When the canine epicardium is stimulated, the spread of epicardial excitation is 2.4 times faster parallel to the long axes of the cardiac fibers than perpendicular to them. Likewise, gross tissue resistivity is lower parallel to fibers by a factor of 3.2, and the voltage across the depolarization wave is approximately three times as great in the longitudinal direction. Equations are presented which relate these variables. Theoretical considerations confirm the experimental finding that the potentials around a wave of depolarization cannot be accounted for by the conventional hypothesis that the wavefront is a uniform double-layer current source.
We tested the hypothesis that rapid increases in muscle blood flow and vascular conductance (C) at onset of dynamic exercise are caused by the muscle pump. We measured arterial (AP) and central venous pressure (CVP) in nine awake dogs, eight with atrioventricular block, pacemakers, and ascending aortic flow probes for control of cardiac output (CO) (2 also had terminal aortic flow probes). One dog had only an iliac artery probe. At exercise onset (0 and 10% grade, 4 mph) C and CVP rose to early plateaus, and AP reached a nadir, all in 2-5 s. At 20% grade and 4 mph, C increased continuously after its initial sudden rise. Timing and magnitude of initial change in conductance (delta C) were independent of CO, AP, work rate (change in grade at constant speed), or autonomic function (blocked by hexamethonium). Speed of initial delta C and its independence from work rate and blood flow ruled out metabolic vasodilation as its cause; insensitivity to AP and autonomic blockade ruled out myogenic relaxation and sympathetic vasodilation as causes of sudden delta C. Sensitivity to contraction frequency (not work per se) implicates the muscle pump. When reflexes were blocked, a large secondary rise in C, presumably caused by metabolic vasodilation, began after 10 s of mild exercise. When reflexes were intact in mild exercise, C was lowered below its initial plateau by sympathetic vasoconstriction, which partially raised AP from its nadir toward its preexercise level. Our conclusion is that dynamic exercise has a large rapid effect on C that is not explained by known neural, metabolic, myogenic, or hydrostatic influences.(ABSTRACT TRUNCATED AT 250 WORDS)
SUMMARY. The extracellular epicardial potential fields produced by simple depolarization waves in the in situ canine left ventricular myocardium were analyzed. A mathematical model that included tissue anisotropy was developed to explain the observed fields. Values of intracellular (i), extracellular (o), longitudinal (f), and transverse (t) resistivity which gave the best fit between the model and experimental data were (in ohm-cm, mean ± SD): r,,, = 852 ± 232, r,,, = 1247 ± 210, r,, = 291 ± 38, rii = 1677 ± 331. The potential fields around simple stimulated waves on the epicardium can best be explained if the extracellular wavefront voltage is (mean ± SD) 74 ± 7 mV for a wave propagating parallel to the local muscle fibers, and 43 ± 6 mV for a wave propagating perpendicular to these fibers. We conclude that the anisotropy of the electrical conductivity of cardiac muscle has important effects on the propagation of waves of depolarization and on the potential fields produced by depolarization in the intact heart. (Circ Res 50: 342-351, 1982)
In six dogs trained to run at 2, 4, and 6 mph, we caused graded reductions in hindlimb perfusion by compressing the terminal aorta. Our goal was to examine the relationship between hindlimb perfusion [terminal aortic flow (TAQ) and femoral arterial pressure (FP)] and cardiovascular responses [aortic pressure (AP), heart rate, and ascending aortic flow (CO)]. Small reductions in TAQ and FP produced bradycardia, small decreases in CO, and small increases in AP. Further reductions in TAQ and FP produced tachycardia, increased CO, and large increases in AP. AP rose by about 1 mmHg for each 1-mmHg fall in FP. The response was similar at all speeds, but as work load increased it required smaller reductions in FP and TAQ to cause a pressor response (e.g., at 6 mph we could not demonstrate a nonlinear relationship between TAQ and AP). At low work loads the cardiovascular responses to exercise were most likely set by signals other than feedback from exercising muscle because substantial reductions in hindlimb perfusion caused no significant cardiovascular responses. At moderate-to-high work loads or where muscle perfusion is restricted, metabolic feedback from muscle may play a role in cardiovascular responses to exercise.
Graded reductions in hindlimb perfusion in dogs exercising at 2 miles/h (0% grade) elicited reflex pressor responses by what is referred to as the "muscle chemoreflex." To determine the extent to which arterial baroreceptor reflexes oppose the muscle chemoreflex, we elicited pressor responses to muscle ischemia before and after chronic surgical denervation of the arterial baroreceptors. The muscle chemoreflex showed a threshold beyond which systemic pressure rose approximately 3 mmHg for each 1-mmHg decrease in hindlimb perfusion pressure when the arterial baroreceptors were intact. Arterial baroreceptor denervation approximately doubled the pressor responses, i.e., systemic pressure rose by approximately 6 mmHg for each 1-mmHg fall in hindlimb perfusion pressure, without alteration in threshold. We conclude that during mild dynamic exercise, the arterial baroreflexes oppose the pressor response to graded reductions in hindlimb perfusion, reducing it by approximately 50%. When unopposed by the arterial baroreflexes the muscle chemoreflex exhibits a gain (ratio of change in systemic pressure to change in hindlimb perfusion pressure) of approximately -6; thus this reflex can correct by 85% the decrease in muscle perfusion pressure caused by partial vascular occlusion.
At rest, central venous pressure (CVP) falls when cardiac output (CO) rises. This can be attributed to flow-dependent redistribution of blood volume from central to peripheral blood vessels. In contrast, CVP rises during dynamic exercise despite a rise in CO. Therefore peripheral circulatory changes during exercise must counteract the factors that lower CVP when CO rises during rest. Our objectives were to determine the importance of blood flow, the muscle pump, and reflexes on changes in ventricular filling pressure during dynamic exercise. In seven dogs with a surgically produced atrioventricular (AV) block, normal relationships between CO and CVP were established by AV-linked pacing (normal heart rates) during rest and exercise. Cardiac output was altered during rest and treadmill exercise (4 miles/h at 0, 10, or 20% grade) by changing ventricular pacing rate to establish curves relating delta CVP to delta CO. These curves were displaced rightward (higher CO) and upward (higher CVP) by exercise because of the muscle pump. Changing CO by pacing during rest and exercise revealed a constant slope for delta CVP/delta CO of -2.7 mmHg.l-1.min-1. Blockade of reflex vasoconstriction and venoconstriction with hexamethonium at rest and during mild exercise (to isolate effects of the muscle pump) did not alter these slopes or the displacement of the curves by exercise, although CVP was 4.3 mmHg lower at a given CO after blockade.(ABSTRACT TRUNCATED AT 250 WORDS)
In dogs running on a treadmill at 2 or 4 mph or 4 mph plus 10% incline, graded reductions in hindlimb perfusion reflexly elicited pressor responses. To test the idea that systemic arterial pressure (SAP) is raised by accumulation in muscle of a nerve-activating "pressor substance" release when O2 delivery becomes inadequate, arterial O2 content (CaO2) was reduced 29.1% by carbon monoxide (CO) inhalation before repeating exercise at 2 mph. We reasoned that the pressor substance, or related substances, should appear in femoral venous blood and be correlated to SAP. [K+] behaved inappropriately as a signal to raise SAP, i.e., when flow was reduced, SAP rose markedly with little or no change in [K+]. SAP was well correlated to pH and [lactate] over the three work loads. Compared with the same work load with normal CaO2, CO shifted the relation between SAP and terminal aortic flow rightward 0.30 l/min (34.5%) and the relation between SAP and PO2 leftward 7.7 mmHg. CO did not affect the relation of SAP to terminal aortic O2 delivery, hindlimb O2 uptake index, pH, or [lactate]. Thus pressor responses are apparently generated when O2 delivery falls below some critical level causing accumulation of a pressor substance the release of which is linked to a metabolic event that precipitates lactate accumulation.
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