Sensory neglect produced by lateral hypothalamic damage.

Unilateral lateral hypothalamlic lesions in rats produce deficits in orientation to contralateral visucal, olfactory, whisker-toluch, and somatosetnsory stimuli. This syndrome of sensory neglect appears to be involved in some of the deficits in feedinig and attack which follow bilateral lateral hypothalamic lesions.

Compulsive, abnormal walking caused by anticholinergics in akinetic, 6-hydroxydopamine-treated rats.

In otherwise profoundly akinetic rats that had been severely depleted of brain catecholamines, anticholinergic drugs caused excessive walking. The effect did not appear until 10 days after surgery and then increased with time, suggesting that a phenomenon analogous to denervation supersensitivity may be involved. If the animals walked into corners, they were unable to turn around or back out. Their gait (extremely short steps) was reminiscent of that of patients with Parkinson's disease. The results are consistent with a mutually antagonistic interaction between cholinergic and dopaminergic brain systems and emphasize certain complexities in this interaction.

Travel medicine resources for Canadian practitioners.

OBJECTIVE: To provide travel medicine practitioners with a comprehensive (though not exhaustive) list of resources. Resources that appear to be most frequently used by health professionals currently practising this specialty have been included. METHODS: Select members of TravelMed, an international e-mail discussion forum for travel medicine practitioners were informally canvassed and presented with a question regarding which travel medicine resources they find to be most useful. Their responses informed the development of this Statement. In addition, the opinions of experts in travel medicine were solicited to identify resources. The scope was international; however, particular attention was given to Canadian sources of information. RESULTS: Travel medicine resources are listed and organized into the following categories: Courses, conferences and local travel medicine groups; Books; Canadian recommendations; Handbooks; periodicals and reports; Journals; Internet medicine forums; Online subscription services; Outbreak reports and travel advisories; Sources of malaria recommendations; More useful websites; Travel medicine clinics in Canada and abroad; and Certification. CONCLUSION: There are many Canadian and international resources available to inform Canadian travel medicine practitioners.

Compound complementarities in the study of motivated behavior.

In his classic article, Stellar (1954) proposed that diverse motivated behaviors reflected the activity of excitatory and inhibitory centers in the hypothalamus. His specific and testable ideas provided the theoretical focus for a great deal of fruitful research on the biological bases of behavior for 2 decades. Subsequently, new findings and technical developments again changed the perspective and experimental approaches in behavioral neuroscience. The authors suggest that the modern emphasis on the anatomy and chemical function of neuronal systems has come at the expense of understanding the subcomponents of behavior and the hierarchical levels of integration involved in transforming reflexes into operant acts. Increased attention in the future to the infrastructure of the behaviors being elucidated, when combined with reductionistic studies of neurons, will fulfill the potential contribution to behavioral neuroscience that is implicit in Stellar's article.

The morphogenesis of stereotyped behavior induced by the dopamine receptor agonist apomorphine in the laboratory rat.

The seemingly unrelated stereotyped locomotor "acts" reported in the literature to be produced by apomorphine in rats are shown to be composites, whose form and sequence are determined by the particular values of a few component variables which form a common denominator in each of the behaviors. Three variables, continuous snout contact, forward progression and turning, account for much of the behavior. In the course of the drug's action these emerge in succession and vary in amount, the latter two successively reaching a peak and subsiding. The interaction between forward progression and turning yields in sequence, forward walking, circling, revolving, tight pivoting and finally side-to-side movements of the forequarters around the relatively stationary hindquarters. Later behaviors in this list are gradually incorporated into the sequence as earlier ones are eliminated. The course of change in forward progression and turning is also reflected in changes in the sequence and in the direction of stepping of each of the four legs. The order in which the behavior unfolds under the drug is opposite to that manifested in ontogeny and in recovery from lateral hypothalamic damage, suggesting that at the particular high dose used, apomorphine is acting not only to activate the behavior but also to shut it down.

Morphine catalepsy as an adaptive reflex state in rats.

These experiments demonstrate that morphine-induced catalepsy consists of two complementary, but opposite, behavioral extremes (rigid immobility and sudden locomotor bursts), each of which can be controlled by distinct classes of external stimuli. When stimuli that involve pain and/or nonnociceptive skin pressure are tonic (continuous), morphine-induced electroencephalographic (EEG) deactivation and behavioral immobility are potentiated, even to the extent that a stimulation-bound reversible coma results. In contrast, phasic (discrete) stimulation produces behavioral and/or EEG activation. EEG and behavioral rebound effects are observed following stressful (intense, prolonged) stimuli. On the basis of the observed stimulus controls, sensorimotor characteristics, and EEG reactions, it is suggested that similarities may exist between morphine-induced catalepsy and defensive reactions of immobility and escape in drug-free animals (i.e., the adaptive death- feigning reflex).

Reversal of akinesia and release of festination by morphine or GABA applied focally to the nucleus reticularis tegmenti pontis.

Focal application of 5 micrograms of morphine sulfate to the nucleus reticularis tegmenti pontis (NRTP) in rats reversed the akinesia induced by 5 mg/kg systemic haloperidol or 40 mg/kg systemic morphine and released festinating forward locomotion. gamma-Aminobutyric acid (200 micrograms) applied to this nucleus also reversed such akinesia. Intraventricular naloxone (10 micrograms) or picrotoxin (0.1 microgram), respectively, blocked the effects of such focally applied drugs. Thus, morphine and gamma-aminobutyric acid appear to act physiologically on the cells of the NRTP. The results suggest that systemic morphine, in addition to producing immobility, simultaneously facilitates a readiness for locomotion by inactivating a final common inhibitory system in the region of the NRTP.

Previous experience disrupts atropine-induced stereotyped "trapping" in rats.

Three experiments were conducted to investigate the phenomenon of atropine-induced stereotypic trapping in rats reported by Schallert, De Ryck, and Teitelbaum (1980). The first two showed that such trapping was disrupted by previous experience with the specific trapping task or the test context alone. The third showed that, in response to the test context, specific behaviors were altered in rats experienced with the context. Inexperienced atropine-treated animals moved slowly and showed a strong thigmotaxis to surfaces with the body and particularly the snout. The hindquarters did not cooperate well with the movements of the forequarters. In contrast, atropine-treated animals familiar with the context moved with medium-speed, coordinated movements, were independent of surface contact with body and snout, and the hindquarters cooperated fully with forequarter movements. These reactions of drugged animals were exaggerated forms of those of undrugged animals to the unfamiliar and familiar context, respectively. Thus, atropine enhances the reactions of the rat to both a novel and a familiar environment. The enhanced reactions to a novel environment appear as stereotyped behaviors that trap the animal in particular configurations of surfaces. The enhanced reactions to a familiar environment abolish the stereotypic trapping normally produced by atropine. This pattern of results indicates that it is not atropine per se that leads to trapping. Rather, stereotypic trapping develops as a consequence of an interaction between the adaptive responses of the rat to a novel environment and atropine.

Morphine subtracts subcomponents of haloperidol-isolated postural support reflexes to reveal gradients of their integration.

Although cataleptic rats do not spontaneously orient, scan, or walk, they will cling, stand, right themselves in the air, and resist being displaced from a stable position (Schallert, Whishaw, De Ryck, & Teitelbaum, 1978). Morphine produces a state of immobility in which all reflexes used for stable static support (e.g., standing, righting, clinging, and bracing) appear to be inhibited (De Ryck, Schallert, & Teitelbaum, 1980). Addition of morphine to haloperidol abolished or reduced those reflexes used to defend against slow postural displacements (e.g., bracing) but left intact those used to protect against fast postural displacements (e.g., righting in the air). However, although intact, these responses to fast postural displacements were completely abolished by labyrinthectomy, showing that they were controlled only by vestibular inputs. During recovery from morphine's effects, the responses to slow postural displacements reemerged, revealing fractional subcomponents. Furthermore, the reorganization of the subcomponents proceeded along specific body gradients; for example, bracing and standing reemerged caudorostrally, while at the same time, righting and clinging reemerged rostrocaudally.

Escalation of feline predation along a gradient from avoidance through "play" to killing.

In this article, we show that feline predation involves a continuous gradient of activation between defense and attack and that predatory "play" results from an interaction of the two. Benzodiazepines (oxazepam, diazepam) escalated attack toward killing, so that cats that had avoided mice prior to the drug now played with them, cats that had originally played now killed, and cats that killed mice now did so with less preliminary contact. In such shifts, no sharp demarcation between play and predation was evident. Lateral hypothalamic lesions disrupted the escalation of attack. During recovery, attack was escalated once again along the gradient toward killing, but in the absence of both defense and play. A similar result was obtained in intact killers and nonkillers by the application of mild tail pinch. These results suggest that play with prey is a misnomer for predatory behavior that fails to escalate along the gradient between defense and attack. Movement notation analysis revealed that playful movements are adaptive in that they protect the cat from injury.

Effect of food and antacid on absorption of orally administered ticlopidine hydrochloride.

Ticlopidine is a potent inhibitor of platelet aggregation. Absorption of ticlopidine after oral dosing is rapid and complete. Ticlopidine is extensively metabolized with a relative minor component of unchanged ticlopidine in plasma. The randomized crossover study described here was undertaken to examine the effect of food and antacid on the oral bioavailability of a single dose of ticlopidine (250 mg) in normal volunteers. After postprandial treatment the rate and extent of absorption of ticlopidine was earlier and greater relative to fasting treatment [tmax = 1.71 +/- 0.33 hr (fed) vs 1.92 +/- 0.56 hr (fasting) and AUC0-infinity = 2.164 +/- 0.813 micrograms X hr/mL (fed) vs 1.808 +/- 1.052 micrograms X hr/mL (fasting)]. The oral bioavailability of ticlopidine was increased by 20% when taken after a meal. In contrast, absorption of ticlopidine administered after antacid treatment was approximately 20% lower than under fasting conditions. Administration of ticlopidine with food is recommended to maximize gastrointestinal tolerance.

The pharmacokinetics and safety profile of oral ganciclovir combined with zalcitabine or stavudine in asymptomatic HIV- and CMV-seropositive patients.

Two open-label, randomized, multiple-dose, three-way crossover studies were performed to assess the pharmacokinetics and safety of oral ganciclovir 1000 mg q8h in asymptomatic patients seropositive for human immunodeficiency virus and cytomegalovirus. Ganciclovir was administered alone and in combination with zalcitabine 0.75 mg q8h (study 1) or stavudine 40 mg q12h (study 2). In the presence of zalcitabine, the only statistically significant change in the pharmacokinetic parameters of ganciclovir was a 22.2% mean increase in AUC0-8. However, there was no significant change in the renal clearance of ganciclovir when coadministered with zalcitabine, suggesting that the increase in serum ganciclovir concentration cannot be attributed to competition for active renal tubular secretion. No change in zalcitabine pharmacokinetics was observed in combination with ganciclovir. There were no significant changes in the pharmacokinetics of ganciclovir or stavudine when coadministered. Ganciclovir was well tolerated when given alone and in combination with either zalcitabine or stavudine.

Labyrinthine and other supraspinal inhibitory controls over head-and-body ventroflexion.

The vestibular head righting reflex can be demonstrated by holding an adult rat vertically downward, so that the snout points downward. In this situation, the animal dorsiflexes its head and neck, bringing the head towards its normal orientation in space. Bilateral labyrinthectomy not only blocks this response, but releases an actively maintained ventroflexion of the head and neck. Bilateral electrolytic lesions of the lateral hypothalamus (LH) exaggerate such ventroflexion in labyrinthectomized rats. By themselves, LH lesions had no such effect. Therefore, it is argued that there are vestibular and supraspinal inhibitory mechanisms which, in the intact adult animal, keep this ventroflexion response in check. In addition, when the rats were held with their heads down, and with gentle paw contact with the ground, they did not ventroflex. However, they ventroflexed immediately upon releasing this paw contact. These observations suggest that there are tactile mechanisms which can also inhibit this exaggerated ventroflexion released by labyrinthectomy.

Labyrinthine and visual involvement in the dorsal immobility response of adult rats.

The dorsal immobility response (DIR) is typically seen in the infants of many altricial mammalian species. Lifting the animal into the air by the nape of the neck is the primary releasing stimulus. Functionally, this response appears to facilitate carrying of the infants by the adults. When grasped by the nape and lifted into the air, adult rats will also exhibit the DIR. In this paper, the role of the labyrinths in the DIR of adult male rats was examined. Vestibular stimulation produced by vertical circular acceleration increased the duration of the DIR, while labyrinthectomy greatly diminished the DIR. In rats with intact labyrinths, visual occlusion greatly potentiated the DIR, whereas, in labyrinthectomized rats, visual occlusion had little effect. These data indicate that the vestibular system plays a major role in mediating the DIR of adult rats. The retention of the DIR into adulthood and the possible increased role of the labyrinths in the control of the adult DIR, are discussed with respect to the possible role of the DIR as an anti-predator mechanism.

Air righting without the cervical righting reflex in adult rats.

The current explanation of air righting in animals is that when falling supine in the air, labyrinthine stimulation triggers head rotation. The head rotation involves neck rotation which, via the cervical righting reflex, triggers rotation of the body. (In cats and monkeys, when the labyrinths are absent, visual stimulation when falling supine can also trigger this righting sequence.) In the present paper, a descriptive analysis of air righting in the rat shows that the shoulders rotate, carrying the unmoving head and neck passively along. Thus, for this species, labyrinthine input appears to trigger shoulder rotation directly, independently of the cervical righting reflex. This suggests that at least two physiological mechanisms exist for labyrinthine control of head rotation during air righting, one via the neck and the other via the shoulder girdle.

Haloperidol exaggerates proprioceptive-tactile support reflexes and diminishes vestibular dominance over them.

Rats made immobile and cataleptic by haloperidol, a dopamine receptor blocker, maintain their static stable equilibrium by employing a variety of allied postural support reflexes. Under some test conditions, competition between such reflexes occurs, and in haloperidol-treated rats, unlike undrugged controls, proprioceptive-tactile stimuli appear to be dominant over vestibular stimuli. We investigated this relationship in rats by testing their air-righting with and without simultaneous contact of the tail on a wooden platform. The rats were lightly held in a supine position by the shoulders and pelvis, with or without tail contact on a small wooden platform 47 cm above the ground. Undrugged rats showed the normal pattern of righting which involves axial rotation with cephalocaudal recruitment whether the tail is contacting the platform or not. Upon release, the haloperidol-treated rats (2.5 mg/kg) gripped the platform with their tail, which interfered with the air-righting reflex. This demonstrates that in haloperidol-treated rats, the dominance of tactile-proprioceptive postural support reflexes over those triggered vestibularly.

Seemingly paradoxical jumping in cataleptic haloperidol-treated rats is triggered by postural instability.

Paradoxically, animals exhibiting haloperidol-induced cataleptic immobility can be induced to leap vigorously, by pushing them forward from behind. It is shown here that such jumping can also be produced by placing them on a board and tilting it tail-end upward until about 50 degrees above horizontal. In both situations, jumps only occurred when the animal's hindlegs began to slip forward, as they lost their postural stability. As alternatives to jumping from the slope, rats turned to face upwards (negative geotaxis), or adopted a spread-eagled posture during head-first downward sliding, with the body and head flattened against the substrate. All 3 responses to the sloping board were present in some undrugged rats. Such rats, and those given low doses of haloperidol (0.5, 1.0 mg/kg), were more likely to turn upwards than to jump or slide. At high doses (7.5, 10.0 mg/kg), they were more likely to slide downward than to turn or jump. Jumping was most likely to occur at an intermediate dose (5 mg/kg), approximately 60 min after injection. We suggest that in the absence of haloperidol, and at low doses, locomotion is dominant over reflexes defending static equilibrium, and hence rats are more likely to turn upwards (which involves stepping). In contrast, at higher doses, locomotion is more fully suppressed, reducing the likelihood of turning. At very high doses of haloperidol and later in the action of the drug, muscle tonus appears to be weakened, reducing the likelihood of jumping. This possibility was supported by the finding that combined injection of the optimal dose of haloperidol and 2 mg/kg diazepam reduced the ability to cling vertically (suggesting weakness of muscle tone). In such rats, jumping from the sloping board was decreased, and active downward sliding was increased. Thus, different factors influence the occurrence of jumping at different doses of haloperidol. However, these are all active defensive responses to postural instability, and hence are similar to the other reflexes used by haloperidol-treated rats to defend against displacement from static stable equilibrium, such as standing immobile, bracing, clinging, and righting. Jumping in response to loss of stability on the sloping board also occasionally occurred in undrugged rats. Unlike jumps by haloperidol-treated rats, those by undrugged animals only occurred when they could be directed to a safe landing place. Thus, if the board faced the edge of the table, so that the jump would carry the animal into space over the edge, undrugged rats either did not jump or jumped off the side of the board onto the table.(ABSTRACT TRUNCATED AT 400 WORDS)

Visual modulation of vestibularly-triggered air-righting in the rat.

Unlike cats, which can initiate righting in the air either with vestibular or visual input alone, the rat is dependent solely upon the labyrinths to trigger this response. We show, however, that the rat can modulate the onset and speed of its rotation according to the height above the ground from which it is dropped. In the absence of vision, rates initiate rotation with a latency of about 50 ms, irrespective of the height from which they are dropped. With vision, rats can modulate their latency to begin rotation, from about 102 ms at 50 cm, to about 39 ms at 7.5 cm. Similarly, as height of release decreases, the speed of rotation (i.e. degrees/ms) increases. Thus, in rats, even though vision cannot trigger air-righting, it does adaptively modulate this behavior as an allied reflex, increasing the likelihood that the animals will land on their feet.

Recovery from axial apraxia in the lateral hypothalamic labyrinthectomized rat reveals three elements of contact-righting: cephalocaudal dominance, axial rotation, and distal limb action.

In earlier work, we showed that in rats, proprioceptive-tactile information is sufficient for contact-righting on the ground (from lying on one side to prone). Thus, axial rotation, starting with the shoulders and followed by the pelvis, occurs normally in labyrinthectomized animals with eyes occluded. After damage to the lateral hypothalamus, even with labyrinths intact, contact-righting is at first abolished (1-2 days postoperatively), and when it reappears, involves pushing by the hindlegs. Rostrocaudal contact-righting, involving axial rotation, takes 3-4 days to recover. If labyrinthectomy is combined with lateral hypothalamic damage, the deficit is exaggerated and recovery is greatly slowed down, now requiring 2-3 weeks. The present paper shows that during this prolonged period of recovery several transitional forms of righting are present, each produced by a different combination of limb and body axis movements. At first, axial rotation is absent, and righting is achieved only by pushing with the limbs. This is followed by a transitional form in which, even though axial rotation cannot be triggered directly by contact with the ground, it can be triggered indirectly as an allied reflex when the paw places on the ground. Eventually the body axis actively initiates the rotation to proneness (at first, in the pelvis, later in recovery, in the shoulders), with the limbs being carried. Recovery of axial rotation overlaps with the recovery of cephalic dominance, yielding complex intermediate forms of righting.