The Behavior of Animals. Группа авторов
Чтение книги онлайн.

Читать онлайн книгу The Behavior of Animals - Группа авторов страница 22

Название: The Behavior of Animals

Автор: Группа авторов

Издательство: John Wiley & Sons Limited

Жанр: Биология

Серия:

isbn: 9781119109525

isbn:

СКАЧАТЬ an experimental procedure enables one to measure a toad’s prey-catching activity in response to the visual feature in question and to change it, while other stimulus parameters are held constant. This allows one to evaluate the effect of this change on prey-category formation (Ewert 1974, 1984; see also Further Reading, Movie A2).

      Table 2.5 Constants α and β determining essential traits of the features (p,c)-relating-algorithm; k1 and k2 depending on other stimulus parameters and the toad’s prey-catching motivation. RB = prey-catching orienting activity [responses/30s]. (Ewert 1984).

      Variations in other stimulus parameters, e.g., movement direction (Figure 2.4), velocity, motion pattern, or background pattern (cf. Movie A2) influence a toad’s general prey-catching activity, but the basic effects of the configurational features p and c (Figure 2.8A, charts p,c) are invariant to those changes (Burghagen & Ewert 1982, 1983).

      Developmental studies showed that the features-relating-algorithm emerges—without prey-catching experience—after metamorphosis with transition from aquatic to terrestrial life (Traud 1983; cit. Ewert 1984). The principle is common to terrestrial anurans but shows species specificities (Burghagen 1979; Ewert & Burghagen 1969; cit. Ewert 1984).

       What does the eye tell its brain?

      Figure 2.9 Neuroimaging toad’s visual system. (A) Dorsal view of toad’s brain. A stimulus (S) traverses the receptive field (RF) of a retinal ganglion cell (G) of the right eye (E), whose optic nerve (ON) projects to left optic tectum (T) and pretectal thalamus (TH). R, receptor cells; DT, dorsal tectal lobe; VT, ventral tectal lobe; MP, telencephalic ventro-medial pallium; M, medulla oblongata. (B) Functional neuroimaging: 14C-2DG-uptake in brain transverse sections at levels a-d. (see also Suggested Reading, Movie A1). (a) After hand-conditioning of a right-eyed toad, left MP showed 14C-2DG-uptake toward the conditioned stimulus (Finkenstädt & Ewert 1988). (b) Toad escaping a predator stimulus showed strong 14C-2DG-uptake in DT and TH. (c) Toad stiffening toward a threat-like moving stripe presented to the right eye showed moderate 14C-2DG-uptake in left TH and less so in DT. (d) Toad binocularly snapping toward a prey-like stripe showed strong 14C-2DG-uptake bilaterally in VT (Finkenstädt et al. 1985.).

       In search of brain structures involved in feature detection

      A neuroimaging technique allows one to check the regional neural activities in response to prey or predator stimuli (Finkenstädt et al. 1985). If 14C-labeled 2-deoxy-D-glucose, 14C-2DG, was administered systemically to the toad, active neurons were confusing the 2-deoxy-D-glucose with glucose, hence taking it up, but failing in decomposing it like glucose. The more active neurons were, the greater the storage of 14C-2DG and thus the radioactivity measured in brain sections later on (Figure 2.9B; see also Suggested Reading, Movie A1).

      Figure 2.9 Bd shows a color-coded autoradiographic image of a transverse section through the midbrain of a toad snapping toward a prey-like stripe moving in the binocular field. Strong radioactivity was focused bilaterally on the ventrolateral tectum: “snapping-evoking areas” (Figure 2.9 Bd, VT). In a toad escaping from a moving large square, the overall radioactivity was high, strongest in tectal and pretectal/thalamic structures (Figure 2.9 Bb, DT and TH). This substantiates Tinbergen’s prediction that “neural orchestration” of the whole brain may participate in a stimulus-response. In a toad becoming stiffened toward a threat-like stripe moving in the right visual field, moderate radioactivity in the corresponding left pretectal thalamus was stronger than in the optic tectum (Figure 2.9 Bc).

       Configurational object perception involves parallel processing streams and their interaction

      Optic tectum and pretectal thalamus are involved СКАЧАТЬ