Abstract
Sleep fragmentation is a common symptom in sleep disorders and other medical complaints resulting in excessive daytime sleepiness. The present study seeks to explore the effects of sleep fragmentation on learning and memory in a spatial reference memory task and a spatial working memory task. Fisher/Brown Norway rats lived in custom treadmills designed to induce locomotor activity every 2 minutes throughout a 24 hour period. Separate rats were either on a treadmill schedule that allowed for consolidated sleep or experienced no locomotor activation. Rats were tested in one of two water maze based tests of learning and memory immediately following 24 hours of sleep interruption (SI). Rats tested in a spatial reference memory task (8 massed acquisition trials) with a 24 hour follow-up probe trial to assess memory retention showed no differences in acquisition performance but were impaired on the 24 hour retention of the platform location. In contrast, the performance of rats tested in a spatial working memory task (delayed matching to position task) was not impaired. Therefore, sleepiness induced by SI effectively impairs the recall of spatial reference memories but does not impair spatial reference memory acquisition or spatial working memory in Fischer-Norway rats.
Keywords: sleep deprivation, water maze, hippocampus, sleepiness
Introduction
There is growing evidence that sleep plays an important role in the consolidation of memories (Stickgold and Walker 2007). Most studies that have explored this question have focused on the role of sleep after new information has been learned. On the other hand, relatively little research has looked at the role of sleep prior to learning. The disruption of sleep is associated with decreased learning capacity in students as well as impairments in declarative and procedural learning (Curcio et al. 2006). Additionally, patients suffering from primary insomnia have increased difficulty in acquiring procedural memories (Nissen et al. 2006).
Previous research in rodents has shown that hippocampal dependent memory processes are especially sensitive to disruptions in sleep. Selective rapid eye movement (REM) sleep deprivation impairs place acquisition, but not cued learning of the water maze task (Youngblood et al. 1997) nor the working memory component of a radial arm task(Smith and Rose 1996). Sleep deprivation also impaired performance on hippocampal dependent contextual fear task following the first five hours after acquisition (Graves et al. 2003). Total sleep deprivation prior to learning can also impair retention of a spatial water maze task (Guan et al. 2004). Other disruptions of sleep such as twenty-four hours of sleep fragmentation prior to learning also impair water maze performance (Tartar et al. 2006). Deficits in hippocampal long-term potentiation (LTP) have also been found following selective REM sleep deprivation (Davis et al. 2003;McDermott et al. 2003) and sleep fragmentation (Tartar et al. 2006). Sleep deprived human participants show decreased hippocampal activity during learning (Yoo et al. 2007).
In many sleep disorders such as obstructive sleep apnea, as well as other diseases and disorders, sleep is fragmented throughout the night leading to daytime symptoms resembling those of total sleep loss (Bonnet and Arand 2003). In experiments with normal humans, sleep that is interrupted every minute produces deficits in thought and vigilance tasks (Bonnet 1986). Given the relevance of sleep fragmentation in human lives, rodent models of sleep interruption have not been sufficiently studied. Prior research in our lab has indicated that sleep fragmentation can impair spatial memory and hippocampal synaptic plasticity (Tartar et al. 2006). Additionally, we found that 24 hrs of sleep fragmentation can impair cognitive flexibility in an attentional set shifting task (McCoy et al. 2007a). In an attempt to more closely model human experience, the present experiment explores the effects of sleepiness on two types of spatial learning tasks. The sleep of rats was interrupted every two minutes for a twenty-four hour period prior to the acquisition of a spatial reference learning task or prior to performing a spatial working memory task.
Methods
Animals
Adult male Fisher/Brown Norway F1 (275−325g; Harlan, Indianapolis, IN) were used in behavioral testing. Rats were housed in groups of 3 in standard cages (unless otherwise noted) under constant temperature (23°C) and a 12:12 light dark cycle (lights on at 7:00am) with food and water available ad libitum. All animals were treated in accordance with the National Institute of Health Guide for the Care and Use of Laboratory Animals (NIH Publications No. 80−23) revised 1996. All procedures were approved by the institutional animal care and use committee (IACUC) of the Boston VA Healthcare System.
Sleep Interruption Procedure
The experimental sleep fragmentation procedures have been described and characterized in detail previously(McCoy et al. 2007a;McKenna et al. 2007;Tartar et al. 2006). This procedure has provided consistent and reliable disruptions of sleep in rats. Polysomnography was not recorded to avoid the invasive surgery required for the unnecessary replication of data. Briefly, during the sleep interruption (SI) protocol, rats lived in a treadmill cage (L × W × H; 50.8 cm × 16.51 cm × 30.48 cm) with free access to food and water. The floor is a horizontal rubber belt automatically programmed to move slowly at a rate of 0.02 m/s. The treadmill ran at this slow speed for 30 s, followed by no treadmill movement for 90 s. This 30 s on /90 s off schedule produced 30 interruptions of sleep per hour continuously for 24 hrs. In order to habituate the rats to the treadmill movement, rats were placed in the treadmills 2 days prior to the experiment. Treadmills were turned on (5 min on followed by 5 min off) for 1 hr on each of the 2 days. As a control for the nonspecific effects of locomotor activity, an exercise control (EC) group was included in this study. In this group, rats obtained an equivalent amount of treadmill movement/exercise, but with a treadmill on/off schedule of 10 min on/30 min off, allowing for longer periods of undisturbed sleep. Cage control (CC) rats lived in the same cage without any treadmill movement.
Apparatus
All animals were trained in a pool 2.0 m in diameter and 0.4 m in depth, containing water made opaque by nontoxic, water-soluble paint. The pool was in a 3 × 5 m room with several distinctive spatial cues (e.g. signs, laboratory furniture). A 10 cm diameter platform submerged approximately 1 cm below the surface of the water. To make the platform visible, a flag was attached that extended approximately 10 cm above the water surface. Rodent performance was tracked with a video tracking system (EzVideo Multi Track System, AccuScan, Columbus, OH).
Spatial Reference Memory
In the reference memory water maze task, rats (n=12 SI, n=12 EC, n=11 CC) were tested in one training session consisting of 8 consecutive trials with a 60 s inter-trial interval (Packard and Teather 1997). This version of the water maze task allows rats to be fully trained rapidly, which is necessary for manipulations that cannot be given on multiple days, such as 24 hr sleep fragmentation. This protocol also denied rodents time to sleep between testing trials. Rats were tested in the water maze during the last two hours of the 12 hr lights-on period. On each trial, rats were placed in the WM facing the wall in one of three quadrants that did not contain the hidden platform. The starting position was in a semi-random order so that no start point was repeated and no point was used more than three times. The location of the hidden platform remained constant. If the animal did not find the hidden platform within 60 s, the rat was guided to the platform by the experimenter and allowed to remain on the platform for approximately 15 s before being placed in a dry holding cage for an additional 60 s. Following the last training trial, rats were returned to their home cages and were left undisturbed until the probe trial. A probe trial was given 24 hr after the last learning trail. During the probe trial, the platform was removed and each rat had a 30 s free swim in the pool. All rats were started in the quadrant across from the target quadrant.
Spatial Working Memory
Separate rats (n=17 SI, n=11 CC) were tested in the spatial working memory water maze task. The EC group was not utilized since no significant differences were eventually found between CC and SI groups. Initially, rats were trained in a standard water maze protocol as described above. During this training, the location of the hidden platform remained constant across all trials. This training occurred approximately one week before spatial working memory testing and allowed rats to learn the basic form of the water maze task.
Following the water maze training, rodents were tested in spatial working memory protocol. The spatial working memory task consisted of pairs of trials. In the first trial, a visible platform marked with a flag was placed in a novel location in the tank. The nine novel positions used in the task were modified from Steele and Morris (Steele and Morris 1999) (see Fig. 1). Rats were released facing the wall from one of the 3 quadrants that did not contain the platform. Rats were given 120 s to locate the visible platform before the experimenter would guide the rat to the platform. After 15 s on the platform, rats were removed to an individual holding cage. During this time, the flag was removed from the platform so that it was hidden but in the same location as in the first trial. After the rodent spent 1, 5, or 10 min in the holding cage, the rat was placed in the tank in on of the two quadrants that did not contain the platform and was not the starting quadrant from the first trial. Rats were once again given 120 s to find the hidden platform before the experimenter would guide the rat. After approximately 5 s on the platform, the rat was placed back in the holding cage for 10 min before a new pair of trials (visible followed by hidden platform) with a novel platform location was given. Three rats were tested at a time. The order of delays was counterbalanced so that each rat was tested three times at 1, 5, or 10 min delays between the visible and hidden platforms. Therefore, each rat was tested with 9 pairs of trials with the platform in a novel location for each pair. The total testing time for 3 rats was less than 2.5 hrs.
Data Analysis
The main dependent variables collected in both tests were latency and path distance rats took to find the platform in the water maze. In probe trial data, the main dependent variables were percent time and swim distance spent in the quadrant of the pool that formerly contained the hidden platform. Water maze testing was analyzed by factorial repeated measures analysis of variance (ANOVA). Trend analysis of data was conducted using Tests of Within-Subjects Contrasts and sphercity was verified using Mauchly's Test. Probe trial data were analyzed by ANOVA followed by Dunnett's post hoc analysis. All data analysis was conducted utilizing SPSS (v 13.0) with an alpha level of 0.05.
Results
Reference Memory Water Maze Task
Twenty-four hrs of SI did not alter acquisition of platform location in massed trial learning, but did impair the memory of platform location 24 hrs later (see Fig. 2). In acquisition trials (Fig. 2A), no significant differences in learning were observed among the 3 different groups of rats as indicated by either latency (F(2,32) = 2.139, p > 0.05) or swim distance to reach the platform (F(2,33) = 2.148, p > 0.05), nor was there a significant trial x group interaction for latency or distance (F(14,224) = 1.287, p > 0.05; F(14,224) = 1.086, p > 0.05 respectively). There was a significant effect across trials (latency: F(7,224) = 24.683, p < 0.05; distance: F(7,224) = 15.308, p < 0.05) indicating the animals learned the location of the platform. Twenty-four hours after the last trial, rats were tested in a single probe trial to test memory of the platform location. The percentage of total time and distance the animals spent searching in the quadrant that formerly contained the hidden platform was calculated (Fig. 2B). There was a significant difference among the groups in percent time (F(2,32) = 4.405, p < 0.05) and percent distance (F(2,32) = 10.750, p < 0.05) indicating SI rats overall spent significantly less time in the target quadrant than did CC (p < 0.05), but EC was not significantly different from CC. Differences in probe performance cannot be attributed to motor impairments since swim velocity was not significantly altered (F(2,32) = 0.404, p > .05) (data not shown).
Spatial Working Memory Water Maze Task
In the spatial working memory task, control rats took increasingly longer time periods and distances to reach the hidden platform as delay periods lengthened from 1 to 10 min (see Fig. 3). In control rats, there were no significant differences in the latency (F(2,44) = 0.084, p < 0.05) or swim distance (F(2,44) = 0.015, p > 0.05) to reach the visible platform among the different delay intervals. However, there was a significant effect of delay time on rodents latency (F(2,44) = 7.814, p < 0.05) and path length (F(2,44) = 6.829, p = 0.005) to find the hidden platform. The pattern of responses showed a significant linear trend (F(1,11) = 11.594, p < 0.05) with the shortest mean latencies following the 1 min delay and the longest average latency following the 10 min delay. The same linear pattern of responses was observed for swim distance (F(1,11) = 9.945, p = 0.009) where once again, the shortest average distances were observed after the 1 min delay and the longest average distances followed the 10 min delay. There was not a significant main effect for the trial number in latency (F(1.318,44.0) = 3.083, p > 0.05) or swim distance (F(1.263,44.0) = 3.762, p > 0.05) indicating that rats performed similarly across the 3 trials of the same delay. The delay X trial interaction was also not significant for latency (F(4,44) = 1.220, p > 0.05), or distance (F(4,44) = 1.204, p > 0.05).
Twenty-four hours of SI did not impair performance on the spatial working memory task (See Fig. 4). There were no significant differences between SI and CC groups in either latency (F(1,26) = 0.216, p > 0.05) or in the path length to find the hidden platform (F(1,26) = 0.236, p > 0.05). Motivation to escape the water maze was not affected by 24 hrs of SI. There were no significant differences in latency (F(2,33) = 0.977, p > 0.05) or swim distance (F(2,33) = 1.513, p > 0.05) to find the visible platform (data not shown). Additionally, as seen in the previous experiment, swim speed velocity was not affected by SI (F(2,33) = 0.046, p > 0.05) (data not shown).
Discussion
The present set of experiments demonstrate that 24 hrs of sleep fragmentation causes a deficit in the retention of a spatial reference memory task, but no impairments in a spatial working memory task. There were also no impairments observed in the learning of the location of the hidden platform in the spatial reference memory task. This suggests that prior sleep disturbances selectively interfere with the consolidation of spatial memories.
When compared to previous findings, the present data indicate that subtle differences in water maze testing protocols and/or the use of different rat strains can influence the outcome of studies investigating the effect of sleep disruption on learning and memory. Previous research from our laboratory demonstrated that 24 hrs of SI impaired water maze acquisition (Tartar et al. 2006). The differences in results are likely due to the choice of rat strains. Prior research in our lab utilized Sprague Dawley (SD) rats while the present study utilized Fisher/Brown Norway (FBN) rats, which are superior performers in spatial learning tasks when compared to Sprague Dawley rats (Harker and Whishaw 2002). The idea that different strains could be impacted by sleep loss differently could be a reflection of individual variations in response to sleep loss in humans (Van Dongen et al. 2005).
Another major difference between the present study and previous findings (Tartar et al. 2006) is changes in testing protocol. Prior research utilized a protocol in which rats were allowed one hr breaks between three sessions of four trials/session. The present protocol does not utilize any breaks between the eight consecutive acquisition trials as described by Packard and Teather (1997). This rapid protocol allows testing to be completed in a minimal amount of time after being removed from SI. The pattern of results observed in the present experiment are consistent with a finding in another laboratory where rats were not given a break between trails and only showed deficits in the recall of the platform location and not acquisition following total sleep deprivation (Guan et al. 2004).
These results propose an interesting hypothesis that the choice of water maze protocol is important in that the two protocols used in our sleep fragmentation studies gave different results. If sleepiness produced by sleep fragmentation selectively impairs the consolidation of spatial memories, it is possible that utilizing a protocol that allows for 1 hr breaks between blocks of sessions relies more on the consolidation of memories in prior blocks as opposed to keeping the memories “fresh” during continuous training. The results of the spatial working memory task could support this argument.
It is likely that there is an interaction effect of rat strain and task difficulty. Additional research in our laboratory (McCoy et al. 2007b) in which FBN rats were tested utilizing the same protocol as previously reported with SD rats (Tartar et al. 2006). demonstrated that FBN rats show no learning or recall deficits following 24 hr of sleep fragmentation (McCoy et al. 2007b). The SD rats showed sleep loss related deficits in the easier water maze task (i.e. three sessions of four trials/session) and, in pilot studies, performed very poorly on the harder water maze task (eight consecutive trials and 24 hr recall) without any manipulations. On the other hand, FBN rats do not show deficits due to sleep disruption in the easy water maze task (McCoy et al. 2007b) but do show deficits in the retention of spatial memory.
The impact of the SI procedure utilized in the present experiment on sleep architecture has been characterized in prior research from our laboratory. This procedure has used with both SD (McKenna et al. 2007;Tartar et al. 2006) and FBN (McCoy et al. 2007a) rats. Twenty-four hours of SI produces a reduction in sleep bout length, and a reduction in total amount of sleep, mainly at the expense of rapid eye movement (REM) sleep. Total amount of non-REM sleep is not greatly affected (McCoy et al. 2007a;McKenna et al. 2007;Tartar et al. 2006). Rats show an increase in sleepiness following 24 hrs SI as defined by decreased time to fall asleep in a multiple sleep latency test (McKenna et al. 2007) and increased extracellular levels of the inhibitory neuromodulator, adenosine, in the basal forebrain (McKenna et al. 2007). Basal forebrain levels of adenosine has previously been shown to increase during prolonged wakefulness and dissipate during recovery sleep (Porkka-Heiskanen et al. 1997;Porkka-Heiskanen et al. 2000). Additionally, electroencephalogram measures indicate an increase in non-REM delta power in recovery sleep (McCoy et al. 2007a;McKenna et al. 2007;Tartar et al. 2006). Non-REM delta power has been proposed as a homeostatic marker of sleep drive (Franken et al. 1991).
The evidence for sleepiness persists for approximately three hours following the termination of the SI protocol (McCoy et al. 2007a;McKenna et al. 2007;Tartar et al. 2006), therefore, the spatial memory tests utilized in the present study were specifically designed to be completed within this time constraint. Standard protocols in the reference memory version of the water maze task typically divide training over several days (Morris et al. 1982;Sutherland et al. 1982). Rapid training protocols for this task has been previously developed (Frick et al. 2000;Packard and Teather 1997). On the other hand, to the author's knowledge, no spatial working memory task that can be completed within three hours has been developed. Much like the standard water maze task, typical working memory protocols take many days (Steele and Morris 1999;Whishaw 1985). The delayed matching to sample task used to asses spatial working memory in the present study is a novel task that allows for completion in under three hours while rodents are still sleepy (McKenna et al. 2007). This task shows increased memory demands on rodents as delay periods increase (see Fig. 3). Additionally, as a spatial working memory tasks defines (Olton 1977;Steele and Morris 1999;Whishaw 1985), each cued/non-cued trial pairing is in a unique spatial location, rodents must disregard previous platform locations and recall only the most recent cued location. The task also includes a built-in test for motivation, sensory, and motor ability since the initial trial is cued by a visible target. While this task is promising as a rapid measure of spatial working memory in rodents, additional test validation is needed to demonstrate that the test is sensitive to known manipulations that disrupt spatial working memory.
While there is still some debate about the role of sleep in memory consolidation (Vertes 2004), there is growing evidence that sleep does play an important role in the consolidation of memories (Stickgold and Walker 2007) even though the mechanisms are not fully understood (Frank and Benington 2006). While the role of sleep after learning a new task has generated a great deal of research, experiments exploring learning a new task while sleepy has received less attention (Guan et al. 2004;Stern 1971;Yoo et al. 2007). In humans, a recent functional imaging study showed that participants with a single night of sleep deprivation had impaired hippocampal activity during episodic memory encoding (Yoo et al. 2007). Prior research from our laboratory has demonstrated that sleepiness resulting from 24 hrs of SI causes a deficit in the acquisition of a spatial learning task that correlated with an absence of hippocampal long-term potentiation (LTP) (Tartar et al. 2006). Other laboratories have also noted impaired hippocampal LTP following selective REM sleep deprivation (Davis et al. 2003;McDermott et al. 2003). Prior sleep deprivation has also been shown to reduce phosphorylated extracellular signal-regulated kinase (ERK) in the hippocampus (Guan et al. 2004). Sleepiness in rodents also caused a deficit in cognitive flexibility in a test of executive functioning (McCoy et al. 2007b). It is a possibility that increases in basal forebrain adenosine due to sleep fragmentation (McKenna et al. 2007) inhibits excitatory projections from the basal forebrain to the frontal cortex and hippocampus.
Another possible hypothesis is that memory impairments following sleep fragmentation is a secondary effect, and that deficits in attention are the primary effect. Sleep loss impacts measures of attention in humans (Dinges et al. 1997) and rats (Cordova et al. 2006;Godoi et al. 2005). If attentional functions are compromised, this will affect later encoding of memories. While the impact of sleepiness on attention cannot be overlooked, evidence from impaired hippocampal function following sleep loss suggests that there are additional deficits in the memory circuit. Additionally, stress produced by the treadmill-induced SI procedure is an unlikely explanation for the memory deficit since prior research has shown that EC and SI both have elevated levels of circulating corticosterone (Tartar et al. 2006), though only SI rats indicate difficulty in the recall of the platform location.
In conclusion, sleepiness induced by 24 hrs of sleep fragmentation (McKenna et al. 2007) effectively impairs rodents’ performance in the recall of a reference memory task but not a working memory task. Combined with our previous work the findings indicate that sleep disruption more easily impairs spatial reference memory in SD rats compared to FBN rats; and, the effect of sleep disruption on spatial reference memory is influenced by the trial frequency of the water maze protocol used (massed versus spaced acquisition trials). This adds to the growing set of literature that the disruption of sleep can severely impact the ability to consolidate hippocampal dependent memories.
Acknowledgements
The authors wish to thank Matthew Heard for his excellent technical assistance. This research was supported by NIH HL060292 and the Department of Veterans Affairs.
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