Facial morphology and vibrissal movement in the golden hamster

The major cranial vibrissae in the golden hamster can be moved in complex ways that suggest they are served by a finely controlled motor system. Movements are hypothesized to be the products of differential blood flow and pressure regulation in the sinus surrounding each vibrissal follicle, contractions of the striated facial muscles, and elastic rebound in the connective tissues. The vasculature contributes hydrostatic forces that erect the vibrissae slightly and distort their connective tissue bedding, rigidify the vibrissal capsules, thus forming firm bases of attachment for certain facial muscles, and theoretically provide a pressure plate around the follicle, important in lowering the firing thresholds of receptor endings. The facial muscles supply the major forces in erection and protraction of the vibrissae by acting on both the capsules and the connective tissue bedding. The connective tissues are organized into capsular and extracapsular systems that serve to stabilize the vibrissae and return them to initial rest positions. The slight movements of the genal vibrissa are the effects of vascular and connective tissue dynamics, the musculature being uninvolved. Wide angle movements of the supraorbital vibrissae are products of the vasculature and connective tissues, plus contractions of the Mm. orbicularis oculi and frontalis. Mystacial vibrissal movement is quite complex. The vasculature supplies a small degree of capsular erection and mystacial pad distortion, but primarily rigidifies the capsules. The bulk of erection and protraction is produced by the M. nasolabialis profundus (NLP) and the vibrissal capsular muscles (VCM). The NLP distorts the mystacial pad; the VCM tilt the capsules relative to the pad. Retraction is mainly accomplished by elastic rebound in the pad, this being aided in its extreme degrees by the Mm. nasolabialis and maxillolabialis. The Mm. nasolabialis superficialis and buccinator pars orbicularis oris help to spread the vibrissae into a dorsoventral fan and stabilize the mystacial pad during whisking.     

Unilateral vibrissa contact: changes in amplitude but not timing of rhythmic whisking

Electromyographic recordings from the mystacial pad of rats were used to assess the effect of unilateral vibrissa contact on the bilateral movement of the vibrissae. A first group of animals was trained to whisk freely in air and served to establish the baseline variability in bilateral symmetry. We observed that the electromyogram (EMG) activity across the two mystacial pads was rhythmic and synchronous to within 2 ms on a whisk-by-whisk basis; this value is small in comparison with the approximately 50 ms required for protraction during the whisk cycle. A second group of animals was trained to use their vibrissae to contact a sensor that was located on one side of the head. The average EMG activity across the two pads was synchronous at the time of vibrissa contact, albeit with higher variability than for the case of free whisking. In contrast, the average amplitude of the activity on the contact vs noncontact side of the face was transiently greater, by 25% or approximately 10 degrees, at the time of contact. These data show that the amplitude of the vibrissae on the two sides of the face can be controlled independently, while the timing of vibrissa movement is largely synchronous.     

Electromyographic activity of mystacial pad musculature during whisking behavior in the rat

Cinematographic measurements of whisker movements generated by behaving rats were compared with electromyographic (EMG) activity recorded simultaneously from mystacial pad musculature. Muscle activity consisted of repetitive bursts, each of which initiated a "whisking" cycle consisting of a protraction followed by a retraction. Protraction amplitude and velocity were directly proportional to the amount of EMG activity during forward whisker movement. Overtime, the intensity of muscle discharge determined the set point about which the vibrissae moved; higher levels of muscle activity resulted in a greater degree of overall whisker protraction. These findings are consistent with the known anatomy of the facial musculature and underscore the importance of whisker protraction in the acquisition of tactile information by the vibrissae.     

Fast Feedback in Active Sensing: Touch-Induced Changes to Whisker-Object Interaction

Whisking mediated touch is an active sense whereby whisker movements are modulated by sensory input and behavioral context. Here we studied the effects of touching an object on whisking in head-fixed rats. Simultaneous movements of whiskers C1, C2, and D1 were tracked bilaterally and their movements compared. During free-air whisking, whisker protractions were typically characterized by a single acceleration-deceleration event, whisking amplitude and velocity were correlated, and whisk duration correlated with neither amplitude nor velocity. Upon contact with an object, a second acceleration-deceleration event occurred in about 25% of whisk cycles, involving both contacting (C2) and non-contacting (C1, D1) whiskers ipsilateral to the object. In these cases, the rostral whisker (C2) remained in contact with the object throughout the double-peak phase, which effectively prolonged the duration of C2 contact. These “touch-induced pumps” (TIPs) were detected, on average, 17.9 ms after contact. On a slower time scale, starting at the cycle following first touch, contralateral amplitude increased while ipsilateral amplitude decreased. Our results demonstrate that sensory-induced motor modulations occur at various timescales, and directly affect object palpation.     

Chemoanatomical separation of vibrissal trigeminal primary afferents in the rat: a special central representation of supraorbital vibrissae

A choleratoxin B subunit transganglionic labelling technique and NPY immunohistochemistry were applied in the rat to achieve the chemoanatomical separation of myelinated vibrissal primary afferents, previously considered to be morphologically indistinguishable. Further, a special central representation pattern of supraorbital vibrissae was observed in the trigeminal brainstem nuclear complex: (1) Choleratoxin-labelled supraorbital vibrissal primary afferents terminated densely in their appropriate barrelettes in the trigeminal principal sensory nucleus, in the spinal oral subnucleus, in the caudal part of the spinal interpolar subnucleus, and in lamina IV of the caudal part of the spinal caudal subnucleus. (2) A second population of choleratoxin-labelled vibrissal afferents was also observed, terminating only in lamina III of the caudal subnucleus. (3) After peripheral nerve transection, NPY-immunoreactive supraorbital vibrissal primary afferent fibres appeared in their appropriate barrelettes in the principal sensory nucleus and the caudal part of the interpolar subnucleus, while in the caudal part of the caudal subnucleus NPY-immunoreactive vibrissal primary afferent terminals were found exclusively in the inner part of lamina II, extending over the outer part of lamina III. NPY-immunoreactive supraorbital vibrissal primary afferents were never found in the oral subnucleus. In contrast with the rules of the central representation of the mystacial (infraorbital) vibrissae, the multiple representation of the supraorbital vibrissae in the caudal subnucleus and the dense, barrelette-like terminal arborization of the choleratoxin-labelled supraorbital vibrissal primary afferents in the oral subnucleus apparently indicate an enhanced role of supraorbital vibrissae in reflexes that protect the eyes and the head from damage.     

Discriminative whisking in the head-fixed rat: optoelectronic monitoring during tactile detection and discrimination tasks

We compared whisking movement patterns during acquisition of tactile detection and object discrimination under conditions in which (a) head movements are excluded and (b) exposure to tactile discriminanda is confined to the large, moveable vibrissae (macrovibrissae). We used optoelectronic instrumentation to track the movements of an individual whisker with high spatio-temporal resolution and a testing paradigm, which allowed us to dissociate performance on an "indicator" response (lever pressing) from the rat's "observing" responses (discriminative whisking). We analyzed the relation between discrimination performance and whisking movement patterns in order to clarify the process by which the indicator response comes under the stimulus control of information acquired by the rat's whisking behavior. Whisking patterns over the course of task acquisition differed with task demands. Acquisition of the Detection task was correlated with modulation of only one whisking movement parameter-total number of whisks emitted, and more whisking was seen on trials in which the discriminandum was absent. Discrimination between a sphere and cube differing in size and texture was correlated with a reduction in whisk duration and protraction amplitude and with a shift towards higher whisking frequencies. Our findings confirm previous reports that acquisition of tactile discriminations involves modulation by the animal of both the amount and the type of whisking. In contrast with a previous report (Brecht et al., 1997), they indicate that rats can solve tactile object detection and discrimination tasks (a) using only the large, motile mystacial vibrissae (macrovibrissae) and (b) without engaging in head movements. We conclude that the functional contribution of the macrovibrissae will vary with the nature of the task and the conditions of testing.     

Frisking the whiskers: patterned sensory input in the rat vibrissa system

How are two prominent environmental features, surface texture and object location, transduced and encoded as rats whisk? Recent papers show that textures may excite intrinsic mechanical vibrations of the vibrissae. Although these vibrations are too rapid to be directly followed by cortical neurons, there is evidence that their speed is encoded by contact-dependent sensory signals. In addition to contact, sensory signals exist that report the angular position of the vibrissae. The combination of contact and reference signals may be used to decode spatial variations in the environment, particularly the location of objects in head-centered coordinates.     

The role of vibrissal sensing in forelimb position control during travelling locomotion in the rat (Rattus norvegicus,Rodentia)

In the stem lineage of therians, a comprehensive reorganization of limb and body mechanics took place to provide dynamic stability for rapid locomotion in a highly structured environment. At what was probably the same time, mammals developed an active sense of touch in the form of movable mystacial vibrissae. The rhythmic movements of the limbs and vibrissae are controlled by central pattern-generating networks which might interact with each other in sensorimotor control. To test this possible interaction, we studied covariation between the two by investigating speed-dependent adjustments in temporal and spatial parameters of forelimb and vibrissal kinematics in the rat. Furthermore, the possible role of carpal vibrissae in connecting the two oscillating systems was explored. We compared locomotion on continuous and discontinuous substrates in the presence and absence of the mystacial or/and carpal vibrissae across a speed range of 0.2–0.5 m/s and found that a close coupling of the kinematics of the two oscillating systems appears to be precluded by their differential dependence on the animal's speed. Speed-related changes in forelimb kinematics mainly occur in temporal parameters, whereas vibrissae change their spatial excursion. However, whisking frequency is always high enough that at least one whisk cycle falls into the swing phase of the limb, which is the maximum critical period for sensing the substrate on which the forepaw will be placed. The influence of tactile cues on forelimb positional control is more subtle than expected. Tactile cues appear to affect the degree of parameter variation but not average parameters or the failure rate of limbs during walking on a perforated treadmill. The carpal vibrissae appear to play a role in sensing the animal's speed by measuring the duration of the stance phase. The absence of this cue significantly reduces speed-related variation in stride frequency and vibrissal protraction.     

Discriminative whisking in the head-fixed rat: optoelectronic monitoring during tactile detection and discrimination tasks

We compared whisking movement patterns during acquisition of tactile detection and object discrimination under conditions in which (a) head movements are excluded and (b) exposure to tactile discriminanda is confined to the large, moveable vibrissae (macrovibrissae). We used optoelectronic instrumentation to track the movements of an individual whisker with high spatio-temporal resolution and a testing paradigm, which allowed us to dissociate performance on an “indicator” response (lever pressing) from the rat's “observing” responses (discriminative whisking). We analyzed the relation between discrimination performance and whisking movement patterns in order to clarify the process by which the indicator response comes under the stimulus control of information acquired by the rat's whisking behavior. Whisking patterns over the course of task acquisition differed with task demands. Acquisition of the Detection task was correlated with modulation of only one whisking movement parameter - total number of whisks emitted, and more whisking was seen on trials in which the discriminandum was absent. Discrimination between a sphere and cube differing in size and texture was correlated with a reduction in whisk duration and protraction amplitude and with a shift towards higher whisking frequencies. Our findings confirm previous reports that acquisition of tactile discriminations involves modulation by the animal of both the amount and the type of whisking. In contrast with a previous report (Brecht et al., 1997), they indicate that rats can solve tactile object detection and discrimination tasks (a) using only the large, motile mystacial vibrissae (macrovibrissae) and (b) without engaging in head movements.We conclude that the functional contribution of the macrovibrissae will vary with the nature of the task and the conditions of testing.     

Vibrissa Self-Motion and Touch Are Reliably Encoded along the Same Somatosensory Pathway from Brainstem through Thalamus

Active sensing involves the fusion of internally generated motor events with external sensation. For rodents, active somatosensation includes scanning the immediate environment with the mystacial vibrissae. In doing so, the vibrissae may touch an object at any angle in the whisk cycle. The representation of touch and vibrissa self-motion may in principle be encoded along separate pathways, or share a single pathway, from the periphery to cortex. Past studies established that the spike rates in neurons along the lemniscal pathway from receptors to cortex, which includes the principal trigeminal and ventral-posterior-medial thalamic nuclei, are substantially modulated by touch. In contrast, spike rates along the paralemniscal pathway, which includes the rostral spinal trigeminal interpolaris, posteromedial thalamic, and ventral zona incerta nuclei, are only weakly modulated by touch. Here we find that neurons along the lemniscal pathway robustly encode rhythmic whisking on a cycle-by-cycle basis, while encoding along the paralemniscal pathway is relatively poor. Thus, the representations of both touch and self-motion share one pathway. In fact, some individual neurons carry both signals, so that upstream neurons with a supralinear gain function could, in principle, demodulate these signals to recover the known decoding of touch as a function of vibrissa position in the whisk cycle.     

Topography of whisking II: interaction of whisker and pad

The peripheral effector system mediating rodent whisking produces protraction/retraction movements of the whiskers and translation movements of the collagenous mystacial pad. To examine the interaction of these movements during whisking in air we used high-resolution, optoelectronic methods for two-dimensional monitoring of whisker and pad movements in head-fixed rats. Under these testing conditions (1) whisker movements on the same side of the face are synchronous and of similar amplitude; (2) pad movements exhibit the characteristic 'exploratory' rhythm (6-12 Hz) of whisking but their movements often have a low frequency (1-2 Hz) component; (3) Pad movements occur in both antero-posterior and dorso-ventral planes but there are considerable variations in the amplitude and topography of movement parameters in the two planes. We conclude that (a) both whisker and pad receive input from a common central rhythm generator; (b) differences in whisker and pad amplitude and topography probably reflect differences in the biomechanical properties of the structures receiving that input; (c) pad movements make a significant contribution to the kinematics of whisking behavior and (d) the two-dimensional nature of pad translation movements significantly increases the rat's flexible control of its mobile sensor.     

Localization in the gasserian ganglion of axons innervating the common hairs of the mystacial pad in the normal adult rat and in rats dewhiskered at birth

The neurons which innervate the small common hairs of the mystacial pad are shown to be located in the dorsomedial part of the ganglion of Gasser. In ganglia atrophied as a consequence of early destruction of vibrissae follicles, neurons that innervate these small hairs are still active.     

Feedback control in active sensing: rat exploratory whisking is modulated by environmental contact

Rats sweep their facial whiskers back and forth to generate tactile sensory information through contact with environmental structure. The neural processes operating on the signals arising from these whisker contacts are widely studied as a model of sensing in general, even though detailed knowledge of the natural circumstances under which such signals are generated is lacking. We used digital video tracking and wireless recording of mystacial electromyogram signals to assess the effects of whisker-object contact on whisking in freely moving animals exploring simple environments. Our results show that contact leads to reduced protraction (forward whisker motion) on the side of the animal ipsilateral to an obstruction and increased protraction on the contralateral side. Reduced ipsilateral protraction occurs rapidly and in the same whisk cycle as the initial contact. We conclude that whisker movements are actively controlled so as to increase the likelihood of environmental contacts while constraining such interactions to involve a gentle touch. That whisking pattern generation is under strong feedback control has important implications for understanding the nature of the signals reaching upstream neural processes.     

Topography of rodent whisking--I. Two-dimensional monitoring of whisker movements

During 'active touch' the rodent whiskers scan the environment in a series of repetitive movements ('whisks') generating afferent signals which transform the spatial properties of objects into spatio-temporal patterns of neural activity. Based upon analyses carried out in a single movement plane, it has been generally assumed that these trajectories are essentially uni-dimensional, although more complex movements have been described in some rodents. The present study was designed to examine this assumption and to more precisely characterize whisking topography by monitoring whisking trajectories along both the antero-posterior and dorso-ventral axes. Using optoelectronic monitoring techniques with high-spatio-temporal resolution, movement data were obtained from a population of vibrissae sampled at different locations on the mystacial pad in head-fixed rats isolated from the perturbing effects of contact. For a substantial proportion of the population of whisking movements sampled, the trajectories generated by a single whisker is most accurately described as occupying an expended two-dimensional space in which the A-P component predominates. However, the whisker system exhibits a considerable range of trajectory types, suggesting a high degree of movement flexibility. For each vibrissa position, it was possible to delineate a 'trajectory' domain-that portion of the animal's whisking space which is scanned by the movements of that vibrissa during whisking. Since the 'domains' of adjacent whiskers in the same row tend to overlap, synchronized movements of a subset of whiskers could generate a set of overlapping somatosensory fields analogous to overlapping retinal receptive fields. The organization of such trajectory domains within the rats' whisking space could provide the spatial component of the spatio-temporal integration process required to extract information about environmental features from the inputs generated by its recursive whisking movements.     

Topography of rodent whisking--I. Two-dimensional monitoring of whisker movements

During 'active touch' the rodent whiskers scan the environment in a series of repetitive movements ('whisks') generating afferent signals which transform the spatial properties of objects into spatio-temporal patterns of neural activity. Based upon analyses carried out in a single movement plane, it has been generally assumed that these trajectories are essentially uni-dimensional, although more complex movements have been described in some rodents. The present study was designed to examine this assumption and to more precisely characterize whisking topography by monitoring whisking trajectories along both the antero-posterior and dorso-ventral axes. Using optoelectronic monitoring techniques with high-spatio-temporal resolution, movement data were obtained from a population of vibrissae sampled at different locations on the mystacial pad in head-fixed rats isolated from the perturbing effects of contact. For a substantial proportion of the population of whisking movements sampled, the trajectories generated by a single whisker is most accurately described as occupying an expended two-dimensional space in which the A-P component predominates. However, the whisker system exhibits a considerable range of trajectory types, suggesting a high degree of movement flexibility. For each vibrissa position, it was possible to delineate a 'trajectory' domain -- that portion of the animal's whisking space which is scanned by the movements of that vibrissa during whisking. Since the 'domains' of adjacent whiskers in the same row tend to overlap, synchronized movements of a subset of whiskers could generate a set of overlapping somatosensory fields analogous to overlapping retinal receptive fields. The organization of such trajectory domains within the rats' whisking space could provide the spatial component of the spatio-temporal integration process required to extract information about environmental features from the inputs generated by its recursive whisking movements.     

Immunohistochemical comparison of whisker pad cutaneous innervation in Swiss Webster and hairless mice

To establish the mouse mutant, hairless (Hr), as a useful model for future analyses of target-ending interactions, we assessed the cutaneous innervation in the whisker pad after loss of primary hair targets. Postnatal (P) development of fur in Hr begins similarly to that of "normal" Swiss Webster (SW) mice. Around P10, hairs are shed and the follicles rendered permanently incompetent. Hair loss progresses rostrocaudally until the entire skin is denuded. Substantial alterations in the distribution and density of sensory and autonomic endings in the mystacial pad vibrissal and intervibrissal fur innervation were discovered. Pilo-neural complexes innervating fur hairs were dismantled in Hr. Epidermal innervation in SW was rich; only a few endings expressed growth-associated protein-43?kdal (GAP), suggesting limited changes in axonal elongation. Innervation in Hr formed a dense layer passing upward through the thickened epidermis, with substantial increases among all types of endings. Vibrissal follicle-sinus complexes were also hyperinnervated. Endings in Hr vibrissae and fur were strongly GAP-positive, suggesting reorganization of innervation. Dermal and vascular autonomic innervation in both strains co-localized tyrosine hydroxylase and neuropeptide Y, but only in Hr did neuropeptide Y co-localize calcitonin gene-related peptide (CGRP) and express GAP immunolabeling. Stereological quantitation of trigeminal ganglia revealed no differences in neuron number between Hr and SW, although there were small increases in cell volume in Hr trigeminal ganglion cells. These results suggested that a form of collateral sprouting was active in Hr mystacial pads, not in response to local injury, but as a result of loss of primary target tissues.     

Development of Merkel cell populations with contrasting sensitivities to neonatal deafferentation in the rat whisker pad

In this study, we used the quinacrine fluorescence technique to investigate the embryonic and early postnatal development of two distinct populations of Merkel cells in the rat whisker pad and the consequences of neonatal deafferentation on their subsequent development. Annular clusters of Merkel cells first appear in the epidermis near the caudal margin of the mystacial region between embryonic days E14 and E15 at dome sites located on horizontal ridges where the primordial vibrissal follicles develop. The development of these cells progresses in a caudorostral sequence across the whisker pad as does the development of the vibrissal follicles. Each cluster eventually forms a conical ridge or collar of about 130 Merkel cells that surrounds the vibrissal hair shaft as it penetrates the overlying pad epidermis. In the vibrissae, which develop as downgrowths from the horizontal ridges at the dome sites, Merkel cells first appear (caudally) between E16 and E17 and form a cylindrical cuff within the outer root sheath; cells are added progressively until about the end of the first postnatal week when a plateau level of about 750-800 cells is reached. Following unilateral transection of the infraorbital nerve at 24-36 hr after birth, these vibrissal Merkel cells continued to develop along a time course that was indistinguishable from normal, at least over the first 2 weeks of postnatal life. In contrast, all or most of the Merkel cells that normally develop within collars or annular clusters in the pad epidermis (around both the vibrissal and intervibrissal or pelage hairs) either disappeared within a few days or failed to develop. Other light and electron microscopic procedures supported the main findings and confirmed that the denervation was successful. Thus, the vibrissal Merkel cells, like those in the glabrous hindpaw, behaved as a distinct class which develops postnatally and is maintained (at least over a 2-week period) without the presence of sensory nerves. Since both the mystacial vibrissae and glabrous hindpaw have specialized cortical representations, a possible relationship between these findings and the organization of the somatosensory cortex during development is discussed.     

Conditioned Whisking in the Rat

The rat's mystacial vibrissae are active during exploratory and discriminative behaviors, with individual vibrissae serving as elements in a receptive array scanned across object surfaces. To facilitate neurobehavioral analysis of this sensorimotor system, we have developed an experimental paradigm that confines vibrissa movements to a defined physical location, makes possible on-line monitoring of “whisking” activity, and brings such activity under associative control using operant conditioning procedures. Rats were secured, and movements of an identified bilaterally homologous pair of vibrissae (right and left gamma straddlers) were detected by laser-based photodetectors. Subjects were maintained on a water deprivation schedule, and whisker movements were monitored during adaptation to the test situation and after the clipping of other vibrissae on both sides of the snout. Rats were reinforced with water delivery for emitting vibrissa movements in the presence of a conditioned stimulus (tone) whose presentation was made contingent upon a prior period of nonwhisking. The rate and temporal distribution of vibrissa movements were brought under experimental control by means of interval and ratio reinforcement schedules. Although the procedures provide minimal information about the kinematics or topography of conditioned vibrissa movements, they permit the investigator to manipulate response parameters normally under the voluntary control of the animal in a preparation amenable to neurophysiological analysis     

Tactile size discrimination by a California sea lion (Zalophus californianus) using its mystacial vibrissae

The capability of a blindfolded California sea lion (Zalophus californianus) to discriminate diameter differences of circular discs by means of active touch with its mystacial vibrissae was studied. Using a forced choice paradigm the sea lion was required to choose the larger of two simultaneously presented perspex discs. Absolute difference thresholds (D) were determined for 3 standard discs (1.12 cm Ø, 2.52 cm Ø, 8.74 cm Ø) by the psychophysical method of constants. Increasing disc size resulted in an increase in the absolute difference threshold from 0.33 cm for the smallest disc size to 1.55 cm for the largest disc size. The relative difference threshold (Weber fraction) remained approximately constant at a mean value of 0.26. According to a video analysis the sea lion did not move its vibrissae when touching the discs. Instead, it performed precisely controlled lateral head movements, with the touched disc located centrally between the vibrissae of both sides of the muzzle. Since the extent of these head movements was identical at discs to be compared, discs of different size must have led to different degrees of deflection of vibrissae involved in the tactile process, resulting in quantitatively different mechanical stimulations of mechanoreceptors in the follicles. This suggests that the accuracy of the sea lion's size discrimination was determined by the efficiency of two sensory systems: the mechanosensitivity of follicle receptors as well as kinaesthesis.Abbreviations D starting stimulus size - D _i size of the interpolated comparison disc at 75% correct choices - D absolute difference threshold     

Development of rodent macrovibrissae: effects of neonatal whisker denervation and bilateral neonatal enucleation

In this paper we describe the effects of manipulating two kinds of sensory input in neonatal rats upon the development of the macrovibrissae--that movable subset of the rodent mystacial vibrissae. In an initial study of normal whisker development, data on whisker size were obtained from neonatal, perinatal, and adult rats. Data on whisker size were also obtained from rats sustaining either neonatal sensory or motor denervation of the whiskers and from both rats and mice bilaterally enucleated as neonates (BEN). In normally reared rats, most whiskers attain their final size over the first three postnatal weeks but development of rows 6 and 7 are not completed until after the first month. In normal animals we found a significant correlation both between body weight and whisker size and between the size of a whisker and the size of its corresponding cortical barrel. Rats sustaining neonatal denervation of the whiskers have shorter and thinner whiskers as adults than normally reared animals. In both rats and mice bilaterally enucleated as neonates a subset of the macrovibrissae are significantly larger than those of normal controls but no such effect is seen if the enucleation is carried out in adults. Moreover, BEN rats exposed to a novel stimulus environment whisk at a significantly higher frequency than normally reared animals. Mechanisms which might mediate these effects are discussed.