Application of scaling to mouse spontaneous movement: Path curvature varies with speed and linear distance features isochrony.

To conserve sequential behavior in relation to the topographic challenges of space, it is proposed that humans and nonhuman animals can organize behavior using different scaling principles. To deal with increases in linear distance, isochrony suggest that there is a corresponding increase in speed, whereas to deal with changes in curvature, speed is adjusted according to a power function. The present study investigates whether these principles provide a framework for describing the organization of mouse behavior in a variety of standard experimental tasks. The structure of movement was examined in ambulation during open field exploration; manipulation in a string-pulling task, in which a string is advanced hand over hand to retrieve food; and rung-walking, in which the limbs successively step from rung to rung on a horizontal ladder. Both principles were found to be conserved in the organization of mouse behavior across scales of movement. These principles provide novel measures of the temporal and geometric features of movement in the mouse and insights into how the temporal and geometric features of movement are conserved within different species.

The differential contributions of the parvocellular and the magnocellular subdivisions of the red nucleus to skilled reaching in the rat.

During the execution of the skilled reaching task, naïve rats bring their elbow to the midline of their body to aim at the food target, perform the arpeggio movement to grasp it and supinate the paw to bring the food to their mouth. Red nucleus lesions in the rat interfere with each of these three movement elements of reaching. On the other hand, lesions to the rubrospinal tract, which originate from the magnocellular subdivision of the red nucleus, only interfere with the arpeggio movement. This latter evidence strongly suggests that impairment in aiming and supinating could be under the control of the parvocellular subdivision of the red nucleus. In order to test this hypothesis, rats were trained on the skilled reaching task and then received either complete lesions of the red nucleus or lesions restricted to its parvo- or magnocellular subdivision. In line with previous data, complete excitotoxic lesions of the red nucleus compromised limb aiming, arpeggio and supination. Lesions restricted to the parvocellular division of the red nucleus abolish supination and interfere with aiming, although the latter result did not reach significance. The results are discussed in terms of the distinct connectivity and functional significance of these two architectonic subdivisions of the red nucleus.

Posterior hypothalamic nucleus deep brain stimulation restores locomotion in rats with haloperidol-induced akinesia but not skilled forelimb use in pellet reaching and lever pressing.

Recent studies have shown that electrical stimulation of the posterior hypothalamic nucleus (PH) facilitates locomotion in control rats, and rats were made akinetic by dopaminergic blockade via haloperidol or dopamine depletion by the neurotoxin 6-hydroxydopamine. These findings suggest that PH stimulation might be a promising treatment for akinesia associated with dopamine loss in Parkinson's disease. The present study further examined the positive effects of PH stimulation on behavior by characterizing its potential facilitatory effects on tasks that require skilled movements. Rats were trained to reach for food pellets with a forelimb (skilled reaching) or press a bar in an operant conditioning task for food. PH stimulation in undrugged rats not only facilitated locomotion in each of the tasks, but also impaired performance of the skilled movement components of the tasks. Haloperidol reduced locomotion and skilled movement, and PH stimulation only restored locomotion. The results are discussed in relation to the idea that PH stimulation selectively facilitates locomotor behavior and may have limited use in restoring impairments in skilled movements and consummatory behavior that results from dopaminergic depletion.

Thinning, movement, and volume loss of residual cortical tissue occurs after stroke in the adult rat as identified by histological and magnetic resonance imaging analysis.

Plasticity of residual cortical tissue has been identified as an important mediator of functional post-stroke recovery. Many studies have been directed toward describing biochemical, electrophysiological, and cytoarchitectural changes in residual cortex and correlating them with functional changes. Additionally, after neonatal stroke the thickness of residual tissue can change, the tissue can move, and tissue can fill in the stroke core. The purpose of the present study was to systematically investigate and document possible gross morphological changes in peri-infarct tissue after forelimb motor cortex stroke in the adult rat. Rats received a unilateral forelimb motor cortex stroke of equivalent size by pial strip devascularization or photothrombotic occlusion and were then examined using histology or magnetic resonance imaging (MRI) at 1 h, 1, 3, 7, 14, or 31 days post-stroke. Middle cerebral artery occlusion was used as a control stroke procedure. Decreases in cortical thickness, volume, and neural density were found to extend far beyond the stroke infarct and included most of the sensorimotor regions of the stroke and intact hemispheres. Movement of residual tissue towards the infarct was observed and confirmed using anatomical markers placed in intact cortical tissue at the time of stroke induction. The results are discussed in relation to the idea that extensive time-dependent morphological changes that occur in residual tissue must be considered when evaluating plasticity-related cortical changes associated with post-stroke recovery of function.

Compensation aids skilled reaching in aging and in recovery from forelimb motor cortex stroke in the rat.

Compensatory movements mediate success in skilled reaching for food after stroke to the forelimb region of motor cortex (MtCx) in the rat. The present study asks whether the neural plasticity that enables compensation after motor stroke is preserved in aging. In order to avoid potential confounding effects of age-related negative-learning, rats were trained in a single pellet reaching task during young-adulthood. Subgroups were retested before and after contralateral forelimb MtCx stroke via pial stripping given at 3, 18, or 23 months of age. Over a two-month post-stroke rehabilitation period, end point measures were made of learned nonuse, recovery, retention, and performance ratings were made of reaching movement elements. Prior to stroke, young and aged rats maintained equivalent end point performance but older rats displayed compensatory changes in limb use as measured with ratings of the elements of forelimb movement. Following stroke, the aged groups of rats were more impaired on end point, movement, and anatomical measures. Nevertheless, the aged rats displayed substantial recovery via the use of compensatory movements. Thus, this study demonstrates that the neural plasticity that mediates compensatory movements after stroke in young adults is preserved prior to and following stroke in aging.

Acute but not chronic differences in skilled reaching for food following motor cortex devascularization vs. photothrombotic stroke in the rat.

The variability in the behavioral outcome of human and nonhuman animals after stroke raises the question whether the way that a stroke occurs is a contributing factor. Photothrombotic stroke in rats has been reported to produce especially variable results, with some animals showing either slight to no impairment to other animals displaying severe impairments. The present study investigated this variability. Rats received three different-sized photothrombotic treatments and were contrasted to rats receiving a "standard" motor cortex stroke produced by pial stripping. Rats were assessed acutely and chronically on a skilled reaching for food task using end-point measures and movement assessment in a constraint-induced rehabilitation paradigm. The results indicated that as the size of the photothrombotic infarct approached the size of the pial strip infarct so did chronic behavioral deficits. Nevertheless there were differences in the time course of recovery. Rats with photothrombotic lesions of all sizes were less impaired in the acute period of recovery both on measures of learned nonuse and constrained-induced recovery. The findings are discussed in relation to the idea that whereas the course of recovery might be altered as a function of the type of stroke, chronic deficits are more closely related to the ensuing damage.

Neurotoxic lesions of the caudate-putamen on a reaching for food task in the rat: acute sensorimotor neglect and chronic qualitative motor impairment follow lateral lesions and improved success follows medial lesions.

Reaching for food, or skilled reaching, is used as a test of basal ganglia function in preclinical studies as well as studies of human neurological conditions. Although changes in the end-point measure of success document the effects of neurotoxic cellular damage to the caudate-putamen and its treatment in rodents, there has been no examination of the cause of change in success after neurotoxic lesions of the striatum. This objective was addressed in the present study, in which rats trained to reach for single food pellets with one forelimb, received contralateral quinolinic acid or ibotenic acid lesions of the medial and lateral caudate-putamen. Over 21 postsurgical days, reaching performance was scored for success and qualitative changes in movement elements were examined using frame-by-frame video analysis. In the acute postoperative period, extending over 3 to 4 days, the rats with lateral lesions transported their forelimb and grasped the food, but then ignored the food and did not withdraw their limb to their mouth. After recovery of the withdrawal movement, the rats displayed chronic qualitative impairments in the rotatory movements of aiming, pronating, and supinating the forepaw. Medial quinolinic lesions improved success relative to control rats and did not change qualitative aspects of limb movement. The acute dissociation between transport and withdrawal, the chronic qualitative changes in movement elements, and the differential effect of medial and lateral injury on success, support a complex contribution of the caudate-putamen to skilled reaching that includes sensorimotor neglect, and quantitative and qualitative motoric changes.

Subcortical middle cerebral artery ischemia abolishes the digit flexion and closing used for grasping in rat skilled reaching.

That rats reach for and grasp a food item using a single paw has prompted their use in neurobiological studies of skilled movements and modeling neural injury including middle cerebral artery stroke. Although motor system lesions have been shown to disrupt various qualitative aspects of the transport of a limb to a food target and withdrawal of the limb with the food, no lesion has been found to abolish digit flexion for grasping. Here, rats received unilateral transient middle cerebral artery ischemia that was restricted mainly to subcortical tissue of the forebrain (caudate-putamen, globus pallidus, and associated fibers) or a sham operation. Both paws were later trained and evaluated on skilled reaching using a rating scale for digit use. Middle cerebral artery rats did not flex and close their digits to grasp food when using their contralateral-to-lesion limb. The grasp impairment was not due to a failure to learn the task as middle cerebral artery rats used the ipsilateral limb as successfully as control rats and they were reinforced for reaching by raking food into the reaching box using an open paw. The impairment was also not due to an inability to move the digits, as they were flexed and closed in other phases of the reach. The paradigm should prove useful for further studies of rehabilitation in relation to the idea that digit closure may be controlled by the joint action of a number of neural systems that converge in the basal ganglia.

Reducing stability of support structure for a target does not alter reach kinematics among younger adults.

Investigation into the reach-to-grasp movement has indicated that this movement sequence is composed of two distinct movement components, independently influenced by the characteristics of the target. It remains undetermined whether properties other than those conveyed by the target also influence the strategy used to complete the task successfully. Here, we explored whether characteristics of the support structure influence reaching kinematics among younger adults. The purpose of the study was to assess whether support structure stability affected movement kinematics of the transport phase. Subjects were required to reach for a full glass of water on a stable or an unstable support structure. Kinematic measures of interest included transport time, peak transport velocity, peak transport acceleration, and timing of kinematic peaks. Analysis showed that reducing the stability of the support structure did not significantly affect any of the measures of interest. The results imply that stability of support structure does not influence transport kinematics among younger adults.

Middle cerebral artery (MCA) stroke produces dysfunction in adjacent motor cortex as detected by intracortical microstimulation in rats.

Middle cerebral artery (MCA) stroke in the rat produces impairments in skilled movements. The lesion damages lateral neocortex but spares primary motor cortex (M1), raising the question of the origin of skilled movement deficits. Here, the behavioral deficits of MCA stroke were identified and then M1 was examined neurophysiologically and neuroanatomically. Rats were trained on a food skilled reaching task then the lateral frontal cortex was damaged by unilateral MCA electrocoagulation contralateral to the reaching forelimb. Reach testing and training on two tasks was conducted over 30 post-surgical days. Later, M1 and the corticospinal tract were investigated using intracortical microstimulation (ICMS), anterograde and retrograde axon tracing. A skilled reaching impairment was observed post-surgery, which partly recovered with time and training. ICMS revealed a diminished forelimb movement representation in MCA rats, but a face representation comparable in size to sham rats. Anterograde and retrograde tract tracing suggest that M1 efferents were intact. Although M1 appears to be in the main anatomically spared after MCA stroke its function as assessed electrophysiologically and behaviorally is disrupted.

Complete sparing of spatial learning following posterior and posterior plus anterior cingulate cortex lesions at 10 days of age in the rat.

Neonatal posterior cingulate cortex lesions spare the spatial deficits that characterize adult lesions. The present experiments examined the possibility that the anterior cingulate cortex mediates the spared spatial behavior. Rats were given bilateral lesions of the posterior cingulate cortex or anterior plus posterior cingulate cortex on postnatal days 4 (P4), 10 (P10), or in adulthood (P120). All groups were tested for spatial learning on the Morris place task in adulthood. Adult animals were impaired on place learning relative to controls whereas place learning was spared in all the neonatal groups and sparing was complete in the group receiving day 10 lesions. The results are discussed in relation to neural mechanisms, including fiber rerouting, synaptic changes and generation of new neurons, that may mediate spared spatial following neonatal posterior cingulate cortex lesions. Also discussed is evidence indicating that the neonatal brain, especially the day 10, has a special ability to compensate for injury.

Drug-induced rotation intensity in unilateral dopamine-depleted rats is not correlated with end point or qualitative measures of forelimb or hindlimb motor performance.

The pharmacological induction of rotational (circling) behavior is widely used to assess the effects of lesions to the dopaminergic system and the success of treatment strategies in rat models of Parkinson's disease. While the number of rotations under apomorphine, L-DOPA and amphetamine is related to the extent of dopamine depletion after unilateral 6-hydroxydopamine lesion of the nigrostriatal dopamine system, the relationship of the intensity of rotational behavior to the degree of impairment in motor behavior is unclear. The present study examined this question by correlating rotational behavior and motor abilities in a rat analogue for Parkinson's disease produced by unilateral nigrostriatal bundle lesion with 6-hydroxydopamine. Ipsiversive and contraversive rotation was measured in the rats following systemic administration of low and high doses of apomorphine, the dopamine precursor L-DOPA, and amphetamine. The motor assessment included end point and qualitative measures of fore- and hindlimbs assessed in a skilled reaching task and a skilled ladder rung walking task. The intensity of drug-induced rotation did not correlate with the measures of motor performance. We conclude that independence of rotational behavior and motor performance argues that both the assessment of 6-hydroxydopamine behavioral deficits and potential treatments for the functional deficits require comprehensive assessment, including both measures of rotation and motor behavior.

Accelerated nervous system development contributes to behavioral efficiency in the laboratory mouse: a behavioral review and theoretical proposal.

The emergence of the laboratory mouse as a favored species for genetic research has posed a number of problems for scientists interested in the reflection of genetic influences in mouse behavior. It is commonly thought that rat behavior, which has been studied more extensively than mouse behavior, could be easily generalized to mice. In this article, a number of categories of behavior displayed by the mouse (motor, spatial, defensive, social) are reviewed and contrasted with the same categories of behavior displayed by the rat. The comparison suggests that mouse behavior is simpler and more dependent upon elementary actions than the behavior of the rat. We suggest that the behavioral simplification in the mouse adapts it for a different ecological niche than that occupied by the rat. We propose that this simplification may be mediated by accelerated brain maturation during development. We further propose that this developmental acceleration in the mouse renders it less dependent upon complex social behavior and plastic nervous system changes associated with learning than the rat. This difference poses problems for the development of relevant methods of behavioral analysis and interpretation. Since the mouse's biological adaptations will be reflected in laboratory behavior, suggestions are made for behavioral approaches to the study and interpretation of mouse behavior.

Dead reckoning (path integration) requires the hippocampal formation: evidence from spontaneous exploration and spatial learning tasks in light (allothetic) and dark (idiothetic) tests.

Animals navigate using cues generated by their own movements (self-movement cues or idiothetic cues), as well as the cues they encounter in their environment (distal cues or allothetic cues). Animals use these cues to navigate in two different ways. When dead reckoning (deduced reckoning or path integration), they integrate self-movement cues over time to locate a present position or to return to a starting location. When piloting, they use allothetic cues as beacons, or they use the relational properties of allothetic cues to locate places in space. The neural structures involved in cue use and navigational strategies are still poorly understood, although considerable attention is directed toward the contributions of the hippocampal formation (hippocampus and associated pathways and structures, including the fimbria-fornix and the retrosplenial cortex). In the present study, using tests in allothetic and idiothetic paradigms, we present four lines of evidence to support the hypothesis that the hippocampal formation plays a central role in dead reckoning. (1) Control but not fimbria-fornix lesion rats can return to a novel refuge location in both light and dark (infrared) food carrying tasks. (2). Control but not fimbria-fornix lesion rats make periodic direct high velocity returns to a starting location in both light and dark exploratory tests. Control but not fimbria-fornix rats trained in the light to carry food from a fixed location to a refuge are able to maintain accurate outward and homebound trajectories when tested in the dark. (3). Control but not fimbria-fornix rats are able to correct an outward trajectory to a food source when the food source is moved when allothetic cues are present. These, tests of spontaneous exploration and foraging suggest a role for the hippocampal formation in dead reckoning.

Chronic levodopa therapy does not improve skilled reach accuracy or reach range on a pasta matrix reaching task in 6-OHDA dopamine-depleted (hemi-Parkinson analogue) rats.

L-dopa therapy reverses some but not all of the motor deficits in human Parkinson patients. Although a number rat analogues of human Parkinson's disease have been developed for evaluating the efficacy of drug therapies, it is not known whether L-dopa has a similar selective action on the motor symptoms in the rat models. To examine the effectiveness of L-dopa in reversing the motor deficits in rats, we administered 6-OHDA unilaterally to produce hemi-Parkinson rats, which were then trained to reach for food using either their impaired (contralateral to the lesion) limb or their good (ipsilateral to the lesion) limb. To assess the skill, accuracy and range of limb movement, rats reached for pasta from a horizontal array of 260 vertically orientated pieces of pasta. The number and location of pasta pieces taken from this matrix was calculated and the qualitative aspects of the reaching movements were rated. The quantitative data on pasta sticks retrieved indicated that forelimb extension and movement radius around the shoulder joint was reduced by 6-OHDA treatment and did not improve after chronic L-dopa treatment. The qualitative analysis showed that grasping patterns, paw movements and body movements impaired by the lesion were also not improved by L-dopa treatment. These findings are the first in the rat to suggest that whereas L-dopa has a general activating effect on the rat's whole-body movements, as displayed in contralateral rotation, its effectiveness does not extend to skilled forelimb movements. The results are discussed in relationship to the idea that the restoration of some skilled movements may require normal synaptic function.

A grasp-related deficit in tactile discrimination following dorsal column lesion in the rat.

The dorsal columns of the spinal cord are a major source of haptic (sense of active touch) and proprioceptive input to the brainstem and sensory-motor cortex. Following injury in primates, there are impairments in two-point discrimination, direction of movement across the skin, and frequency of vibration, and qualitative control of the digits, but simple spatial discriminations recover. In the rat there are qualitative deficits in paw control in skilled reaching, but no sensory deficits have been reported. Because recent investigations of sensory control suggest that sensory functions may be related to specific actions, the present study investigated whether the dorsal columns contribute to hapsis during food grasping in the rat. Adult female Long-Evans rats were trained to reach with a single forepaw for a piece of uncooked pasta or for equivalent sized but tactually different nonfood items. One group was given lesions of the dorsal column ipsilateral to their preferred paw, while the second group served as a control. Postlesion, both groups were tested for skilled reaching success and force application as well as adhesive dot removal and forepaw placing. Performance levels on these tests were normal. Nevertheless, the rats with dorsal column lesions were unable to discriminate a food item from a tactually distinctive nonfood item as part of the reaching act, suggesting that the dorsal columns are important for on-line tactile discriminations, or "haptic actions," which contribute to the normal performance of grasping actions.

The pasta matrix reaching task: a simple test for measuring skilled reaching distance, direction, and dexterity in rats.

Skilled forelimb use has been used in many studies to examine motor system status, learning, and recovery from nervous system damage in rats. The dependent measures in many current skilled reaching models rely on endpoint measures, number of successful reaches, or qualitative measures, the movements used in performing a reach. The present study describes a new reaching task, which allows measurement of distance and direction of skilled forelimb movement while also permitting end point and qualitative measurements. Animals reached from a clear Plexiglas box through an aperture to retrieve pieces of straight, uncooked pasta from an array of 260 vertically oriented pieces of pasta arranged in rows distally and laterally away from the aperture (a matrix). By extending the range of a reach, more pasta is obtained. Limb movements, pieces of pasta removed, and the pattern of pasta removal are dependent measures. The usefulness of the test is demonstrated using control, dorsal column lesion, and unilateral dopamine depleted animals. The task uses a desired food, tests learning and skill, the range of limb movement, and the ability to reach for different distances and directions. The task can also be modified to investigate other features of limb use including skill adjustments, laterality, and force.

Deficits in allothetic and idiothetic spatial behavior in rats with posterior cingulate cortex lesions.

The cingulate cortex plays a central role in bridging neocortical and limbic structures involved in allothetic navigation, a form of navigation requiring the use of external cues. Animals can also navigate using idiothetic cues, which are cues generated by self-movement, but there have been no definitive tests of whether cingulate cortex also plays a role in idiothetic navigation. Rats with anterior cingulate (medial frontal) and posterior cingulate cortex (retrosplenial) suction ablations were trained to search for large food pellets on an open table, and the accuracy with which they returned home with the food was measured. In the idiothetic task they searched for food from a novel starting location under infrared light, and with surface olfactory cues displaced. The rats also received two tests of allothetic navigation. They were tested on a matching-to-place task in which they foraged for food from a number of successively presented new locations under normal room light, and they were trained to locate a hidden platform in a swimming pool (Morris place task). The group with posterior cingulate cortex lesions was severely impaired on all of the navigation tasks whereas the group with anterior cingulate cortex lesions displayed no deficit on the idiothetic task and only moderate deficits on the other tasks. The results demonstrate a role for posterior cingulate region in idiothetic navigation.

Nicotine improvement of Morris water task performance after fimbria-fornix lesion is blocked by mecamylamine.

The focus of this study was to analyze the effects of nicotine on behavioural compensation after fimbria-fornix (FF) lesions in rats tested on the Morris water task (MWT). Nicotine (0.3 mg/kg) was injected subcutaneously for 11 consecutive days before, for 11 consecutive days after, or for 11 consecutive days before and after a FF lesion. Additionally, a lesion group was included that was given mecamylamine (1.0 mg/kg), a nicotine antagonist, 10 min before nicotine administration as well as mecamylamine-only, no treatment lesion, and sham groups. All drug administration ceased 24 h before three consecutive days of behavioural testing on the MWT. Results showed that the sham group and animals receiving both a pre- and post-lesion treatment of nicotine performed significantly better than all other groups, and the pre- and post-lesion nicotine group performed equivalent to sham controls on both acquisition and a probe trial. The compensatory effect of nicotine was blocked by mecamylamine. This study demonstrates that nicotine stimulates recovery from brain damage and the results are discussed in relation to neural mechanisms and potential applications.

Immunosuppression prevents neuronal atrophy in lupus-prone mice: evidence for brain damage induced by autoimmune disease?

An early onset of systemic, lupus-like disease in MRL-lpr mice is accompanied by deterioration in their behavioral performance and atrophy of pyramidal neurons in the parietal cortex and the hippocampal CA1 area. Using the immunosuppressive drug cyclophosphamide (CY) to attenuate the disease, we have tested the hypothesis that the autoimmune/inflammatory process is responsible for changes in brain morphology. A modified Golgi impregnation method revealed that, in comparison to saline-treated controls, immunosuppressive treatment with CY (100 mg/kg/week i.p. over 8 weeks) increased dendritic branching and spine numerical density in the CA1 region of MRL-lpr mice and MRL +/+ mice, which develop less severe manifestations of the disease. More interestingly, CY selectively prevented the atrophy and aberrant morphology of pyramidal neurons in the parietal cortex of MRL-lpr mice. The neuropathological measures (in particular reduced dendritic spine density) significantly correlated with increased serum levels of antinuclear antibodies and splenomegaly. The present results support the hypothesis that chronic autoimmune disease induces functionally important changes in neuronal morphology, and provide an empirical basis for understanding the behavioral dysfunction in systemic lupus erythematosus and autoimmune phenomena reported in some forms of mental illness.