The effect of changes in cardiac output on middle cerebral artery mean blood velocity at rest and during exercise
1 Department of Integrative Physiology University of North Texas Health Science Center at Fort Worth, TX 76107, USA
Abstract
We examined the relationship between changes in cardiac output and middle cerebral artery mean blood velocity (MCA Vmean) in seven healthy volunteer men at rest and during 50% maximal oxygen uptake steady-state submaximal cycling exercise. Reductions in were accomplished using lower body negative pressure (LBNP), while increases in were accomplished using infusions of 25% human serum albumin. Heart rate (HR), arterial blood pressure and MCA Vmean were continuously recorded. At each stage of LBNP and albumin infusion was measured using an acetylene rebreathing technique. Arterial blood samples were analysed for partial pressure of carbon dioxide tension (Pa,CO2. During exercise HR and were increased above rest (P < 0.001), while neither MCA Vmean nor Pa,CO2 was altered (P > 0.05). The MCA Vmean and were linearly related at rest (P < 0.001) and during exercise (P= 0.035). The slope of the regression relationship between MCA Vmean and at rest was greater (P= 0.035) than during exercise. In addition, the phase and gain between MCA Vmean and mean arterial pressure in the low frequency range were not altered from rest to exercise indicating that the cerebral autoregulation was maintained. These data suggest that the associated with the changes in central blood volume influence the MCA Vmean at rest and during exercise and its regulation is independent of cerebral autoregulation. It appears that the exercise induced sympathoexcitation and the change in the distribution of between the cerebral and the systemic circulation modifies the relationship between MCA Vmean and .
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Introduction
Cerebral autoregulation maintains cerebral blood flow constant over a range of arterial pressures from 60 to 150 mmHg (Paulson et al. 1990). In humans, measurements of middle cerebral artery mean blood velocity (MCA Vmean) provide an index of the cerebral blood flow (Ide & Secher, 2000; Van Lieshout et al. 2003). In conditions where MCA Vmean was reduced or increased by 30 Torr lower body negative pressure (LBNP) (Zhang et al. 1998b) and head-up tilt (Jorgensen et al. 1993), or mild and moderate exercise (Brys et al. 2003; Ogoh et al. 2005b), respectively, central blood volume and cardiac output were also decreased or increased, respectively. These changes in MCA Vmean occurred without changes in arterial carbon dioxide tension (Pa,CO2) or cerebral autoregulation. Van Lieshout et al. (2001) confirmed the relationship between , MCA Vmean and central blood volume when they demonstrated that the MCA Vmean was decreased in association with the reduction in that occurs when changing postural positions from supine to standing. This reduction in MCA Vmean was present even though mean arterial pressure (MAP) was increased.
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During exercise the competition for perfusion between active and inactive skeletal muscle, brain and other organ beds is regulated by the sympathetic nervous system (Rowell, 1993). For example, during progressive changes in exercise workloads, from rest to maximal exercise, progressive sympathoexcitation occurs (Hartley et al. 1972) resulting in an increasing proportional distribution of the to the active skeletal muscles (Rowell, 1993). It was found that when healthy subjects performed one-legged exercise MCA Vmean was increased by 20% and was maintained when they performed two-legged exercise (Hellstrom et al. 1997). However, in patients with heart failure, one-legged exercise did not increase MCA Vmean and two-legged exercise resulted in a decreased MCA Vmean (Hellstrom et al. 1997). When the increase in was reduced by 1-blockade (Ide et al. 1998, 2000; Dalsgaard et al. 2004), or atrial fibrillation (Ide et al. 1999), the increase in MCA Vmean during bicycling exercise was reduced. These findings further indicate that is an important factor in establishing the MCA Vmean to be regulated by cerebral autoregulation.
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We hypothesized that the MCA Vmean that is regulated by cerebral autoregulation is directly related to at rest and during exercise. We further hypothesized that the relationship established between MCA Vmean and at rest is reduced during exercise. To test these hypotheses, we manipulated at rest and during exercise by using LBNP of 8 and 16 Torr and infusions of albumin to decrease and increase central blood volume, respectively.
Methods
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Seven men (mean ±S.E.M.: age 26 ± 1 years; height 180 ± 3 cm; weight 89 ± 6 kg) were recruited for participation in the present study. All subjects were free of any known cardiovascular and pulmonary disorders and were not using prescribed or over the counter medications. Each subject provided written informed consent, which conformed to the Declaration of Helsinki and was approved by The University of North Texas Health Science Center Institutional Review Board. Subjects were requested to abstain from caffeinated beverages for 12 h and strenuous physical activity and alcohol intake for at least a day prior to their study. Before any experiments were performed each subject visited the laboratory for familiarization with the measurement techniques and the experimental protocol. All experiments were conducted at a constant room temperature (25.1 ± 0.3°C).
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Maximal exercise
On experimental day 1, each subject performed a maximal incremental load test to volitional fatigue in a 70 deg back-supported semirecumbent position by cycling on an electronically braked ergometer placed within the LBNP box for determining the experimental workload. This test served as the initial screening test and provided evidence of suitability for the study. Before the exercise test, the subject's resting blood pressure and 12-lead electrocardiogram were recorded in the seated and standing positions. The cycle workload was set at 50 W for initial 2 min and was increased 30 W each minute to exhaustion. Criteria for attainment of maximal oxygen uptake included the inability to maintain a cycling cadence of 60 r.p.m. accompanied by a respiratory quotient which exceeds 1.10 or a documented plateau of . Subjects respired through a mouthpiece attached to a low-resistance turbine volume transducer (model VMM E-2 A, Sensor Medics, Anaheim, CA, USA) and mass spectrometry (model MGA1100B, Perkin-Elmer, St Louis, MO, USA) for determination of . The experimental protocol was scheduled at least 3 days after the day of the maximal exercise test.
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Experimental protocol
After arrival at the laboratory and, after instrumentation, the subjects were positioned in the 70 deg back-supported semirecumbent position with the lower body in the LBNP box. In addition, a mercury-in-silastic strain gauge was placed over the largest part of the subject's forearm for the measurement of forearm blood flow (FBF) using venous occlusion plethysmography. Occlusion cuffs were placed at the subject's wrist and upper arm. The subject was sealed in the LBNP box at the level of the iliac crest with a flexible rubber dam. The electrically braked cycle ergometer placed in the LBNP box was adjusted to each subject's leg length. During exercise full extension of the leg was more than 20 deg above the horizontal plane of hip.
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At rest two pressures, 8 Torr (LB8) and 16 Torr (LB16), of LBNP were applied to reduce central blood volume. After data collection at rest, the subjects performed steady-state cycling at 50% (108 ± 23 W) with LBNP applied at 8 and 16 Torr. The same measurements taken at rest and at each pressure of LBNP were obtained during the exercise. Following completion of the exercise protocols with LBNP the subjects rested for 30–40 min to enable haemodynamic recovery from the preceding exercise trial. Subsequently, two discrete infusions of 25% human serum albumin solution were administered via the antecubital vein catheter to raise central venous pressure (CVP) 2.0 ± 0.7 and 2.5 ± 0.4 mmHg, respectively, from the resting value. Before the first infusion protocol, the infusion volume of 25% albumin was 1.15 ± 0.04 ml kg–1 (INF1) and the additional volume was 1.62 ± 0.07 ml kg–1 for second infusion protocol (INF2). After data collection at rest, the subjects performed steady-state leg cycling at 50%. During the resting and exercise experiments, heart rate (HR), arterial blood pressure (ABP) and MCA Vmean were recorded continuously. At each stage of LBNP, or albumin infusion, FBF and were measured.
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Measurements
The HR was monitored with a standard lead II electrocardiogram (Model 78342 A, Hewlett Packard). The ABP was measured by a cannula (1.1 mm i.d., 20 gauge) which was placed in the brachial artery for measurement of the ABP. Another cannula (17 gauge, 65-cm radio-opaque catheter) was introduced into the superior vena cava via the basilica vein for measurement of CVP. Each pressure was recorded with a disposable pressure transducer (Maximum Medical, Athens, TX, USA) positioned at the level of the right atrium in the midaxillary line. In addition, the catheters had extension tubes connected to a slow drip of heparinized normal saline (2 U ml–1). The MCA Vmean was obtained by transcranial Doppler ultrasonography (Multidop X, DWL, Sipplingen, Germany) with a 2-MHz probe placed over the temporal window and fixed with an adjustable headband and adhesive ultrasonic gel (Tensive, Parker Laboratories, Orange, NJ, USA). A venous catheter (1.2 mm i.d., 18 gauge) was inserted into the median antecubital vein for central blood volume expansion by infusing 25% human serum albumin solution. was estimated by an aceytlene re-breathing technique (Triebwasser et al. 1977). The FBF was determined using venous occlusion plethysmography employing a dual loop mercury-in-silastic strain gauge to determine changes in limb volume (Whitney, 1953). The venous occlusion cuff pressure was set at 40 mmHg, and an arterial occlusion cuff (inflated to 250 mmHg) was used to prevent arterial inflow into the hand during each blood flow measurement. Arterial blood samples were obtained at each condition and stored in ice–water until analysed for Pa,CO2 (Instrumentation Laboratory model no. 1735, Lexington, MA, USA). Cerebral vascular resistance index (CVRi) was expressed as (MAP/MCA Vmean).
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Transfer function analysis
Analog signals of ABP and the spectral envelope of MCA Vmean were sampled at 200 Hz and digitized at 12 bits for off-line analysis. Beat-to-beat MAP and MCA Vmean were obtained by integrating analog signals within each cardiac cycle and linearly interpolated and re-sampled at 2 Hz for spectral analysis (Zhang et al. 1998a). For transfer function analysis, the cross-spectrum between change in MAP and MCA Vmean was estimated and then divided by the autospectrum of MAP. At rest and during exercise transfer function gain and phase were calculated (Zhang et al. 1998a,b; Ogoh et al. 2005a,b).
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In addtion, the coherence function was calculated to estimate the fraction of output power (MCA Vmean) that can be linearly related to the input power (MAP) at each frequency. Similarly to a correlation coefficient, it varies between 0 and 1. For this calculation, the 3 min steady-state MAP and MCA Vmean were used at each condition.
Spectral power of MAP, MCA Vmean, mean value of transfer function gain, phase, and coherence function were calculated in the very low (VLF, 0.02–0.07 Hz), low (LF, 0.07–0.20 Hz), and high (HF, 0.20–0.30 Hz) frequency ranges to reflect different patterns of the dynamic pressure–flow relationship (Zhang et al. 1998a, 2002). The ABP fluctuations in the HF range, including those induced by the respiratory frequency, are transferred to MCA Vmean, whereas ABP fluctuations in the LF range are independent of the respiratory frequency and the LF transfer analysis reflects cerebral autoregulation mechanisms (Diehl et al. 1995; Zhang et al. 1998a). Furthermore, the VLF range of both the flow and the pressure variabilities appears to reflect multiple physiological mechanisms that confound interpretation. Thus, we used the LF range for the spectral analysis to identify the dynamic cerebral autoregulation during exercise.
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Statistics
Statistical comparisons of physiological variables were made utilizing a repeated-measures two-way analysis of variance (ANOVA) with a 5 x 2 design (condition x exercise). A Student-Newman-Keuls test was employed post hoc when interactions were significant. The relationship between MCA Vmean or FBF and was described using simple linear regression analysis. These relationships (slope of linear regression) at rest and exercise were compared by using Student's paired t test. Statistical significance was set at P < 0.05 and results are presented as means ±S.E.M. Analyses were conducted using SigmaStat (Systat Software Inc., Point Richmond, CA, USA).
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Results
This study involved two protocols designed to alter by increasing and decreasing central blood volume. One protocol used LBNP to decrease while the second protocol used human serum albumin infusions to increase . In response to LB8 and LB16, the reduction in CVP was 1.5 ± 0.3 and 2.8 ± 0.5 mmHg at rest, and 0.9 ± 0.4 and 2.9 ± 0.4 mmHg during exercise, respectively. In response to the first and second albumin infusions, the increase in CVP was 2.0 ± 0.7 and 2.5 ± 0.4 mmHg at rest, and 3.2 ± 1.0 and 4.9 ± 1.0 mmHg during exercise, respectively.
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The haemodynamic changes that occurred at rest and during exercise during the experimental manipulation of central blood volume are presented in Table 1. The HR tended to increase during LBNP at rest (P > 0.05) and was increased during LBNP and exercise. The was reduced during LBNP as a result of a larger reduction in stroke volume despite the increase in HR. The HR gradually increased during the infusions of albumin at rest and during exercise (P < 0.05) resulting in increases in because both HR and stroke volume increased. Thus, the changes in were larger during the infusion of albumin than those that occurred during LBNP. The changes in central blood volume produced by LB8, LB16 and infusions 1 and 2 did not affect MAP at rest or during exercise. The Pa,CO2 remained constant throughout all experimental conditions. However, MCA Vmean tended to decrease during LBNP and increase during the infusions of albumin, both at rest and during exercise.
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The response of the FBF and MCA Vmean to the changes in are summarized in Figs 1 and 2. Although the FBF increased from rest to exercise by 30.4 ± 4.9% (P < 0.001), the FBF response to the changes in was the same during exercise as that observed at rest. The linear relationships between FBF and were statistically significant at rest and during exercise (Fig. 1). In addition, there was no difference between rest and exercise in the average slope of the linear regression between percentage FBF (where control FBF at rest was equal to 100%) and (P= 0.205) (Fig. 2). In contrast, even though the increases in the MCA Vmean from rest to exercise were not statistically significant (Table 1), the linear relationships between and MCA Vmean were statistically significant at rest (P < 0.001) and during exercise (P= 0.035). However, the MCA Vmean response to the changes in was greater at rest compared with that during exercise. Thus, there was a reduction in the average slope of the linear regression of the relationship between percentage MCA Vmean and (P= 0.035) from rest to exercise. In addition, the percentage change from rest MCA Vmean to the absolute changes in was lower than the percentage changes in FBF to the absolute changes in at rest (13.3 ± 2.4 versus 4.7 ± 1.1% min l–1) and during exercise (10.4 ± 1.8 versus 2.1 ± 0.7% min l–1).
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Symbols denote actual group data for all subjects (means ±S.E.M.). The lines represent the linear regressions calculated from the group average data. The significant relationship between (in l min–1) and percentage FBF (where control FBF at rest was equal to 100%) was linear; Rest, FBF (%) = 11.9 x+ 19.4, r= 0.93, P= 0.023; Exercise, FBF (%) = 10.0 x– 37.3, r= 0.98, P= 0.003. The significant relationship between (in l min–1) and MCA Vmean (in cm s–1) was linear; Rest, MCA Vmean= 3.4 x+ 44.0, r= 0.99, P < 0.001; Exercise, MCA Vmean= 1.2 x+ 52.9, r= 0.90, P= 0.035.
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Bars represent the average slope of the linear regression line between percentage FBF and (A) and between percentage MCA Vmean and (B) for all subjects (means ±S.E.M.) at rest and during exercise.
Transfer function analysis of the dynamic relationship between beat-to-beat changes in MCA Vmean and MAP was used to assess cerebral autoregulation across changes in (Table 2 and Fig. 3). Power spectra of MCA Vmean and MAP were not altered at rest and during exercise by the LBNP or the infusion of albumin. The phase and gain between MCA Vmean and MAP in the LF range were not altered across changes in and central blood volume during rest or exercise indicating that the cerebral autoregulation was maintained. The LF coherence between MCA Vmean and MAP was above 0.5 both at rest and during exercise.
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Values are means ±S.E.M.Different from rest.
Discussion
The findings of the present investigation provide new information regarding the influence of cardiac output on middle cerebral artery mean blood velocity and its autoregulation at rest and during dynamic exercise, independent of Pa,CO2. Specifically, the relationship between the changes in MCA Vmean and the changes in at rest and during dynamic exercise were linear and highly significant; however, during exercise the slope of the relationship was reduced by 55% from that at rest (Fig. 2). This exercise-induced decrease in the responsiveness of MCA Vmean to changes in occurred without changes in Pa,CO2 or cerebral autoregulation. These data suggest that the sympathoexcitation associated with exercise may have directly affected MCA Vmean by changing CVRi, or indirectly by enabling a redistribution of between the systemic circulation and the cerebral circulation.
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Patients with chronic heart failure (Hellstrom et al. 1997) and atrial fibrillation (Ide et al. 1999) have an attenuated ability to elevate cerebral perfusion during exercise because of their impaired ability to increase . 1-Blockade-induced reductions in in healthy subjects resulted in a reduction of the increase in MCA Vmean that occurred from rest to dynamic exercise despite the increase in MAP (Ide et al. 1998, 2000; Dalsgaard et al. 2004). These findings indicate that a reduced ability to increase during exercise limits MCA Vmean. Cerebral autoregulation is an important mechanism in maintaining a constant cerebral blood flow within an arterial pressure range of 60–150 mmHg (Paulson et al. 1990), when Pa,CO2 remains constant (Ide & Secher, 2000; LeMarbre et al. 2003; Ainslie et al. 2005). Because the data of the present investigation identify that moderate exercise, LBNP, infusions of human serum albumin and their combination did not alter cerebral autoregulation or Pa,CO2 (Table 1 and Fig. 3), the MCA Vmean observed during this investigation was directly related to the absolute value of . Collectively, these findings suggest that influences the MCA Vmean regulated by cerebral autoregulation.
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MCA Vmean and central blood flow remained constant, or were slightly increased from rest to exercise despite large increases in and MAP (Madsen et al. 1993). In the present study exercise did not increase MCA Vmean(+5.9 ± 4.0%), but interestingly it increased forearm blood flow (+30.4 ± 4.9%) despite the presence of a sympathetically mediated vasoconstriction. More importantly the calculated CVRi increased from rest to exercise (Table 1). These data suggest that cerebral vasoconstriction was a result of the exercise induced sympathoexcitation (Ide et al. 2000) and the change in the vascular resistance was greater in the brain than in the forearm at the same perfusion pressure. This greater increase in vascular resistance of the brain than in the peripheral vasculature may be a mechanism of protection for the brain against the large increases in and MAP that occur during moderate and heavy exercise.
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Sympathetic nerves richly innervate the brain's vasculature; however, it is thought that they have little influence on cerebral vasculature function (Ide et al. 2000). For example, in cats, electrical stimulation of the distal cut end of the petrosal nerve had no effect on total cerebral blood flow (Busija & Heistad, 1981). In rats, sensory nerve stimulation did not significantly affect cerebral blood flow, even after sympathetic denervation (Morita-Tsuzuki et al. 1993). However, Pearce & D'Alecy (1980) demonstrated that in dogs the increase in CVRi induced by haemorrhage is eliminated by -adrenergic blockade. They further demonstrated that sympathetic vasoconstriction contributed approximately 5% to prehaemorrhage CVRi and suggested that the cerebrovascular response to haemorrhage was a balance between autoregulatory vasodilatation and sympathetic vasoconstriction. Moreover, denervation of arterial baroreceptors of rats blunted the cerebral vasodilatation associated with a breakdown of autoregulation (Talman et al. 1994). In humans, handgrip exercise-induced increases in sympathetic activity was associated with increases in CVRi during isocapnia (Ainslie et al. 2005) and dynamic cerebral autoregulation was found to be attenuated by ganglion blockade (Zhang et al. 2002). These findings suggest that autonomic neural control of the cerebral circulation plays a significant role in the beat-to-beat regulation of cerebral blood flow. However, it is well known that CO2 is the most powerful regulator of vascular tone in the brain and it has been reported that baroreflex-induced sympathetic activation had no influence on the cerebral vascular response to CO2 (LeMarbre et al. 2003). Collectively, these findings suggest that the importance of the sympathetically mediated vasoconstriction in the cerebral circulation may be to protect the blood–brain barrier when limits of autoregulation are exceeded.
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The changes in MCA Vmean that occurred in response to the central blood volume-induced changes in were decreased from rest to exercise (P= 0.035, Figs 1 and 2). One possible explanation is the presence of a decrease in the distribution of to the brain during exercise. For example, when exercise increases the cardiac output 4–5 times from rest, to enable blood flow to the active muscle to be increased, the distribution of to the brain was decreased from rest (14%) to exercise (3%) (Rowell, 1993). Thus, the changes in MCA Vmean to changes in during exercise would be less because of the reduced proportion of total being directed to the brain. This reduction in proportion of distributed to the brain would be dependent on the exercise workload. Hence, the exercise-induced decreases in changes of MCA Vmean associated with the changes in may be explained by the reduced proportion of distributed to the brain (Fig. 2).
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As the changes in were associated with the experimentally induced changes in central blood volume, changes in sympathetic activity resulting from the loading and unloading of the cardiopulmonary baroreceptors appear to influence the cerebral vasculature in the presence of a constant MAP. However, if the cardiopulmonary baroreflex-induced sympathetic vasoconstriction of the periphery is a mechanism for maintaining arterial pressure and cerebral perfusion and the same vasoconstriction were to occur at the same magnitude in the brain, cerebral blood flow would be compromised (LeMarbre et al. 2003). A similar vasoconstriction of the brain's vasculature may not assist in defending blood pressure during decreases in central blood volume because the cerebral circulation is located above the level of the heart and the brain has a relatively small vascular bed. Moreover, sympathetic activation elicited by unloading the cardiopulmonary baroreceptors had no influence on the cerebralvascular response to CO2 (LeMarbre et al. 2003). Thus, the different responses between MCA Vmean and FBF may be evidence for the existence of a different cardiopulmonary baroreflex control of the brain vasculature compared to that of others (Johnson et al. 1974; Victor & Leimbach, 1987).
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The contribution of changes in to the carotid baroreflex control of blood pressure during exercise was found to be minimal (Collins et al. 2001; Ogoh et al. 2003) and supported previous work identifying differences in the contribution of carotid-cardiac and carotid-vasomotor arms of the carotid baroreflex to blood pressure regulation during changes in posture (Ogoh et al. 2002). In dogs the reflex response to carotid baroreceptor stimulation was peripheral vasoconstriction and did the alterations in were not identified as being part of the reflex response (Collins et al. 2001). In addition, in humans a carotid-vasomotor reflex-mediated change in total vascular conductance was the major response to carotid baroreceptor stimulation during exercise (Ogoh et al. 2003) and orthostasis (Ogoh et al. 2002). However, the findings of the present study identified that changes in affect the MCA Vmean at rest and during exercise. Thus, carotid-cardiac baroreflex function may prove to be more important to the regulation of MCA Vmean than its control of blood pressure. Interestingly, the changes in MCA Vmean associated with changes in were reduced from rest to exercise and may be related to the reduction in carotid-cardiac baroreflex sensitivity associated with relocation of the operating point of the cardiac arterial baroreflex that occurs during exercise (Ogoh et al. 2005c). These findings suggest that arterial baroreflex regulation of blood pressure via reflex regulation of the systemic vasculature becomes more involved in maintaining cerebral perfusion during exercise.
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Abstract
We examined the relationship between changes in cardiac output and middle cerebral artery mean blood velocity (MCA Vmean) in seven healthy volunteer men at rest and during 50% maximal oxygen uptake steady-state submaximal cycling exercise. Reductions in were accomplished using lower body negative pressure (LBNP), while increases in were accomplished using infusions of 25% human serum albumin. Heart rate (HR), arterial blood pressure and MCA Vmean were continuously recorded. At each stage of LBNP and albumin infusion was measured using an acetylene rebreathing technique. Arterial blood samples were analysed for partial pressure of carbon dioxide tension (Pa,CO2. During exercise HR and were increased above rest (P < 0.001), while neither MCA Vmean nor Pa,CO2 was altered (P > 0.05). The MCA Vmean and were linearly related at rest (P < 0.001) and during exercise (P= 0.035). The slope of the regression relationship between MCA Vmean and at rest was greater (P= 0.035) than during exercise. In addition, the phase and gain between MCA Vmean and mean arterial pressure in the low frequency range were not altered from rest to exercise indicating that the cerebral autoregulation was maintained. These data suggest that the associated with the changes in central blood volume influence the MCA Vmean at rest and during exercise and its regulation is independent of cerebral autoregulation. It appears that the exercise induced sympathoexcitation and the change in the distribution of between the cerebral and the systemic circulation modifies the relationship between MCA Vmean and .
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Introduction
Cerebral autoregulation maintains cerebral blood flow constant over a range of arterial pressures from 60 to 150 mmHg (Paulson et al. 1990). In humans, measurements of middle cerebral artery mean blood velocity (MCA Vmean) provide an index of the cerebral blood flow (Ide & Secher, 2000; Van Lieshout et al. 2003). In conditions where MCA Vmean was reduced or increased by 30 Torr lower body negative pressure (LBNP) (Zhang et al. 1998b) and head-up tilt (Jorgensen et al. 1993), or mild and moderate exercise (Brys et al. 2003; Ogoh et al. 2005b), respectively, central blood volume and cardiac output were also decreased or increased, respectively. These changes in MCA Vmean occurred without changes in arterial carbon dioxide tension (Pa,CO2) or cerebral autoregulation. Van Lieshout et al. (2001) confirmed the relationship between , MCA Vmean and central blood volume when they demonstrated that the MCA Vmean was decreased in association with the reduction in that occurs when changing postural positions from supine to standing. This reduction in MCA Vmean was present even though mean arterial pressure (MAP) was increased.
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During exercise the competition for perfusion between active and inactive skeletal muscle, brain and other organ beds is regulated by the sympathetic nervous system (Rowell, 1993). For example, during progressive changes in exercise workloads, from rest to maximal exercise, progressive sympathoexcitation occurs (Hartley et al. 1972) resulting in an increasing proportional distribution of the to the active skeletal muscles (Rowell, 1993). It was found that when healthy subjects performed one-legged exercise MCA Vmean was increased by 20% and was maintained when they performed two-legged exercise (Hellstrom et al. 1997). However, in patients with heart failure, one-legged exercise did not increase MCA Vmean and two-legged exercise resulted in a decreased MCA Vmean (Hellstrom et al. 1997). When the increase in was reduced by 1-blockade (Ide et al. 1998, 2000; Dalsgaard et al. 2004), or atrial fibrillation (Ide et al. 1999), the increase in MCA Vmean during bicycling exercise was reduced. These findings further indicate that is an important factor in establishing the MCA Vmean to be regulated by cerebral autoregulation.
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We hypothesized that the MCA Vmean that is regulated by cerebral autoregulation is directly related to at rest and during exercise. We further hypothesized that the relationship established between MCA Vmean and at rest is reduced during exercise. To test these hypotheses, we manipulated at rest and during exercise by using LBNP of 8 and 16 Torr and infusions of albumin to decrease and increase central blood volume, respectively.
Methods
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Seven men (mean ±S.E.M.: age 26 ± 1 years; height 180 ± 3 cm; weight 89 ± 6 kg) were recruited for participation in the present study. All subjects were free of any known cardiovascular and pulmonary disorders and were not using prescribed or over the counter medications. Each subject provided written informed consent, which conformed to the Declaration of Helsinki and was approved by The University of North Texas Health Science Center Institutional Review Board. Subjects were requested to abstain from caffeinated beverages for 12 h and strenuous physical activity and alcohol intake for at least a day prior to their study. Before any experiments were performed each subject visited the laboratory for familiarization with the measurement techniques and the experimental protocol. All experiments were conducted at a constant room temperature (25.1 ± 0.3°C).
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Maximal exercise
On experimental day 1, each subject performed a maximal incremental load test to volitional fatigue in a 70 deg back-supported semirecumbent position by cycling on an electronically braked ergometer placed within the LBNP box for determining the experimental workload. This test served as the initial screening test and provided evidence of suitability for the study. Before the exercise test, the subject's resting blood pressure and 12-lead electrocardiogram were recorded in the seated and standing positions. The cycle workload was set at 50 W for initial 2 min and was increased 30 W each minute to exhaustion. Criteria for attainment of maximal oxygen uptake included the inability to maintain a cycling cadence of 60 r.p.m. accompanied by a respiratory quotient which exceeds 1.10 or a documented plateau of . Subjects respired through a mouthpiece attached to a low-resistance turbine volume transducer (model VMM E-2 A, Sensor Medics, Anaheim, CA, USA) and mass spectrometry (model MGA1100B, Perkin-Elmer, St Louis, MO, USA) for determination of . The experimental protocol was scheduled at least 3 days after the day of the maximal exercise test.
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Experimental protocol
After arrival at the laboratory and, after instrumentation, the subjects were positioned in the 70 deg back-supported semirecumbent position with the lower body in the LBNP box. In addition, a mercury-in-silastic strain gauge was placed over the largest part of the subject's forearm for the measurement of forearm blood flow (FBF) using venous occlusion plethysmography. Occlusion cuffs were placed at the subject's wrist and upper arm. The subject was sealed in the LBNP box at the level of the iliac crest with a flexible rubber dam. The electrically braked cycle ergometer placed in the LBNP box was adjusted to each subject's leg length. During exercise full extension of the leg was more than 20 deg above the horizontal plane of hip.
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At rest two pressures, 8 Torr (LB8) and 16 Torr (LB16), of LBNP were applied to reduce central blood volume. After data collection at rest, the subjects performed steady-state cycling at 50% (108 ± 23 W) with LBNP applied at 8 and 16 Torr. The same measurements taken at rest and at each pressure of LBNP were obtained during the exercise. Following completion of the exercise protocols with LBNP the subjects rested for 30–40 min to enable haemodynamic recovery from the preceding exercise trial. Subsequently, two discrete infusions of 25% human serum albumin solution were administered via the antecubital vein catheter to raise central venous pressure (CVP) 2.0 ± 0.7 and 2.5 ± 0.4 mmHg, respectively, from the resting value. Before the first infusion protocol, the infusion volume of 25% albumin was 1.15 ± 0.04 ml kg–1 (INF1) and the additional volume was 1.62 ± 0.07 ml kg–1 for second infusion protocol (INF2). After data collection at rest, the subjects performed steady-state leg cycling at 50%. During the resting and exercise experiments, heart rate (HR), arterial blood pressure (ABP) and MCA Vmean were recorded continuously. At each stage of LBNP, or albumin infusion, FBF and were measured.
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Measurements
The HR was monitored with a standard lead II electrocardiogram (Model 78342 A, Hewlett Packard). The ABP was measured by a cannula (1.1 mm i.d., 20 gauge) which was placed in the brachial artery for measurement of the ABP. Another cannula (17 gauge, 65-cm radio-opaque catheter) was introduced into the superior vena cava via the basilica vein for measurement of CVP. Each pressure was recorded with a disposable pressure transducer (Maximum Medical, Athens, TX, USA) positioned at the level of the right atrium in the midaxillary line. In addition, the catheters had extension tubes connected to a slow drip of heparinized normal saline (2 U ml–1). The MCA Vmean was obtained by transcranial Doppler ultrasonography (Multidop X, DWL, Sipplingen, Germany) with a 2-MHz probe placed over the temporal window and fixed with an adjustable headband and adhesive ultrasonic gel (Tensive, Parker Laboratories, Orange, NJ, USA). A venous catheter (1.2 mm i.d., 18 gauge) was inserted into the median antecubital vein for central blood volume expansion by infusing 25% human serum albumin solution. was estimated by an aceytlene re-breathing technique (Triebwasser et al. 1977). The FBF was determined using venous occlusion plethysmography employing a dual loop mercury-in-silastic strain gauge to determine changes in limb volume (Whitney, 1953). The venous occlusion cuff pressure was set at 40 mmHg, and an arterial occlusion cuff (inflated to 250 mmHg) was used to prevent arterial inflow into the hand during each blood flow measurement. Arterial blood samples were obtained at each condition and stored in ice–water until analysed for Pa,CO2 (Instrumentation Laboratory model no. 1735, Lexington, MA, USA). Cerebral vascular resistance index (CVRi) was expressed as (MAP/MCA Vmean).
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Transfer function analysis
Analog signals of ABP and the spectral envelope of MCA Vmean were sampled at 200 Hz and digitized at 12 bits for off-line analysis. Beat-to-beat MAP and MCA Vmean were obtained by integrating analog signals within each cardiac cycle and linearly interpolated and re-sampled at 2 Hz for spectral analysis (Zhang et al. 1998a). For transfer function analysis, the cross-spectrum between change in MAP and MCA Vmean was estimated and then divided by the autospectrum of MAP. At rest and during exercise transfer function gain and phase were calculated (Zhang et al. 1998a,b; Ogoh et al. 2005a,b).
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In addtion, the coherence function was calculated to estimate the fraction of output power (MCA Vmean) that can be linearly related to the input power (MAP) at each frequency. Similarly to a correlation coefficient, it varies between 0 and 1. For this calculation, the 3 min steady-state MAP and MCA Vmean were used at each condition.
Spectral power of MAP, MCA Vmean, mean value of transfer function gain, phase, and coherence function were calculated in the very low (VLF, 0.02–0.07 Hz), low (LF, 0.07–0.20 Hz), and high (HF, 0.20–0.30 Hz) frequency ranges to reflect different patterns of the dynamic pressure–flow relationship (Zhang et al. 1998a, 2002). The ABP fluctuations in the HF range, including those induced by the respiratory frequency, are transferred to MCA Vmean, whereas ABP fluctuations in the LF range are independent of the respiratory frequency and the LF transfer analysis reflects cerebral autoregulation mechanisms (Diehl et al. 1995; Zhang et al. 1998a). Furthermore, the VLF range of both the flow and the pressure variabilities appears to reflect multiple physiological mechanisms that confound interpretation. Thus, we used the LF range for the spectral analysis to identify the dynamic cerebral autoregulation during exercise.
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Statistics
Statistical comparisons of physiological variables were made utilizing a repeated-measures two-way analysis of variance (ANOVA) with a 5 x 2 design (condition x exercise). A Student-Newman-Keuls test was employed post hoc when interactions were significant. The relationship between MCA Vmean or FBF and was described using simple linear regression analysis. These relationships (slope of linear regression) at rest and exercise were compared by using Student's paired t test. Statistical significance was set at P < 0.05 and results are presented as means ±S.E.M. Analyses were conducted using SigmaStat (Systat Software Inc., Point Richmond, CA, USA).
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Results
This study involved two protocols designed to alter by increasing and decreasing central blood volume. One protocol used LBNP to decrease while the second protocol used human serum albumin infusions to increase . In response to LB8 and LB16, the reduction in CVP was 1.5 ± 0.3 and 2.8 ± 0.5 mmHg at rest, and 0.9 ± 0.4 and 2.9 ± 0.4 mmHg during exercise, respectively. In response to the first and second albumin infusions, the increase in CVP was 2.0 ± 0.7 and 2.5 ± 0.4 mmHg at rest, and 3.2 ± 1.0 and 4.9 ± 1.0 mmHg during exercise, respectively.
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The haemodynamic changes that occurred at rest and during exercise during the experimental manipulation of central blood volume are presented in Table 1. The HR tended to increase during LBNP at rest (P > 0.05) and was increased during LBNP and exercise. The was reduced during LBNP as a result of a larger reduction in stroke volume despite the increase in HR. The HR gradually increased during the infusions of albumin at rest and during exercise (P < 0.05) resulting in increases in because both HR and stroke volume increased. Thus, the changes in were larger during the infusion of albumin than those that occurred during LBNP. The changes in central blood volume produced by LB8, LB16 and infusions 1 and 2 did not affect MAP at rest or during exercise. The Pa,CO2 remained constant throughout all experimental conditions. However, MCA Vmean tended to decrease during LBNP and increase during the infusions of albumin, both at rest and during exercise.
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The response of the FBF and MCA Vmean to the changes in are summarized in Figs 1 and 2. Although the FBF increased from rest to exercise by 30.4 ± 4.9% (P < 0.001), the FBF response to the changes in was the same during exercise as that observed at rest. The linear relationships between FBF and were statistically significant at rest and during exercise (Fig. 1). In addition, there was no difference between rest and exercise in the average slope of the linear regression between percentage FBF (where control FBF at rest was equal to 100%) and (P= 0.205) (Fig. 2). In contrast, even though the increases in the MCA Vmean from rest to exercise were not statistically significant (Table 1), the linear relationships between and MCA Vmean were statistically significant at rest (P < 0.001) and during exercise (P= 0.035). However, the MCA Vmean response to the changes in was greater at rest compared with that during exercise. Thus, there was a reduction in the average slope of the linear regression of the relationship between percentage MCA Vmean and (P= 0.035) from rest to exercise. In addition, the percentage change from rest MCA Vmean to the absolute changes in was lower than the percentage changes in FBF to the absolute changes in at rest (13.3 ± 2.4 versus 4.7 ± 1.1% min l–1) and during exercise (10.4 ± 1.8 versus 2.1 ± 0.7% min l–1).
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Symbols denote actual group data for all subjects (means ±S.E.M.). The lines represent the linear regressions calculated from the group average data. The significant relationship between (in l min–1) and percentage FBF (where control FBF at rest was equal to 100%) was linear; Rest, FBF (%) = 11.9 x+ 19.4, r= 0.93, P= 0.023; Exercise, FBF (%) = 10.0 x– 37.3, r= 0.98, P= 0.003. The significant relationship between (in l min–1) and MCA Vmean (in cm s–1) was linear; Rest, MCA Vmean= 3.4 x+ 44.0, r= 0.99, P < 0.001; Exercise, MCA Vmean= 1.2 x+ 52.9, r= 0.90, P= 0.035.
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Bars represent the average slope of the linear regression line between percentage FBF and (A) and between percentage MCA Vmean and (B) for all subjects (means ±S.E.M.) at rest and during exercise.
Transfer function analysis of the dynamic relationship between beat-to-beat changes in MCA Vmean and MAP was used to assess cerebral autoregulation across changes in (Table 2 and Fig. 3). Power spectra of MCA Vmean and MAP were not altered at rest and during exercise by the LBNP or the infusion of albumin. The phase and gain between MCA Vmean and MAP in the LF range were not altered across changes in and central blood volume during rest or exercise indicating that the cerebral autoregulation was maintained. The LF coherence between MCA Vmean and MAP was above 0.5 both at rest and during exercise.
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Values are means ±S.E.M.Different from rest.
Discussion
The findings of the present investigation provide new information regarding the influence of cardiac output on middle cerebral artery mean blood velocity and its autoregulation at rest and during dynamic exercise, independent of Pa,CO2. Specifically, the relationship between the changes in MCA Vmean and the changes in at rest and during dynamic exercise were linear and highly significant; however, during exercise the slope of the relationship was reduced by 55% from that at rest (Fig. 2). This exercise-induced decrease in the responsiveness of MCA Vmean to changes in occurred without changes in Pa,CO2 or cerebral autoregulation. These data suggest that the sympathoexcitation associated with exercise may have directly affected MCA Vmean by changing CVRi, or indirectly by enabling a redistribution of between the systemic circulation and the cerebral circulation.
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Patients with chronic heart failure (Hellstrom et al. 1997) and atrial fibrillation (Ide et al. 1999) have an attenuated ability to elevate cerebral perfusion during exercise because of their impaired ability to increase . 1-Blockade-induced reductions in in healthy subjects resulted in a reduction of the increase in MCA Vmean that occurred from rest to dynamic exercise despite the increase in MAP (Ide et al. 1998, 2000; Dalsgaard et al. 2004). These findings indicate that a reduced ability to increase during exercise limits MCA Vmean. Cerebral autoregulation is an important mechanism in maintaining a constant cerebral blood flow within an arterial pressure range of 60–150 mmHg (Paulson et al. 1990), when Pa,CO2 remains constant (Ide & Secher, 2000; LeMarbre et al. 2003; Ainslie et al. 2005). Because the data of the present investigation identify that moderate exercise, LBNP, infusions of human serum albumin and their combination did not alter cerebral autoregulation or Pa,CO2 (Table 1 and Fig. 3), the MCA Vmean observed during this investigation was directly related to the absolute value of . Collectively, these findings suggest that influences the MCA Vmean regulated by cerebral autoregulation.
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MCA Vmean and central blood flow remained constant, or were slightly increased from rest to exercise despite large increases in and MAP (Madsen et al. 1993). In the present study exercise did not increase MCA Vmean(+5.9 ± 4.0%), but interestingly it increased forearm blood flow (+30.4 ± 4.9%) despite the presence of a sympathetically mediated vasoconstriction. More importantly the calculated CVRi increased from rest to exercise (Table 1). These data suggest that cerebral vasoconstriction was a result of the exercise induced sympathoexcitation (Ide et al. 2000) and the change in the vascular resistance was greater in the brain than in the forearm at the same perfusion pressure. This greater increase in vascular resistance of the brain than in the peripheral vasculature may be a mechanism of protection for the brain against the large increases in and MAP that occur during moderate and heavy exercise.
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Sympathetic nerves richly innervate the brain's vasculature; however, it is thought that they have little influence on cerebral vasculature function (Ide et al. 2000). For example, in cats, electrical stimulation of the distal cut end of the petrosal nerve had no effect on total cerebral blood flow (Busija & Heistad, 1981). In rats, sensory nerve stimulation did not significantly affect cerebral blood flow, even after sympathetic denervation (Morita-Tsuzuki et al. 1993). However, Pearce & D'Alecy (1980) demonstrated that in dogs the increase in CVRi induced by haemorrhage is eliminated by -adrenergic blockade. They further demonstrated that sympathetic vasoconstriction contributed approximately 5% to prehaemorrhage CVRi and suggested that the cerebrovascular response to haemorrhage was a balance between autoregulatory vasodilatation and sympathetic vasoconstriction. Moreover, denervation of arterial baroreceptors of rats blunted the cerebral vasodilatation associated with a breakdown of autoregulation (Talman et al. 1994). In humans, handgrip exercise-induced increases in sympathetic activity was associated with increases in CVRi during isocapnia (Ainslie et al. 2005) and dynamic cerebral autoregulation was found to be attenuated by ganglion blockade (Zhang et al. 2002). These findings suggest that autonomic neural control of the cerebral circulation plays a significant role in the beat-to-beat regulation of cerebral blood flow. However, it is well known that CO2 is the most powerful regulator of vascular tone in the brain and it has been reported that baroreflex-induced sympathetic activation had no influence on the cerebral vascular response to CO2 (LeMarbre et al. 2003). Collectively, these findings suggest that the importance of the sympathetically mediated vasoconstriction in the cerebral circulation may be to protect the blood–brain barrier when limits of autoregulation are exceeded.
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The changes in MCA Vmean that occurred in response to the central blood volume-induced changes in were decreased from rest to exercise (P= 0.035, Figs 1 and 2). One possible explanation is the presence of a decrease in the distribution of to the brain during exercise. For example, when exercise increases the cardiac output 4–5 times from rest, to enable blood flow to the active muscle to be increased, the distribution of to the brain was decreased from rest (14%) to exercise (3%) (Rowell, 1993). Thus, the changes in MCA Vmean to changes in during exercise would be less because of the reduced proportion of total being directed to the brain. This reduction in proportion of distributed to the brain would be dependent on the exercise workload. Hence, the exercise-induced decreases in changes of MCA Vmean associated with the changes in may be explained by the reduced proportion of distributed to the brain (Fig. 2).
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As the changes in were associated with the experimentally induced changes in central blood volume, changes in sympathetic activity resulting from the loading and unloading of the cardiopulmonary baroreceptors appear to influence the cerebral vasculature in the presence of a constant MAP. However, if the cardiopulmonary baroreflex-induced sympathetic vasoconstriction of the periphery is a mechanism for maintaining arterial pressure and cerebral perfusion and the same vasoconstriction were to occur at the same magnitude in the brain, cerebral blood flow would be compromised (LeMarbre et al. 2003). A similar vasoconstriction of the brain's vasculature may not assist in defending blood pressure during decreases in central blood volume because the cerebral circulation is located above the level of the heart and the brain has a relatively small vascular bed. Moreover, sympathetic activation elicited by unloading the cardiopulmonary baroreceptors had no influence on the cerebralvascular response to CO2 (LeMarbre et al. 2003). Thus, the different responses between MCA Vmean and FBF may be evidence for the existence of a different cardiopulmonary baroreflex control of the brain vasculature compared to that of others (Johnson et al. 1974; Victor & Leimbach, 1987).
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The contribution of changes in to the carotid baroreflex control of blood pressure during exercise was found to be minimal (Collins et al. 2001; Ogoh et al. 2003) and supported previous work identifying differences in the contribution of carotid-cardiac and carotid-vasomotor arms of the carotid baroreflex to blood pressure regulation during changes in posture (Ogoh et al. 2002). In dogs the reflex response to carotid baroreceptor stimulation was peripheral vasoconstriction and did the alterations in were not identified as being part of the reflex response (Collins et al. 2001). In addition, in humans a carotid-vasomotor reflex-mediated change in total vascular conductance was the major response to carotid baroreceptor stimulation during exercise (Ogoh et al. 2003) and orthostasis (Ogoh et al. 2002). However, the findings of the present study identified that changes in affect the MCA Vmean at rest and during exercise. Thus, carotid-cardiac baroreflex function may prove to be more important to the regulation of MCA Vmean than its control of blood pressure. Interestingly, the changes in MCA Vmean associated with changes in were reduced from rest to exercise and may be related to the reduction in carotid-cardiac baroreflex sensitivity associated with relocation of the operating point of the cardiac arterial baroreflex that occurs during exercise (Ogoh et al. 2005c). These findings suggest that arterial baroreflex regulation of blood pressure via reflex regulation of the systemic vasculature becomes more involved in maintaining cerebral perfusion during exercise.
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