Neurochemical characterization of hypothalamic neurons involved in attack behavior: glutamatergic dominance and co-expression of thyrotropin-releasing hormone in a subset of glutamatergic neurons

The electrical stimulation of a specific hypothalamic area rapidly evokes attacks in rats. Noteworthy, attack-related hypothalamic structures were identified in all species studied so far. The area has been extensively mapped in rats, and its anatomical connections have been studied in detail. However, technical difficulties precluded earlier the precise identification of the neural elements mediating the aggressive effects of stimulation. It now appears that a dense and distinct group of glutamatergic cells expressing vesicular glutamate transporter 2 mRNA extends over the entire hypothalamic attack area. Rostral parts overwhelmingly contained glutamatergic neurons. In more caudal parts, glutamatergic and fewer GABAergic neurons were found. The remarkable similarity in the distribution of hypothalamic attack area and glutamatergic cell groups suggests that these cells mediate the aggressive effects of stimulation. Surprisingly, thyrotropin releasing hormone mRNA was co-localized in a subset of glutamatergic neurons. Such neurons were present at all rostro-caudal levels of the hypothalamic attack area, except for that part of the hypothalamic attack area extending into the ventro-lateral part of the ventromedial hypothalamic nucleus. Earlier data on the projections of hypothalamic thyrotropin releasing hormone neurons suggest that this subpopulation plays a specific role in attack behavior. Thus, we identified three neuronal phenotypes in the hypothalamic structure that is involved in the induction of attacks: glutamatergic neurons co-expressing thyrotropin releasing hormone, glutamatergic neurons without thyrotropin releasing hormone, and GABAergic neurons dispersed among the glutamatergic cells. Assessing the specific roles and connections of these neuron subpopulations would contribute to our understanding of the mechanisms underlying attack behavior and aggression.

Chronic glucocorticoid deficiency-induced abnormal aggression, autonomic hypoarousal, and social deficit in rats

Certain aggression-related psychopathologies are associated with decreased glucocorticoid production and autonomic functions in humans. We have previously shown that experimentally-induced chronic glucocorticoid deficiency leads to abnormal forms of attack in rats. Here, we compared the effects of acute and chronic glucocorticoid deficiency on aggressive behaviour, autonomic responses to challenges, and anxiety. Glucocorticoid synthesis was blocked acutely by the glucocorticoid synthesis blocker metyrapone or chronically by adrenalectomy and low glucocorticoid replacement (ADXr). As shown previously, chronic glucocorticoid deficiency facilitated aberrant attacks directed towards the most vulnerable parts of the opponent's body. The acute inhibition of glucocorticoid synthesis lowered aggressive behaviour without affecting attack targeting. In a different experiment, ADXr rats and their sham-operated controls were exposed to different challenges whereas their heart rate and locomotion were telemetrically recorded. Autonomic responses to social challenges were lowered by chronic, but not by acute glucocorticoid deficiency. Autonomic responses to the elevated plus-maze were only slightly affected by chronic glucocorticoid deficiency. Locomotor behaviour was not affected in either challenge; thus, the altered autonomic reactions were not due to interference from workload. The behaviour of ADXr rats was similar to that of sham-operated controls in the elevated plus-maze, but ADXr rats showed reduced social interactions in the social interaction test. Our data demonstrate that, in rats, chronic but not acute glucocorticoid deficiency induces abnormal attack patterns, deviant cardiovascular responses and social deficits that are similar to those seen in abnormally violent humans. Thus, the similar correlations found in humans probably cover a causal relationship. Experimentally-induced glucocorticoid deficiency may be used to assess the mechanisms underlying glucocorticoid deficiency-induced abnormal forms of aggressiveness.

Anticonvulsant drugs differentially suppress individual ictal signs: A pharmacokinetic/pharmacodynamic analysis in the cortical stimulation model in the rat

Antiepileptic drugs can suppress seizures completely, but they may also modify the appearance of drug-resistant seizures. In this study, the effects of three antiepileptic drugs on a seizure pattern were assessed by means of population pharmacokinetic/pharmacodynamic (PK/PD) modeling, yielding estimates of baseline response, EC50, and Hill slope. Lamotrigine did not affect eye closure, although it did suppress the other ictal signs in a concentration-dependent fashion. Midazolam suppressed forelimb clonus less potently than the other ictal signs; the same was observed for tiagabine with respect to eye closure. This study shows that ictal component analysis (ICA) in combination with PK/PD modeling may facilitate drug selection and dose optimization. The application of ICA is not restricted to a single seizure type or anticonvulsant drug and can be used to identify drug combinations that have a complementary action.

Deviant forms of aggression in glucocorticoid hyporeactive rats: a model for 'pathological' aggression?

Deviant forms of aggressiveness have been associated with low plasma glucocorticoid concentrations in humans. Here, we report data on the development of aggressive behaviour in rats in which glucocorticoid secretion was inhibited by adrenalectomy. Such rats were compared with both sham operated rats and adrenalectomized rats in which the fight-induced elevation of plasma glucocorticoids was mimicked by acute injections. Low and stable corticosterone plasma concentrations were maintained by subcutaneous glucocorticoid pellets in adrenalectomized rats. The development of aggressive behaviour was followed over three trials performed at 2-day intervals. Adrenalectomy lead to high aggressiveness already at the first encounter, a decreased threatening (attack signalling) behaviour and a change in attack targeting. While control rats targeted biting attacks towards less vulnerable dorsal parts of the opponent's body, adrenalectomized rats attacked the head frequently. Corticosterone injections that mimicked the fight induced adrenocortical reaction abolished this behavioural pattern. Thus, a reduced responsiveness of the adrenocortical system may be causally linked to deviant forms of aggression in rats.

Ultradian corticosterone rhythm and the propensity to behave aggressively in male rats

Ultradian fluctuations in plasma glucocorticoids have been demonstrated in a variety of species including humans. The significance of such rhythms is poorly known, although disorganized ultradian glucocorticoid rhythms have been associated with behavioural disorders. Here we report that ultradian glucocorticoid rhythms may establish the propensity to behave aggressively in male rats. Male rats were significantly more aggressive in the increasing phase of their corticosterone fluctuation when confronting a male intruder than counterparts in the decreasing phase of their corticosterone fluctuations facing such opponents. Corticosterone fluctuations were mimicked by a combination of treatments with the corticosterone synthesis inhibitor metyrapone and corticosterone. Again, males with increased plasma corticosterone levels were more aggressive than counterparts with a decreased plasma corticosterone concentration. These data suggest that the behavioural response to an aggressive challenge may vary in the same animal across the day due to the pulsating nature of corticosterone secretion. Aggressive behaviour is also episodic in humans; moreover, intermittent explosive behaviour is recognized as a psychological disorder. It can be hypothesized that a temporal coincidence between the occurrence of a challenge and a surge in plasma corticosterone concentration may be one of the factors that promote episodic aggressive outbursts.

The active phase-related increase in corticosterone and aggression are linked

Recently we demonstrated that corticosterone exerts an acute facilitatory effect on aggression in male rats. Corticosterone production reaches a maximum at the onset of the dark period, while male rats are more aggressive in the dark. Here we present evidence demonstrating that the corticosterone increase at the beginning of the dark period is causally linked to the increase in aggressiveness. We measured plasma corticosterone and quantified aggressive behaviour of male territorial rats at various time points of the day-night transition. Low aggression levels were observed in the full light period when plasma concentrations of corticosterone were low. An increase in plasma corticosterone occurred just prior to the dark phase, when aggressive responding was the highest. Aggressive behaviour remained high in the early dark period when corticosterone was still high. We found that blocking the high affinity mineralocorticoid receptor (MR) with spironolactone (5 or 10 mg/kg) during the early dark period dramatically and specifically reduced territorial aggression.

Neuropharmacology of brain-stimulation-evoked aggression

Evidence is reviewed concerning the brain areas and neurotransmitters involved in aggressive behavior in the cat and rodent. In the cat, two distinct neural circuits involving the hypothalamus and PAG subserve two different kinds of aggression: defensive rage and predatory (quiet-biting) attack. The roles played by the neurotransmitters serotonin, GABA, glutamate, opioids, cholecystokinin, substance P, norepinephrine, dopamine, and acetylcholine in the modulation and expression of aggression are discussed. For the rat, a single area, largely coincident with the intermediate hypothalamic area, is crucial for the expression of attack; variations in the rat attack response in natural settings are due largely to environmental variables. Experimental evidence emphasizing the roles of serotonin and GABA in modulating hypothalamically evoked attack in the rat is discussed. It is concluded that significant progress has been made concerning our knowledge of the circuitry underlying the neural basis of aggression. Although new and important insights have been made concerning neurotransmitter regulation of aggressive behavior, wide gaps in our knowledge remain.

The hypothalamus: cross-roads of endocrine and behavioural regulation in grooming and aggression

Anatomical and functional studies show that the hypothalamus is at the junction of mechanisms involved in the exploratory appraisal phase of behaviour and mechanisms involved in the execution of specific consummatory acts. However, the hypothalamus is also a crucial link in endocrine regulation. In natural settings it has been shown that behavioural challenges produce large and fast increases in circulating hormones such as testosterone, prolactin, corticotropin and corticosterone. The behavioural function and neural mechanisms of such fast neuroendocrine changes are not well understood. We suggest that behaviourally specific hypothalamic mechanisms, at the cross-roads of behavioural and endocrine regulation, play a role in such neuroendocrine changes. Mild stimulation of the hypothalamic aggressive area, produces stress levels of circulating prolactin, corticotropin, and corticosterone. Surprisingly luteinizing hormone does not change. This increase in stress hormones is due to the stimulation itself, and not caused by the stress of fighting. Similar increases in corticosterone are observed during electrical stimulation of the hypothalamic self-grooming area. The corticosterone response during self-grooming-evoking stimulation is negatively correlated with the amount of self-grooming observed, suggesting that circulating corticosterone exerts a negative feedback control on grooming. Earlier literature, and preliminary data form our laboratory, show that circulating corticosterone exerts a fast positive feedback control over brain mechanisms involved in aggressive behaviour. Such findings suggest that the hormonal responses caused by the activity of behaviourally specific areas of the hypothalamus may be part of a regulation mechanism involved in facilitating or inhibiting the very behavioural responses that can be evoked from those areas. We suggest that studying such mechanisms may provide a new approach to behavioural dysfunctions associated with endocrine disorders and stress.

Phamacokinetic-pharmacodynamic modelling of behavioural responses

Drug concentrations at the site of action in studies on behavioural pharmacology, are seldom constant. Therefore, observed changes in behaviour can be due to the natural time course of behavioural processes, but equally to changes in drug concentration, and it is therefore crucial to separate the former from the latter. One solution is keeping drug concentrations constant. However, one can also exploit the variation in drug concentration caused by absorption, distribution and elimination of a drug. This is done by simultaneous measurement of drug effect and concentration, while the drug enters and leaves a biologically relevant compartment, such as blood or cerebrospinal fluid. The concept of determining concentration-effect curves in individual animals, by monitoring in parallel drug effect and changes in concentration in one single experiment, has not yet found wide application in behavioural studies. The fact that behavioural processes, like any other physiological process, change over time, may have contributed to the scarcity of pharmacokinetic-pharmacodynamic (PK/PD) studies in behavioural pharmacology. However, there are now mathematical techniques that allow PK/PD modelling even if the effect parameter changes over time or cannot be properly assessed in every instance. Here we use PK/PD modelling to characterize fear-induced ultrasonic vocalizations and the anxiolytic effect of buspirone. This approach reduces the number of animals required to assess concentration-effect relationships. More importantly, it allows the identification of differences in individual drug response over a wide range of concentrations. Consequently, we suggest that PK/PD modelling can be used as a tool to study drug-induced changes in behavioural response. An introduction in PK/PD modelling is presented.

Acute effects of glucocorticoids: behavioral and pharmacological perspectives

There has been evidence since the early eighties that glucocorticoids, apart from their well known chronic effects, may have acute, short-term effects. However, a lack of understanding of the molecular mechanisms of action has hampered appreciation of these observations. Mounting evidence over the years has continued to confirm the early observations on a fast corticosterone control of acute behavioral responses. We summarize experimental data obtained mainly in rats but also in other species which show: (1) that glucocorticoid production is sufficiently quick to affect ongoing behavior; (2) that there exist molecular mechanisms that could conceivably explain the fast neuronal effects of glucocorticoids (although these are still insufficiently understood); (3) that glucocorticoids are able to stimulate a wide variety of behaviors within minutes; and (4) that acute glucocorticoid production (at least in the case of aggressive behavior) is linked to the achievement of the behavioral goal (winning). The achievement of the behavioral goal reduces glucocorticoid production. It is argued that glucocorticoids are regulatory factors having a well-defined behavioral role. Both the acute (stimulatory) effects and the chronic (inhibitory) effects are adaptive in nature. The acute control of behavior by corticosterone is a rather unknown process that deserves further investigation. The pharmacologic importance of the acute glucocorticoid response is that it may readily affect the action of pharmacologic agents. An interaction between acute glucocorticoid increases and noradrenergic treatments has been shown in the case of offensive and defensive agonistic behavior. Non-behavioral data demonstrate that acute increases in glucocorticoids may interfere with other neurotransmitter systems (e.g., with the 5HT system) as well. These observations show the importance of taking into account endocrine background and endocrine responsiveness in behavior pharmacological experiments.

Effects of repeated seizure induction on seizure activity, post-ictal and interictal behavior

Individual variability and numerous interactions between pharmacokinetics, pharmacodynamics, and homeostatic factors complicate the study of the anticonvulsant effect in animal models of seizure activity. In theory, both individual variability and the contribution of these factors to the anticonvulsant effect can be determined by following the time course of the pharmacological response and the corresponding plasma concentrations in individual animals. Currently, there are several formal pharmacokinetic-pharmacodynamic models available for the analysis of such data, which yield accurate estimates of drug intrinsic activity and potency. However, most models of seizure activity are not suited for such an approach, either because they can be applied only once, or because the expression of seizures is not constant over time. In addition, the induction of seizures constitutes repeated jeopardy to the animals, which may profoundly change behavior and interfere in the anticonvulsant response as well as in different physiological processes. In this paper, we compare ictal, post-ictal, and interictal behavior in three different models of seizure activity in rats, namely, the electroconvulsive shock, amygdala kindling and the cortical stimulation model (CSM). The methods were compared in the same way as they are currently in use for the assessment of antiepileptic drug effect. Our results show that repeated seizure activity induced by cortical stimulation does not exacerbate ictal activity (eye closure, jerk, gasp, forelimb clonus, and hind-limb tonus) nor post-ictal behavior (chewing and freezing), while producing less serious changes in interictal behavior (walk, lean, upright rearing, exploratory, grooming, and rest) than kindling or electroconvulsive shock. We conclude that seizures induced by cortical stimulation are reproducible and qualitatively similar to kindling seizures. Our results also suggest that the electroconvulsive shock model is not suited for pharmacokinetic-pharmacodynamic studies and that the assessment of interictal behavior may contribute to the evaluation of overall antiepileptic drug effect in seizure disorders.

Pharmacodynamic interaction between phenytoin and sodium valproate changes seizure thresholds and pattern

1. In this study we used cortical stimulation to assess the effects of phenytoin (PHT), sodium valproate (VPA), and their interaction on total motor seizure and on the constituent elements of the seizure. 2. PHT (40 mg kg(-1)) was administered as an intravenous bolus infusion to animals receiving either a continuous infusion of VPA or saline. VPA plasma concentration was maintained at levels that produced no detectable anticonvulsant effect. 3. Analysis of ictal components (eyes closure, jerk, gasp, forelimb, clonus, and hindlimb tonus) and their durations revealed both qualitative and quantitative differences in drug effects. 4. The anticonvulsant effect is represented by the increase in the duration of the stimulation required to reach a given seizure threshold. PHT significantly increased the duration of the stimulation and of the motor seizure. This increase was greatly enhanced by VPA. In addition, ictal component analysis revealed that the combination of PHT and VPA causes the reduction of a specific seizure component (JERK). 5. Neither the free fraction of PHT nor the biophase equilibration kinetics changes in the presence of VPA. It is concluded that the synergism may be due to a pharmacodynamic rather than a pharmacokinetic interaction.

Aggressive experience affects the sensitivity of neurons towards pharmacological treatment in the hypothalamic attack area

Early investigators of brain stimulation-evoked complex behaviours (attack, escape, feeding, self-grooming, sexual behaviour) reported that experience may affect the behavioural outcome of brain stimulation. This intriguing example of functional neuronal plasticity was later totally neglected. The present experiment investigated the behavioural outcome of in vivo microdialysis perfusion of the glutamate agonist kainate and/or the GABAA antagonist bicuculline into the hypothalamic attack area (HAA) of (1) animals naive to dyadic encounters; (2) animals with a recent aggressive experience (the probe being implanted 6-24 h after the last of a series of dyadic encounters); and (3) animals with an earlier aggressive experience (probe being implanted 2 weeks after the last aggressive experience). On the experimental day, rats received two 5-min infusions during a dyadic encounter lasting 35 min with an unknown opponent. Flow rate was 1.5-2 microliters/min, drug concentrations were 1.8 x 10(-5) and 1.5 x 10(-5) M for kainate and bicuculline, respectively. Behaviour was analysed before, during and after perfusions. Only the combined kainate + bicuculline treatment had significant effects on behaviour at the doses studied. A significant increase in aggressive behaviour was elicited only in animals with a recent aggressive experience, while naive animals and with an earlier experience responded to the treatments by grooming. These results appear to support early observations indicating that one important aspect of brain stimulation effects is previous experience.

Mineralocorticoid receptor blockade inhibits aggressive behaviour in male rats

Previous experiments have demonstrated that aggressive behaviour of male rats in a territorial setting is facilitated by corticosterone. Moreover, the inhibition of the endogenous corticosterone response prevents agonistic behaviour. The aim of the present paper was to investigate the effect of mineralocorticoid receptor (MR) blockade on the expression of aggressive behaviour at the beginning of the dark phase, when MRs are mostly occupied due to the diurnal peak of corticosterone secretion. High levels of aggressive behaviour were induced in male Wistar rats cohabiting with females by exposing them 3 times to an intruder male rat of smaller size. Intruder males were introduced at the beginning of the active period on every second day for 20 minutes, while the female was temporarily removed. A gradual increase in the number of biting attacks was noticed, the rats performing 6.7 +/- 2.0 attacks per 20 min on the last day (n=8). One hour before the fourth encounter rats were injected with the MR blocker spironolactone (10 mg/kg). Attacking behaviour was almost totally abolished (0.87 +/- .35 attacks per 20 min; n=8). Vehicle injections were ineffective (9.3 +/- 2.1 attacks per 20 min; n=8). Offensive threats underwent similar changes while other behaviours showed non-significant variation, with the exception of resting which increased towards the end of the observation period. The time course of these effects showed that the primary action was on offensive aggressive behaviour. This report is the first to show that the almost total MR occupancy at the beginning of the dark (active) period of the day is a prerequisite for the expression of aggressiveness in response to a social challenge.

Catecholaminergic involvement in the control of aggression: hormones, the peripheral sympathetic, and central noradrenergic systems

Noradrenaline is involved in many different functions, which all are known to affect behaviour profoundly. In the present review we argue that noradrenaline affects aggression on three different levels: the hormonal level, the sympathetic autonomous nervous system, and the central nervous system (CNS), in different, but functionally synergistic ways. Part of these effects may arise in indirect ways that are by no means specific to aggressive behaviour, however, they are functionally relevant to it. Other effects may affect brain mechanisms specifically involved in aggression. Hormonal catecholamines (adrenaline and noradrenaline) appear to be involved in metabolic preparations for the prospective fight; the sympathetic system ensures appropriate cardiovascular reaction, while the CNS noradrenergic system prepares the animal for the prospective fight. Indirect CNS effects include: the shift of attention towards socially relevant stimuli; the enhancement of olfaction (a major source of information in rodents); the decrease in pain sensitivity; and the enhancement of memory (an aggressive encounter is very relevant for the future of the animal). Concerning more aggression-specific effects one may notice that a slight activation of the central noradrenergic system stimulates aggression, while a strong activation decreases fight readiness. This biphasic effect may allow the animal to engage or to avoid the conflict, depending on the strength of social challenge. A hypothesis is presented regarding the relevance of different adrenoceptors in controlling aggression. It appears that neurons bearing postsynaptic alpha2-adrenoceptors are responsible for the start and maintenance of aggression, while a situation-dependent fine-tuning is realised through neurons equipped with beta-adrenoceptors. The latter phenomenon may be dependent on a noradrenaline-induced corticosterone secretion. It appears that by activating very different mechanisms the systems working with adrenaline and/or noradrenaline prepare the animal in a very complex way to answer the demands imposed by, and to endure the effects caused by, fights. It is a challenge for future research to elucidate how precisely these mechanisms interact to contribute to functionally relevant and adaptive aggressive behaviour.

Seizure patterns in kindling and cortical stimulation models of experimental epilepsy

A large number of animal models has been proposed for the evaluation of the anticonvulsant effect of antiepileptic drugs. Various seizure patterns are produced and differences are frequently observed in anticonvulsant effect estimates obtained for the same drug in different models. The incidence of seizures and the threshold for the induction are usually the only measures used for the determination of the anticonvulsant effect. However, behavioural components expressed during seizures induced by different means are likely to differ considerably. The aim of this study was to provide a detailed behavioural description of ictal and post-ictal components in two models of electrically induced seizure activity: kindling and cortical stimulation model (CSM). Seizure activity was induced in two groups of 6 Wistar-derived rats. Ictal and post-ictal behaviours were recorded on video tape and quantified using a computer supported frame-by-frame encoding of the behavioural components. We encoded the duration and rate of occurrence of the following behavioural items: whisker movements, eye closure, myoclonic jerk, facial gasping, forelimb clonus, forelimb tonus, hindlimb tonus, immobility and chewing. It appears that both models are, in many respects, qualitatively similar. However, the models differ quantitatively. Behavioural expression of seizure activity differs in the following respects: (1) the total duration of the seizure induced by cortical stimulation is shorter than by kindling; (2) seizure activity in the CSM occurs mainly during stimulation, while in amygdala kindling, it occurs thereafter; and (3) seizures evoked in the CSM comprise relatively less violent behavioural items than in the amygdala kindling. The evaluation of the ictal and post-ictal behavioural components suggests that behavioural analysis could assist in the detection of differences in the mechanisms of action of antiepileptic drugs. In addition, observational measures can also be used to assess animal distress inflicted by different experimental procedures.

A time-structured analysis of hypothalamically induced increases in self-grooming and activity in the rat

Stressors and different manipulations of the paraventricular nucleus of the hypothalamus (PVH) increase self-grooming in the rat. To assess the effect of these PVH manipulations on the timing of grooming in relation to other ongoing behavior, the authors describe these behavioral responses by a time-structured model. The authors show the following: (a) Behavior in each treatment group can be described by a semi-Markov model. Effects of treatments can be described as changes in the parameters of this model, which reflect the tendencies to start and stop grooming and other activities. (b) The PVH manipulations increase self-grooming by increasing the tendencies to start grooming or by extending the period during which grooming occurs. (c) Grooming responses are accompanied by an increase in activity. (d) Different PVH manipulations change the temporal structure of behavior differentially, suggesting that distinct mechanisms within the PVH are involved in the precise timing of grooming in relation to other activities.

Time structure of self-grooming in the rat: self-facilitation and effects of hypothalamic stimulation and neuropeptides

Specific brain manipulations, such as stimulation of the paraventricular nucleus of the hypothalamus (PVH) or injections of neuropeptides, increase self-grooming in the rat. Such manipulations also affect the different movements that constitute grooming. Using models to assess the time structure of these movements, the authors demonstrate that the rules that control the time structure within grooming are different from the ones that control its initiation. This study also showed that grooming is self-facilitating and that different brain manipulations in the same hypothalamic area induce structurally different kinds of grooming. The authors suggest that this part of the hypothalamus is not only involved in setting priorities to grooming, relative to other behaviors, but is also involved in the timing of different grooming components. These findings suggest that different neural mechanisms may be involved in the initiation and internal time structure of grooming.

A time-structured analysis of hypothalamically induced increases in self-grooming and activity in the rat

Stressors and different manipulations of the paraventricular nucleus of the hypothalamus (PVH) increase self-grooming in the rat. To assess the effect of these PVH manipulations on the timing of grooming in relation to other ongoing behavior, the authors describe these behavioral responses by a time-structured model. The authors show the following: (a) Behavior in each treatment group can be described by a semi-Markov model. Effects of treatments can be described as changes in the parameters of this model, which reflect the tendencies to start and stop grooming and other activities. (b) The PVH manipulations increase self-grooming by increasing the tendencies to start grooming or by extending the period during which grooming occurs. (c) Grooming responses are accompanied by an increase in activity. (d) Different PVH manipulations change the temporal structure of behavior differentially, suggesting that distinct mechanisms within the PVH are involved in the precise timing of grooming in relation to other activities.

Time structure of self-grooming in the rat: self-facilitation and effects of hypothalamic stimulation and neuropeptides

Specific brain manipulations, such as stimulation of the paraventricular nucleus of the hypothalamus (PVH) or injections of neuropeptides, increase self-grooming in the rat. Such manipulations also affect the different movements that constitute grooming. Using models to assess the time structure of these movements, the authors demonstrate that the rules that control the time structure within grooming are different from the ones that control its initiation. This study also showed that grooming is self-facilitating and that different brain manipulations in the same hypothalamic area induce structurally different kinds of grooming. The authors suggest that this part of the hypothalamus is not only involved in setting priorities to grooming, relative to other behaviors, but is also involved in the timing of different grooming components. These findings suggest that different neural mechanisms may be involved in the initiation and internal time structure of grooming.

Neuronal substrate of electrically induced grooming in the PVH of the rat: involvement of oxytocinergic systems?

Electrical stimulation of the paraventricular (PVH) and adjacent hypothalamic area evokes self-grooming behaviour. Current intensity thresholds for grooming can be obtained depending on the exact localization of the electrode site. Sites localized at greater distance of the center of the grooming area evoke grooming at greater latencies and higher current intensity, or no grooming at all. Results are compared with injections of neuroactive substances into the PVH from previous studies, which showed a similar site specificity for grooming. We found similarity in the distribution of electrode sites in the paraventricular and anterior hypothalamic areas at which grooming is induced, and hypothalamic immunoreactive oxytocinergic neurons and fibres. In addition, we reported earlier that oxytocin infusions into the PVH in resting animals induce grooming, in contrast to other grooming-related peptides, such as alpha-melanocyte-stimulating hormone. We hypothesize that electrical stimulation may induce grooming by activation of oxytocinergic systems originating from the PVH.

PVH lesions do not inhibit stressor-induced grooming in the rat

Electrical and chemical stimulation of specific parts of the paraventricular hypothalamus (PVH) and the adjacent hypothalamus induce self-grooming responses in the rat. The function of this hypothalamic grooming area (HGA) is not understood. The localization of the HGA in the hypothalamus suggests that grooming, a behavioural response to stressors, is somehow linked to the neuroendocrine response to stressors. In this study it is shown that grooming induced by the stressors, mild restraint and moistening of the fur of the rat, is not inhibited by complete, bilateral radiofrequency lesions of the HGA. The changes in grooming patterns observed following lesions suggest that the HGA may have a function in the timing of different grooming elements.

Effect of environmental stressors on time course, variability and form of self-grooming in the rat: handling, social contact, defeat, novelty, restraint and fur moistening

Grooming is often related to dearousal following stressors. Interestingly, electrical and chemical stimulation of the paraventricular nucleus of the hypothalamus (PVH), at levels that are known to activate the hypothalamus-pituitary adrenal axis (HPA), also elicits grooming. At the level of the PVH, the neuroendocrine stress response is apparently still linked to the behavioural response to stressors. However the precise nature of this relation is not fully understood. Here we report on grooming in rats following exposure to different stressors which are known to activate the HPA axis. Stressors such as handling, restraint, novelty, encounters with aggressive or non-aggressive conspecifics, or moistening the fur, change the amount and time course of grooming upon return in the home cage, as compared with controls that are just handled. However, the amount of grooming is not directly related to the strength of the stressor. Defeated intruders groom less upon return in their home cage. Novelty and non-aggressive encounters with conspecifics reduce the variation in the amount of grooming between rats. The time course of grooming over the 20-min observation period also differs between treatments. Following restraint, or exposure to non-aggressive conspecifics, grooming first increases and then decreases. Moistened rats immediately start grooming which subsequently decreases. Rats used as intruders in the territory of another rat maintain a constant low level of grooming. Rats placed in a novel cage steadily increase grooming during the 20-min observation period. These results suggest that grooming cannot be simply understood as an immediate response necessary to reduce arousal following stressors. Following exposure to a stressor, grooming rather seems temporary suppressed.(ABSTRACT TRUNCATED AT 250 WORDS)

Efferent connections of the hypothalamic "aggression area" in the rat

The efferent connections of the hypothalamic area of the rat, where attack behaviour can be elicited by electrical stimulation, were studied using iontophoretic injections of Phaseolus vulgaris-leucoagglutinin. Specificity for the hypothalamic "attack area" was investigated by comparison with efferents of hypothalamic sites outside the attack area. The hypothalamic attack area consists of the intermediate hypothalamic area and the ventrolateral pole of the ventromedial hypothalamic nucleus. Fibres from the hypothalamic attack area, as well as fibres from several other hypothalamic sites, form diffuse fibre "streams" running rostrally or caudally. Many varicosities that are found on the fibres suggest, that these fibres are capable of influencing many brain sites along their way. Projection sites were found throughout the brain. In the comparison between attack area efferents and controls, many overlapping brain sites were found. Hypothalamic efferents preferentially originating in the largest part of the attack area, i.e. the intermediate hypothalamic area, were found in the mediodorsal and parataenial thalamic nuclei. Within the septum, a spatial organization of hypothalamic innervation was found. Fibres from the attack area formed specialized "pericellular baskets" in the dorsolateral aspect of the intermediate part of the lateral septal nucleus. Fibres from other hypothalamic sites were found in other septal areas and did not form these septal baskets. Within the mesencephalic central gray, fibres from the attack area were found specifically in the dorsal part and dorsal aspect of the lateral part of the central gray. Physiological and pharmacological studies have shown that several brain sites are involved in different aspects of aggressive behaviour. Some of these areas, as for instance the dorsomedial thalamic nucleus, septum and central gray, are innervated by efferents from the hypothalamic attack area, whereas other sites, like ventral premammillary nucleus and ventral tegmental area, are not. It is concluded from the present findings, that a number of brain sites, that are known to be involved in agonistic behaviour, receive hypothalamic information preferentially from the hypothalamic attack area through diffusely arranged varicose fibres. The function of each connection in the regulation of specific behaviours remains to be further investigated.

Periaqueductal gray lesions do not affect grooming, induced electrically in the hypothalamic paraventricular area in the rat

Electrical stimulation inducing behavioral responses from the hypothalamus seems to activate systems involved in the execution phase of the behaviour rather than in the introductory or decision-making phase. However, the pathways involved are not fully understood. Projections originating from hypothalamic areas involved in specific behavioral responses are rather complex. The periaqueductal gray (PAG) has been proposed to be an essential output station of hypothalamic behavioral mechanisms. Here we report that lesions of the periaqueductal gray area have no effect on grooming responses evoked by electrical stimulation of the hypothalamic paraventricular area. Neither threshold current intensities needed to evoke grooming, nor latencies were affected 7 or 14 days after lesioning. The lesions caused severe behavioural deficits. Animals did not drink or eat spontaneously, had problems with motor coordination and sometimes showed strong defensive reactions upon touch. However, their grooming responses induced by hypothalamic stimulation were not changed. The PAG may have a modulatory role on grooming behaviour; however, this modulatory effect apparently is overruled during electrical stimulation of the hypothalamus.

Behavioural responses of bicucculline methiodide injections into the ventral hypothalamus of freely moving, socially interacting rats

Several studies, using electrical stimulation of parts of the hypothalamus, have shown, that different parts of the hypothalamus yield different behavioural responses upon stimulation. In order to differentiate between stimulation of neuronal cell bodies and passing fibres and to investigate the role of GABA in hypothalamically elicited behaviour, 25 local injections with bicucculline methiodide, a GABA antagonist, (35 ng/0.2 microliter) were performed in the ventral parts of the hypothalamus of 16 freely moving rats in a social environment. A cannula system was used that allowed injection without interruption of the ongoing social interactions. Digging, gnawing, drinking and attack behaviour were elicited in different animals. By plotting the behavioural responses of the animals into a detailed hypothalamic atlas, we assessed the hypothalamic distribution of the elicited behavioural responses. A number of injections elicited a combination of two or three different responses, probably due to diffusion of the substance, thus disinhibiting more than one behavioural system. Our results are in general agreement with previous electrical stimulation data and show that, in an overlapping pattern, different populations of neurons are involved in the elicitation of digging, gnawing, drinking and attack behaviour. In the hypothalamus, a tonic GABAergic inhibition of neurons involved in the display of these types of behaviour appears to exist.

Initiation of self-grooming in resting rats by local PVH infusion of oxytocin but not alpha-MSH

The present study was designed to discriminate between factors that initiate and/or prolong self-grooming. The study of factors initiating the grooming response is complicated by the fact that rats may groom already as a consequence of the injection procedure, due to release of endogenous substances after needle insertion or just handling of the animal. Therefore we used an infusion technique that allowed the rats to settle down quietly after they had been connected to an infusion pump, before the actual infusion of the peptide took place. In a previous report, we showed that direct injections of ACTH1-24 and alpha-melanocyte-stimulating hormone (alpha-MSH) into the paraventricular nucleus of the hypothalamus (PVH) prolong self-grooming caused by the injection procedure. Whether these peptides can also initiate grooming, however, is not yet clear. In this report, we compare the effects of alpha-MSH and oxytocin after infusion into the PVH in resting animals. Oxytocin is abundantly present in the PVH and is known to be involved in the regulation of grooming behavior. Slow infusions of oxytocin (0.1 microgram) do initiate grooming, but alpha-MSH (0.1 microgram) is without any behavioral effect. This suggests that oxytocin in the PVH is involved in the initiation of self-grooming, whereas alpha-MSH and probably ACTH do maintain grooming initiated otherwise, either by mechanical activation of the PVH and/or by the handling procedures. Infusion of substances in resting animals apparently is a way to avoid interactions between ongoing overt behavior and peptide-induced effects.

Induction of grooming in resting rats by intracerebroventricular oxytocin but not by adrenocorticotropic hormone-(1-24) and alpha-melanocyte-stimulating hormone

Adrenocorticotropic hormone (ACTH) and alpha-melanocyte-stimulating hormone (alpha-MSH) injected i.c.v. induce so called 'excessive grooming'. Whether these peptides play a role in the initiation of grooming is not clear, since rats will groom even as a consequence of a particular environmental stimulation, such as handling and/or a novel environment. In most studies, therefore, the first 15 min after i.c.v. injection are not examined. Here we report on the effects of slow i.c.v. infusions of ACTH-(1-24), alpha-MSH and oxytocin in resting rats in their home cages. Interestingly, i.c.v. infusions of oxytocin did initiate grooming in a dose-related way. In contrast, i.c.v. infusions of both ACTH-(1-24) and alpha-MSH in resting rats were without effect on grooming. Oxytocin is apparently involved in the initiation of self-grooming in rats, whereas ACTH and alpha-MSH prolonged grooming initiated by other means, e.g. handling procedures and/or a novel environment. We conclude that the effects of alpha-MSH and ACTH on grooming are conditional, depending on the behavioural state (active or resting) of the animal.

Differential effect of ACTH1-24 and alpha-MSH induced grooming in the paraventricular nucleus of the hypothalamus

Injection of ACTH1-24 as well as alpha-MSH in the paraventricular nucleus of the hypothalamus (PVH) induces intense grooming in the rat. While comparing the details of MSH, ACTH and control grooming, we found that the induction of grooming was highly site specific. Even injection of saline in that specific area produced some grooming, possibly due to the release of endogenous substances. To distinguish between effects caused by the peptides and the effects caused by the injection procedure, we compared the behavioural effects of saline and peptide injections in sites with exactly the same location in the PVH, in a post-hoc matched pairs design. Using this design we found that the grooming response induced by saline is of a limited duration. ACTH1-24 and alpha-MSH prolong grooming beyond that period. Interestingly, rats receiving alpha-MSH continued to groom, while rats receiving ACTH1-24 changed to scratching. This confirms earlier findings suggesting that grooming and scratching have a differential organization at the level of the PVH. Whether the peptides also have a role in the initiation of the grooming response, or just prolong a response caused by other local factors requires another experimental approach.

Ethology and pharmacology of hypothalamic aggression in the rat

Stimulation of a restricted area of the rat's hypothalamus elicits unprovoked violent attacks of a species-specific and strain-specific nature. Serotonergic drugs affecting 5HT1 receptors, propranolol, the 5HT re-uptake inhibitor fluvoxamine, and the anxiolytic oxazepam, inhibit hypothalamic attack selectively. However, hypothalamic attack is extremely unsensitive for many drugs that do affect attack provoked by natural stimuli. The pharmacology, the form, the impulsive nature, the absence of preliminaries, the insensitivity for contexts and ultimate aims of aggressive behaviour, suggest that a mechanism with the limited function of damaging adversaries of any kind is activated in the hypothalamus. This hypothalamic attack release mechanism (harm) requires specific sensory input for the expression of specific motor components, such as biting and kicking. The back and dorsal part of the opponent's head are the important attack releasing and directing stimuli. Attacks of this nature are part of the "aggressive" repertoire of the rat in natural settings. "Lateral" or "sideways" postures, specific for intermale fighting cannot be induced by hypothalamic stimulation. Drug, lesion, and stimulation studies suggest that attack and "sideways" postures are under the control of different central mechanisms. These results suggest new ways to describe the patterning of aggressive behaviour. There are interesting ethopharmacological similarities between hypothalamic responses and obsessive compulsive disorders (OCD) in man. It is suggested that further study of the ethopharmacology of hypothalamic responses may shed light on the pathophysiology of impulsive behavioural symptoms which in man seem to be beyond the control of appraisal or context.

Behavioural effects of NMDA injected into the hypothalamic paraventricular nucleus of the rat

Electrical stimulation of the hypothalamic paraventricular nucleus (PVH) and of the adjacent dorsal hypothalamic area (DHA) evokes grooming behaviour. Microinjections of low doses of kainic acid, an agonist of the kainate type of glutamate receptors, into the same area evokes the same behaviour. To test whether other glutamate receptors are involved, microinjections with N-methyl-D-aspartic acid (NMDA) were made into the PVH/DHA area and the behaviour was observed. From the total observation time (30 min) up to 73% was spent on grooming, accompanied by yawning. Pronounced feeding behaviour was also noticed at 3 injection sites but not until 23 min after injection. Conclusions are that neurones within the PVH/DHA area are involved in grooming behaviour, possibly via glutamatergic innervation. The interaction between grooming and feeding behaviour at the level of the PVH is discussed.

Grooming induced by intrahypothalamic injection of ACTH in the rat: comparison with grooming induced by intrahypothalamic electrical stimulation and i.c.v. injection of ACTH

Intracerebroventricular (i.c.v.) injection of adrenocorticotropic hormone (ACTH) elicits grooming in the rat, but the neural organization of this response is still obscure. Electrical stimulation (EHS) in an area around the hypothalamic paraventricular nucleus (PVH) also elicits grooming. This hypothalamic area contains many ACTH-immunoreactive fibres. Injection of ACTH1-24 (0.3 microgram/0.3 microliters) in the same area elicits intense grooming responses in the rat. Latency, intensity and precise patterning of the grooming response are dependent upon the exact site of injection. Comparison of grooming responses elicited by EHS, ACTH injected i.c.v. and ACTH injected in the PVH reveals that these are slightly dissimilar. This may provide clues as to the brain mechanisms involved in the organization of the different components of grooming. EHS does not elicits scratching and even reduces 'spontaneous' scratching. Also, EHS-elicited grooming is characterized by short pauses. The time-course of appearance of yawning differs between ACTH-PVH and ACTH-i.c.v. injections. Excited locomotion elicited only by ACTH-i.c.v. is apparently caused by ACTH-sensitive systems outside the PVH. The results suggest that the ACTH-containing part of the hypothalamus around the PVH is crucially involved in the organization of grooming behaviour. We believe that at this level in the brain, the subroutines of grooming, scratching and yawning are integrated into one skin maintenance behaviour.

Interactions between simultaneously activated behavioral systems in the rat

Interactions between electrically induced attack and teeth-chattering from 1 electrode and grooming from another were examined in male albino rats. The interaction between electrically induced attack and deprivation-induced feeding, as well as the effect of food deprivation on attack, was also studied. Results indicate that attack appears to be a dominant response, for it suppressed grooming and feeding at a low level of activation. On the other hand, it was not affected by simultaneously induced grooming or feeding. However, food deprivation decreased the threshold for attack, leaving attack latency, attack form, or bite targets unaffected. Teeth-chattering, suggested to be related to attack and flight, was also a dominant response. Results suggest that interactions between behavioral systems are in favor of the systems that must act acutely on activation in order to survive. Apparently, the regulations governing these interactions are represented in the functional organization of the brain.

Interactions between simultaneously activated behavioral systems in the rat

Interactions between electrically induced attack and teeth-chattering from 1 electrode and grooming from another were examined in male albino rats. The interaction between electrically induced attack and deprivation-induced feeding, as well as the effect of food deprivation on attack, was also studied. Results indicate that attack appears to be a dominant response, for it suppressed grooming and feeding at a low level of activation. On the other hand, it was not affected by simultaneously induced grooming or feeding. However, food deprivation decreased the threshold for attack, leaving attack latency, attack form, or bite targets unaffected. Teeth-chattering, suggested to be related to attack and flight, was also a dominant response. Results suggest that interactions between behavioral systems are in favor of the systems that must act acutely on activation in order to survive. Apparently, the regulations governing these interactions are represented in the functional organization of the brain.

Hypothalamic substrates for brain stimulation-induced patterns of locomotion and escape jumps in the rat

The hypothalamic response area for electrically induced locomotion was determined using moveable electrodes and discriminant analysis as an appropriate statistical technique. At 241 out of 641 stimulated sites locomotion was induced. The distribution of locomotion sites is relatively diffuse. Discriminant analysis of both positive and negative electrode localizations yields areas with high, intermediate or low probability of inducing the response. The response is considered to be mediated by fibres of the subpallido-pedunculopontine system, which includes the mesencephalic locomotor region. Different categories of exploratory and flight-directed locomotion were distinguished, and response areas for both categories were determined. In addition the response area for escape jumps was delimited. Exploratory locomotion is mainly induced from the lateral hypothalamus, while flight-directed locomotion and escape jumps are evoked from the medial hypothalamus. The response area for exploratory locomotion reflects the lateral hypothalamic distribution of the subpallidal projection to the mesencephalic locomotor region. A diffuse substrate for flight behavior seems to occupy almost the entire medial hypothalamus. It is concluded that a locomotor subroutine subserving different behavioural mechanisms can be activated at many hypothalamic sites.

Hypothalamic substrates for brain stimulation-induced attack, teeth-chattering and social grooming in the rat

In this paper the boundaries of the hypothalamic response areas for brain stimulation-induced attack, social grooming and teeth-chattering were delimited. A total of 641 hypothalamic sites in 71 male CPW/WU Wistar rats were electrically stimulated. Positive sites for any behavioural response cluster into restricted hypothalamic areas. Discriminant analysis of both positive and negative electrode localizations yields areas with high, intermediate and low probabilities of inducing the behavioural response concerned. Each response has its own response area where probabilities are high. Neuroanatomical correlates of these response areas are discussed. The response area of attack is suggested to be an integrative processing area, stimulation of which overrules some aspects of integration and directly activates the behavioural program of attack. Although some authors consider all three responses to be part of the behavioural repertoire of aggression, the response areas are not identical. Social grooming and attack are considered to be induced from different neural systems. Similarly, attack and teeth-chattering have been shown to derive from different neural mechanisms, despite substantial overlap of both response areas. It is suggested that teeth-chattering derives from the simultaneous activation of both attack and flight tendencies. No further distinctions with respect to threshold current intensities can be made within responses areas. However, the underlying neural substrates are not homogeneous, for thresholds vary along the course of individual electrodes.

Hypothalamic substrates for brain stimulation-induced grooming, digging and circling in the rat

Despite a great number of studies concerned with the induction of specific behavioural responses from the rat hypothalamus by electrical brain stimulation, hypothalamic response areas and underlying neural substrates have never been determined accurately. In this study the boundaries of the hypothalamic response areas for grooming, digging and circling were delimited using moveable electrodes, an enriched environment containing a variety of goal objects, and an appropriate statistical technique. A total of 641 hypothalamic sites in 71 male CPB/WU Wistar rats were electrically stimulated. Results are plotted on a detailed stereotaxic brain atlas of the rat hypothalamus. Positive sites for any behavioural response cluster into restricted hypothalamic areas. Discriminant analysis of both positive and negative electrode localizations yields areas with high, intermediate or low probabilities of inducing the behavioural response concerned. Each response has its own response area where probabilities are high, although there may be overlap. Even within response areas a distinction can be made between areas in which the response can be induced at relatively high or low threshold current intensities. Lowest threshold sites within electrode tracks are often clustered. In search of neuroanatomical correlates, grooming is related to the distribution of ACTH-immunoreactive neural elements, digging is related to the distribution of efferent fibres from the bed nucleus of the stria terminalis, and circling is related to the distribution of dopaminergic fibres of the nigrostriatal pathway. The results clearly point to the stimulation site being the most important determinant of the evoked behavioural response. Evidently behavioural specificity does exist within the hypothalamus.

Postpartum aggression in rats does not influence threshold currents for EBS-induced aggression

Female Wistar rats were tested for aggressive behaviour induced by electrical brain stimulation (EBS) in the lateral hypothalamus. Threshold currents for the induction of aggression were determined on several days before the females were paired with experienced breeder males. Beginning in the second week of pregnancy threshold current values were measured once or twice weekly. No change in thresholds was observed either during pregnancy, the early postpartum period or after weaning. Lactation was the only period during which the females were spontaneously aggressive towards male intruders in their home cage, but not in the EBS cage. Analysis of bite targets revealed no difference between the bite patterns in the postpartum maternal aggression test and the EBS-induced attacks. The results demonstrate that the change in physiological and hormonal status in pregnant and lactating females has no influence on the propensity to attack during EBS. The similarity in wound patterns does not advocate a major difference in the types of aggression studied. We speculate upon the nature of EBS-induced attacks as the activation of a rigid, final pathway of aggression which is rather insensitive to mild modulations.

A locked, non-rotating, completely embedded, moveable electrode for chronic brain stimulation studies in freely moving, fighting rats

A light-weight, yet rugged moveable electrode assembly is described for chronic brain stimulation studies in small-brained animals. The assembly can be completely embedded in a smooth, unobtrusive dental cement cap and is therefore suitable for use in fighting experiments, where collisions with partners and cage walls will limit the use of other assemblies. It permits a variable electrode distance penetration of 3 mm in 75 mu-steps by using a separate unlocking turning-key. This design excludes the possibility of inadvertent displacement of the electrode tips by the animal itself. Since the electrode itself does not rotate during displacement, extra damage arising from possible eccentricity is avoided. The assembly has been used in a number of hypothalamic penetrations, demonstrating its usefulness and reliability.

Discriminant analysis of the localization of aggression-inducing electrode placements in the hypothalamus of male rats

Over 400 sites in the hypothalami of 270 male CPB/WE-zob rats were electrically stimulated in order to induce fights between males. The localization of electrodes inducing fights seems to differ from the localization of electrodes in which no fights can be induced. The differences in localization were detected and tested by a non-parametric discriminant analysis. The results were plotted by computer in a stereotaxic atlas of the hypothalamus of the CPB/WE strain. The method delimits areas within the hypothalamus where the probability to induce aggression is high, intermediate or low. Moreover, the procedure allows discrimination between areas where the thresholds for attack behaviour are generally lower than elsewhere and where the fiercest forms of attack are induced. None of the areas delimited coincide with a classical subdivision of the hypothalamus. Parts of the perifornical, anterior, lateral and ventromedial hypothalamus seem to be involved. The methods developed here may help to relate stimulation-induced aggression to other characteristics of the 'aggressive' area which cannot be obtained directly from fighting rats such as cytological, endocrinological, biochemical or physiological data. In addition, the procedure may help to settle disputes on the specificity of the localization of neural substrates of other stimulation-induced behaviours. The methods to discriminate between overlapping 3-dimensional reconstructions validated here for aggressive responses, can also be applied to other types of stereotaxic data and other types of effects, such as electrical, hormonal or other physiological responses. They may be especially useful if the localization of the neural population involved is not yet known, and unknown current-spread or diffusion of substances complicates the interpretation of stereotaxic data.

Anti-aggressive effect of a new phenylpiperazine compound (DU27716) on hypothalamically induced behavioural activities

Using the same hypothalamic electrodes, the following behaviour was evoked in male rats by electrical stimulation at roughly equal current intensities: attacks on a partner, teeth-chattering, switch-off behaviour and locomotion. Current thresholds were determined for each behaviour following the intraperitoneal administration of saline or DU27716, a new phenylpiperazine compound with interesting inhibitory effects on territorial and intermale aggression. DU27716 raised current thresholds for attack and teeth-chattering beginning at the lowest dose (4 mg/kg), whereas there was no effect on switch-off behaviour, and only a slight but significant effect on locomotion thresholds at the highest dose (8 mg/kg). The results provide support for the hypothesis that DU27716 possesses behaviourally selective, anti-aggressive properties, and illustrate the usefulness of hypothalamically induced behaviours as a pharmacological model.

Aggression induced by stimulation of the hypothalamus: effects of androgens

Aggressive behavior between male rats induced by electrical stimulation of the hypothalamus (ESH) is stimulated by androgens. This was demonstrated by recording the changes in threshold current intensities (the amount of current needed to induce attack behavior in 50% of the trials), just before castration, after castration, during subsequent treatment with high doses of testosterone propionate, and finally during oil treatment. The results demonstrate that, to induce the same aggressive responses, in absence of androgens more electrical current is needed than when these hormones are present in the general circulation of the ESH stimulated animals.