Markers for biogenic amines in the aged rat brain: relationship to decline in spatial learning ability

Animal models of normal aging: relationship between cognitive decline and markers in hippocampal circuitry

Alzheimer's disease (AD) occurs against a background of cognitive and neurobiological aging. Animal models of normal aging may be used to study the neurobiological structures that are most involved in AD pathology, i.e. hippocampal/cortical systems. For example, spatial learning is dependent upon the integrity of the hippocampus, a structure that is much affected in humans with AD. Spatial learning tasks, such as the Morris water maze, have been used to screen aged rats for cognitive status prior to neurobiological assessment of hippocampal circuitry. Manifestations of the aging process, which are often minimal or entirely obscured in studies comparing young and aged brains, become apparent when the cognitive status of aged animals is taken into account. For example, studies examining the septohippocampal cholinergic system in behaviorally-characterized rodents have shown that there is a decline in many markers for these cholinergic neurons that coincides with severity of spatial learning impairment. Another advantage of cognitive assessment in animal models used to study aging is that it may help to distinguish between those neurobiological changes that are functionally detrimental and those that may represent compensatory adaptations to maintain cognitive function. Age-related changes in two neurobiological measures in the hippocampus are discussed in this report. Alterations in the opioid peptide dynorphin (increased peptide content and prodynorphin mRNA) in hippocampus may contribute to impairment in that the greatest changes occur in those aged rats with severe spatial learning deficits.(ABSTRACT TRUNCATED AT 250 WORDS)

The interaction of L-deprenyl and scopolamine on spatial learning/memory in rats

L-Deprenyl, a specific MAO-B inhibitor, has been reported to improve learning/memory in some cognitive tests in aged rats. The present study investigated whether L-deprenyl could alleviate the spatial learning deficit induced by muscarinic blockade and aging in OFA rats. Scopolamine (0.25 mg/kg) impaired the acquisition of a water maze task in adult rats and increased their swimming speeds. L-Deprenyl (0.25 mg/kg, 14 days) had no effect on water maze performance in saline treated adult rats, but markedly alleviated the learning deficit induced by scopolamine and increased the time and distance of swimming in the training quadrant when the platform was removed (spatial probe trial). L-Deprenyl partly reduced the effect of scopolamine on speed of swimming. Nevertheless, administration of l-deprenyl (0.25 mg/kg, 14 days) had no effect on spatial learning/memory in aged rats. We suggest that the l-deprenyl-scopolamine interaction in the water maze test may be considered as a premise for further investigations of l-deprenyl as cognition enhancer.

Morphologic alterations of choline acetyltransferase-positive neurons in the basal forebrain of aged behaviorally characterized Fisher 344 rats

We examined Fisher 344 female rats aged 6, 27, and 33 months old. Prior to sacrifice and morphometric analyses of forebrain cholinergic neurons all rats underwent behavioral characterization in a spatial learning task using the Morris water maze. Performance on the spatial task permitted subsequent grouping of the 27- and 33-month-old animals into impaired or nonimpaired groups. Importantly, the percentage of animals that displayed spatial impairments increased sharply with advancing age. Quantitative assessment of the size and density of choline acetyltransferase (ChAT)-positive neurons throughout the basal forebrain revealed a significant enlargement of forebrain cholinergic neurons within 27-month-old nonimpaired rats compared to 6-month-old rats and 27- and 33-month-old impaired animals. This increase in size was most noted in the medial septum and nucleus of the diagonal band. Significant decreases in the density of ChAT-positive neurons was observed only in the nucleus of the diagonal band of 27-month-old impaired rats compared to 6-month-old controls. Although the significance of enlarged forebrain cholinergic neurons is unclear, we discuss the possibility that within aged rodents neuronal swelling is an active event and represents an early manifestation of the aging process and may constitute a restorative and/or compensatory event in that these rats are relatively asymptomatic with respect to their behavioral deficits. In addition, we discuss in some detail various technical and life effect issues which may vary the outcome of investigations of aged rodents.

Age-related changes in correlation between behavioral and biochemical parameters in Lewis rats

This study evaluated aging by using a correlational analysis of behavior and biochemistry in young (4 months old) and old (24 months old) Lewis rats. The rats were subjected to different learning tasks (spatial discrimination learning in the Morris task and cone-field task, temporal discrimination learning, one-trial inhibitory avoidance task) and noncognitive tests (emotional reactivity, motor coordination, and food motivation) and the relation between the various parameters was assessed. In the learning tasks, except for the inhibitory avoidance task, the first part of the learning curve was taken as an index of learning. Blood glucose (baseline and blood glucose regulation) and hippocampal choline acetyltransferase (ChAT) activity were also measured. There was no correlation between the different parameters of learning in young and old rats. This indicates that there are individual differences in performance in different learning and memory tasks. Measures of noncognitive behavior (food motivation, emotional reactivity, and motor performance) did not predict performance in the learning tasks. Hippocampal ChAT activity did not correlate with learning performance in old rats, whereas blood glucose level was found to correlate with spatial learning in old rats. These results suggest that an impaired regulation of blood glucose may be related to cognitive performance in aging.

Effects of aging on spatial learning and hippocampal protein kinase C in mice

C57BL/6Nia and F1(B6xD2)Nia mice were tested on the Morris water maze task for 5 days followed by 12 days of testing on the place learning-set task (8 trials/day with each task). Mice were tested at 3, 14, and 25 months of age. C57 mice, 25 months of age, were significantly impaired in both the Morris and place learning-set task probe trial performance compared to mice 3 months of age (p < 0.05). These aged C57 mice also demonstrated a significant reduction in membrane-bound hippocampal protein kinase C (PKC) activity (p < 0.05) with no significant change in cytosolic PKC activity. F1 mice, however, showed no effect of age on probe trial performance on the spatial learning tasks. In addition, in a comparison of C57 and F1 mice within each age group, F1 mice demonstrated superior learning performance which was accompanied by a significant elevation in PKC activity (p < 0.05). Spatial learning performance of both strains significantly correlated with membrane-bound PKC activity (p < 0.01). These data provide additional support for our previous hypothesis of an involvement of hippocampal PKC activity in spatial learning and suggest that the amount of membrane-bound PKC activity may be a determinant of age-related decline in spatial learning.

Alterations in [3H]-kainate receptor binding in the hippocampal formation of aged Long-Evans rats

The present study used in vitro autoradiography to examine the density of [3H]-kainate (KA) binding in subregions of the hippocampal formation and certain cortical areas in young (7-8 months) and aged (27-29 months) Long-Evans rats. In addition, the topography of KA binding in the dentate molecular layer was examined for evidence of reactive reorganization in the aged brain. This investigation of age-related changes in [3H]-KA binding included correlations with the animals' spatial learning performance in a Morris water maze. The results showed an age-related decrease in the density of [3H]-KA binding in several regions of the hippocampal formation (CA3, CA1, hilus) and within related cortical areas (subicular complex, entorhinal cortex, perirhinal cortex). In addition, an expanded zone of KA binding in the molecular layer of the dentate gyrus was observed in the aged group. This expansion of KA binding may reflect sprouting due to a loss of perforant path input to the dentate. The results of additional correlational analyses, however, indicated that these changes in the density and topography of [3H]-KA binding were not strongly correlated with a decline in place learning ability.

Increased responsiveness of hippocampal pyramidal neurons to nicotine in aged, learning-impaired rats

The effect of aging upon the responsiveness of hippocampal CA1 pyramidal neurons to nicotine was investigated using electrophysiological techniques in male Fischer 344 rats. Prior to electrophysiological recording, animals were behaviorally tested using the Morris water maze. All 3-6 and 18-21 month rats displayed rapid place learning in this task, while none of the 27-30 month animals learned within the 5-day test period. By contrast, rats of all age groups were able to learn a cue version of the water maze task. Following behavioral testing, the animals were anesthetized with sodium pentobarbital for acute recording. Nicotine was locally applied to electrophysiologically identified CA1 pyramidal neurons using pressure microejection from two-barreled glass microelectrodes. For each neuron, a dose of nicotine was found which elicited a 300-400% increase in basal firing rate. These data were used to construct cumulative dose response curves for populations of neurons tested in 3-6-, 18-21-, and 27-30-month-old animals. An age-related increase in the responsiveness of CA1 pyramidal neurons to locally applied nicotine was observed. The results of this study suggest that an increase in hippocampal CA1 pyramidal cell responsiveness to nicotine could be related to the impaired place learning ability seen with aging.

Neocortical, hippocampal and septal parvalbumin- and somatostatin-containing neurons in young and aged rats: correlation with passive avoidance and water maze performance

Aged (26-month-old) rats were impaired compared with young (three-month-old) rats in passive avoidance and water maze tasks. In order to study whether changes in inhibitory circuits are involved in these age-related cognitive impairments, the number of two different subpopulations of GABAergic neurons, i.e. somatostatin- and parvalbumin-containing neurons, were counted in the hippocampal formation, septum and neocortex. We found that the number of parvalbumin-containing neurons was decreased in the entorhinal, somatosensory and motor cortex as well as in the medial septum and vertical limb of the diagonal band of Broca, but not in the hippocampus of aged rats. Somatostatin-containing neurons were affected in the somatosensory and motor cortex, and in the dorsolateral septum, but not in the hippocampus or in the entorhinal cortex. The decreased number of parvalbumin-containing neurons in the entorhinal cortex of the aged rats correlated with their performance deficits in passive avoidance and spatial learning. We propose that impaired functioning of the entorhinal cortex parvalbumin-containing inhibitory neurons may, to some extent, be responsible for the learning and memory defects found in aged rats.

Aging and 3H-paroxetine binding in rat brain: effect of imipramine and tetrahydroacridine

3H-Paroxetine (PA) binding was studied in the frontal cortex (FC) and hippocampus (H) of 4 mos (young), 15 mos (adult) and 24 mos (aged) old Fischer 344 rats. Bmax (maximum number of binding sites) of PA binding was significantly higher in the H of adult rats compared with either young or old rats. There was no difference in Bmax between young and old rats. No change in Kd was observed in H and Kd or Bmax in FC with age. We also studied the effect of imipramine and tetrahydroacridine (THA) on PA binding in FC and H. Both drugs inhibited PA binding in FC and H but THA was 2000 times less potent than imipramine. There was no effect of age on IC50 values of imipramine and THA. These observations suggest that the number of 5-HT transporter sites in the hippocampus increases with brain maturity but then drops significantly during old age. This finding may have implications for age-related decrements in learning and memory, thought to be mediated by hippocampal structures.

The neuropharmacological and neurochemical basis of place learning in the Morris water maze

The Morris water maze (MWM) offers several advantages over other methods of studying the neurochemical basis of learning and memory, particularly with respect to its ability to dissociate deficits in memory formation from deficits in sensory, motor, motivational and retrieval processes. The contributions of nearly all of the major neurotransmitter systems have been investigated and consistent patterns have emerged. Normal function in glutamatergic and cholinergic systems is necessary for spatial learning, as blockade of NMDA receptors and cholinergic hypofunction prevents spatial learning but does not impair recall. Peptides such as adrenal and sex hormones and somatostatin may also be necessary for spatial learning. In contrast, activity in either GABAergic or opioidergic systems impairs spatial learning, though by quite different means. GABAergic activity prevents memory function, whereas opioidergic activity reduces motivation. Normal monoaminergic activity is necessary for normal performance in the MWM, but not for spatial learning per se. However, noradrenergic and serotonergic systems may enhance cholinergic-mediated mnemonic processes. Further research into the relative contributions of different receptor subtypes as well as interactions between neurochemical systems should provide significant advances in our understanding of the neural basis of learning and memory in mammals.

A longitudinal study of reaction time performance in Long-Evans rats

This study was undertaken to examine individual differences in the progression of age-related decline on a measure of sensorimotor function. Twenty-one adult rats were trained on a simple reaction time (RT) task and assessed every 6 weeks from 14.5 to 25 months of age. An overall slowing of RT latencies associated with chronological age was observed. However, some rats maintained a stable performance with age while others slowed considerably. Another measure within the RT task, accuracy of performance, appeared to represent a stable individual characteristic that was insensitive to the effects of age. However, no measure of performance on the RT task at 14.5 months of age predicted later impairment in RT latency. At the completion of longitudinal testing, spatial learning in the Morris water maze was assessed in these aged rats along with a young comparison group. The aged rats were impaired relative to young controls in locating the escape platform. Measures of cognitive function and sensorimotor function within the spatial task were, however, unrelated to slowing of RT latency.

Age influences abnormalities in striatal dopamine metabolism during and after transient forebrain ischemia

Age has been found to be a significant risk factor for brain ischemia and its mortality. After cerebral ischemia, the nigrostriatal dopaminergic system undergoes selective vulnerability with necrosis of striatal neurons. To study the effect of age and transient forebrain ischemia on striatal dopamine metabolism, investigations were performed in 1-year-old (adult) and 2-year-old (aged) male Wistar rats. A 15 min period of bilateral transient incomplete ischemia (ICI) was induced, and the concentrations of dopamine (DA), 3,4-dihydroxyphenylacetic acid (DOPAC), 3-methoxytyramine (3-MT), and homovanillic acid (HVA) were measured in the striatum by means of HPLC and electrochemical detection at the end of ischemia without reperfusion, and after 1 h, 24 h, 72 h, 144 h, and 288 h of postischemic cerebral reperfusion. In normal conditions, no 3-MT was detectable in either age group studied, and no other age-related changes could be found in DA or its metabolites. During ICI, an age-related difference became obvious in the 3-MT concentration, which was higher in aged animals. In this group, DOPAC dropped and DA turnover increased. After 1 h of postischemic reperfusion, the concentrations of DOPAC and HVA, as well as the turnover rate, had increased in both age groups, whereas an increase in the DA concentration became apparent in the adult animals only. The enhancement of the concentration of both DOPAC and HVA was more marked in adult animals than in aged ones. At 24 h of postischemic cerebral reperfusion, DA concentration was still elevated in both age groups, and HVA in the 1-year-old animals only. At 72 h of postischemic cerebral reperfusion, no differences were obvious between adult experimental animals and controls, whereas the elevated DA concentration persisted in aged animals, being higher than in the control group and in the 1-year-old rats. DA turnover was reduced. Longer periods of postischemic cerebral reperfusion were not found to be followed by any abnormalities compared with controls except for the DA concentration at 288 h (1-year-old group); nor were there any differences between the two age groups studied. The data obtained in this investigation clearly indicate age-related differences in the striatal dopaminergic neurotransmission after transient cerebral ischemia, in that in the aged brain reactions are markedly delayed after an injurious event such as ischemia.

Individual differences in the cognitive and neurobiological consequences of normal aging

Defining the neural basis of age-related cognitive dysfunction is a major goal of current research on aging. Compelling evidence from laboratory animals and humans indicates that aging does not inevitably lead to cognitive decline. Conducting neurobiological investigations in subjects that have previously undergone behavioral characterization has therefore emerged as a promising strategy for identifying those alterations in brain structure and function that are specifically associated with age-related cognitive impairment.

The effects of alpha-2 adrenoceptor antagonist, atipamezole, on spatial learning in scopolamine-treated and aged rats

In order to study whether noradrenergic drugs improve age-related cognitive dysfunctions the present experiments investigated whether atipamezole, a selective and specific alpha-2 antagonist, improves spatial learning impairment due to cholinergic blockade (scopolamine 0.8 mg/kg) or aging in rats. Previously, it has been shown that atipamezole dose-dependently (0.03-3.0 mg/kg) increases the turnover of noradrenaline in rat brain. According to the present results, atipamezole (0.1, 0.3, 0.6 mg/kg) did not affect spatial learning/memory when assessed in a free swim trial of the water maze task in control rats. Furthermore, atipamezole (0.1, 0.6 mg/kg) did not improve learning deficit in scopolamine treated young rats. Higher doses (greater than or equal to 1.0 mg/kg) of atipamezole could not be tested, because they induce floating behaviour in rats. In aged rats, which were screened to be impaired in the initial acquisition of the water maze task, 0.3 mg/kg atipamezole impaired further learning of this task. Because previous studies suggest that age-related learning impairment in the water maze may be, at least partly, due to a cholinergic deficit, the present results suggest that atipamezole which increases the release of noradrenaline in brain does not alleviate this learning deficit.

Hippocampal nerve growth factor levels are related to spatial learning ability in aged rats

Brain nerve growth factor (NGF) was determined in two groups of aged rats: 'good' and 'poor' performers. The animals were selected out of a population of 40 aged rats (26-28 months old) trained in a spatial learning task. Animals performing well in the test had significantly higher NGF in the hippocampus when compared to 'poor' performers. No differences in the levels of NGF were found in the cortex, septum and cerebellum. The results implicate hippocampal NGF in cognitive functioning of aged rats, and suggests that the forebrain cholinergic neuronal atrophy which has been observed in cognitively impaired aged rats may be due to reduced availability of target-derived NGF.

Convergent cholinergic activities in aging and Alzheimer's disease

Choline acetyltransferase (ChAT) and acetylcholinesterase (AChE) activities have been examined postmortem in a series of 66 individuals with no evidence of CNS disease, ranging in age from 24 gestational weeks to 95 years and in 33 cases of Alzheimer's disease (AD) aged 57-89 years. In the normal human hippocampus a striking and highly significant age-related decline in ChAT occurred from middle to old age (between 40 and 100 years); a trend apparent at a later stage and to a lesser extent in the hippocampal gyrus. In both areas enzyme activity in AD was inversely related to age at death; reductions compared with the normal were on average 70-80% in the 60-70 year old groups compared with 30-40% in the 80-90 year old group. A similar trend was apparent with respect to acetylcholinesterase (AchE) histochemical activity associated with fibers and terminals (predominantly cholinergic and concentrated in CA3 and 4 of the hippocampus) but not with reactive perikarya (considered to be noncholinergic) present in both hippocampus and cortex. These data indicate that the normal aging human hippocampus may constitute a useful model for investigating the dysfunction or degeneration of basal forebrain cholinergic neurons in AD.

Decreased [3H]hemicholinium binding to high-affinity choline uptake sites in aged rat brain

The binding of [3H]hemicholinium ([3H]HCh-3) to sodium-dependent high-affinity choline uptake sites provides a useful neuroanatomical and functional marker of the cholinergic system. We examined the autoradiographic distribution of [3H]HCh-3 binding sites in the forebrain of young (4-6 months) and old (32 months) rats. There was a widespread reduction of [3H]HCh-3 binding site density in the aged rat brain. This loss presented regional differences with maximal reduction in the medial and posterior striatum (55%) and in the dentate gyrus (47%), in limbic areas such as basolateral amygdala, tubercle olfactorium and piriform cortex the autoradiographic signal was about 25-30% lower. In aged hippocampus and cerebral cortex the density of [3H]HCh-3 binding sites was about 40% lower, the difference between young and senescent animals being less evident in the medial septum and basal nucleus. No significant alterations were observed in interpeduncular nucleus from old rats. These data are in agreement with the functional results obtained by measuring other cholinergic parameters in the aged rat and confirm the vulnerability of cholinergic system during aging.

Progressive decline in spatial learning and integrity of forebrain cholinergic neurons in rats during aging

Rats distributed over five different age groups, 3, 12, 18, 24 and 30 months of age, were screened for their spatial learning and memory ability in the Morris water maze, and the degree of place navigational impairments was correlated with morphological changes in the four major forebrain cholinergic cell groups (medial septum, MS; vertical limb of the diagonal band of Broca, VDB; nucleus basalis magnocellularis, NBM; and striatum) using choline acetyltransferase (ChAT) and nerve growth factor receptor (NGFr) histochemistry. Impaired place navigation developed progressively with age, such that 8% of the 12-month-old rats, 45% of the 18-month-old, 53% of the 24-month-old, and over 90% of the 30-month-old rats were behaviorally impaired. Significant reductions in the number of ChAT/NGFr-positive cell bodies, amounting to between 19 and 45%, were observed in all four cell groups, and the remaining cells were reduced in size (6-24% reduction in cross-sectional area in the oldest age groups). Although the morphological changes were less severe and tended to develop later than the behavioral impairments, there was overall a significant correlation between water maze performance and ChAT/NGFr-positive cell counts, and to a lesser degree also cell size in all four cell groups. These changes were also highly correlated with age. The highest correlations were seen in MS, VDB and NBM, which are known to play a role in spatial memory performance in young rats. The results indicate that degenerative and/or atrophic changes in the forebrain cholinergic system and decline in spatial learning ability are parallel processes during aging. Although the magnitude of the morphological changes does not appear to be substantial enough, by itself, to explain the severe spatial learning impairments that develop in the oldest animals, the present data are consistent with the view that impaired function in the forebrain cholinergic system can contribute to age-dependent cognitive decline in rodents.

The effects of noradrenergic neurotoxin, DSP-4, on the performance of young and aged rats in spatial navigation task

The present study investigated whether an overactive noradrenergic system is related to the impairment in learning/memory in aged subjects. The effects of partial noradrenaline depletion (using the noradrenergic neurotoxin DSP-4) on the acquisition of a water maze task was investigated in young and aged rats, and hippocampal noradrenaline content was correlated with spatial learning performance in similar rats. DSP-4 treatment impaired markedly the acquisition of the water maze task in aged rats, but improved it slightly in young rats. DSP-4 treatment decreased swimming speed, and this effect tended to be more marked in young rats. In the group of control rats, hippocampal noradrenaline tended to correlate positively with spatial bias in aged rats (the rats with the highest noradrenaline content in the hippocampus tended to have the best spatial learning/memory), but negatively in young rats. These results do not support the hypothesis that spatial learning/memory impairment is due to an overactive noradrenergic system in aged rats. Further studies are needed to clarify the reasons of the marked age-related difference in the effects of DSP-4 on the performance of water maze task in rats.

Divergence of biological and chronological aging: evidence from rodent studies

Literature on aging populations of rodents supports the intuitive view that significant functional variation exists among like-aged, elderly individuals: chronological age as a solitary measure is a poor indicator of biological age. In this report, we review a variety of studies which classify aged rodents based on genetic and/or behavioral similarities, in addition to chronological age, and have provided valuable neurobiological and physiological information on age-related changes which accompany functional impairments, or the lack of them. Beyond their descriptive value for gerontological research, these findings suggest ways in which biological aging can be manipulated to promote good function in aged individuals.

Decreased glutamate release correlates with elevated dynorphin content in the hippocampus of aged rats with spatial learning deficits

The effects of aging on extracellular glutamate and tissue dynorphin content in the hippocampus were examined in Fischer-344 rats. Young adult (4-month-old) and aged (24-month-old) rats were trained to find a hidden platform in the Morris water task. Aged rats were unable to acquire the spatial learning task as rapidly as young controls. Following behavioral testing, an in vivo microdialysis perfusion method was used to determine extracellular glutamate levels in the hippocampus. There was a 25-35% reduction in extracellular glutamate concentration in both dorsal and ventral hippocampus of aged rats compared to young rats, in the absence of any change in tissue glutamate levels. Radioimmunoassay showed an increase in dynorphin A(1-8)-like immunoreactivity [DYN-A(1-8)LI] in both dorsal and ventral hippocampus, but not striatum, of aged rats. Immunocytochemistry indicated that this increase was localized to the dentate granule cells and mossy fibers. Furthermore, among the aged rats the increase in DYN-A(1-8)LI was inversely correlated with the decrease in extracellular glutamate. These results suggest that the disregulation of dynorphin observed in cognitively impaired aged rats is related to reduced excitatory transmission within the hippocampal formation.

Recognition memory deficits in a subpopulation of aged monkeys resemble the effects of medial temporal lobe damage

The present study examined individual differences in recognition memory function in a group of Old World monkeys (Macaca mulatta). Four young (9-11 years) and 10 aged (22-33 years) monkeys were tested in the same delayed-nonmatching-to-sample (DNMS) recognition memory procedure that has been widely used to study the effects of experimental hippocampal lesions in young subjects. Animals were first trained to a 90% correct learning criterion in the DNMS task using a 10-second delay between the sample and recognition phase of each trial. The memory demands of the task were then increased by gradually extending the retention interval from 15 seconds to 10 minutes. Three of the aged monkeys performed as accurately as young subjects at all delays. The remaining aged monkeys performed well at the shortest delays (15 and 30 seconds), but progressively greater impairments emerged across delays of 60 seconds, 2 minutes, and 10 minutes. These results suggest that recognition memory is only compromised in a subpopulation of aged monkeys. Moreover, aged monkeys that are impaired in the DNMS task exhibit the same delay-dependent pattern of deficits that is the hallmark of memory dysfunction resulting from medial temporal lobe damage.

In vivo acetylcholine release as measured by microdialysis is unaltered in the hippocampus of cognitively impaired aged rats with degenerative changes in the basal forebrain

Acetylcholine (ACh) release was studied in awake, freely moving animals using in vivo microdialysis in the hippocampus of young (3-month-old) and aged (24-month-old) female Sprague-Dawley rats. Two groups of aged rats were selected on basis of their spatial learning performance in the Morris water maze: non-impaired aged rats which performed as well as the young control animals, and impaired aged rats which learnt the task very poorly. Baseline ACh overflow (in the presence of 5 microM neostigmine) was 1.9 +/- 0.3 +/- pmol/15 min in the young animals and 1.6 +/- 0.4 pmol/15 min in both the impaired and the non-impaired aged rats; these levels did not differ from each other. Depolarization by KCl (100 mM) or muscarinic receptor blockade by atropine (3 microM) added to the perfusion fluid produced dramatic, 4-6-fold, increases in ACh overflow that was similar in magnitude in both the young and the aged impaired and non-impaired rats. Behavioral activation by either handling or electrical stimulation of the lateral habenula produced 2-3-fold increases in extracellular ACh-levels in the hippocampus similarly in all three groups. The results indicate that hippocampal ACh release is maintained in aged rats that exhibit severe spatial learning and memory impairments and that the septo-hippocampal cholinergic system retains its capacity to increase its ACh release in response to both K(+)-induced depolarization and behavioral activation in the aged rat.(ABSTRACT TRUNCATED AT 250 WORDS)