Recoverable and nonrecoverable deficits in conditioned responses after cerebellar cortical lesions

Harvey, J A; Welsh, JP; Yeo, Ch; Romano, Anthony G.

doi:10.1523/jneurosci.13-04-01624.1993

Cited by 65 publications

(47 citation statements)

References 48 publications

(76 reference statements)

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“…compared with the modest effect observed in New Zealand White rabbits used in all other experiments (Clark and Lavond 1994). More recent data from Yeo and associates, however, suggest that the prelesion CR frequency is recoverable to some degree in Dutch belted rabbits with postlesion training, but that a concomitant decrease in CR amplitude does not recover with additional training (Harvey et al 1990;Yeo and Hardiman 1992;Gruart and Yeo 1995). The effects of HVI lesions on CR amplitude remain in dispute, although the converging evidence suggests that unilateral lesions minimally disrupt retention of the CR Lavond et al 1987;Clark et al 1990;Perrett and Mauk 1995).…”

Section: Hvi and Cr Acquisition And Expressionmentioning

confidence: 84%

“…Some of the earliest studies to target this region were performed by Yeo and colleagues, and the results suggested that selective lesions of HVI or HVI and the ansiform lobule completely block expression of the conditioned response in well trained animals (Yeo et al 1984(Yeo et al , 1985bHardiman et al 1988;Yeo and Hardiman 1988). Subsequent attempts to replicate this result have proven unsuccessful; however, even when the complex conditioning protocol used in the Yeo et al studies is employed Lavond et al 1987;Clark et al 1990;Harvey et al 1993;Perrett and Mauk 1995).…”

Section: Hvi and Cr Acquisition And Expressionmentioning

confidence: 99%

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Neural Substrates of Eyeblink Conditioning: Acquisition and Retention

Christian¹,

Thompson²

2003

Learn. Mem.

564

473

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Classical conditioning of the eyeblink reflex to a neutral stimulus that predicts an aversive stimulus is a basic form of associative learning. Acquisition and retention of this learned response require the cerebellum and associated sensory and motor pathways and engage several other brain regions including the hippocampus, neocortex, neostriatum, septum, and amygdala. The cerebellum and its associated circuitry form the essential neural system for delay eyeblink conditioning. Trace eyeblink conditioning, a learning paradigm in which the conditioned and unconditioned stimuli are noncontiguous, requires both the cerebellum and the hippocampus and exhibits striking parallels to declarative memory formation in humans. Identification of the neural structures critical to the development and maintenance of the conditioned eyeblink response is an essential precursor to the investigation of the mechanisms responsible for the formation of these associative memories. In this review, we describe the evidence used to identify the neural substrates of classical eyeblink conditioning and potential mechanisms of memory formation in critical regions of the hippocampus and cerebellum. Addressing a central goal of behavioral neuroscience, exploitation of this simple yet robust model of learning and memory has yielded one of the most comprehensive descriptions to date of the physical basis of a learned behavior in mammals.

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Section: Hvi and Cr Acquisition And Expressionmentioning

confidence: 84%

Section: Hvi and Cr Acquisition And Expressionmentioning

confidence: 99%

Neural Substrates of Eyeblink Conditioning: Acquisition and Retention

Christian¹,

Thompson²

2003

Learn. Mem.

564

473

View full text Add to dashboard Cite

show abstract

“…Finally, the results of the cortical-lesioned group deserve additional comment in this context since different results have been obtained and different interpretations have been offered for conditioning of the nictitating membrane when the cerebellar cortex has been lesioned (Clark & Lavond, 1994;Dersarkissian, Logan, & Thompson, 1995;Glickstein, 1992;Hardiman & Yeo, 1992;Harvey, Welsh, Yeo, & Romano, 1993). Given all of this information, we cannot conclude at the present time that the cerebellar cortex is not necessary for concurrent TAL and, on the contrary, it appears to meet the essential requirements for participating in the acquisition process, as can be deduced from anatomical, electrophysiological, and other behavioral studies (Black, Isaacs, Anderson, Alcantara, & Greenough, 1990;Kim & Thompson, 1997;Schreurs, Sanchez-Andres, & Alkon, 1991).…”

Section: Discussionmentioning

confidence: 99%

Inferior Olive Lesions Impair Concurrent Taste Aversion Learning in Rats

Mediavilla

Molina

Puerto

1999

Neurobiology of Learning and Memory

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Taste aversion learning can be established according to two different procedures, concurrent and sequential. For the concurrent task, two different taste stimuli are offered at the same time, one associated with simultaneous intragastric administration of an aversive stimulus and the other associated with physiological saline. This discrimination is learned by sham-lesioned control animals and by animals with lesions in the cerebellar cortex but not by rats lesioned in the inferior olive. At the same time, animals with lesions in the inferior olive and sham-lesioned animals achieve sequential learning when the gustatory stimuli are offered individually during each daily session. The results obtained show that electrolytic lesions in the inferior olive impair acquisition of concurrent learning and are analyzed in terms of an anatomical system consisting of the vagus nerve, inferior olive, and cerebellum, which differentiates between the two modalities of taste aversion learning, concurrent and sequential.

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“…Figure 6 shows example photographs of the cerebellar cortex for saline and OX7-saporin rats. The moderate cell loss in the inferior olive associated with Purkinje cell depletion is also seen following cerebellar cortical lesions (Harvey et al, 1993;Lavond et al, 1987;Woodruff-Pak et al, 1993;Yeo et al, 1985) and in pcd mice (Chen, Bao, Lockard, Kim, & Thompson, 1996;Chen, Bao, & Thompson, 1999). Other components of the eyeblink conditioning circuitry, including the cochlear nuclei, pontine nuclei, red nucleus, facial motor nucleus, and deep nuclei (see below), were unaffected by OX7-saporin.…”

Section: General Histologymentioning

confidence: 94%

Purkinje Cell Loss by OX7-Saporin Impairs Excitatory and Inhibitory Eyeblink Conditioning.

Nolan¹,

Freeman²

2005

Behavioral Neuroscience

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Cerebellar cortical contributions to eyeblink conditioned excitation have been examined extensively. In contrast, very little evidence exists concerning the role of the cerebellar cortex in eyeblink conditioned inhibition. In the current study, rats were given intraventricular infusions of the immunotoxin OX7-saporin to selectively destroy Purkinje cells throughout the cerebellar cortex following excitatory conditioning. After a 2-week postinfusion period, the rats were given reacquisition training. After reacquiring excitatory conditioning, the rats were trained in a featurenegative discrimination procedure to establish conditioned inhibition. Rats treated with OX7-saporin showed impaired reacquisition of excitatory conditioning and acquisition of conditioned inhibition. The results suggest that Purkinje cells play important, but different, roles in conditioned excitation and inhibition in rats.

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Recoverable and nonrecoverable deficits in conditioned responses after cerebellar cortical lesions

Cited by 65 publications

References 48 publications

Neural Substrates of Eyeblink Conditioning: Acquisition and Retention

Neural Substrates of Eyeblink Conditioning: Acquisition and Retention

Inferior Olive Lesions Impair Concurrent Taste Aversion Learning in Rats

Purkinje Cell Loss by OX7-Saporin Impairs Excitatory and Inhibitory Eyeblink Conditioning.

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