Neuronal unit activity in the abducens nucleus during classical conditioning of the nictitating membrane response in the rabbit (Oryctolagus cuniculus).

Cegavske, Craig F.; Patterson, Michael M.; Thompson, Richard F.

doi:10.1037/h0077601

Cited by 65 publications

(33 citation statements)

References 30 publications

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“…In mapping, we typically record multiple-unit activity, but isol~ted single-unit recording can also be done using higher impedance microelectrodes. Vnit discharges are converted to standard pulses and stored and analyzed in a computer, as described previously (Berger & Thompson, 1978;Cegavske, Patterson. & Thompson, 1979).…”

Section: Methodsmentioning

confidence: 99%

Effects of ipsilateral rostral pontine reticular lesions on retention of classically conditioned nictitating membrane and eyelid responses

et al. 1981

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Section: Methodsmentioning

confidence: 99%

Effects of ipsilateral rostral pontine reticular lesions on retention of classically conditioned nictitating membrane and eyelid responses

et al. 1981

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“…First, Lorente de No reported more than 50 years ago, in quite a different context, that cornea1 stimulation caused activation of the retractor bulbi as well as the other six extraocular muscles in rabbit. Cegavske et al (1976Cegavske et al ( , 1979 had reported that abducens multiple units were highly correlated with conditioned and unconditioned NM extension in the rabbit. Later, Harrison et al (1976) reported the same phenomenon for oculomotor nucleus multiple units.…”

Section: Discussionmentioning

confidence: 99%

Accessory abducens nucleus and conditioned eye retraction/nictitating membrane extension in rabbit

Disterhoft¹,

Kj²,

Weiss³

et al. 1985

J. Neurosci.

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The role of accessory abducens nucleus neurons in the conditioned eye retraction/nictitating membrane extension response was defined in the rabbit. Horseradish peroxidase injections into the retractor bulbi muscle showed that accessory abducens nucleus is the principal location of its motorneurons. Single and multiple unit recording in accessory abducens indicated that these motor neurons show a marked responsiveness to cornea1 and periorbital stimulation and fire in close correlation with conditioned, unconditioned, or spontaneous eye retraction/nictitating membrane extension. Complete lesions of accessory abducens showed, at most, a partial reduction of the conditioned and unconditioned eye retraction response. Section of the extraocular muscles, other than retractor bulbi, also caused a partial reduction of the eye retraction response. Accessory abducens lesions, combined with extraocular muscle section, were necessary to dramatically reduce the eye retraction response permanently. These experiments demonstrated that accessory abducens is a primary controller of eye retraction through its axons to retractor bulbi. The other extraocular muscles act in concert with retractor bulbi to elicit conditioned and unconditioned eye retractions.Analysis of the neural substrates of associative learning in mammalian brain is a complex problem. The use of a relatively simple behavioral paradigm in which the stimuli to be associated are easily controlled, in which at least one behavioral output is readily measured, and in which physiological recordings may be made in the animal during and after learning will facilitate progress in understanding the learning process. The rabbit nictitating membrane (NM) preparation, which was originally described by Gormezano et al. (1962) has many characteristics making it desirable for use in physiological and anatomical studies of learning (Thompson, 1976; Disterhoft et al., 1977). It and closely related eyeblink conditioning (Woody and Brozek, 1969) have been adapted by several groups as "model systems" in which to study the systems neurophysiology of learning.A typical approach is to pair an auditory conditioned stimulus (CS) with a cornea1 air puff or periorbital shock unconditioned stimulus

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“…Initial studies of motor control of the reflex and conditioned responses focused on NM extension, actually eyeball retraction, controlled mostly (but not entirely) by the retractor bulbus muscle, innervated largely by axons of the sixth nerve originating in the accessory abducens (and to a much lesser extent, abducens) nuclei. However, the other extraocular muscles also contract synergistically with the retractor bulbus or relax in an antagonistic manner in the case of the levator palpebrae motor neurons (Cegavske et al 1976(Cegavske et al , 1979(Cegavske et al , 1987Berthier et al 1987;Disterhoft et al 1987). At the time there was much debate about the details of innervation of the retractor bulbus muscle, which in retrospect was somewhat irrelevant because the most prominent and sensitive component of the response is EMG activity in the orbicularis oculi muscle controlling external eyelid closure ), innervated by the seventh nerve from the facial nucleus.…”

Section: The Ur Pathwaysmentioning

confidence: 99%

Neural Substrates of Eyeblink Conditioning: Acquisition and Retention

Christian¹,

Thompson²

2003

Learn. Mem.

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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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Neuronal unit activity in the abducens nucleus during classical conditioning of the nictitating membrane response in the rabbit (Oryctolagus cuniculus).

Cited by 65 publications

References 30 publications

Effects of ipsilateral rostral pontine reticular lesions on retention of classically conditioned nictitating membrane and eyelid responses

Effects of ipsilateral rostral pontine reticular lesions on retention of classically conditioned nictitating membrane and eyelid responses

Accessory abducens nucleus and conditioned eye retraction/nictitating membrane extension in rabbit

Neural Substrates of Eyeblink Conditioning: Acquisition and Retention

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