Lesions Of Ectostriatum Research Articles

Participation of the thalamofugal visual pathway in a coarse pattern discrimination task in an open arena

The purpose of this study was to examine the role of the thalamofugal pathway in far-field visual processing. Experiment 1 examined the role of the visual wulst and the ectostriatum in a far-field pattern discrimination task in a large open arena. Control pigeons, pigeons with ectostriatum lesions, and pigeons with wulst lesions were trained to discriminate between four patterns within the arena. Ectostriatum-lesioned pigeons were unimpaired and behaved similar to controls. By contrast, wulst-lesioned pigeons were severely impaired in the pattern discrimination task in the open arena and performed poorer than control pigeons and pigeons with ectostriatum lesions. Statistical analyses of regional contributions to the observed impairment identified the left visual wulst and bilateral hyperstriatum ventrale, which lies outside the wulst, as interesting areas. To ensure that the impairment was not due to a general learning deficit, experiment 2 involved training the pigeons in a pattern discrimination task carried out in an operant chamber, which presumably required use of near-field visual information. Wulst-lesioned pigeons were able to learn the task and performed at a level no different from control pigeons. The results of these experiments support the proposal that the wulst may be important for processing far-field information.

Effects of Wulst and ectostriatum lesions on repeated acquisition of spatial discrimination in pigeons

The avian telencephalon has two visual areas, (1) a ‘Wulst’ that consists of hyperstriatum accessorium, hyperstriatum intercalatus superior and hyperstriatum dorsale, and (2) the ectostriatum. Deficits in visual discrimination have been observed after ectostratal lesions but not after Wulst lesions. In the present experiments, the cognitive functions of the Wulst in pigeons were examined. Pigeons were trained on repeated acquisition of a three key discrimination. Every time the subjects reached the criterion of discrimination, they were trained on different discriminations in which one of two previously incorrect keys became the correct key. The Wulst lesions disrupted the acquisition of discrimination, while the ectostriatal lesions did not.

Color reversal-learning deficits after tectofugal pathway lesions in the pigeon telencephalon

Pigeons were post-operatively trained to discriminate two colors presented simultaneously. After reaching criterion on this task, they were required to perform a series of reversals of the color discrimination in which the positive and negative consequences of the stimuli were interchanged. Lesions of ectostriatum (the telencephalic target of the avian tectofugal visual pathway) impaired the ability of pigeons to learn a color-reversal task. An examination of the pattern of sparing and loss of performance on this task after lesions of various components of the ascending visual pathways suggests that deficits in color-reversal learning observed after lesions of the visual Wulst are not due to the Wulst's connections with the thalamofugal pathway. Instead, the data suggest that the visual Wulst maintains a role in color-reversal learning through its connections with the tectofugal pathway.

Intensity difference thresholds after lesions of ectostriatum in pigeons

Seven pigeons were trained to perform in a psychophysical procedure to determine the smallest difference in luminous intensity (intensity difference threshold) that they could discriminate. When their performance stabilized, lesions were made in the ectostriatum in 4 birds and in the neostriatum in the remaining 3 birds. After surgery, the pigeons with ectostriatum lesions showed markedly elevated thresholds. The neostriatum control cases showed only trivial threshold changes as a consequence of the surgery. A psychophysical scaling analysis showed that the ectostriatum-lesioned pigeons had lost from 50% to 83% of their preoperative capacity to discriminate differences in the intensity of visual stimuli. A multiple-regression analysis based on quantitative reconstructions of the lesions revealed that only damage to the core region of the ectostriatum contributed to the postoperative threshold changes.

Effects of serial lesions of telencephalic components of the visual system in pigeons.

A serial-lesion technique was used to investigate interactions in visual processing between telencephalic components of the pigeon visual system. Pigeons were trained to discriminate pairs of stimuli that differed in color, intensity or pattern. After mastering the discrimination tasks, they were assigned to one of three groups. The first group (WI-EII) received lesions of the visual Wulst and were retested. After the discrimination tasks were again mastered, a second set of lesions was made, this time in the ectostriatum. The birds were tested once again after the second surgery. The second group (EI-WII), underwent the same sequence of events except that the order of the lesions was reversed. In the third group (E + W), lesions of both the visual Wulst and ectostriatum were made in a single operation, followed by retesting. The performance after the first lesion of the subjects in each of the two-stage lesion groups was typical of performance after such lesions; i.e. the birds with visual-Wulst lesions showed little or no impairment on any of the tasks, whereas the pigeons with ectostriatum lesions showed considerable deficits in intensity and pattern discrimination, which diminished after prolonged retraining. In contrast, the pigeons in the one-stage group (E + W) showed profound deficits that appeared to be permanent. The performance after the second operation of the WI-EII group was the same as that of pigeons with lesions of ectostriatum alone; i.e. destruction of ectostriatum first or second resulted in the same duration of impairment. The performance of the EI-WII group after its visual Wulst lesion, however, was similar to that observed in the E + W group. The results are interpreted as a reflection of parallel processing within the avian visual system; i.e. the presence of an intact tectofugal pathway may mask the effects of thalamofugal pathway interruption.

Effects of unilateral neck deafferentation on the posturo-kinetic limb responses following cortical stimulation in the cat

Pigeons were post-operatively trained to discriminate two colors presented simultaneously. After reaching criterion on this task, they were required to perform a series of reversals of the color discrimination in which the positive and negative consequences of the stimuli were interchanged. Lesions of ectostriatum (the telencephalic target of the avian tectofugal visual pathway) impaired the ability of pigeons to learn a color-reversal task. An examination of the pattern of sparing and loss of performance on this task after lesions of various components of the ascending visual pathways suggests that deficits in color-reversal learning observed after lesions of the visual Wulst are not due to the Wulst's connections with the thalamofugal pathway. Instead, the data suggest that the visual Wulst maintains a role in color-reversal learning through its connections with the tectofugal pathway.

Learning and interocular transfer of visual discriminations following bilateral ectostriatum lesions in pigeons

Learning and interocular transfer of visual discriminations following bilateral ectostriatum lesions in pigeons

Visual intensity and pattern discrimination deficits after lesions of ectostriatum in pigeons.

AbstractEighteen pigeons were trained to discriminate between visual stimuli that differed in either intensity or pattern. Bilateral, electrolytic lesions were made in ectostriatum or the lateral neostriatum. Pigeons with ectostriatum lesions had severe post‐operative performance deficits. The magnitude of the deficit and the amount of post‐operative retraining necessary to restore the birds to pre‐operative performance levels varied directly with the amount of bilateral destruction of ectostriatum. Pigeons with little or no involvement of ectostriatum showed little or no change in discrimination performance post‐operatively. Similarities between morphological and functional organization of the reptilian, avian and mammalian visual systems are discussed.

Studies of avian visual pathways involved in cardiac conditioning: nucleus rotundus and ectostriatum.

The rotundo-ectostriatal pathway of the pigeon was investigated to determine its involvement in the visual pathway necessary for heart and respiratory rate conditioning. The study included 20 birds with bilateral electrolytic lesions of ectostriatum, 10 birds with bilateral electrolytic lesions of nucleus rotundus, and 10 surgical control birds. Following recovery from surgery, each bird was trained in a defensive conditioning situation in which light was paired with foot-shock, and changes in heart and respiratory rates were measured.