Courville, 1966;Han et al, 2018;Martin and Lodge, 1977;Papez, 1927;Semba and Egger, 1986;Uemura-Sumi et al, 1986;Wang-Bennett and Coker, 1990). However, a comprehensive map of facial nucleus musculotopic organization in mouse is lacking.…”

Section: Introductionmentioning

confidence: 99%