Solid-state animal detection system: its application to open field activity and freezing behavior

NK1 tachykinin receptor treatment is superior to capsaicin pre-treatment in improving functional outcome following acute ischemic stroke

Previous results from our laboratory have shown that blockade of the substance P (SP) pathway with an NK1 tachykinin receptor antagonist significantly reduces blood brain barrier breakdown, cerebral edema and functional deficits following ischemic stroke. However, it is unclear whether removal of all neuropeptides is more efficacious than blocking SP alone. As such, the aim of the present study was to determine the effect of neuropeptide depletion with capsaicin pre-treatment on functional outcome following acute ischemic stroke in rats. Animals received 125 mg/kg of capsaicin or equal volume of saline vehicle, administered subcutaneously over a 3-day period. At 14 days following treatment animals were subject to 2h of middle cerebral artery occlusion followed by reperfusion. A subset of animals was treated with an NK1 tachykinin receptor antagonist (NAT) or vehicle at 4h after the onset of stroke only. The functional outcome of animals was assessed for a 7-day period following stroke using a rotarod device, the bilateral asymmetry test, modified neurological severity score, open field and angleboard. Although capsaicin pre-treatment improved outcome, treatment with an NK1 tachykinin receptor antagonist was superior in improving post-stroke functional outcome. This data suggests that some neuropeptides may play a beneficial role following stroke, whilst others such as SP are deleterious.

Animal model for sport-related concussion; ICP and cognitive function

BACKGROUND

We have recently developed and characterized a rat model of mild traumatic brain injury which simulates the concussive injuries frequently encountered by players in American professional football.

OBJECTIVES

To study the effect of multiple impacts to the head on intracranial pressure, cognitive function, and exploratory behavior.

MATERIALS AND METHODS

The model was employed to cause concussion. Intracranial pressure, cognitive function, and exploratory behavior were examined following the multiple impacts of a 50 or 100 g projectile at a velocity of 9.3 or 11.2 m/s to the helmet protected head.

RESULTS

Intracranial pressure measured at 6 and 10 h, and 1, 2, 3, 5, and 7 days. It was maximally elevated 10 h after impact and returned to the control levels 7 days later. Morris Water Maze assessment, 48 h after impact, revealed impaired cognitive function. Open field testing 2-4 days and 1 and 2 weeks after impacts indicated consistently reduced spontaneous exploratory activity.

CONCLUSION

Multiple impacts to the head raise intracranial pressure and impair cognitive function and exploratory activity in this animal model.

A novel open field activity detector to determine spatial and temporal movement of laboratory animals after injury and disease

The wide range of tests for laboratory animal behavior after neurological injury or disease each have their benefits and detriments. The varied behavior an animal exhibits makes it difficult to decide which test to use. However, a fundamental instinct for the laboratory animal is to explore when placed in a new environment. A way to test exploratory behavior is in the open field. Here, we introduce a simple activity box without the use of video equipment to determine the exploratory movement of a rat after traumatic brain injury. The activity box is an open field and the rat explores its surroundings when placed inside. Four infrared beams were placed in both the X and Y-axis inside the box. Using a novel system to determine which beam the rat breaks, we describe where the rat is in space and time while in the activity box. Other models can show the number of beams broken, but here we elucidate the methods to additionally determine the amount of area explored, the total distance traveled by the rat and percent time exploring.

Effects of daily versus weekly testing and pre-training on the assessment of neurologic impairment following diffuse traumatic brain injury in rats

A number of test paradigms have been used to determine acute and chronic motor and cognitive deficits after experimental traumatic brain injury (TBI). Some involve daily testing of either trained or untrained animals whereas others utilize periodic testing over extended time periods. Which test paradigm is the most appropriate for the assessment of motor and cognitive deficits is, however, unclear. In the current study, we have used both daily and weekly testing in trained and untrained animals to ascertain which assessment protocol is most suited for the detection of functional deficits after diffuse TBI in rats. Animals were subjected to severe injury using the impact-acceleration model of diffuse TBI. An equal number of animals were also prepared surgically but not subject to injury (shams). The rotarod device and the Barnes Maze were used for motor and cognitive assessment respectively, with half of the animals being pre-trained on each test for 10 days prior to injury. The open field test was used to assess spontaneous exploratory activity (stress). Following injury, animals were assessed for neurologic deficits either on a daily basis (for 10 days) or a weekly basis (for 4 weeks). In trained animals, the greatest differences in neurologic outcome between injured and sham animals were observed early after injury. In contrast, in untrained animals, greatest differences between injured and sham animals were observed at later time points. Pre-injury training did not improve the rate of cognitive recover, or the rate of motor recovery in the weekly test paradigm, but did improve the rate of motor recovery in the daily assessment paradigm. Daily assessment promoted rapid functional recovery whereas weekly assessments did not significantly affect outcome in injured animals over the 4-week assessment period. Spontaneous exploratory activity was decreased after TBI and was not influenced by task exposure. These studies demonstrate that the functional assessment paradigm needs to be considered when quantifying functional deficits following diffuse TBI in rats.

Interaction between anesthesia, gender, and functional outcome task following diffuse traumatic brain injury in rats

A number of experimental and clinical studies have demonstrated that functional outcome following traumatic brain injury differs between males and females. Some studies report that females have a better outcome than males following trauma while others report the opposite. In experimental studies, some of the contradictory results may be due to the different experimental conditions, including type of anesthesia and the outcome measures employed. In the present study we have used three different anesthetic protocols and four different outcome measures to determine how these parameters interact and affect functional outcome following traumatic brain injury in male and female rats. Diffuse traumatic brain injury was induced in adult male and female animals using the impact-acceleration brain injury model. Mortality in female animals was no different than males when using halothane anesthesia, slightly better than males when using isoflurane anesthesia, but significantly worse than males under pentobarbital anesthesia. Female animals always performed better than males on rotarod tests of motor outcome, with this effect being unrelated to anesthetic effects. Conversely, in cognitive tests using the Barnes Maze, only isoflurane-anesthetized females performed better than their male counterparts. Similarly, in an open field activity task, females always performed better than males after trauma, with isoflurane-anesthetized females also performing significantly better than the halothane-anesthetized female group after injury. Our results suggest that female animals do better than males after diffuse traumatic brain injury, although this observation is dependent upon the type of anesthesia and the functional task employed. Isoflurane is particularly protective in females, pentobarbital is deleterious to female outcome, while halothane anesthesia has the least influence on gender-related outcome.

Infusion of adrenergic receptor agonists and antagonists into the locus coeruleus and ventricular system of the brain. Effects on swim-motivated and spontaneous motor activity

These studies examined how pharmacological stimulation and blockade of alpha receptors would affect active motor behavior in rats. In experiment I, alpha-2 receptor antagonists (piperoxane, yohimbine) and agonists [clonidine, norepinephrine (NE)] were infused into various locations in the ventricular system of the brain, including the locus coeruleus region, and motor activity was measured. Activity was measured principally in a swim test but spontaneous (ambulatory) activity was also recorded while drugs were being infused. When infused into the locus coeruleus region, small doses of the antagonists piperoxane and yohimbine depressed activity in the swim test while infusion of the agonists clonidine and NE had the opposite effect of stimulating activity. These effects were highly specific to the region of the locus coeruleus, since infusions of these drugs into other nearby locations in the ventricular system or use of larger doses had different, often opposite effects. This was especially true of clonidine and NE which profoundly depressed activity when infused posterior to the locus coeruleus, particularly over the dorsal vagal complex. Infusion of small doses of these drugs into the lateral ventricle had effects similar to infusion into the locus coeruleus region, though less pronounced. Changes in spontaneous motor activity were also observed, but this measure differentiated the groups less well than did the swim test. In experiment II, the predominantly postsynaptic receptor agonists isoproterenol (beta agonist) and phenylephrine (alpha-1 agonist) were infused into the ventricular system. Since infusions of piperoxane and yohimbine into the locus coeruleus that decreased activity in experiment I increase the release of NE by blocking alpha-2 inhibitory receptors on cell bodies and dendrites of the locus coeruleus, experiment II tested whether ventricular infusion of predominantly postsynaptic receptor agonists would also decrease activity in the swim test. Both isoproterenol and phenylephrine produced this effect, but did so selectively with respect to dose and location of infusion in the ventricular system. These findings are consistent with recent results relating to the mechanism that underlies stress-induced depression of active behavior.

Stress-induced depression of motor activity correlates with regional changes in brain norepinephrine but not in dopamine

This experiment examined how inescapable tail shock alters the level of dopamine and norepinephrine within various brain regions of the rat and the relationship of these changes to the depression of motor activity produced by the shock. Following exposure to tail shock that is known to interfere with acquisition of active behavioral tasks, animals were briefly tested for spontaneous motor activity and then sacrificed for neurochemical measures. Norepinephrine and dopamine levels in the frontal cortex, brain stem, striatum, olfactory tubercle, hypothalamus, hippocampus, septum, and amygdala were measured by a sensitive radioenzymatic technique. Exposure to 45 min of tail shock did not alter motor activity significantly, but shock sessions of 60 and 75 min duration produced a marked decrease in motor activity. Levels of dopamine were found to be very little changed in all brain regions studied except for the hypothalamus, in which a substantial rise in dopamine level was observed. Norepinephrine levels, in contrast, fell in many brain regions in response to shock. The fall in norepinephrine levels observed in two brain regions was significantly correlated with the decline in motor activity (brain stem r = +0.70, hypothalamus r = +0.60). These data suggest that deficits in active motor behavior produced by shock parameters similar to those used in this study may reflect concomitant disturbances of noradrenergic function in specific brain regions.

Central and peripheral norepinephrine concentrations in rat strains selectively bred for differences in response to stress: confirmation and extension

Inbred rats from the Maudsley Reactive (MR) strain had lower concentrations of norepinephrine in hypothalamus, heart, and spleen, and lower total catecholamines in adrenal than inbred Maudsley Non-Reactive rats (MNRA line). In contrast, they had a higher concentration of telencephalic NE than MNRA rats. These results confirmed previous findings obtained on rats maintained by non-systematic breeding within the two lines. Comparisons were also made between MR and a second Maudsley Non-Reactive strain (MNR). Rats of the two Non-Reactive lines (MNRA, MNR) have been bred from the same foundation population and selected for the same behavioral characteristics, but have been genetically isolated from each other for many generations. It was found that MR rats showed differences from MNR rats in hypothalamic and peripheral (but not telencephalic) NE concentrations similar to those seen in MR/MNRA comparisons. Since rats of the two Non-Reactive lines differ appreciably from MR rats in open-field defecation (the criterion on which they were selected), their differences from MR rats in a neurochemical system involved in sympathetic function suggests that this system may be functionally related to well established behavioral and physiological differences between the lines.