Infantile stimulation induces brain lateralization in rats

Ontogenesis of neocortical asymmetry: a [3H]thymidine study

Previous research has demonstrated that symmetric regions in one brain are, on the whole, larger than their asymmetric counterparts in another brain, and that side differences in the volumes of homologous architectonic areas are the result of a decrease in neuronal number in the smaller of the two areas. Therefore, understanding mechanisms by which neuronal numbers are regulated during development may be essential to the investigation of the ontogeny of asymmetry. The radial unit hypothesis of Rakic postulates four factors that determine the number of neurons within a neocortical region: (i) early progenitor cell division; (ii) late cell division; (iii) the effect of thalamocortical and corticocortical afferents, which govern, in part, boundary placement; and (iv) ontogenetic cell death. We report here on experiments that address the development of anatomical asymmetry in the light of this hypothesis. Pregnant Wistar rats were injected with [3H]thymidine on several dates during embryogenesis and their pups killed at several postnatal ages. An estimate of the total number of neurons contained within area 17 and area 18a of each hemisphere was determined and the percentage of those which were labeled was calculated. There were no side differences in this measure between either symmetric or asymmetric architectonic areas although there were consistent differences between areas 17 and 18a. This indicated that while late neuroblast division may be important for cytoarchitectonic differentiation, it may play little or no role in interhemispheric asymmetry.

Infantile stimulation and perinatal administration of Ro 15-1788: additive anxiety-reducing effects in rats

Both postnatal handling of rat pups and perinatal treatment with Ro 15-1788 have been reported to reduce the emotional reactivity of the rats in adulthood, as measured by open field behavior, by the corticosterone response to stress, and by labyrinth and novelty-induced behaviors. We now report results obtained with a well-validated animal model of anxiety (i.e. the elevated plus-maze) that support and extend these previous findings. The results show the clearest reduction of anxiety-related behavior when postnatal handling and perinatal Ro 15-1788 administration were simultaneous.

Cerebral lateralization of olfactory-mediated affective processes in rats

To determine whether processing of information is lateralized in the brain of non-human mammalian species, rats that had undergone ablation of the left or right olfactory bulb were compared to sham-operated animals and to bilaterally bulbectomized animals in their response to emotionally positive or negative social odours. Left-bulbectomized rats were impaired in their behavioural reaction but not in their hormonal response to an odour from a stressed conspecific. They fully retained, however, their ability to recognize a nonstressed juvenile conspecific on the basis of its olfactory characteristics. These results suggest that hemispheric asymmetries develop in mammals not for recognition of emotional stimuli but for association of emotional experiences with appropriate adaptive behaviour.

Neonatal handling reverses behavioral abnormalities induced in rats by prenatal stress

The aim of this study was to see whether neonatal handling can reverse the behavioral deficits induced in rats by unpredictable prenatal stress. Rats (24) were exposed to random noise and light stress (RS) on a random basis throughout pregnancy. Half the litters of RS and control (C) dams were subjected to neonatal handling (NH), 3' daily for 21 days. Behavioral measures, open field in both sexes and plus maze test in females only were conducted at 1.5-2 months, and spatial lateralization by amphetamine-induced rotation, in females at 3 months. RS caused significant increases in emotionality and timidity (higher incidence of defecation and less time in open arms of plus maze), and a change in directional bias towards the left. NH completely reversed all these behavioral abnormalities in RS rats but had little effect in C. It is concluded that NH can influence postnatal development of brain organisation in the opposite direction to that induced by prenatal stress.

The stability and interest consonance of lateral postural--motor biases in rats: results and implications

Each of six different tests of lateral postural-motor asymmetries was repeatedly administered to 126 rats. Directional reliability was found for rotatory swimming, open-field exploration, and stepping down from a beam. Neonatal posture, turn in an unbaited T maze, and orientation to tail pinch proved not to be reliable across days. The behavioral asymmetries in the open-field and step-down tests were directionally consonant with each other, but neither was related to the asymmetry exhibited in rotatory swimming, implying the existence of at least two independent asymmetrical neural substrates underlying the behaviors. Neither sample-wide directional biases nor major sex differences in bias were found. The sexes were, however, differentially influenced in direction on some tests by the number of males in their natal litters, implying a role for intrauterine exposure to androgens in predisposing rats toward some left- or right-biased behaviors.

Cerebral lateralization as a source of interindividual differences in behavior

Cerebral laterality can no longer be considered an exclusively human trait, as over the last 15 years there has been an emergence of data to suggest that animal brains are also lateralized. Morphologic, chemical and behavioral indices of brain asymmetry in the rodent have been reported, and it is suggested that variations in the magnitude and direction of these indices are determined by a complex interaction of genetic, hormonal and experiential factors. Interindividual differences in cerebral laterality have been shown to covary with, or predict, individual differences in spatial behavior and stress reactivity, as well as susceptibility to stress pathology and drug sensitivity. Such findings suggest that it is possible to study individual differences in lateralized brain function through the use of animal models.

Alterations in behavioral and striatal dopamine asymmetries induced by prenatal stress

We investigated the effects of maternal noise and light stress, randomly applied throughout pregnancy, on the development of behavioral and neurochemical asymmetries in the rat offspring. This form of maternal stress resulted in a rightward positioning of the tail of both sexes soon after birth as opposed to the leftward bias in controls. At adulthood, prenatally stressed offspring showed a change in directional bias compared to controls with a preponderance of left turns after amphetamine. In the males, this was expressed as a reduction in directional preference, while in females a reversal occurred of their dominant turning direction from right (controls) to left. We also observed a reduction in dopamine turnover rates in the left corpora striata of stressed offspring of both sexes. Again, in the females, this change was particularly marked and resulted in a reversal towards the right hemisphere. The findings from this study are consistent with the possibility that the alterations in cerebral asymmetries induced by prenatal stress may underly the decrease in the ability of the offspring to cope with anxiety provoking situations.

Interhemispheric connections differ between symmetrical and asymmetrical brain regions

Coronal sections from the brains of male Wistar rats that underwent corpus-callosectomy in adulthood were stained with Cresyl Violet for Nissl substance or by the Fink-Heimer method for terminal axonal degeneration. Measurements of volumetric asymmetry of neocortical region SM-I were made, and the per cent of terminal degeneration computed. As in previous studies, there was a negative correlation between asymmetry coefficient and total (right plus left) architectonic volume, indicating that symmetrical brain regions are larger than the average of the corresponding regions in asymmetrical brains. It was also found that as volumetric asymmetry increased, the per cent of axonal termination decreased, partly as a result of a decrease in the number of patches of callosal axonal termination. These results are interpreted in the light of what is known about the ontogenesis of callosal connectivity, and mechanisms for the development of architectonic asymmetry in the cerebral cortex are postulated.

Cortical lateralization of function in rats in a visual reaction time task

Rats were trained to orient to a visual cue presented in either visual field. An asymmetry in reaction time showed that they used one eye to control responses to both visual fields. Cortical removal contralateral to this dominant eye produced a severe and permanent response deficit. Cortical removal ipsilateral to the dominant eye caused a mild and temporary change. Thus, in the rat, there is a functional lateralization that is similar to that seen in humans.

The anxiolytic action of benzodiazepines is not present in handling-habituated rats

The acquisition of two-way shuttle avoidance (40 first trials) was used to test the anxiolytic activity of diazepam (2 and 4 mg/kg) and alprazolam (1.25 mg/kg) vs. vehicle, IP, in rats. These rats had received three different previous treatments: acute, acute with previous handling habituation for 15 days, and handling habituation combined with chronic treatment for 15 days. Results of the acute treatment showed a comparable anxiolytic action of diazepam and alprazolam, reflected by an improvement in avoidance acquisition. After handling habituation, no effect on shuttle box acquisition was obtained in rats acutely treated with diazepam, whereas the alprazolam-treated group showed a significantly impaired avoidance performance. When handling habituation was combined with chronic benzodiazepine treatment, the drugs' anxiolytic action persisted although there was a complete disappearance of their sedative effects. These behavioral results are discussed in relation to the emotional changes induced by the procedures of handling. They are tentatively linked with possible changes in the functionality of GABA neurotransmission, possibly at the level of the GABA-benzodiazepine receptor which some studies have found associated to handling habituation.

Some effects of commissurotomy on the reinstatement and potentiation of lesion deficits

Two experiments investigated in rats the effects of cutting the corpus callosum after recovery from unilateral cortical lesions that produce transient symptoms of neglect and circling. Side of lesion was also examined. In Expt. I, 60 rats received left or right lesions of parietal, medial frontal, or motor cortex. After one month of testing for visual, auditory and somatosensory responsiveness and for circling, the callosum was cut, and the sequence of measures was repeated. Callosotomy reinstated neglect after recovery from the lesions in the parietal and medial frontal groups, more severely and consistently in the frontal group. Side of lesion made no difference. Circling was predominantly ipsiversive after the cortical lesions, due entirely to the frontal group. Callosum section markedly potentiated contraversive circling in the left parietal group; right parietal animals showed no preference. This was the only hemisphere difference found. Circling remained ipsiversive in medial frontal animals after callosotomy. These circling biases did not diminish in the postcallosotomy period. Expt. II replicated the circling procedures with 58 animals that were given the same unilateral cortical lesions or were unoperated controls. Callosotomy was performed one month postlesion. Again, left parietal animals circled contraversively, and there was no bias in the right parietal group. A left-right difference was also evident in the motor cortex group, left lesions producing contraversive turning. We confirm the reinstatement of neglect from frontal lesions by callosum section previously found in the monkey and show that it also occurs with parietal lesions. While neglect symptoms do not differ after left or right lesions, circling does: left parietal lesions plus callosotomy produce a marked contraversive tendency that may reflect an elemental spatial lateralization.

Corpus callosum: region-specific effects of sex, early experience and age

In infancy, rats were provided handling stimulation and compared at 110 and 215 days of age with non-handled controls. Measurements were made of corpus callosum area, perimeter and length; and width measures were taken at 7 points along the longitudinal axis of the callosum. Callosal size was larger in males than in females, even when adjusted for the larger brain weight of the male. At 110 days handling stimulation increased callosal parameters and resulted in a more regular callosum in males, but this effect was no longer apparent by 215 days. Within the callosum, region-specific effects were found, suggesting that certain callosal fiber populations were involved. Handled males have previously been shown to be more lateralized than non-handled males; thus at least in this experimental system, increased callosal size and regularity is associated with greater hemispheric specialization.

Increased interhemispheric coupling of the dopamine systems induced by prenatal stress

Maternal noise and light stress, randomly applied throughout pregnancy, has previously been shown to induce alterations in behavioral asymmetries in the adult offspring. In the present study, we investigated whether interhemispheric communication of neurotransmitters would be influenced by this treatment. Dopamine and serotonin turnover rates were measured in the left and right prefrontal cortex, nucleus accumbens and caudate nucleus of adult rats which were stressed prenatally. In control animals, dopamine turnover was only significantly correlated between the left and right hemispheres in the males (p less than 0.01). Prenatal stress greatly increased the degree of interhemispheric correlation (p less than 0.001) which now became highly significant in both sexes (p less than 0.001). For serotonin, left-right turnover rates only correlated in control females and no effect of gestational stress was seen. These results indicate that prenatal stress greatly increases interhemispheric coupling of dopamine in the adult offspring. We suggest that this facilitated communication may underly the alterations in behavioral asymmetries induced by prenatal stress.

Asymmetrical involvement of the cerebral neocortex on the response to an immunopotentiator, sodium diethyldithiocarbamate

We have previously shown that the neocortex in mice has a lateralized influence on the immune system. A partial left or bilateral neocortical lesion selectively decreases spleen T-cell numbers and function, natural killer and (NK) activity, but a right neocortical lesion do not affect NK activity, and increases T-cell numbers and T-cell-mediated events. Here we report that the immunopotentiating activity of sodium diethyldithiocarbamate (Imuthiol), a compound that selectively increases T-cell numbers and activities, is dependent on an intact neocortex. The effects of Imuthiol were examined in female C3H/HeJ mice 10 weeks after partial neocortical lesions. In animals with right or bilateral neocortical lesions, Imuthiol failed to increase the percentage of spleen T cells, did not influence the expression of class I MHC antigen on these cells, no longer induced the release in serum of specific T-cell-inducing factors, and failed to enhance T-cell-mediated events. In contrast, in animals with a left neocortical lesion, Imuthiol increased T-cell numbers and activities in a fashion that was comparable to that observed in unlesioned controls, but did not enhance NK activity. It is concluded that Imuthiol may affect immune responsiveness by acting directly on the neocortex and/or by interacting at subcortical levels with signals emitted by the neocortex. Moreover, this study reveals a major hemispheric asymmetry in the response to a drug.

Callosal mediation of cortical inhibition in the lateralized rat brain

This paper tested a brain model for muricide. The model states that, in animals given handling stimulation in infancy, the right hemisphere is dominant for the occurrence of mouse killing and the left hemisphere acts to inhibit this behavior. On the assumption that the inhibition is mediated transcortically, it follows that severing the corpus callosum should result in an increase in muricide. This prediction was confirmed. In addition, prior research has found that animals not given extra stimulation in infancy show no evidence of lateralization for muricide. Therefore, splitting the brains of this group should not have any effect. This prediction was also confirmed. Latency analyses of muricidal rats found that those with only an intact right hemisphere killed much more quickly than those with only an intact left hemisphere. Sham controls had killing latencies similar to animals with only a right hemisphere. This pattern represents a brain model in which the right hemisphere is dominant for latency to kill. Rats exposed to mice in early life killed much more quickly than those without this early social experience, thus indicating that familiarity can reduce killing latency.

Olfactory asymmetry in the rat brain

Based on cytoarchitecture, myeloarchitecture, and physiological observations in the literature, two concentric strata are identified in the olfactory bulb of the albino rat. Stimulated by a report of physiologic asymmetry between the left and right bulb of the rodent brain, we parcelled the inner and outer strata of the olfactory bulbs of 16 albino rats and measured the volume of these olfactory subdivisions. The volume of the entire olfactory bulb was found to be significantly greater in the right hemisphere. This volume asymmetry was the result of a significantly larger right outer stratum. No significant asymmetry was demonstrated for the inner stratum. These findings are discussed in the light of some physiologic and anatomic properties of the olfactory bulb.

A simple rapid swim test to determine spatial preference in the rat

A swim test is described for the evaluation of spatial preference in untreated male rats. The test is rapid, objective and simple to perform and was able to distinguish right-left preferences in 47 rats. It is encouraged that the swim test be compared to or used in conjunction with other spatial preference tests.

Lateral differences in the GABAergic system of the rat striatum

Asymmetric differences have been found in the pre- and postsynaptic activity of the GABAergic system of the left and right striata of the rat. 3H-GABA binding shows a higher dissociation constant (KD) and a higher number of sites (Bmax) in the left striatum than in the right. Moreover, 3H-diazepam binding seems to be more extensively activated by GABA in the right striatum suggesting a more sensitive postsynaptic GABAergic activity than on the left side. However, when the presynaptic marker (GAD activity) was measured, the asymmetry was in the opposite direction. The results provide further neurochemical evidence of the functional asymmetry of the rat brain.

Intracortical 5,7-dihydroxytryptamine depletes brain serotonin concentrations without affecting spontaneous activity

Microinjections of either 2 or 4 micrograms of the serotonergic neurotoxin 5,7-dihydroxytryptamine (5,7-DHT) were made into either the right or left frontal cortex of male rats pretreated with desmethylimipramine. Although both the 2 and 4 micrograms doses produced significant depletions of serotonin concentrations in the cortex and median raphe, neither dose produced a significant increase in spontaneous activity. This is in contrast to our findings with the noradrenergic neurotoxins, 6-hydroxydopamine and DSP-4, which produced hyperactivity following right but not left hemisphere injections. These findings do not rule out the involvement of 5-HT in the asymmetrically elicited hyperactivity but they do suggest some transmitter and neural pathway specificity to the lateralized response to cortical injury.

Lateralized state-dependent learning produced by hippocampal kindled convulsions: effect of split-brain

In previous experiments, it was demonstrated that convulsions kindled from a ventral hippocampal focus in rats supported state-dependent learning which tended to lateralized to, and asymmetrical in, the right hemisphere. The question of the differential contribution of the left and right hippocampus to the production of state-dependency can best be addressed through confining the seizure to one or the other hemisphere via commissurotomy. In the present investigation, then, commissurally-intact and split-brain rats were implanted with bilateral hippocampal electrodes, then a left or a right focus was kindled. Later behavioral testing in an aversive inhibitory avoidance (IA) paradigm, revealed that intact animals, both left and right kindled groups, displayed good state-dependency. Split-brain animals, however, exhibited differential state-dependent responses to convulsive stimulation. Those kindled in the left hippocampus showed good retention when the conditions of seizure during training and testing were the same (same-state conditions), while showing deficient recall in changed-state conditions (a good state-dependent profile). On the other hand, those kindled in the right hippocampus displayed good retention of the IA experience in both same- and changed-state conditions. Differential recall after a left versus a right hippocampal convulsion in split-brain animals could not be accounted for in terms of differential seizure parameters, laterality of afterdischarge, extent of extracommissural damage or the extent of the actual transection. Possible mechanisms underlying this effect were discussed.

The neuropathology of amnesia

Relations between brain damage and memory disturbance are outlined with emphasis on the so-called amnesic syndrome. Following a brief introduction into forms of memory and memory failures, the basic causes of brain damaage (with relevance to amnestic failures) are described. Thereafter, the two best-known forms of brain damage-amnesia relations are reviewed: the consequences of damage to medial temporal lobe structures and to diencephalic regions. For the cases with medial temporal lobe damage, evidence is reported in greater detail for H.M., who has been examined more than any other amnesic patient for more than 30 years now, as a considerable amount of literature has accumulated on his behavior in diverse situations. Other cases with more or less circumscribed damage to medial temporal lobe structures are reviewed so as to outline criteria for or against the hypothesis that there are regions within the medial temporal lobe whose damage might be critical for the amnesic syndrome. Two cases of diencephalic amnesia are summarized in particular (cases of Mair et al., 1979) as they have received extensive neuropsychological and neuropathological investigation. Other cases with, for example, Korsakoff's disease are reviewed, as well as cases with diencephalic, or combined mesencephalic-diencephalic damage without nutritional causes. A third group of patients with massive, but still selective amnesic disturbances are then described: cases of basal forebrain damage, followed by descriptions of Alzheimer's disease which has similarities in the underlying neuropathology. This leads over to cases with more generalized intellectual deteriorations (dementia), which may have developed on the basis of primarily cortical damage or damage principally to basal ganglia structures. After reviewing cases with mainly material-specific memory failures--usually as a consequence of restricted neocortical damage--a separate section follows on patients in whom retrograde amnesia is the prominent symptom. The contribution of animal models of human amnesia is critically reviewed and discrepancies are analyzed between human and animal memory disturbances. This section emphasizes the value of investigating inter-dependencies between brain structures by pointing out that relations between memory disturbances and brain damage may be more complicated than apparent from a simple structure-function assignment. This aspect is further followed up in the conclusions.

Differential lateralization for positive and negative emotion in the human brain: EEG spectral analysis

The present experiment utilized EEG spectral analysis to investigate lateralization for emotional processes in the human brain. In frontal zones, a differential lateralization for positive and negative emotion was observed, with relative left-hemispheric activation (as measured by decreases in alpha abundance) for positive emotions and relative right-hemispheric activation for negative emotions. In parietal zones, a differential lateralization for verbal and spatial processes was observed, with relative left-hemispheric activation for verbal questions and relative right-hemispheric activation for spatial questions. Examination of EEG bands other than alpha (i.e. delta, theta, beta, and total power) suggested that emotional and cognitive processes are further distinguished by different EEG spectral patterns.

Neocortical asymmetry and open-field behavior in the rat

The total volume of the neocortex in each cerebral hemisphere was measured in male and female rats that had been exposed to one of two early experience treatments and subsequently tested behaviorally. Rats were either handled in infancy and raised in enriched environments or not handled in infancy and raised in standard lab cages. In adulthood they were tested in the open field for activity, for initial direction of movement out of the start box, and for laterality of wall-hugging behavior. Early experience did not have an effect on neocortical asymmetry, but a gender difference was disclosed. The right neocortex of males was larger than the left by a mean of 1.5%. Females rats did not show a significant asymmetry, although when asymmetry was present it was in favor of the left side. Cortical asymmetry correlated with open-field behavior. The degree of activity decreased with increasing neocortical asymmetry, and an interesting gender effect was present. Also, there was a positive correlation between neocortical asymmetry and direction of wall-hugging behavior, but only in animals with volume differences of less than 1%. These findings represent the first documentation of behavioral correlations with anatomic brain asymmetries in nonhuman species.

Emotionality and the course of collagen arthritis in the rat

43 female Sprague-Dawley rats were tested for emotionality using standard open-field procedures. The subjects were then injected with emulsified collagen-II. 31 responded with arthritic activity, clearly evidencing edema and erythema in from one to all 4 limbs. Duration of active response varied from 29 to 59 days. For the arthritic rats, severity of disease (combining duration and number of limbs by standard scores) correlated with both premorbid emotionality (where the partial r, controlling for preweight, was .47, with p < .01), and premorbid weight (where the partial r, controlling for pre-emotionality, was .38, with p < .05). The results encourage further study of premorbid behavioral tendencies as predictors of variations in arthritic responsivity.

Sex differences in the effects of early experience on the development of behavioral and brain asymmetries in rats

The influence of early experience (preweaning handling) on the development of several postural/motor asymmetries (side bias in an open field, turn preference in a T-maze, amphetamine-induced rotational behavior, tail pinch-induced asymmetries) and the lateralization of brain dopamine was studied in adult male and female rats. In many cases the adult patterns of behavioral and brain asymmetries were modified by early handling in a sexually dimorphic manner. In addition, the direction of postural/motor asymmetries was very much task-dependent, especially in females. We conclude that: early experience may modify the development of behavioral and brain asymmetries; sex differences in asymmetries are very common; early handling may affect males and females differently; and different measures of postural/motor asymmetries may reflect different and multiple brain asymmetries.

Asymmetrical locomotor response to unilateral cortical injections of DSP-4

The role of norepinephrine depletion in the lateralized production of spontaneous hyperactivity was assessed by unilateral fronto-cortical injections of either 10 or 20 micrograms of the noradrenergic neurotoxin, DSP-4 (N-2-chlorethyl-N-ethyl-bromobenzylamine hydrochloride). Ten micrograms of DSP-4 produced significant hyperkinesis only when injected into the right hemisphere. A 20 micrograms dose produced hyperactivity when injected into either hemisphere. DSP-4 injections resulted in significant NE and ipsilateral and contralateral 5HT depletions in the frontal cortex. The 20 micrograms right hemispheric injection significantly increased both DOPAC and DA levels in the contralateral caudate in a manner unrelated to behavior. These findings, in conjunction with results from previous neurotoxin studies, support a hypothesis of greater relative sensitivity to injury of right hemispheric NE terminal fields compared with injury to left hemispheric fields as demonstrated by spontaneous hyperactivity.

Effect of anterior-posterior lesion location on the asymmetrical behavioral and biochemical response to cortical suction ablations in the rat

Small cortical suction ablations were produced at one of several stereotaxically located sites along the anterior-posterior axis of the right or left hemisphere in the rat. Analysis of variance showed a highly significant effect of lesion location in the right hemisphere on locomotor activity. The most anterior lesions produced both the most hyperactivity and also the greatest reductions in the concentrations of norepinephrine in the ipsilateral and contralateral cortex and locus coeruleus. These results suggest that the effect of cortical lesions on spontaneous activity may be graded across the right hemisphere and that the anatomy of certain neurotransmitter pathways in the cortex may help to explain both the biochemical and behavioral findings.

Asymmetrical effects of cortical island lesions in the rat

Baseline spontaneous activity of male Sprague-Dawley rats was established in home running wheel cages 3 weeks prior to receiving cortical circumscription lesions. Circumscriptions 2 mm in diameter and 2 mm deep were produced by means of a rotating microknife and were centered approximately 9.0 mm anterior to ear bar zero. Circular knife cuts of the right, but not the homologous left cortex produced long-lasting depletions of ipsilateral and contralateral fronto- and posterio-cortical NE. Right hemisphere lesions produced a 35% increase in activity while left hemispheric lesions uniformly decreased spontaneous home cage running wheel activity by 35%. These results are consistent with our hypothesis that injury to transcortical pathways (perhaps noradrenergic fibers) are sufficient to produce lateralized spontaneous hyperactivity. The possible existence of competing excitatory and inhibitory mechanisms in the left frontal cerebral cortex is discussed.

Hemispheric asymmetry for a visuo-spatial task in monkeys

The hypothesis that hemispheric asymmetries for visuo-spatial ability exist in rhesus monkeys was tested using a task for which the right hemisphere is specialized in man. The task required discrimination between two squares, one containing a central dot and the other a dot displaced upwards from centre. The animals' thresholds were determined before and after left-sided (LH-lesion) or right-sided (RH-lesion) unilateral occipital lobectomy combined with splenial transection, and the percentage change in threshold calculated. The LH-lesion monkeys were all worse than the RH-lesion monkeys on this measure, indicating the existence of a functional asymmetry.

A balanced brain asymmetry modulates T cell-mediated events

Partial ablation of the left fronto-parietal cerebral cortex decreases the number of spleen T cells, impairs IgG-alpha SRBC and T mitogen-induced responses, and delays the response to alloantigens. In contrast, these events are increased following a symmetric lesion of the right neocortex. The findings extend previous results showing that the neocortex modulates NK activity and the efficacy of T cell-specific serum factors. B cells and macrophages are not affected. In these assays, mice subjected to ablation of one lateral cerebral neocortex serve as controls for symmetrically lesioned mice, in addition to no surgery or sham-operated controls. The findings suggest that brain lateralization for cognitive processes should be extended to T cell immune recognition. The phenomenon is present at a population level.

Lateralization of spatial preference in the female rat

Female rat pups were either left undisturbed in infancy and raised in lab cages or were handled in infancy and raised in enriched environments. In adulthood, animals underwent brain surgery consisting of: 1) a right neocortical ablation, 2) a left neocortical ablation, 3) a sham operation, or 4) no surgery. After recovering, they were tested for the initial direction of movement (left or right) in the open field. Nonhandled intact females were biased to move leftward indicating an asymmetrical brain organization. The intact handled-enriched group was unbiased. The right and left lesions caused the animals to move ipsilateral to the lesion, but there was no difference in the magnitude or response in either early experience group. Thus, early experience in the female rat has a different effect then in the male, and the nature of the brain organization in the two sexes is markedly different.

Hemisphere specialization of the animal brain for information processing principles

The experiments were performed on white rats. Different techniques for forming conditioned reflexes were used. Hemisphere cortex inactivation was carried out by means of spreading depression. The right hemisphere was shown to dominate for space perception, simultaneous information processing, concrete characteristics perception, and deductive processing; the left hemisphere was shown to dominate for time perception, successive information processing, abstract characteristics perception, and inductive processing. A hypothesis of induction and deduction being the main factors determining function lateralization in the hemispheres of the animal brain was put forward.

Left-handedness: association with immune disease, migraine, and developmental learning disorder

We report an experimental study designed to test the following hypothesis derived from clinical observations: There is an elevated frequency in left-handed individuals and in their families of immune disease, migraine, and developmental learning disorders. In two separate investigations the frequency of these conditions was compared in strongly left-handed subjects and in strongly right-handed controls. In each of the investigations we found markedly higher frequencies of immune disease in the left-handers than in the right-handers. The rate of learning disabilities was also much higher in the left-handers than in the right-handers in both investigations. In a second study the frequency of left-handedness was compared in patients with migraine or immune disease and in general population control subjects free of these disorders. There was a higher frequency of left-handedness in patients with migraine and myasthenia gravis than in controls. We present a brief outline of a hypothesis that may account for an increased frequency of immune disease in left-handers and in their families.

Suction lesions of the frontal cerebral cortex in the rat induce asymmetrical behavioral and catecholaminergic responses

Suction lesions of the right frontal cerebral cortex in rats induce a period of spontaneous hyperactivity. The hyperactivity, as measured by an increase in running wheel activity begins about one week post-operatively and continues throughout the remainder of a 30-day observation period. The increased activity is accompanied by a bilateral decrease in norepinephrine concentrations in both the ipsilateral and contralateral cortex and locus coeruleus. Identical lesions of the left frontal cerebral cortex produce neither the hyperactivity nor a decrease in norepinephrine concentrations. These experiments have reproduced many of the behavioral and biochemical asymmetries seen after middle cerebral artery ligation; however, suction lesions are both simpler to produce and histologically less variable in their effects.

Intracortical 6-hydroxydopamine induced an asymmetrical behavioral response in the rat

Doses of 6-hydroxydopamine (6-OHDA) from 1 to 6 microgram injected into the right frontal cortex of rats led to spontaneous hyperactivity beginning 1 week after injection and lasting throughout the 30-day postoperative period. Identical left hemispheric injections did not elicit hyperactivity until a dose of 6 microgram was reached. Biochemical assays revealed that 6-OHDA injected into either hemisphere caused approximately the same amount of depletion of norepinephrine. These results suggest that the neural asymmetry which leads to hyperactivity may be post-synaptic to the cortical noradrenergic terminals.

Mood change following left hemispheric brain injury

Eighteen patients with left hemispheric strokes were compared to 11 patients with traumatic brain injury for frequency and severity of depression, using several mood scales. More than 60% of the stroke patients had clinically significant depressions as compared with about 20% of the trauma patients, even though the two groups had comparable impairments in their activities of daily living and global cognitive functions. Analyses of brain CT scans revealed that the two groups had similar-sized lesions, but the areas of ischemic injury were more anterior than the traumatic lesions. When the results were controlled for lesion location, there were no significant differences in mood between the two groups. The severity of depression was directly correlated with the closeness of the lesion to the frontal pole. These results suggest that depression following left hemispheric brain injury may not be a nonspecific neurological or psychological response, but rather may be a symptom of injury to specific pathways, such as the catecholamine-containing ones, as they pass through the frontal cortex.

On the evolution and growth of lateralization

This is a welcome attempt to seek common biological principles underlying laterality in animals and humans. I do not think it is wholly convincing, but this is partly because many of the results from nonhuman species are not yet firmly established or understood. I suspect that the author's characterization of lateralization, with the left hemisphere supposedly specialized for communicative functions and the right for spatial and affective functions, will require modification. For instance, it now seems fairly clear that the left hemisphere in humans plays a general role in the production and perception of sequences not restricted to communicative acts (Craig 1980; Kimura 1979), and indeed some of the examples of left-hemispheric specialization listed in Table 2 are not obviously communicative. Even so, there are some fairly striking parallels between humans and nonhumans with respect to the pattern of lateralization, and one suspects that common principles are operating. At the same time, in the enthusiastic search for functional asymmetries, we should not overlook the striking degree of bilateral symmetry that characterizes the brains of all animals, including humans.