Hippocampal plasticity during jaw movement conditioning in the rabbit

Hippocampal response patterns during discriminative eyeblink/jaw movement conditioning in the rabbit

Rabbits were given concurrent training in eyeblink (EB) and jaw movement (JM) conditioning in which 1 tone predicted an airpuff and another tone predicted water. After 10 days of discrimination training, the animals were given 10 days of reversal training. In the discrimination phase, acquisition of the 2 conditioned responses was not significantly different; however JM discrimination errors were much more frequent than were EB errors. In the reversal phase, correct performance on EB trials increased gradually, as was expected, whereas there was immediate behavioral reversal on JM trials. Differences in size and topography of dorsal CA1 multiple-unit responses reflected the ability of the hippocampus to discriminate between stimuli in trained animals, corresponding to the performance of the behavioral discrimination. During JM trials, the rhythmicity of the neural response was further modulated by the type of the prior trial, suggesting the coding of sequential events by the hippocampus. Thus, hippocampal conditioned activity can rapidly change its magnitude and pattern depending on the specific trial type during a concurrent EB/JM discrimination task and its reversal. (PsycINFO Database Record (c) 2008 APA, all rights reserved).

Differential mastication kinematics of the rabbit in response to food and water: implications for conditioned movement

Analysis of naturalistic chewing patterns may provide insight into mapping the neural substrates of jaw movement control systems, including their adaptive modification during the classically conditioned jaw movement (CJM) paradigm. Here, New Zealand White rabbits were administered food and water stimuli orally to evaluate the influence of stimulus consistency on masticatory pattern. Chewing patterns were recorded via video camera and movements were analyzed by computerized image analysis. The mandibular kinematics, specifically the extent of dorsal/ventral, medial/lateral, and rostral/caudal movement, were significantly larger in food-evoked than water-evoked chewing. Water-evoked chewing frequency, however, was significantly higher than that of food-evoked movements. In light of known cortical mastication modulatory centers, our findings implicate different neural substrates for the responses to food and water stimuli in the rabbit. A detailed delineation of jaw movement patterns and circuitry is essential to characterize the neural substrates of CJM.

Inactivation of the anterior cingulate cortex impairs extinction of rabbit jaw movement conditioning and prevents extinction-related inhibition of hippocampal activity

Although past research has highlighted the involvement of limbic structures such as the anterior cingulate cortex (ACC) and hippocampus in learning, few have addressed the nature of their interaction. The current study of rabbit jaw movement conditioning used a combination of reversible lesions and electrophysiology to examine the involvement of the hippocampus and the ACC during acquisition, performance, and extinction. We found that microinfusions of procaine into the ACC did not significantly alter the rate of behavioral learning or the amplitude of hippocampal conditioned unit responses, but that they disrupted the rhythmic periodicity of conditioned jaw movements. During extinction, whereas controls showed a rapid decline in behavioral CRs and active inhibition of hippocampal unit responses, ACC lesioned rabbits showed a persistence of conditioning-related hippocampal activity and behavioral responding. The results show that the ACC can be important for adaptive suppression of conditioned behavior and suggest a crucial physiological modulation of hippocampus by ACC during extinction.

Theta-contingent trial presentation accelerates learning rate and enhances hippocampal plasticity during trace eyeblink conditioning

Hippocampal theta activity has been established as a key predictor of acquisition rate in rabbit (Orcytolagus cuniculus) classical conditioning. The current study used an online brain--computer interface to administer conditioning trials only in the explicit presence or absence of spontaneous theta activity in the hippocampus-dependent task of trace conditioning. The findings indicate that animals given theta-contingent training learned significantly faster than those given nontheta-contingent training. In parallel with the behavioral results, the theta-triggered group, and not the nontheta-triggered group, exhibited profound increases in hippocampal conditioned unit responses early in training. The results not only suggest that theta-contingent training has a dramatic facilitory effect on trace conditioning but also implicate theta activity in enhancing the plasticity of hippocampal neurons.

Heart rate changes accompanying jaw movement Pavlovian conditioning in rabbits: concomitant blood pressure adjustments and effects of peripheral autonomic blockade

Two experiments were conducted to ascertain the cardiovascular accompaniments of differential Pavlovian jaw movement (JM) conditioning. The first examined the blood pressure (BP) changes that accompany the tachycardiac conditioned responses (CRs) associated with JM conditioning. The BP response in all instances consisted of a depressor response that was greater to the reinforced CS+ than CS-, although the magnitude of the CR was quite small. The second experiment determined the effects of peripheral autonomic antagonists on the cardiac accelerations associated with JM conditioning. It was found that the peripheral vagal antagonist methyl scopolamine completely abolished responses to both CS+ and CS-, whereas atenolol, a beta adrenergic antagonist, augmented the response, compared to saline control injections. The JM responses were also affected by the autonomic blockades, with minimal responding occurring in the scopolamine group but slightly more JM CRs in the atenolol group, compared to saline control animals. These results suggest that the major cardiovascular response to an appetitive stimulus, which evokes JM conditioning, consists of cardiac accelerations with the BP depressor responses playing a minimal, if any, role. Moreover, these conditioned cardiac increases appear to be due solely to the release of vagal inhibition.

Hippocampal theta oscillations and classical conditioning

Studies are reviewed that support a hypothesized role for hippocampal theta oscillations in the neural plasticity underlying behavioral learning. Begun in Richard F. Thompson's laboratory in the 1970s, these experiments have documented a relationship between free-running 3- to 7-Hz hippocampal slow waves (theta) and rates of acquisition in rabbit classical nictitating membrane (NM) conditioning. Lesion and drug manipulations of septohippocampal projections have affected NM and jaw movement conditioning in ways consistent with a theta-related brain state being an important modulator of behavioral acquisition. These findings provide essential empirical support for the recently developed neurobiological and computational models that posit an important role for rhythmic oscillations (such as theta) in cellular plasticity and behavioral learning.

Scopolamine disruption of behavioral and hippocampal responses in appetitive trace classical conditioning

Twelve young rabbits (3-6 months; Oryctolagus cuniculus) were classically conditioned in a trace jaw movement paradigm (300 ms tone, 450 ms trace, 200 ms intraoral water) after implantation of electrodes into area CA1 of dorsal hippocampus. Rabbits were divided into two groups and administered either 0.5 mg/kg scopolamine hydrobromide (HBr) or 0.5 mg/kg scopolamine methylbromide (MBr) subcutaneously before daily training sessions. Rabbits given HBr took significantly more trials to reach a behavioral criterion of eight conditioned responses in any nine consecutive trials than rabbits given MBr (P = 0.03). Conditioned, but not unconditioned, rhythmic jaw movement responses of the HBr group were of a lower frequency (Hz) than those of MBr rabbits (P = 0.02). The magnitude of hippocampal conditioning-related responses across the first 3 days of training was significantly smaller for HBr rabbits than for MBr rabbits (P = 0.02). These effects of central cholinergic blockade are similar to those reported for undrugged aging rabbits trained in the same paradigm (Seager MA, Borgnis RL, Berry SD. Neurobiol. Aging 1997;18(6):631 639).

Pavlovian heart rate and jaw movement conditioning in the rabbit: effects of medial prefrontal lesions

An experiment was conducted in which jaw movements (JM) and heart rate (HR) were concomitantly assessed in rabbits during simple Pavlovian conditioning. A 2-s 1200-Hz tone was the conditioned stimulus (CS) and an intraoral 1-cc pulse of 0.5 M sucrose-water solution was the unconditioned stimulus (US). Sham and medial prefrontal (mPFC)-lesioned animals received paired CS/US training with a 70- to 75-dB CS and were compared with sham- and mPFC-lesioned animals that received explicitly unpaired CS/US presentations. The percentages of JM CRs were significantly greater in the paired than the unpaired groups, but mPFC lesions had no effect on this measure. Conditioned HR decelerations occurred only in the paired groups and then only during the first session of training. Moreover, these CS-evoked cardiac decelerations were somewhat attenuated by the mPFC lesion. CS-evoked HR accelerations, which were significantly greater in unpaired than in paired animals, occurred during the four subsequent sessions. These results suggest that a CS-evoked cardioinhibitory process, mediated by the mPFC, is engendered by Pavlovian appetitive conditioning, as has been previously demonstrated for aversive conditioning. However, during JM conditioning these inhibitory changes are quickly replaced by tachycardia, possibly related to increased nonspecific somatomotor activity, since the tachycardia was somewhat greater in the unpaired animals.

Hippocampal age differences reoccur after modification of stimulus configurations in rabbit jaw movement conditioning

Rabbits of two age groups, young (3-7 months; n = 7) and aging (40-49 months; n = 7), were implanted with chronic recording electrodes in area CA1 of dorsal hippocampus and trained in a delay conditioned jaw movement (CJM) paradigm (after previously reaching criterion in a trace CJM paradigm with the same conditioned stimulus and unconditioned stimulus). Unlike results from the trace experiment, there was no significant difference in trials to behavioral criterion between the two age groups. There were large, but temporary, differences in the magnitude of conditioning-related hippocampal neural responses early in delay training. Aging rabbits' hippocampal responses were significantly smaller on Day 2 of delay training than corresponding responses of young rabbits (p = 0.0008). It is important to note that neural differences were not observed on Days 1 and 3 of delay training or at criterion performance in the prior trace conditioning. These results are interpreted in terms of age-related differences in hippocampal responsiveness to changes in biologically significant stimulus configurations.

Delayed acquisition of behavioral and hippocampal responses during jaw movement conditioning in aging rabbits

Young (3-7 months; n = 7) and aging (40-49 months; n = 7) rabbits (Oryctolagus cuniculus) were classically conditioned in a trace jaw movement paradigm (300 ms tone, 450 ms trace, 200 ms intraoral water) after implantation of electrodes into area CAI of dorsal hippocampus. Aging rabbits took significantly more trials to reach a behavioral criterion of 8 conditioned responses in any 9 consecutive trials than young rabbits (p = 0.04), and their conditioned, but not unconditioned, jaw movement responses were of a lower frequency than those of young rabbits (p = 0.02). Early in training, aging rabbits' hippocampal responses were significantly smaller just before water onset than corresponding responses of young rabbits (p = .03). The magnitude of this response was negatively correlated with trials to criterion (r = -0.60, p = 0.03). These results are interpreted in terms of age-related differences in the hippocampal contribution to jaw movement learning.

Behavioral and hippocampal evoked responses in an auditory oddball situation when an unconditioned stimulus is paired with deviant tones in the cat: experiment II

Event-related potentials (ERP) in the areas CA1, CA3 and dentate fascia (Df) of the hippocampal formation were recorded during an oddball situation in the cat. A rewarding electrical stimulation of the lateral hypothalamus (US) was paired with deviant tones (2500 Hz) that occurred randomly in a series of the standard tones (2000 Hz) given to the left ear. In addition to developing orienting head movements to the side of the deviant tones, an increase in the amplitude of parallel hippocampal ERPs was observed. Both the behavioral and neural responses appeared not until a 50 ms latency range. Furthermore, time-amplitude characteristics of the ERPs corresponded to time-acceleration characteristics of the conditioned orienting head movements. The results are discussed in the context of a cat analogue of the human mismatch negativity (MMN) and a role of the hippocampal formation to model and predict the conditioned behavioral orienting responses.

Age-dependent taste preferences in rabbits for a .025% sodium saccharin solution: preliminary findings

Classical conditioning of rhythmic jaw movements in rabbits is an accepted model of associative learning that may be useful in assessing age-related changes in learning and motivation. A saccharin solution has been thought to be rewarding to rabbits and is often used as an unconditioned stimulus (US). To determine whether age-related differences in preference for saccharin exist, we assessed (a) saccharin versus water preferences and (b) fluid intake level differences (which might account for differing drive levels) in young (4-6 months) and old (31-69 months) rabbits. Young animals demonstrated a significant preference for water, whereas old animals strongly preferred the saccharin solution. There were no differences between young and old rabbits in overall fluid intake. These results suggest that whereas saccharin may be an appetitive US for old rabbits, it may be aversive to young ones. Thus aging may affect the incentive value of rewarding stimuli, complicating the interpretation of interactions among aging, learning, and motivational processes.