Phenotypic differences in the hemodynamic response during REM sleep in six strains of inbred mice
Matthew J. Campen1,
Yugo Tagaito2,
Todd P. Jenkins1,
Philip L. Smith1,
Alan R. Schwartz1 and
Christopher P. ODonnell1
1 Department of Medicine, Division of Pulmonary and Critical Care, Johns Hopkins University, Baltimore, Maryland 21224
2 Department of Anesthesiology, Chiba University School of Medicine, Chiba 260, Japan
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ABSTRACT
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The pattern of cardiovascular changes that occur at nighttime can have an impact on morbidity and mortality. Rapid-eye-movement (REM) sleep, in particular, represents a period of increased risk due to marked cardiovascular instability. We hypothesized that genetic differences between inbred strains of mice would affect the phenotypic expression of cardiovascular responses that occur in REM sleep. We monitored polysomnography and arterial blood pressure (PSA) simultaneously in six inbred strains of mice as they naturally cycled through sleep/wake states. Two strains elevated their PSA above non-REM (NREM) levels for 57.9 ± 6.6% (BALB/cJ) and 51.8 ± 8.4% (DBA/2J) of the REM period and exhibited a significant (P < 0.05) number of PSA surges greater than 10 mmHg (0.78 ± 0.36 surges/min for BALB/cJ; 0.63 ± 0.13 surges/min for DBA/2J). Despite similar PSA responses, the DBA/2J strain exhibited a decreased heart rate and the BALB/cJ strain exhibited an increased heart rate during REM sleep. The four other strains (A/J, C57BL/6J, C3H/HeJ, and CBA/J) exhibited a significant hypotensive response associated with no change in heart rate in three of the strains and a significant decrease in heart rate in the A/J strain. The overall variability in PSA during REM sleep was significantly greater in the C3H/HeJ strain (26.8 ± 2.0 mmHg; P < 0.0125) compared with the other five strains. We conclude that genetic background contributes to the magnitude, variability, and arterial baroreceptor buffering capacity of cardiovascular responses during REM sleep.
arterial baroreceptors; autonomic function; genetic; heart rate; heart rate variability; non-rapid-eye-movement sleep; sympathetic nerve activity; systemic arterial blood pressure
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INTRODUCTION
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THE REGULATION of systemic arterial pressure (PSA) is markedly different between sleep stages. The transition from wakefulness to non-rapid-eye-movement (NREM) sleep is accompanied by an overall reduction in autonomic functions including metabolism, ventilation, heart rate, and PSA (2, 14, 16). In the transition from NREM to REM sleep, however, autonomic activity is distinctly variable, causing ventilation, heart rate, and PSA to become highly labile, potentially uncoupling blood supply from metabolic needs (5, 14, 16, 20). As such, REM sleep represents a period of increased cardiovascular vulnerability (19).
The variability of autonomic function during REM sleep makes it difficult to define a "normal" PSA response. In humans, REM sleep appears to cause an erratic but overall unchanged or increased PSA (2, 5, 16). This human profile of PSA change in REM sleep has also been reported in studies on rats and cats (9, 11, 13). In contrast, we have shown that dogs (8) and C57BL/6J mice (7) exhibit a distinct and repeatable hypotension during REM sleep, a response also seen in other studies using cats (4) and pigs (21). Many potential factors could contribute to these seemingly disparate findings between studies and species, including time spent in phasic vs. tonic REM sleep (10, 16) and baroreceptor buffering capacity (12). Moreover, it is possible that genetic factors affect the neural activity or peripheral vascular responses that occur during REM sleep and, therefore, account for the previously reported variation in PSA responses.
To date, there has been no systematic investigation of whether genetic factors influence the phenotypic expression of PSA responses during REM sleep. We have previously developed techniques to simultaneously record polysomnography and PSA in chronically instrumented C57BL/6J mice during REM sleep (7). Therefore, the purpose of the current study was to extend these initial observations from a single strain and compare PSA and heart rate responses during REM sleep in six common inbred strains of mice. We hypothesized that genetic differences between inbred strains of mice would affect the phenotypic expression of cardiovascular responses that occur in REM sleep.
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METHODS
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Surgical Procedures
Experiments were performed in 52 adult, male mice (1216 wk old; Jackson Laboratories, Bar Harbor, ME). The animals were housed at the Johns Hopkins University in an antigen-free and virus-free facility and subjected to a 12-h light (09002100) and 12-h dark cycle. Temperature and humidity were carefully monitored and maintained between 2124°C and 3060%, respectively. Food and water were available ad libitum throughout the study. A total of 612 animals were studied from each of the following strains in random order: A/J, BALB/cJ, C57BL/6J, DBA/2J, C3H/HeJ, and CBA/J. Two separate surgeries were performed on each animal. Anesthesia was induced and maintained using isoflurane administered through a face mask.
In the first surgery the mice were instrumented with chronically implanted polysomnographic electrodes for determination of sleep/wake state, as previously described (7). To describe in brief, a midline incision was made to expose the skull and muscles immediately posterior to the skull. Four electroencephalographic (EEG) electrodes and two nuchal electromyographic electrodes (EMG) were fashioned from Teflon-coated stainless steel wire (outside diameter 0.018 cm Teflon coated and 0.013 cm bare; A-M Systems, Everett, WA). The EEG electrodes were inserted into four predrilled holes in the frontal and parietal regions and bonded to the dorsal surface of the skull with dental acrylic (Land Dental, Wheeling, IL). The two EMG electrodes were stitched flat onto the surface of the muscle immediately posterior to the dorsal area of the mouse skull (EMG). The skin overlying the skull and posterior muscles was reapposed, and the six electrodes exited the skin dorsally
1.25 cm posterior to the point of EMG attachment. The total time from induction of anesthesia to recovery of consciousness was
3040 min. All animals were allowed 35 days to recover from the first surgery before undergoing the second surgery.
In the second surgery, an arterial catheter was chronically implanted in the left femoral artery for measurement of PSA (18). The femoral artery was exposed by a 1.5-cm cutaneous incision and blunt dissection of the fascia and surrounding connective tissue, then tied with 6-0 suture distal to the point of catheter insertion. A 60-cm Renathane catheter (model MRE025; Braintree Scientific), heat-stretched and formed into a J-shape, was inserted with the aid of a 26-gauge needle and advanced
0.51.0 cm toward the bifurcation of the aorta. The catheter was secured by suture and cyanoacrylate glue (Quicktite Superglue, Manco), then exteriorized at the base of the skull and secured to the EEG/EMG electrodes. The catheter was attached to a single-channel fluid swivel (model 375/25; Instech Laboratories) and perfused throughout the recovery and monitoring period by an infusion pump (0.5 ml/day) with a sterile saline solution containing heparin (80 U/ml). The total time from induction of anesthesia to recovery of consciousness was
5060 min. The success rate for the EEG/EMG implantation was 100%, and the success rate from the femoral artery catheterization was 71% (Table 1). Implant failure was decided based on poor recovery from surgery (behavioral assessment) and also on the quality of the pulsatile PSA signal; no specific strain differences were noted in the success rate of catheterization. All animals were allowed a minimum of 48 h to recover from the second surgery before beginning data collection. The study was approved by the Johns Hopkins University Animal Use and Care Committee and complied with the American Physiological Society Guidelines.
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Table 1. Systemic arterial pressure and heart rate averaged over a consecutive 24-h period in six inbred strains of mice
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Apparatus and Methods of Measurement
Arterial pressure measurements were made with pressure transducers (Cobe, Lakewood, CO) zeroed at midthoracic level. Calibrations were verified at the beginning and end of each experiment. A pen recorder (Grass Instruments, Quincy, MA) was used to record EEG activity, EMG activity, and PSA; the arterial pulse rate was used to determine heart rate. Signals from the pen recorder were digitized at 300 Hz (DI-200 data acquisition board; Dataq Instruments, Akron, OH) and stored on optical disk with Windaq/200 acquisition software (Dataq Instruments).
During data collection periods the animals remained in their single occupancy cages. The stripped ends of the polysomnographic electrodes were attached to the Grass polygraph via an input cable (7P5B; Grass Astromed, West Warwick, RI) and the arterial catheter connected to the pressure transducer. The length of the electrode-catheter unit allowed the animal to move freely within the cage throughout the data collection period.
Experimental Protocol
Experiments were conducted during the light cycle between 1200 and 1700 h in a quiet room. Each animal was permitted to acclimate for
30 min before beginning data collection. The protocol consisted of allowing the mice to naturally cycle through their normal sleep/wake states for 34 h while polysomnography and PSA was continuously recorded.
Data Analysis
Sleep/wake states were assessed from continuous EEG and EMG recordings over 30-s epochs as described previously (7). Wakefulness was characterized by low-amplitude, high-frequency (
1020 Hz) EEG waves and high levels of EMG activity compared with the sleep states. NREM sleep was characterized by high-amplitude, low-frequency (
25 Hz) EEG waves and an EMG activity considerably less than during wakefulness. REM sleep was characterized by low-amplitude, mixed frequency (
510 Hz) EEG waves, although the predominant pattern was a fixed amplitude theta frequency consistent with hippocampal theta rhythm. During REM sleep, the EMG activity was either equal to or less than that seen during NREM sleep, but always less than that seen during wakefulness. Two trained investigators conducted all sleep/wake state assessments manually; reproducibility of these methods has been confirmed previously (7).
The PSA and heart rate were analyzed for each period of REM sleep and compared with the corresponding mean values for the immediately preceding 120 s of NREM sleep. During each individual period of REM sleep the following parameters were determined: mean PSA; mean heart rate; maximum PSA; minimum PSA; percent of time in REM sleep that the PSA was above the mean value for the immediately preceding 120 s of NREM sleep; and number of PSA surges per minute greater than 10 mmHg above the mean value for the immediately preceding 120 s of NREM sleep. All PSA measurements were determined from the digitally filtered PSA signal (Windaq, filter factor 100, Dataq Instruments). The maximum and minimum PSA were used to determine the overall variability of PSA during REM sleep; percent of time in REM sleep that the PSA was above NREM sleep levels and the number of PSA surges per minute greater than 10 mmHg during REM sleep were used to determine the degree of hypertensive stress that occurred in REM sleep relative to NREM sleep. At the completion of the REM sleep protocol, monitoring was continued for a further 24-h period to establish baseline values for mean PSA and heart rate for each of the six strains.
Heart rate variability (HRV) was calculated from beat-to-beat intervals obtained by identifying systolic peaks of the arterial pressure waveform. The resulting tachograms (RR interval vs. time) were examined individually to detect and correct arrhythmias or artifactual values from the series. The tachogram was then transformed using a Lomb-type periodogram to determine the frequency spectrum (6) using a software program generated in collaboration the US Environmental Protection Agency and Dr. William P. Watkinson. This method was preferred over traditional Fourier analysis, as the Lomb-type transform is better suited for analyzing discrete data series as opposed to continuous, evenly sampled waveforms. The low-frequency range was calculated as the area under the curve from 0.02 to 1.5 Hz, and the high-frequency range was calculated between 1.5 Hz and the Nyquist frequency (heart rate frequency divided by two, typically between 4 and 5 Hz during sleep). As heart rate was not grossly different between sleep stages, no power normalization for greater frequency ranges was implemented.
Phenotypic measurements of PSA, heart rate, and HRV for each individual period of REM sleep were averaged for each mouse. A statistical difference in cardiovascular parameters between NREM and REM sleep was determined by paired t-test within each strain. One-way ANOVA was used to detect significant differences in change in PSA, change in heart rate, variability of PSA, percent time PSA was above NREM levels, and the duration of REM sleep between the six different strains. If the ANOVA was significant, then a post hoc test (Scheffé method) was used to identify which means were significantly different. Data are reported as means ± SE, and differences were considered significant if P < 0.025.
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RESULTS
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Baseline PSA and Heart Rate
Table 1 shows mean PSA and heart rate averaged over a continuous 24-h period in each of the six strains. The A/J and DBA/2J strains exhibited significantly lower PSA values, and the C3H/HeJ and CBA/J strains exhibited significantly higher heart rates, compared with the other strains.
Cardiovascular Changes During REM Sleep
REM sleep duration.
The number of REM cycles ranged between 4.8 ± 1.0 and 9.2 ± 0.4 for the various mouse strains during the experimental period (Table 2). REM cycle duration lasted on average more than 60 s in all strains (range 62.9 ± 19.4 to 106.8 ± 14.5 s) but was of significantly longer duration in the DBA/2J strain compared with all other strains except the C3H/HeJ strain.
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Table 2. REM cycles, mean REM cycle duration, percent of the REM cycle period in which the PSA is above preceding NREM level, and PSA surges above the NREM level in six strains of inbred mice
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PSA and heart rate.
Distinct patterns of cardiovascular behavior were observed between strains during REM sleep. Figure 1 is a sample tracing that illustrates contrasting cardiovascular responses exhibited by the A/J and DBA/2J strains during REM sleep. The A/J mouse (Fig. 1, top) develops a significant and sustained hypotension throughout the REM period. In contrast, the DBA/2J mouse shows a slightly elevated PSA during REM sleep, punctuated by short hypertensive surges above the preceding NREM levels.

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Fig. 1. Representative tracings of arterial blood pressure (PSA) responses during NREM and REM sleep in an A/J (top) and DBA/2J (bottom) mouse. At the onset of REM sleep, the PSA of the A/J mouse decreases steadily from a mean of 9684 mmHg. In contrast, the PSA does not decrease and shows surges of 10 mmHg or more above NREM levels during REM sleep in the DBA/2J mouse. REM, rapid eye movement; NREM, non-REM.
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The individual and mean changes in PSA and heart rate for each strain are shown in Figs. 24. The A/J, CBA/J, C3H/HeJ, and C57BL/6J strains all displayed significant hypotension during REM sleep (Fig. 2). The BALB/cJ and DBA/2J strains, however, maintained their PSA during REM sleep. When the change in PSA between NREM and REM sleep is plotted for each animal (Fig. 3, top), there is effectively no overlap in responses between the BALB/cJ and DBA/2J strains compared with the other four strains.

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Fig. 2. Individual and mean (±SE) PSA responses during NREM and REM sleep for six inbred mouse strains. Solid diamonds connected by solid lines represent individual responses, and open diamonds represent mean strain responses. *Significant change from NREM by paired t-test (P < 0.05).
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Fig. 3. Top: individual responses for change in mean PSA between NREM and REM sleep in six inbred strains of mice. The change in mean PSA between NREM and REM was significantly higher (P < 0.0025) in the DBA/2J and BALB/cJ strains compared with the other four strains of mice. Bottom: individual responses for the difference between maximum and minimum PSA during REM sleep in six inbred strains of mice. The difference between maximum and minimum PSA during REM sleep was significantly higher (P < 0.0125) in the C3H/HeJ strain compared with the other five strains of mice. *Strains with significant differences from other strains determined by the Scheffé method.
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Fig. 4. Individual and mean (±SE) heart rate responses during NREM and REM sleep for six inbred mouse strains. Solid diamonds connected by solid lines represent individual responses, and open diamonds represent mean strain responses. *Significant change from NREM by paired t-test (P < 0.05).
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The C3H/HeJ strain displayed the greatest lability in PSA of all six strains during REM sleep as determined by the maximum range of PSA fluctuation during REM sleep (i.e., maximum - minimum PSA; Fig. 3, bottom). Further evidence of the greater range of variability in PSA in the C3H/HeJ strain can be seen in the two right columns in Table 2. Despite the C3H/HeJ mice spending less than 20% of the REM period with the PSA above NREM levels, they still exhibited 0.38 ± 0.11 surges/min of greater than 10 mmHg above NREM levels. In contrast, the CBA/J strain, which had a comparable period of time to the C3H/HeJ mice above NREM levels, exhibited no surges in PSA.
The pattern of heart rate changes during REM sleep shown in Fig. 4 appears unrelated to the pattern of PSA responses in the six strains described above (Fig. 2). Heart rate decreased significantly in the A/J and DBA/2J strains, increased in BALB/cJ strain, and displayed no significant trends in C57BL/6J, C3H/HeJ, and CBA/J strains.
Heart rate variability.
No significant strain differences were observed with respect to baseline HRV values [high frequency (HF), low frequency (LF), or standard deviation of beat-to-beat intervals (SDNN)] during either NREM or REM sleep (Fig. 5) among the different strains. The change from NREM to REM sleep was associated with decreased high-frequency power (Fig. 5, top), a reported index of cardiac vagal activity, and increased low-frequency power (Fig. 5, middle), a reported index of cardiac sympathetic activity (1). SDNN values (Fig. 5, bottom) increased from NREM to REM sleep similar to the pattern seen for low-frequency power.

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Fig. 5. Heart rate variability (HRV) during NREM and REM sleep in six inbred strains of mice. High-frequency power is a marker for cardiac parasympathetic activity, low-frequency power is a marker for cardiac sympathetic activity, and the standard deviation of beat-to-beat intervals (SDNN) estimates overall variability of heart rate. Values are means ± SE. *Significant difference between NREM and REM sleep by paired t-test (P < 0.05).
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DISCUSSION
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The current study presents a number of findings demonstrating that the phenotypic expression of PSA and heart rate responses during REM sleep differ between inbred mouse strains. We report differences between strains in the overall change in PSA during REM sleep (Figs. 2 and 3), the extremes of PSA lability during REM sleep (Fig. 3), and the heart rate responses that accompanied changes in PSA (Fig. 4). In the discussion that follows, we propose that genetic factors may in large part account for the variable PSA responses previously reported during REM, and we examine potential neural pathways and neurotransmitters that regulate PSA during REM sleep.
Pattern of PSA Responses During REM Sleep
At least three factors have previously been proposed to account for the diversity of PSA responses reported during REM sleep. First, the time of recovery after chronic instrumentation in animal studies may influence the pattern of PSA response seen during REM sleep. Early studies showed that chronically instrumented cats exhibited a marked hypotension and peripheral vasodilation during REM sleep (4). A more recent study in cats, however, demonstrated hypotension during REM sleep was restricted to the first few days after surgery (13). After more prolonged periods of recovery, REM sleep produced a hypertensive response that the authors (13) claim is similar to reports in other animals. Based on these data it could be concluded that under optimal conditions, neither humans nor animals exhibit a predominantly hypotensive response during REM sleep. However, in the context of the current study in which experiments were conducted within 25 days after surgical intervention, four strains of mice exhibited hypotension during REM sleep and two strains did not. This suggests that differences between strains are more likely related to genetic differences rather than effects associated with recovery time from surgery, although it is possible that the experimental conditions (e.g., invasive surgery) interacted with differences in genetic background to influence the cardiovascular phenotypes. However, our previous studies in chronically instrumented dogs argue against any time-related phenotypic effects, since REM sleep inevitably produced a hypotensive response despite animals being instrumented for several months (8). Thus genetic background is likely an important determinant of cardiovascular responses during REM sleep.
Second, studies in humans and animals have indicated that phasic REM periods, characterized by eye movements and pontogeniculooccipital (PGO) waves, are associated with surges in arterial PSA (10, 16). As such, the relative amount of time spent in phasic REM vs. tonic REM may influence the overall magnitude of the PSA response observed throughout a REM sleep period. In the current study, we did not measure eye movements or PGO waves, so we cannot exclude the possibility that the four strains of mice that exhibited a hypotensive response spent a greater proportion of their REM period in phasic REM than the two strains that did not exhibit hypotension. However, it should be noted that the C3H/HeJ strain, which produced an overall hypotensive response during REM sleep, exhibited the most labile PSA profile. Thus, at least in the C3H/HeJ strain, overall hypotension and heightened lability occur simultaneously, suggesting that if phasic REM accounts for the labile response, it was not sufficient to prevent hypotension. Future studies will be necessary to determine whether various inbred strains of mice display different proportions of tonic vs. phasic REM.
Third, baroreceptor buffering capacity may influence the PSA changes that occur during REM sleep. An early study in rats showed that baroreceptor denervation converted a previous hypertensive response during REM sleep to a hypotensive response (3). More recently, however, it has been reported that baroreceptor denervation accentuates the hypertensive response during REM sleep in rats (12). It is unclear what accounts for these opposite PSA responses during REM sleep after baroreceptor denervation in the rat, although genetic differences may have played a role. In our study, the relationship between PSA and heart rate varied between strains. Interestingly, heart rate changed in opposite directions during REM sleep in the DBA/2J and BALB/cJ strains, yet both strains similarly increased their PSA above NREM levels for more than 50% of the REM period and exhibited comparable surges in PSA. Furthermore, in the four strains that exhibited significant hypotension during REM sleep, there were no consistent changes in heart rate. Thus the absence of consistent heart rate changes to specific patterns of PSA response suggests that genetic background may influence baroreceptor buffering capacity during REM sleep in mice.
Neurotransmitters and Neural Pathways
A key neurotransmitter in the genesis of REM sleep and its associated cardiovascular response is acetylcholine. Carbachol, an acetylcholine agonist, can induce a REM-like state and cause an initial hypotension when injected into the pons. These findings led Shiromani et al. (15) to hypothesize that pontine muscarinic mechanisms trigger REM sleep and an associated hypotension. Furthermore, Shiromani et al. (15) suggested that with increasing time in REM sleep, acetylcholine nicotinic receptors mediate a PSA increase that overrides any muscarinic-induced decrease in PSA. Thus, any genetic variation in nicotinic and muscarinic receptor distribution or function may influence the pattern and magnitude of PSA responses that occur in REM sleep. Interestingly, a polymorphism in a neuronal acetylcholine nicotinic subunit has been reported in the DBA/2J mouse, but not in any of the other five strains we studied (17), suggesting the possibility that the PSA response during REM sleep in the DBA/2J strain may be related to nicotinic receptor function.
The cardiovascular changes that occur in REM sleep are ultimately determined by autonomic output to the heart and vasculature. Previous studies in cats suggested that during REM sleep autonomic activity can vary between vascular beds, and, therefore, the PSA, total peripheral resistance, and cardiac output changes during REM sleep will represent the sum of responses in all vascular beds (4). It is possible that the strain differences in cardiovascular responses during REM sleep we report result from a varying pattern of autonomic activity in specific vascular beds. Although our study did not assess autonomic activity to specific vascular beds, we did perform HRV analysis as a marker of cardiac autonomic activity. Our data, however, showed a similar pattern of response in all strains with a decrease in high-frequency power and an increase in low-frequency power from NREM to REM sleep, a pattern comparable to that reported in humans (1). Thus a genetic basis for differences in regional autonomic control of vascular activity during REM sleep remains to be determined.
Summary and Implications
The findings of the current study show that genetic background can have a significant impact on the phenotypic expression of cardiovascular responses during REM sleep. We propose that these data may, in part, explain the inability of previous studies to define a consistent cardiovascular pattern during REM sleep, even within a single species. Thus genetic background may render particular individuals more susceptible to adverse cardiovascular outcomes during REM sleep, particularly in the presence of a comorbid condition such as obstructive sleep apnea. For example, an individual with the highly labile PSA profile of the C3H/HeJ strain and significant REM-related apnea may be at increased risk of ischemia if PSA fell precipitously during hypoxic events and at increased risk of elevated afterload if PSA rose precipitously during posthypoxic periods of arousal. A goal of future studies will be to determine what specific genetic profile predisposes to cardiovascular pathology during REM sleep.
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ACKNOWLEDGMENTS
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We thank Jessica A. Wilson and Kathryn M. Soaper for superb technical assistance.
This study was funded by National Heart, Lung, and Blood Institute Grants HL-51292 and HL-66324.
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FOOTNOTES
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Article published online before print. See web site for date of publication (http://physiolgenomics.physiology.org).
Address for reprint requests and other correspondence: C. P. ODonnell, Johns Hopkins Asthma and Allergy Center; Rm. 4B.61, 5501 Hopkins Bayview Circle, Baltimore, MD 21224 (E-mail: codonnel{at}jhmi.edu).
10.1152/physiolgenomics.00031.2002.
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