Abstract
Rotational head motion in vertebrates is detected by the semicircular canal system, whose innervating primary afferent fibers carry information about movement in specific head planes. The semicircular canals have been qualitatively examined over a number of years, and the canal planes have been quantitatively characterized in several animal species. The present study first determined the geometric relationship between individual semicircular canals and between the canals and the stereotactic head planes in pigeons. Stereotactic measurements of multiple points along the circumference of the bony canals were taken, and the measured points fitted with a three-dimensional planar surface. Direction normals to the plane's surface were calculated and used to define angles between semicircular canal pairs. Because of the unusual shape of the anterior semicircular canals in pigeons, two planes, a major and a minor, were fitted to the canal's course. Calculated angle values for all canals indicated that the horizontal and posterior semicircular canals are nearly orthogonal, but the anterior canals have substantial deviations from orthogonality with other canal planes. Next, the responses of the afferent fibers that innervate each of the semicircular canals to 0.5 Hz sinusoidal rotation about an earth-vertical axis were obtained. The head orientation relative to the rotation axis was systematically varied so that directions of maximum sensitivity for each canal afferent could be determined. These sensitivity vectors were then compared with the canal plane direction normals. The afferents that innervated specific semicircular canals formed homogeneous clusters of sensitivity vectors in different head planes. The horizontal and posterior afferents had average sensitivity vectors that were largely coincident with the innervated canal plane direction normals. Anterior canal afferents, however, appeared to synthesize contributions from the major and minor plane components of the bony canal structure to produce a resultant sensitivity vector that was positioned between the canal planes. Calculated angles between the average canal afferent sensitivity vectors revealed that direction orthogonality is preserved at the afferent signal level, even though deviations from canal plane orthogonality exist.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Anastasio TJ, Correia MJ, Perachio AA (1985) Spontaneous and driven responses of semicircular canal primary afferents in the unanesthetized pigeon. J Neurophysiol 54:335–347
Bernstein MH, Duran HL, Pinshow B (1984) Extrapulmonary gas exchange enhances brain oxygen in pigeons. Science 226:564–566
Blanks RHI, Precht W (1976) Functional characterization of primary vestibular afferents in the frog. Exp Brain Res 25:369–390
Blanks RHI, Curthoys IS, Markham CH (1972) Planar relationships of semicircular canals in the cat. Am J Physiol 223:55–62
Blanks RHI, Curthoys IS, Markham CH (1975) Planar relationships of the semicircular canals in man. Acta Otolaryngol 80:185–196
Blanks RHI, Curthoys IS, Bennett ML, Markham CH (1985) Planar relationships of the semicircular canals in rhesus and squirrel monkeys. Brain Res 340:315–324
Brown RHJ (1952) The flight of birds. II. Wing function in relation to flight speed. J Exp Biol 30:90–103
Curthoys IS, Curthoys EJ, Blanks RHI, Markham CH (1975) The orientation of the semicircular canals in the guinea pig. Acta Otolaryngol 80:197–205
Dickman JD, Correia MJ (1989) Responses of pigeon horizontal semicircular canal afferent fibers. I. Step, trapezoid, and low-frequency sinusoid mechanical and rotational stimulation. J Neurophysiol 62: 1090–1101
Dickman JD, Correia MJ (1993) Bilateral communication between vestibular labyrinths in pigeons. Neuroscience 57:1097–1108
Erichsen JT, Hodos W, Evinger C, Bessette BB, Phillips SJ. (1989) Head orientation in pigeons: postural, locomotor, and visual determinants. Brain Behav Evol 33:268–278
Estes MS, Blanks RHI, Markham CH (1975) Physiologic characteristics of vestibular first-order canal neurons in the cat. I. Response plane determination and resting discharge characteristics. J Neurophysiol 38:1232–1249
Ezure K, Graf KW (1984a) A quantitative analysis of the spatial organization of the vestibulo-ocular reflexes in lateral- and frontal-eyed animals. I. Orientation of semicircular canals and extraocular muscles. Neuroscience 12:85–94
Ezure K, Graf KW (1984b) A quantitative analysis of the spatial organization of the vestibulo-ocular reflexes in lateral- and frontal-eyed animals. II. Neuronal networked underlying vestibulo-oculomotor coordination. Neuroscience 12:95–109
Fukushima K, Perlmutter SI, Baker JF, Peterson BW (1990) Spatial properties of second-order vestibulo-ocular relay neurons in the alert cat. Exp Brain Res 81:462–478
Graf W (1988) Motion detection in physical space and its peripheral and central representation. Ann N Y Acad Sci 545:154–169
Graf W, Waele C de, Vidal PP, Wang DH, Evinger C (1995) The orientation of the cervical vertebral column in unrestrained awake animals. Brain Behav Evol 45:209–231
Hart WL (1957) Analytic geometry and calculus. Heath, Boston
Hayward JN, Baker MA (1969) A comparative study of the role of the cerebral arterial blood in the regulation of brain temperature in five mammals. Brain Res 16:417–440
Jones GM, Spells KE (1963) A theoretical and comparative study of the functional dependence of the semicircular canal upon its physical dimensions. Proc R Soc [B] 157:403–419
Landolt JP, Correia MJ, Young ER, Cardin RPS, Sweet RC (1975) A scanning electron microscopic study of the morphology and geometry of neural surfaces and structures associated with the vestibular apparatus of the pigeon. J Comp Neurol 159:257–288
Melvill Jones G (1974) The functional significance of semicircular canal size. In: Kornhuber HH (ed) Vestibular system, part 1: Basic mechanisms. (Handbook of sensory physiology) Springer, New York Berlin Heidelberg, pp 171–184
Money KE, Correia MJ (1972) The vestibular system of the owl. Comp Biochem Physiol [A] 42: 353–358
Reisine H, Simpson JI, Henn V (1988) A geometric analysis of semicircular canals and induced activity in their peripheral afferents in the rhesus monkey. In: Cohen B, Henn V (ededs) Representation of three-dimensional space in the vestibular, oculomotor, and visual systems. New York Academy of Sciences, New York, pp 10–20
Retzius G (1884) Das Gehörorgan der Wirbelthiere. Morphologische-histologische Studien II. Das Gehörorgan der Reptilien, der Vögel und der Säugethiere. Samson and Wallin, Stockholm
Robinson DA (1982) The use of matrices in analyzing the three-dimensional behavior of the vestibulo-ocular reflex. Biol Cybern 46:53–66
Ross DA (1936) Electrical studies on the frog's labyrinth. J Physiol 86:117–146
Thomas RC, Wilson VJ (1965) Precise localization of renshaw cells with a new marking technique. Nature 206:211
Van Egmond AAH, Groen JJ, Jongkees LBW (1952) The function of the vestibular organ. Pract Otorhinolaryngol 14 [Suppl2]: 1–109
Vidal PP, Graf W, Berthoz A (1986) The orientation of the cervical vertebral column in unrestrained awake animals. Exp Brain Res 61:549–559
Wersäll J, Bagger-Sjoback D (1974) Morphology of the vestibular sense organ. In: Kornhuber HH (ed) Vestibular System, part 1: Basic mechanisms. (Handbook of Sensory Physiology) Springer, New York Berlin Heidelberg, pp 123–170
Wilson VJ, Melvill Jones G (1979) Mammalian vestibular physiology. Plenum Press, New York
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Dickman, J.D. Spatial orientation of semicircular canals and afferent sensitivity vectors in pigeons. Exp Brain Res 111, 8–20 (1996). https://doi.org/10.1007/BF00229550
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00229550