Carotid baroreflex pressor responses at rest and during exercise: cardiac output vs. regional vasoconstriction

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

Carotid baroreflex pressor responses at rest and during exercise: cardiac output vs. regional vasoconstriction

Heidi L. Collins, Robert A. Augustyniak, Eric J. Ansorge, and Donal S. O'Leary

Department of Physiology, Wayne State University School of Medicine, Detroit, Michigan 48201

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

The arterial baroreflex mediates changes in arterial pressure via reflex changes in cardiac output (CO) and regional vascularconductance, and the relative roles may change between rest andexercise and across workloads. Therefore, we quantified the contributionof CO and regional vascular conductances to carotid baroreflex-mediatedincreases in mean arterial pressure (MAP) at rest and during mildto heavy treadmill exercise (3.2 kph; 6.4 kph, 10% grade; and8 kph, 15% grade). Dogs (n = 8) were chronically instrumentedto measure changes in MAP, CO, hindlimb vascular conductance,and renal vascular conductance in response to bilateral carotidocclusion (BCO). At rest and at each workload, BCO caused similarincreases in MAP (average 35 ± 2 mmHg). In response to BCO, neitherat rest nor at any workload were there significant increases inCO; therefore, the pressor response occurred via peripheral vasoconstriction.At rest, 10.7 ± 1.4% of the rise in MAP was due to vasoconstrictionin the hindlimb, whereas 4.0 ± 0.7% was due to renal vasoconstriction.Linear regression analysis revealed that, with increasing workloads,relative contributions of the hindlimb increased and those ofthe kidney decreased. At the highest workload, the decrease inhindlimb vascular conductance contributed 24.3 ± 3.4% to the pressorresponse, whereas the renal contribution decreased to only 1.6± 0.3%. We conclude that the pressor response during BCO was mediatedsolely by peripheral vasoconstriction. As workload increases,a progressively larger fraction of the pressor response is mediatedvia vasoconstriction in active skeletal muscle and the contributionof vasoconstriction in inactive beds (e.g., renal) becomes progressivelysmaller.

carotid sinus hypotension; dog; regional vascular conductance

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

THE ARTERIAL BAROREFLEX FUNCTIONS as the primary short-term, negative-feedback controller of arterial pressure via modulationof cardiac output (CO) and peripheral vascular conductance tomaintain arterial pressure at normal levels. However, during dynamicexercise, arterial pressure and heart rate (HR) increase. Thegenerally accepted conclusion is that dynamic exercise is associatedwith a rapid resetting of the arterial baroreflex to a higherpressure without a change in gain (4, 13, 18-20, 22, 23).That is, the prevailing arterial pressure remains on the high-gainportion of the baroreflex function curve, and the strength ofcontrol of arterial pressure isunaltered.

Several investigators have proposed that the active skeletal muscle must be an important site for the baroreflex-mediatedvasoconstriction during exercise (2, 12, 17, 22, 23,26). This was suggested because as exercise intensity increases,active muscle vascular conductance becomes a progressively greaterfraction of total vascular conductance. To test this hypothesis,O'Leary et al. (17) measured the decreases in hindlimb vascularconductance (HVC) at rest and during exercise in response to bilateralcarotid artery occlusion (BCO) in conscious dogs. The magnitudeof the carotid baroreflex-mediated reduction in HVC increasedwith exercise intensity, thus indicating that active skeletalmuscle participates importantly in BCO-mediated pressor responses.However, only arterial pressure, hindlimb blood flow (HBF), andHVC were measured in that study, and thus the authors were unableto directly address the mechanism(s) contributing to the BCO-mediatedpressor response. This is an important consideration, since carotidbaroreflex-mediated increases in arterial pressure may be affectedby changes in CO as well as peripheral vasoconstriction, and theirrelative roles may change with exerciseintensity.

Therefore, we designed the present study to quantify the contribution of CO and peripheral vasoconstriction in mediating thepressor response to carotid sinus hypotension. We hypothesizethat changes in CO will have little effect on the BCO-mediatedpressor response, since it has been previously reported that carotidsinus hypotension resulted in little change in HR during restor exercise (17, 28). Furthermore, with increasing exerciseintensity, as the contribution of active skeletal muscle to totalvascular conductance (TVC) increases, reflex decreases in conductancein this bed will make a greater contribution to the BCO-mediatedpressor response. Conversely, with increasing exercise intensity,as the contribution of nonactive beds (e.g., renal) to TVC decreases,vasoconstriction in these beds will contribute less to the BCO-mediatedpressorresponse.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

All experiments were performed using eight conscious dogs of either gender (21-26 kg) selected for their willingness to runon a motor-driven treadmill. All procedures were reviewed andapproved by the Institutional Animal Care and Use Committee andconformed to the American Physiological Society's "Guiding Principlesin the Care and Use ofAnimals."

Surgical preparation. Each animal (n = 8) was instrumented for chronic hemodynamic measurements in a series of three sterile surgical proceduresas described in detail previously (1, 14, 15, 24). Briefly,through a left thoracotomy, a 20-mm Transonic flow probe was positionedaround the ascending aorta for measurements of CO. For experimentalprotocols unrelated to the present study, three stainless steelventricular pacing electrodes were sutured to the apex of theleft ventricle, and in four animals a 4-mm Transonic flow probewas positioned around the circumflex artery and sonomicrometercrystals were sutured into the wall of the left ventricle. Thepericardium was reapproximated, and the chest was closed inlayers.

In the second surgical procedure, the abdominal cavity was exposed by means of a midline laparotomy. Transonic flow probeswere placed on the terminal aorta and the left renal artery tomonitor HBF and renal blood flow (RBF), respectively. A pneumaticvascular occluder (In Vivo Metrics) was placed on the terminalaorta just distal to the flow probe. All side branches betweenthe iliac arteries and the flow probe were ligated and severed.A Tygon catheter was placed in a side branch of the aorta proximalto the flow probe and occluder to monitor mean arterial pressure(MAP).

In the third and final procedure, a Tygon catheter was inserted into the right jugular vein and advanced to the atrial-cavaljunction to monitor central venous pressure (CVP). In addition,a pneumatic vascular occluder was placed around each common carotidartery. All flow probe cables, ventricular pacing leads, occludertubing, and catheters were tunneled subcutaneously and exteriorizedbetween thescapulae.

Experimental design. All experiments were performed after the animals had fully recovered from the last surgery ( $>=$ 1 wk) and were active, afebrile,and of good appetite. The responses of MAP, HR, CO, HBF, and RBFto a 2-min BCO were recorded at rest and during three levels ofgraded treadmill exercise ranging from mild (3.2 kph, 0% grade),to moderate (6.4 kph, 10% grade), to heavy (8 kph, 15% grade)intensities.

Data collection. The blood flow transducers were connected to the flowmeters (Transonic Systems), and MAP and CVP catheters were connectedto pressure transducers (Transpac IV, Abbott Laboratories). HRwas monitored via a cardiotachometer triggered by the CO signal.All data were recorded continuously on a Gould 3800 recorder andon a laboratory computer at 1,000 Hz. Mean values for each cardiaccycle were saved on hard disk for subsequentanalysis.

Experimental procedures. On the day of the experiment, the animal was brought to the laboratory and allowed to roam freely for 15-30 min. Subsequently,the dog was directed to the treadmill, and the flow probe cablesand catheters were connected. With the dog standing quietly onthe treadmill, baseline resting hemodynamic parameters were obtained.Subsequently, both carotid arterial occluders were rapidly inflatedfor 2 min and then rapidly deflated. A 10-min recovery periodwas allowed before the onset of exercise. After 3-5 min of steady-stateexercise, both occluders were again rapidly inflated for 2 min,the occluders were deflated, and the treadmill was shut off. Theanimal was allowed to recover for $>=$ 30 min before a second experimentalrun was performed. The order of the exercise intensities was randomized.There were never more than two experiments performed on the sameday.

Data analysis. Control levels of each variable were taken as the 1-min average immediately before BCO. The responses to BCO were taken asthe average of the values during the last 30 s of the occlusion.At least two experiments in each setting were performed on eachanimal, and the responses to BCO were averaged within each animalto yield mean values for that animal at rest and at each exerciseintensity. These mean values were then averaged across animalsto yield mean responses for the experimental group. Thus eachanimal served as its own control. Because of technical difficulties,we were unable to obtain RBF data in one animal and all hemodynamicdata at the highest workload in oneanimal.

The average values of MAP, HR, CO, HBF, HVC [i.e., HBF/(MAP $-$ CVP)], RBF, renal vascular conductance [RVC = RBF/(MAP $-$ CVP)],and TVC [i.e., CO/(MAP $-$ CVP)] were obtained before (control)and in response to BCO. RBF and RVC values were doubled to accountfor hemodynamic responses in both kidneys. Since TVC is the sumof all regional vascular conductances, the percent contributionsof regional vasoconstrictions and CO in mediating the pressorresponse to BCO can be directly calculated. This was achievedby calculating the predicted change in MAP during BCO if onlythe individual changes in CO, HVC, or RVC occurred and all otherparameters remained at control levels, which thereby reflectsthe cardiac or regional peripheral vasoconstriction componentsof the pressor response. These equations are as follows

predicted change MAP<SUB>CO</SUB><IT>=</IT>[(CO<SUB>obs</SUB>/TVC<SUB>avg control</SUB>)

(1)

<IT>+</IT>CVP<SUB>avg control</SUB>]<IT>−</IT>MAP<SUB>avg control</SUB>

where MAP_CO is the MAP response to BCO due to CO alone, CO_obs is the CO observed during the BCO, and TVC_avg controland MAP_avg control are the baseline control values averagedover 1 min before the onset of the BCO. CVP_avg controlvalues at rest and during mild, moderate, and heavy exercise were3.7 ± 0.4, 4.1 ± 0.7, 7.5 ± 1.2, and 9.3 ± 1.1 mmHg, respectively,and no significant changes occurred with BCO at rest or any workload.The predicted change of MAP_HVC is as follows

predicted change MAP<SUB>HVC</SUB><IT>=</IT>[(CO<SUB>avg control</SUB>/HVC<SUB>obs</SUB>

(2)

<IT>+</IT>RVC<SUB>avg control</SUB><IT>+</IT>EVC<SUB>avg control</SUB>)<IT>+</IT>CVP<SUB>avg control</SUB>]

where EVC = TVC $-$ (HVC + RVC) and represents vascular conductance elsewhere in the body. The predicted change of MAP_RVC isas follows

predicted change MAP<SUB>RVC</SUB><IT>=</IT>[(CO<SUB>avg control</SUB>/HVC<SUB>avg control</SUB>

(3)

<IT>+</IT>RVC<SUB>obs</SUB><IT>+</IT>EVC<SUB>avg control</SUB>)<IT>+</IT>CVP<SUB>avg control</SUB>]<IT>−</IT>MAP<SUB>avg control</SUB>

Equations 1-3 are similar to those recently reported from our laboratory (1). The predicted changes in MAP due to the individualresponses in CO, HVC, and RVC were used to calculate the percentcontribution of these individual responses to the observed reflexincrease in MAP during BCO. The averaged percent contributionsof HVC, RVC, and CO to the pressor response during bilateral carotidocclusion at rest and during mild, moderate, and heavy exerciseare presented in Table 1.

View this table:
[in this window]
[in a new window]

Table 1. Contributions of HVC, RVC, and CO to the pressor response during BCO at rest and during mild, moderate, and heavy exercise

Statistical analysis. Values are means ± SE. A two-way ANOVA with repeated measures was used for determining differences in the hemodynamic responsesto BCO at rest and during exercise (9). Significant interactionsobserved by the ANOVA were further evaluated by a test for simpleeffects (Systat 8.0). A linear regression analysis was used todetermine the relationship between the percent contribution ofHVC, RVC, and CO to the carotid baroreflex-induced pressor responseand as workload and baseline HBF increased (16, 17). A one-wayANOVA with repeated measures was used to determine a workloadeffect on the change of MAP, HVC, RVC, and CO in response to BCO.Because of the unequal variance across workloads of HVC, a logarithmictransformation of the HVC values was performed before the one-and two-way ANOVAs. An $alpha$ -level of P < 0.05 was used to determinestatisticalsignificance.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Figure 1 presents an example of the hemodynamic responses to BCO in one dog at rest and during heavy exercise. BCO at restincreased MAP with little or no change in CO. Modest decreasesin TVC, HVC, and RVC occurred, suggesting that peripheral vasoconstrictionmediated the pressor response to BCO. Heavy exercise substantiallyincreased MAP, CO, TVC, and HVC. BCO during heavy exercise inducedhemodynamic responses similar to those observed at rest; however,greater decreases in TVC and HVC and a somewhat smaller decreasein RVC occurred in this animal.

View larger version (26K):
[in this window]
[in a new window]

Fig. 1. Actual data from 1 animal presenting mean arterial pressure (MAP), cardiac output (CO), total vascular conductance (TVC), hindlimb vascular conductance (HVC), (A) and renal vascular conductance (RVC) at rest and during heavy exercise (8 kph, 15% grade) (B) 1 min before and during bilateral carotid occlusion (2 min). Vertical line, onset of bilateral carotid occlusion (BCO).

Figure 2 presents the average hemodynamic responses at rest and during exercise before (control) and during BCO. A one-wayANOVA revealed similar changes in MAP during BCO at rest and acrossexercise intensities (average 35 ± 2 mmHg, P = 0.071). The reductionsin TVC, RVC, and HVC in response to carotid sinus hypotensioncompared with control values were significant at rest and acrossworkloads, whereas no significant change in CO occurred. Furthermore,a significant workload effect on the decrease in HVC was observed,indicating that as workload increased, a greater vasoconstrictorresponse in the hindlimb vascular bed occurred (P = 0.001). Incontrast, a workload effect on the decrease in RVC was not observed.A small but statistically significant increase in HR occurredat 3.2 kph during BCO (11 ± 5 beats/min, P = 0.04).

View larger version (38K):
[in this window]
[in a new window]

Fig. 2. Averaged hemodynamic values during control (solid bars) and in response to BCO (open bars) at rest and during 3 levels of exercise. RBF, renal blood flow; HBF, hindlimb blood flow. *P < 0.05, control vs. BCO.

Figure 3 presents the relationship between the percent contributions of HVC, RVC, and CO to the BCO-mediated pressor responseas a function of baseline HBF. Baseline HBF was used, since thesevalues are closely related to exercise intensity (5, 11).Linear regression analysis revealed a positive correlation betweenthe percent contribution of HVC to the pressor response and baselineHBF (r = 0.714), and the slope was significantly different fromzero (P < 0.001). These results indicate that reductions in HVCcontribute progressively more to the carotid baroreflex-inducedpressor response with increasing workloads. Conversely, a negativecorrelation existed between the percent contribution of RVC tothe pressor response and baseline HBF (r = 0.700), and the slopewas also significantly different from zero (P < 0.001). Theseresults indicate that reductions in RVC contribute progressivelyless to the carotid baroreflex-induced pressor response with increasingworkloads. Finally, a significant relationship between the percentcontribution of CO and baseline HBF was not observed (r = 0.235,P > 0.05).

View larger version (18K):
[in this window]
[in a new window]

Fig. 3. Relationship among percent contributions of HVC, RVC, and CO to the pressor response during BCO and baseline HBF at rest and during exercise in all animals. Results indicate an increase in the relative contribution of the hindlimb and a decrease in the contribution of the kidney to the carotid baroreflex-induced pressor response with increasing workloads. P < 0.05; slope was significantly different from zero.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The major finding in this study is that neither at rest nor at any workload were there significant increases in CO duringBCO, indicating that the pressor response to carotid sinus hypotensionis mediated solely by peripheral vasoconstriction. Furthermore,active skeletal muscle becomes an increasingly more importanttarget vasculature for carotid baroreflex-induced vasoconstrictionas exercise intensity rises. This was demonstrated by progressivelylarger contributions of reductions in HVC to the pressor responseduring carotid sinus hypotension as exercise intensity increased(Fig. 3). Furthermore, as exercise intensity increases, the renalvascular bed becomes a progressively less important site for carotidbaroreflex-induced vasoconstriction (Fig. 3).

The magnitude of the reduction in TVC during carotid sinus hypotension increased as workload increased. The contribution ofa given change in regional vascular conductance to the regulationof blood pressure is dependent on the level of TVC (12). IfTVC is high and if a given regional vascular conductance comprisesa large fraction of TVC, then changes in conductance in this regionalvascular bed can contribute more to blood pressure regulationthan if that regional vascular conductance is low. HVC constituted19.7 ± 0.9% of TVC at rest and 33.5 ± 2.6% during heavy exercise.Thus, accordingly, HVC could make a greater contribution to bloodpressure regulation during heavy exercise than at rest. Indeed,HVC contributed 10.7 ± 1.4% to the pressor response during carotidsinus hypotension at rest (~3.5 mmHg), whereas at the highestworkload, changes in HVC made a significantly greater contributionto the pressor response (24.3 ± 3.4%, ~8.5 mmHg). Conversely,if regional vascular conductance does not comprise a large fractionof TVC, then changes in conductance in this regional vascularbed likely contribute less to blood pressure regulation. At rest,RVC constituted ~5% of TVC. This fraction of TVC decreased to<1% during heavy exercise. Accordingly, at rest, RVC contributedonly 4.0 ± 0.7% (~1.4 mmHg) to the pressor response during carotidsinus hypotension, and at the highest workload, RVC contributedonly 1.6 ± 0.3%, which represents <1 mmHg of the pressorresponse.

Our data indicate that as workload increased, the contribution of vasoconstriction within the active skeletal muscle to thereflex pressor response to BCO also progressively increased. Indogs at rest, skeletal muscle blood flow accounts for 45% of COand, therefore, 45% of TVC (6). At rest in our experiments,TVC averaged 42 ml · min¹ · mmHg¹, which therefore reflects 19 ml · min¹ · mmHg¹ to skeletal muscle and 23 ml · min¹ · mmHg¹ to nonskeletal muscle. This latter value includes cardiac vascularconductance, which is ~2.5 ml · min¹ · mmHg¹ at rest (6). Thus vascular conductance to nonmuscle areasis 20.5 ml · min¹ · mmHg¹ at rest. In dogs during exercise, vascular conductance in nonactiveareas does not increase (and may decrease); thus all the risein TVC with increasing workloads reflects vasodilation withinthe active muscle (including the cardiac vasculature). At thehighest workload, TVC decreased by 24 ml · min¹ · mmHg¹ in response to BCO. Even if all nonactive areas, including thebrain, spinal cord, and kidneys, vasoconstricted completely (e.g.,zero blood flow, zero vascular conductance, and infinite vascularresistance), which was not the case (see RVC responses in Fig.2), the maximal decrease in TVC could only be at most 20.5 ml· min¹ · mmHg¹, which is less than the observed decrease in TVC (24.1 ± 4.2ml · min¹ · mmHg¹) in response to BCO at this workload. Thus we conclude that vasoconstrictionwithin the active skeletal muscle must participate in the pressorresponse to BCO during heavy exercise. Indeed, Fig. 3 shows thatthe reduction in HVC [of which the vast majority is to skeletalmuscle even at rest (6)] plays an increasingly important rolein mediating the pressor response to BCO as workload rises. Furthermore,if the response of all skeletal muscle is similar to that of thehindlimb, then we calculate that vasoconstriction within all skeletalmuscle (skeletal muscle in the hindlimb and elsewhere) contributes29% to the pressor response at rest and 61% at the highest workload[calculations based on the known percent contribution of the hindlimband the known distribution of CO at rest in dogs (5) and thefact that all the increase in TVC with exercise is muscle vasodilation].Therefore, during heavy exercise, skeletal muscle is the primarytarget organ for baroreflex-mediatedvasoconstriction.

The MAP, HR, and HVC responses to carotid sinus hypotension at rest and during exercise were similar to those described byO'Leary et al. (17). They concluded that since carotid sinushypotension caused little change in HR during rest or exercise,most of the pressor response was caused by reflex vasoconstrictionand not CO. However, they did not measure CO. This is an importantconsideration, since changes in HR alone may not accurately depictchanges in CO (14, 29). Furthermore, they were not able todistinguish the mechanism (CO vs. peripheral vasoconstriction)or the relative contributions of the regional vasoconstrictionto the pressor response during carotid sinus hypotension. Thepresent study extends these previous observations by quantifyingthe relative contributions of CO and active and inactive vascularbeds in mediating the reflex pressor response to BCO. On the basisof CO values reported previously for resting and exercising dogs(10, 28), O'Leary and colleagues reported that ~11% of thepressor response to carotid sinus hypotension was due to vasoconstrictionin the hindlimb, and during higher workloads, ~59% of the pressorresponse was attributable to a reduction in HVC. Our conclusionsare in agreement with these previous findings; however, the percentcontribution of the decrease in HVC to the pressor response duringheavy exercise is considerably lower in the present study (24vs. 59%). A likely explanation for this divergent result is thatO'Leary and colleagues may have underestimated CO, and thus TVC,at the higher workload. Since a given change in HVC will havea greater effect on blood pressure regulation when TVC is lowthan when TVC was high (12), it may not be surprising that wereport a lower value when TVC was directly calculated than whenit wasestimated.

A major point of controversy in the field of neural control of the circulation during exercise has been the existence of "functionalsympatholysis." The term functional sympatholysis was coined toexpress a commonly held view that metabolic vasodilation in activeskeletal muscle attenuates neurogenic vasoconstriction (21).Indeed, there are several lines of evidence spanning several decadessuggesting a reduced vasoconstrictor response to sympathetic stimulationin contracting skeletal muscle (3, 8, 21, 27). Conversely,a number of other studies have reported that local metabolic vasodilationin the active skeletal muscle does not override neurogenic vasoconstriction(5, 7, 17, 25, 26). Causes for the disparate resultsare not entirely clear. However, it has been argued that withthe vast differences that exist in baseline blood flow, resistance,and conductance between rest and exercise, opposite conclusionscan be drawn on the magnitude of the vasoconstrictor responsewhen the responses are analyzed in terms of resistance vs. conductanceor absolute change vs. percent change (12). One limitation withthis study and others that examine baroreflex-induced increasesin sympathetic nerve activity is that it is unknown whether therise is sympathetic nerve activity is similar at rest and throughoutexercise. However, despite this limitation, our data demonstratethat as workload increases, the active skeletal muscle vascularbed becomes the primary site for carotid baroreflex-inducedvasoconstriction.

The pressor response to carotid sinus hypotension in the intact, conscious animal will, in turn, activate a variety of controlmechanisms. It is important to note, however, that we wanted toexamine the relative contributions of CO and peripheral conductancemediating the pressor response to carotid sinus hypotension underphysiological conditions, where the multiple interactions inherentin the feedback control of arterial pressure are intact. It isrecognized that the observed hemodynamic changes may be more profoundin the absence of the opposing compensatory mechanisms (e.g.,after aortic and cardiopulmonarybarodenervation).

Summary. This is the first study to quantify the contribution of CO and regional vascular conductances to the carotid baroreflex-mediatedincreases in MAP at rest and during mild to heavy treadmill exercise.Our data demonstrate that the pressor response to carotid sinushypotension is mediated via peripheral vasoconstriction. SinceTVC is the sum of all regional vascular conductances, we wereable to determine the contributions of HVC and RVC to the carotidbaroreflex-mediated pressor response. The relative contributionof the hindlimb increased and that of the kidney decreased withincreasing workloads. These data suggest that the active skeletalmuscle vascular bed and not the renal bed is an important sitefor carotid baroreflex-induced vasoconstriction to raise and maintainarterial pressure during a hypotensive stimulus. Thus, in responseto carotid sinus hypotension, the relative importance of vasoconstrictionin active skeletal muscle increases and that in inactive beds(e.g., renal) decreases as exercise intensityrises.

	ACKNOWLEDGEMENTS

We thank Sue Harris for expert technicalassistance.

	FOOTNOTES

This study was supported by National Heart, Lung, and Blood Institute Grant HL-55473 and by a National Institutes of HealthMinority Individual in Postdoctoral TrainingSupplement.

Address for reprint requests and other correspondence: D. S. O'Leary, Dept. of Physiology, Wayne State University School ofMedicine, 540 East Canfield Ave., Detroit, MI 48201 (E-mail: doleary{at}med.wayne.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

Received 17 April 2000; accepted in final form 30 August 2000.

	REFERENCES

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

1. Augustyniak, RA, Ansorge EJ, and O'Leary DS. Muscle metaboreflex control of cardiac output and peripheral vasoconstriction exhibit different latencies. Am J Physiol Heart Circ Physiol 278: H530-H537, 2000[Abstract/Free Full Text].

2. Baily, RG, Prophet SA, Shenberger JS, Zelis R, and Sinoway LI. Direct neurohumoral evidence for isolated sympathetic nervous system activation to skeletal muscle in response to cardiopulmonary baroreceptor unloading. Circ Res 66: 1720-1728, 1990[Abstract/Free Full Text].

3. Burcher, E, and Garlic D. Antagonism of vasoconstrictor responses by exercise in the gracilis muscle of the dog. J Pharmacol Exp Ther 187: 78-85, 1973[Abstract/Free Full Text].

4. DiCarlo, SE, and Bishop VS. Onset of exercise shifts operating point of arterial baroreflex to higher pressures. Am J Physiol Heart Circ Physiol 262: H303-H307, 1992[Abstract/Free Full Text].

5. Donald, DE, Rowlands DJ, and Ferguson DA. Similarity of blood flow in the normal and sympathectomized dog hindlimb during graded exercise. Circ Res 26: 185-199, 1970[Abstract/Free Full Text].

6. Hales, JRS, and Dampney RAL The redistribution of cardiac output in the dog during heat stress. J Therm Biol 1: 29-34, 1975.

7. Joyner, MJ, Lennon RL, Wedel DJ, Rose SH, and Shepherd JT. Blood flow to contracting muscles: influence of increased sympathetic nerve activity. J Appl Physiol 68: 1453-1457, 1990[Abstract/Free Full Text].

8. Kjellmer, I. On the competition between metabolic vasodilation and neurogenic vasoconstriction in skeletal muscle. Acta Physiol Scand 63: 450-459, 1965[ISI][Medline].

9. Ludbrook, J. On making multiple comparisons in clinical and experimental pharmacology and physiology. Clin Exp Pharmacol Physiol 18: 379-392, 1991[ISI][Medline].

10. Melcher, A, and Donald DE. Maintained ability of carotid baroreflex to regulate arterial pressure during exercise. Am J Physiol Heart Circ Physiol 241: H838-H849, 1981[Abstract/Free Full Text].

11. Musch, TI, Friedman DB, Pitetti KH, Haidet GC, Stray-Gundersen J, Mitchell JH, and Ordway GA. Regional distribution of blood flow of dogs during graded dynamic exercise. J Appl Physiol 63: 2269-2277, 1987[Abstract/Free Full Text].

12. O'Leary, DS. Regional vascular resistance vs. conductance: which index for baroreflex responses? Am J Physiol Heart Circ Physiol 260: H632-H637, 1991[Abstract/Free Full Text].

13. O'Leary, DS. Heart rate control during exercise by baroreceptors and skeletal muscle afferents. Med Sci Sports Exerc 28: 210-217, 1996[ISI][Medline].

14. O'Leary, DS, and Augustyniak RA. Muscle metaboreflex increases ventricular performance in conscious dogs. Am J Physiol Heart Circ Physiol 275: H220-H224, 1998[Abstract/Free Full Text].

15. O'Leary, DS, Augustyniak RA, Ansorge EJ, and Collins HL. Muscle metaboreflex improves O₂ delivery to ischemic active skeletal muscle. Am J Physiol Heart Circ Physiol 276: H1399-H1403, 1999[Abstract/Free Full Text].

16. O'Leary, DS, and Johnson JM. Baroreflex control of the rat tail circulation in normothermia and hyperthermia. J Appl Physiol 66: 1234-1241, 1989[Abstract/Free Full Text].

17. O'Leary, DS, Rowell LB, and Scher AM. Baroreflex-induced vasoconstriction in active skeletal muscle of conscious dogs. Am J Physiol Heart Circ Physiol 260: H37-H41, 1991[Abstract/Free Full Text].

18. Papelier, Y, Escourrou P, Gauthier JP, and Rowell LB. Carotid baroreflex control of blood pressure and heart rate in men during dynamic exercise. J Appl Physiol 77: 502-506, 1994[Abstract/Free Full Text].

19. Potts, JT, and Mitchell JH. Rapid resetting of carotid baroreceptor reflex by afferent input from skeletal muscle receptors. Am J Physiol Heart Circ Physiol 275: H2000-H2008, 1998[Abstract/Free Full Text].

20. Potts, JT, Shi XR, and Raven PB. Carotid baroreflex responsiveness during dynamic exercise in humans. Am J Physiol Heart Circ Physiol 265: H1928-H1938, 1993[Abstract/Free Full Text].

21. Remensnyder, JP, Mitchell JH, and Sarnoff SJ. Functional sympatholysis during muscular activity. Circ Res 11: 370-380, 1962[Abstract/Free Full Text].

22. Rowell, LB, and O'Leary DS. Reflex control of the circulation during exercise: chemoreflexes and mechanoreflexes. J Appl Physiol 69: 407-418, 1990[Abstract/Free Full Text].

23. Rowell, LB, O'Leary DS, and Kellogg DL, Jr. Integration of the cardiovascular control systems in dynamic exercise. In: Handbook of Physiology. Regulation and Integration of Multiple Systems. Bethesda, MD: Am. Physiol. Soc, 1996, chapt. 17, p. 770-840.

24. Sheriff, DD, Augustyniak RA, and O'Leary DS. Muscle chemoreflex-induced increases in right atrial pressure. Am J Physiol Heart Circ Physiol 275: H767-H775, 1998[Abstract/Free Full Text].

25. Shoemaker, JK, Pandey P, Herr MD, Silber DH, Yang QX, Smith MB, Gray K, and Sinoway LI. Augmented sympathetic tone alters muscle metabolism with exercise: lack of evidence for functional sympatholysis. J Appl Physiol 82: 1932-1938, 1997[Abstract/Free Full Text].

26. Strange, S, Rowell LB, Christensen NJ, and Saltin B. Cardiovascular responses to carotid sinus baroreceptor stimulation during moderate to severe exercise in man. Acta Physiol Scand 138: 145-153, 1990[ISI][Medline].

27. Thomas, GD, Hansen J, and Victor RG. Inhibition of $alpha$ ₂-adrenergic vasoconstriction during contraction of glycolytic, not oxidative, rat hindlimb muscle. Am J Physiol Heart Circ Physiol 266: H920-H929, 1994[Abstract/Free Full Text].

28. Walgenbach, SC, and Donald DE. Inhibition by carotid baroreflex of exercise-induced increases in arterial pressure. Circ Res 52: 253-262, 1983[Abstract/Free Full Text].

29. White, S, Patrick T, Higgins CB, Vatner SF, Franklin D, and Braunwald E. Effects of altering ventricular rate on blood flow distribution in conscious dogs. Am J Physiol 221: 1402-1407, 1971.

This article has been cited by other articles:

S. Ogoh, J. P. Fisher, P. B. Raven, and P. J. Fadel
Arterial baroreflex control of muscle sympathetic nerve activity in the transition from rest to steady-state dynamic exercise in humans
Am J Physiol Heart Circ Physiol, October 1, 2007; 293(4): H2202 - H2209.
[Abstract] [Full Text] [PDF]

D. D. Sheriff, R. A. Augustyniak, and D. S. O'Leary
Active venoconstriction is/is not important in maintaining or raising end-diastolic volume and stroke volume during exercise and orthostasis
J Appl Physiol, November 1, 2006; 101(5): 1531 - 1531.
[Full Text] [PDF]

S. Ogoh, R. M. Brothers, Q. Barnes, W. L. Eubank, M. N. Hawkins, S. Purkayastha, A. O-Yurvati, and P. B. Raven
Effects of changes in central blood volume on carotid-vasomotor baroreflex sensitivity at rest and during exercise
J Appl Physiol, July 1, 2006; 101(1): 68 - 75.
[Abstract] [Full Text] [PDF]

D. S. O'Leary and M. J. Joyner
Point: The muscle metaboreflex does restore blood flow to contracting muscles
J Appl Physiol, January 1, 2006; 100(1): 357 - 361.
[Full Text] [PDF]

D. S O'Leary
Altered reflex cardiovascular control during exercise in heart failure: animal studies
Exp Physiol, January 1, 2006; 91(1): 73 - 77.
[Abstract] [Full Text] [PDF]

J.-K. Kim, J. A. Sala-Mercado, R. L. Hammond, J. Rodriguez, T. J. Scislo, and D. S. O'Leary
Attenuated arterial baroreflex buffering of muscle metaboreflex in heart failure
Am J Physiol Heart Circ Physiol, December 1, 2005; 289(6): H2416 - H2423.
[Abstract] [Full Text] [PDF]

J.-K. Kim, J. A. Sala-Mercado, J. Rodriguez, T. J. Scislo, and D. S. O'Leary
Arterial baroreflex alters strength and mechanisms of muscle metaboreflex during dynamic exercise
Am J Physiol Heart Circ Physiol, March 1, 2005; 288(3): H1374 - H1380.
[Abstract] [Full Text] [PDF]

D. M. Keller, S. Ogoh, S. Greene, A Olivencia-Yurvati, and P. B Raven
Inhibition of KATP channel activity augments baroreflex-mediated vasoconstriction in exercising human skeletal muscle
J. Physiol., November 15, 2004; 561(1): 273 - 282.
[Abstract] [Full Text] [PDF]

D. M. Keller, P. J Fadel, S. Ogoh, R. M. Brothers, M. Hawkins, A. Olivencia-Yurvati, and P. B Raven
Carotid baroreflex control of leg vasculature in exercising and non-exercising skeletal muscle in humans
J. Physiol., November 15, 2004; 561(1): 283 - 293.
[Abstract] [Full Text] [PDF]

J.-K. Kim, R. A. Augustyniak, J. A. Sala-Mercado, R. L. Hammond, E. J. Ansorge, N. F. Rossi, and D. S. O'Leary
Heart failure alters the strength and mechanisms of arterial baroreflex pressor responses during dynamic exercise
Am J Physiol Heart Circ Physiol, October 1, 2004; 287(4): H1682 - H1688.
[Abstract] [Full Text] [PDF]

M. D. Delp and D. S. O'Leary
Integrative control of the skeletal muscle microcirculation in the maintenance of arterial pressure during exercise
J Appl Physiol, September 1, 2004; 97(3): 1112 - 1118.
[Abstract] [Full Text] [PDF]

L. B. Rowell
Ideas about control of skeletal and cardiac muscle blood flow (1876-2003): cycles of revision and new vision
J Appl Physiol, July 1, 2004; 97(1): 384 - 392.
[Abstract] [Full Text] [PDF]

D. M. Keller, W. L. Wasmund, D. W. Wray, S. Ogoh, P. J. Fadel, M. L. Smith, and P. B. Raven
Carotid baroreflex control of leg vascular conductance at rest and during exercise
J Appl Physiol, February 1, 2003; 94(2): 542 - 548.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Alert me when this article is cited

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via ISI Web of Science (21)

Citing Articles via Google Scholar

Google Scholar

Articles by Collins, H. L.

Articles by O'Leary, D. S.

Search for Related Content

PubMed

PubMed Citation

Articles by Collins, H. L.

Articles by O'Leary, D. S.

				D. D. Sheriff, R. A. Augustyniak, and D. S. O'Leary Active venoconstriction is/is not important in maintaining or raising end-diastolic volume and stroke volume during exercise and orthostasis J Appl Physiol, November 1, 2006; 101(5): 1531 - 1531. [Full Text] [PDF]

				S. Ogoh, R. M. Brothers, Q. Barnes, W. L. Eubank, M. N. Hawkins, S. Purkayastha, A. O-Yurvati, and P. B. Raven Effects of changes in central blood volume on carotid-vasomotor baroreflex sensitivity at rest and during exercise J Appl Physiol, July 1, 2006; 101(1): 68 - 75. [Abstract] [Full Text] [PDF]

				D. S. O'Leary and M. J. Joyner Point: The muscle metaboreflex does restore blood flow to contracting muscles J Appl Physiol, January 1, 2006; 100(1): 357 - 361. [Full Text] [PDF]

				D. S O'Leary Altered reflex cardiovascular control during exercise in heart failure: animal studies Exp Physiol, January 1, 2006; 91(1): 73 - 77. [Abstract] [Full Text] [PDF]

				J.-K. Kim, J. A. Sala-Mercado, R. L. Hammond, J. Rodriguez, T. J. Scislo, and D. S. O'Leary Attenuated arterial baroreflex buffering of muscle metaboreflex in heart failure Am J Physiol Heart Circ Physiol, December 1, 2005; 289(6): H2416 - H2423. [Abstract] [Full Text] [PDF]

				J.-K. Kim, J. A. Sala-Mercado, J. Rodriguez, T. J. Scislo, and D. S. O'Leary Arterial baroreflex alters strength and mechanisms of muscle metaboreflex during dynamic exercise Am J Physiol Heart Circ Physiol, March 1, 2005; 288(3): H1374 - H1380. [Abstract] [Full Text] [PDF]

				D. M. Keller, S. Ogoh, S. Greene, A Olivencia-Yurvati, and P. B Raven Inhibition of KATP channel activity augments baroreflex-mediated vasoconstriction in exercising human skeletal muscle J. Physiol., November 15, 2004; 561(1): 273 - 282. [Abstract] [Full Text] [PDF]

				D. M. Keller, P. J Fadel, S. Ogoh, R. M. Brothers, M. Hawkins, A. Olivencia-Yurvati, and P. B Raven Carotid baroreflex control of leg vasculature in exercising and non-exercising skeletal muscle in humans J. Physiol., November 15, 2004; 561(1): 283 - 293. [Abstract] [Full Text] [PDF]

				J.-K. Kim, R. A. Augustyniak, J. A. Sala-Mercado, R. L. Hammond, E. J. Ansorge, N. F. Rossi, and D. S. O'Leary Heart failure alters the strength and mechanisms of arterial baroreflex pressor responses during dynamic exercise Am J Physiol Heart Circ Physiol, October 1, 2004; 287(4): H1682 - H1688. [Abstract] [Full Text] [PDF]

				M. D. Delp and D. S. O'Leary Integrative control of the skeletal muscle microcirculation in the maintenance of arterial pressure during exercise J Appl Physiol, September 1, 2004; 97(3): 1112 - 1118. [Abstract] [Full Text] [PDF]

				L. B. Rowell Ideas about control of skeletal and cardiac muscle blood flow (1876-2003): cycles of revision and new vision J Appl Physiol, July 1, 2004; 97(1): 384 - 392. [Abstract] [Full Text] [PDF]

				D. M. Keller, W. L. Wasmund, D. W. Wray, S. Ogoh, P. J. Fadel, M. L. Smith, and P. B. Raven Carotid baroreflex control of leg vascular conductance at rest and during exercise J Appl Physiol, February 1, 2003; 94(2): 542 - 548. [Abstract] [Full Text] [PDF]