Physiological Adjustments To Exercise Lecture 2 PDF

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This document is a lecture notes on physiological adjustments to exercise, focusing on cardiovascular and respiratory systems. It covers topics such as cardiac output, stroke volume, and ventilatory responses. The lecture is designed for undergraduate students.

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Prof. K.C. Kregel Exercise Physiology Lecture 2

MECHANISMS OF HEALTH AND DISEASE
Physiological Adjustments to Exercise
Lecture 2
Kevin C. Kregel, Ph.D.
Professor, Department of Health & Human Physiology
Executive Vice President and Provost
The University of Iowa
e-mail: [email protected]
Ph: 319-335-3565

Learning Objectives
1. Understand the broad array of cardiovascular system adjustments that are associated with an
increase in exercise intensity. Understand the exercise-intensity dependent pattern of
redistribution of cardiac output away from visceral regions to active skeletal muscle.

2. Understand how the type of exercise being performed (e.g., dynamic vs. isometric) can
impact the blood pressure response to exercise.

3. Understand how exercise performance can be impacted by parameters such as oxygen
carrying-capacity, red blood cell number, and hemoglobin concentration.

4. Understand various pulmonary responses to aerobic exercise (e.g., ventilation, tidal volume,
and respiratory rate).

5. Understand the metabolic changes that occur with increasing intensity of aerobic exercise
and appreciate how these responses are reflected in changes in respiratory and blood gas
parameters.

Key Terms
Cardiac output Mean arterial pressure
Stroke volume Dynamic exercise
Heart rate Isometric exercise
Arteriovenous oxygen difference Hemoglobinopathies
Splanchnic blood flow Erythropoietin
Cutaneous blood flow Minute ventilation
Skeletal muscle blood flow Tidal volume
Blood pressure Respiratory rate
Total peripheral resistance

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IV. CARDIOVASCULAR RESPONSES
A. Central Circulatory Responses
1. Cardiac Output (CO): During exercise, CO increases with O2
uptake in a relatively sedentary individual from a resting value of 4-
6 liters/min to 25-30 liters/min (Fig. 8). Highly trained endurance
athletes may have CO's of 35 to 40 liters/min. With training, the
relationship between oxygen uptake and CO is not altered (i.e., for
a given work load, CO is unchanged). However, maximal oxygen
uptake and maximal CO are increased with aerobic training. The
factors responsible for the increase in CO during exercise include
the integrated effects of tachycardia, sympathetic stimulation, and
the operation of the Frank-Starling mechanism.

Fig. 8. Cardiac
output response to
increasing levels of
exercise in
untrained and
trained individuals.

2. Stroke Volume (SV): SV is the amount of blood ejected by the
heart per beat. SV is governed by: (a) venous return, (b)
distensibility of the ventricles, and (c) contractile force in relation to
aortic pressure. The change in SV from rest to exercise depends
upon body position. Moving from a supine to a standing or sitting
position is accompanied by a diminution in end-diastolic size of the
heart and a decrease in SV.
Exercise responses: SV increases rapidly at the onset of exercise
and then reaches a plateau that is maintained throughout the exercise
period (Fig. 9).

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Prof. K.C. Kregel Exercise Physiology Lecture 2

Fig. 9. Stroke volume
response to changes in
posture and increasing
levels of exercise in
untrained and trained
individuals.

Training effect: aerobically trained individuals have a higher SV at
rest and at any absolute submaximal exercise level (Fig. 9).

3. Heart Rate (HR): HR increases linearly with workload (Fig. 10).
Hot environments, emotional factors, nervousness and
apprehension may affect it both at rest and during light to moderate
work. During maximal work, HR is remarkably similar under
various conditions with a standard deviation of only ± a few
beats/min. With habitual training, heart rate at rest and during a
given bout of submaximal work is lower than in the untrained
subject. The mechanisms responsible for these training effects are
assumed to involve an increased centrogenic vagal cholinergic
drive combined with a reduction in sympathetic activity.

Note also that maximal HR is similar in sedentary and aerobically
trained individuals (there is some evidence for a decline of a few
beats/min in trained).

Fig. 10. Heart rate
response to increasing
levels of exercise in
untrained and trained
individuals.

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Prof. K.C. Kregel Exercise Physiology Lecture 2

4. Relationship between CO, SV, and HR:
CO (L/min) = SV (mL/beat) x HR (beats/min)

There is a linear increase in CO as a function of oxygen consumption
(VO2) with aerobic exercise (see Fig. 8), and this response is
mediated by increases in both HR and SV.

Example for sedentary young individual:
Rest: 5.25 L/min = 75 mL/beat x 70 beats/min

Exercise: 24.0 L/min = 120 mL/beat x 200 beats/min

5. Cardiovascular Drift: During prolonged aerobic exercise at a
constant submaximal workload (steady-state), there is a gradual
increase in HR and decrease in SV, while cardiac output stays
constant (see Fig. 11). The mechanism driving this response
involves a decrease in blood volume (due to sweating and fluid shift
from plasma to tissues), followed by an increase in skin blood flow
(to aid thermoregulation). This redistribution of cardiac output
generates a decrease in central venous cardiac filling pressure
(preload) that reduces stroke volume. Note that there is a
compensatory increase in HR (baroreceptor-mediated) to maintain
cardiac output.

Panel B: Separate experiments were performed in endurance-trained
cyclists. The protocol involved cycling at 62-65% of VO2max in a
35°C environment for 120 min. Subjects became dehydrated and
hyperthermic (they lost 4.9% of their body weight over the 120-min
exercise bout). Note the declines in cardiac output, stroke volume,
and skin blood flow as a function of exercise duration.

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Note that the Y-axis values are % change and not absolute values.

Fig. 11. Changes in cardiovascular parameters during prolonged submaximal exercise
(Modified from Coyle and Gonzalez-Alonso, 2001).

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B. Partitioning of Cardiac Output during Exercise

1. Overview of cardiac output
redistribution with exercise.
With increasing intensity of
exercise (i.e., increasing
VO2), there is an increase in
sympathetic-mediated
vasoconstriction to kidneys,
splanchnic regions, and
inactive muscle. This results
in increases vascular
muscle
resistance, which diverts
blood away from these areas
and redistributes it to active
muscle (Fig. 12).

Fig. 12. Redistribution of cardiac output at rest and
different levels of exercise up to VO2 max in a healthy
young man. (Modified from L.B. Rowell, Human
Circulation, Oxford University Press, 1986).

2. Splanchnic and Renal Blood Flows (SBF, RBF):

a) The splanchnic and renal vascular beds each receive about
25% of the CO at rest, yet extract only 15-20% of the
available oxygen.

b) These regions are regarded as major sites for redistribution
of oxygen and regulation of blood pressure. Blood flow to
each declines during exercise in proportion to the intensity
of the work performed, as represented by the declining
portion of cardiac output going to the region in Fig. 12.

3. Cutaneous Blood Flow

a) The distribution of CO to the skin may also be a function of
percent max VO2. Skin blood flow initially decreases during
exercise and then increases as body temperature rises with
increments in the duration and intensity of exercise. Skin
blood flow finally decreases when the skin vessels constrict
as total body oxygen consumption nears maximal values
(Fig. 12).

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b) Blood pools in the skin during heat exposure (and during
exercise in the heat), thus reducing venous return and central
blood volume (the volume of blood in the lungs and heart).

4. Cerebral Blood Flow: is unchanged during exercise.

5. Skeletal Muscle Blood Flow (MBF):
a) The major circulatory adjustment to prolonged exercise occurs
in the vasculature of active muscles. Local formation of
vasoactive metabolites dilates the resistance vessels in the
active skeletal muscle beds, and this dilation progresses with
increasing intensity of exercise (see Fig. 12).

b) Maximal muscle blood flow increases with training.

C. Blood Pressure
1. Relationship between CO, total peripheral resistance (TPR),
and mean arterial blood pressure (MAP):
MAP = CO x TPR
Note that systolic blood pressure (SBP) increases progressively with
workload in a subject going from rest to maximal exercise. SBP
increases can be in the range of 60-80 mmHg. At the same time,
diastolic BP will remain relatively unchanged or even fall slightly
from resting levels (due in part to a decline in TPR – see below). As
a result, there is only a modest increase in MAP over the course of
a maximal exercise test.
2. TPR: As noted above, CO increases in relation to increases in
workload (or VO2). There is an abrupt and profound fall in TPR at
the onset of exercise, and there is a progressive decline in TPR with
increases exercise intensity. As a result, MAP rises slightly with
increasing exercise intensity (Fig. 13).

Fig. 13. Blood pressure
responses to increasing
intensities of aerobic
exercise.

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3. Type of Exercise impacts BP responses
a) Dynamic (or rhythmic) exercise: The larger the activated
muscle mass with dynamic exercise, the more pronounced is
the vasodilatation of the resistance vessels. The result is a
lower peripheral resistance, which contributes to a lower
mean blood pressure.
b) Isometric exercise: Isometric contractions can cause far
greater increases in arterial BP than does dynamic exercise.
The rate of rise of arterial BP is proportional to the isometric
contraction force expressed as percent of maximal voluntary
contraction (%MVC) (Fig. 14A). In addition, the larger the
mass of contracting muscle, the greater the pressor (i.e.,
increase in BP) response (Fig. 14B)

Fig. 14. A) Blood pressure responses to increasing levels of handgrip exercise (isometric),
represented as a percent of maximal voluntary handgrip (MVC). B) Blood pressure responses to
different levels of isometric contraction (i.e., different amounts of muscle mass) as a function of
duration of contraction.

4. Effects of Training

a) Aerobic Training: Arterial blood pressure responses during
an aerobic exercise bout are similar in trained and untrained
subjects. However, resting blood pressure is generally lower
in endurance-trained individuals (especially in those who are

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borderline or moderately hypertensive before training).
These reductions occur in both systolic and diastolic blood
pressure.

b) Resistance Training: Although large increases in blood
pressure are produced during lifting of heavy weights,
resistance training does not result in elevations of resting
blood pressure. If fact, mild reductions in resting systolic
and diastolic blood pressure have been observed.

D. SUMMARY: Cardiovascular responses during exercise (Fig. 15 below):

Fig. 15. Effect of
different levels of
Heart rate exercise on several
(beats/min) cardiovascular
responses (modified
from Berne et al.).
Stroke
Volume (ml) Over progressively
increasing workloads:
Cardiac
linear increase in
Output (L/min) HR

SV increases and
then plateaus
Arterial
pressure linear increase in
(mmHg) CO

small linear increase
Total peripheral in MAP
resistance
(mm Hg/ml/min) decline in TPR

linear increase in
O2 consumption VO2
(ml/min)
linear increase in a-v
Arteriovenous O2 difference
oxygen difference
(ml/dl)

Work (kg-m/min)

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E. Blood Volume
1. Total Blood Volume. Endurance training increases total blood volume,
and the effect is dependent on the intensity of training. This increased
blood volume results primarily from an increase in plasma volume (PV),
but there is also an increase in the volume of red blood cells (RBCs).

2. PV. The increase in PV with aerobic training is thought to result from
two mechanisms. First, exercise increases the levels of plasma proteins
such as albumin, which produces an increase in the blood's osmotic
pressure; the result is that more fluid is retained in the blood. Second,
exercise increases the release of antidiuretic hormone and aldosterone
(hormones that cause the reabsorption of water and sodium in the
kidneys), which contributes to an increase in plasma volume.

3. RBCs and Hemoglobin (Hb). RBCs transport oxygen, which is primarily
bound to Hb. An increase in RBC volume with endurance training also
contributes to the overall increase in blood volume (although this is an
inconsistent finding).

While the actual number of RBCs may increase (along with Hb
concentration), the hematocrit (ratio of RBC volume to total blood
volume) may actually decrease. Interestingly, a trained individual’s
hematocrit can decrease to such an extent that the athlete appears to be
anemic.

F. O2 Carrying Capacity and Performance Impact
1. Overview. Both the total amount (absolute values) of Hb and the total
number of RBCs are typically elevated in highly trained athletes.
Importantly, these changes increase oxygen carrying capacity in the
blood, enhance the delivery of oxygen to active muscles, and
contribute to an increase in maximal oxygen consumption and aerobic
capacity.

2. Oxygen Extraction during Exercise: Oxygen extraction is the
amount of oxygen removed from the blood by tissues as blood passes
through the tissue. Therefore, a-vO2 difference represents the arterial
concentration of oxygen minus the venous concentration of oxygen (in
mL/100 mL blood). The governing equation, known as the Fick
equation, is:
VO2 = CO x a-vO2 difference

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3. Key point: a-vO2 difference increases with exercise intensity (see Fig.
16). At any given absolute workload, a-vO2 difference does not
change in trained vs. untrained subjects.

Fig. 16. a-vO2
difference values in
response to increasing
levels of exercise.

4. Erythropoietin (EPO): EPO is a glycoprotein that controls
erythropoiesis (RBC production). EPO is produced primarily by
interstitial fibroblasts in the kidney in response to reduced oxygen
pressure in arterial plasma and regulates RBC production within the
marrow of the long bones.

5. Medical uses of EPO (recombinant human EPO; rHuEpo):
effective treatment for combatting anemia from conditions such as
various hemoglobinopathies, chronic kidney disease, inflammatory
bowel diseases (e.g., Crohn’s), and chemotherapy.

6. EPO as an ergogenic aid: EPO use can enhance performance in
endurance sports.

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Scientific data: EPO treatment (e.g., weeks) increases RBC
number/mass and Hb concentration. These changes result in increased
oxygen transport capacity in the blood, which is the primary reason for
an accompanying increase in VO2max*.

*Note 1: These increases can be on the order of 8-10% in healthy
subjects or endurance-trained recreational athletes. However, there is
no evidence of improved performance in elite athletes (see Heuberger
et al., Br J Clin Pharmacol 2013).

*Note 2: Performance gains at submaximal exercise intensities have
also been noted, with improvements of more than 50% in ‘time to
exhaustion’ (with a standardized exercise test).

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V. Respiratory function

A. Ventilatory responses to exercise:
VE = minute ventilation
VT = tidal volume
fb = frequency of breathing (or respiratory rate)

VE = VT x fb
(L/min) (L/b) (breaths/min)

1. Example
At rest: 12 br/min x 0.5 L/br = 6 L/min

Maximal exercise: 60 br/min x 2.5 L/br = 150 L/min

2. Relevant points:
The relationship between VE and VO2 (or work rate) has two
components. These are a linear rise followed by a curvilinear,
accelerated increase in response to exercise work rates greater than
than 65 to 75% of VO2 max (Fig. 19).

Fig. 19. Relationship
between increasing
oxygen uptake (VO2)
with aerobic exercise and
minute ventilation (VE).

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B. Changes in VT and fb with exercise (Fig. 20):

1. Both increase linearly until heavy exercise

2. At heavy exercise intensities, VT plateaus and the increase in VE is
met by a greater increase in respiratory rate (fb).

Fig. 20. Changes in
tidal volume (VT) and
frequency of
breathing (fb) as a
function of increasing
exercise intensity.

C. Impact of aerobic training on VE responses (Fig. 21 below):
1. trained subjects have lower VE at a given submax VO2
2. A higher VE max is attained in trained subjects.

Fig. 21. Relationship
between increasing
oxygen uptake (VO2)
with aerobic exercise and
minute ventilation (VE) in
trained (T) and untrained
(UT) subjects.

D. Depth vs. rate of breathing:

Breathing styles during aerobic exercise will vary; however, in trained
individuals exercising at moderate intensities, most of the increase in VE
will be due to an increase in VT (because of small increases in fb)

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E. Does VE limit work capacity?
If you were to plot the increases in VO2 and VE during a progressive
exercise test to maximal workloads, VO2 will reach a plateau (i.e., VO2
max). If exercise continues for a few additional minutes, VO2 remains
constant but VE continues to rise due to the progressively increasing
stimulus of anaerobic metabolites (primarily lactate). key point from these
observations is that pulmonary ventilation does not limit maximal oxygen
uptake.

F. Ventilatory adjustments during exercise:

There are several metabolic changes that occur during progressive
increases in exercise intensity (Fig. 22).
Note the changes in pattern in some of the variables, including blood
gas concentrations, at the dark vertical line in the figure, which
represents a stage termed the "anaerobic threshold" or "lactate
inflection point."
This inflection point typically occurs at VO2 max levels of 65 to 75%
of VO2 max, and is postulated to be linked to the developing lactic
acidosis at higher work loads as anaerobic glycolysis takes over more
of the muscle energy supply.

Fig. 22. Changes in respiratory
“anaerobic threshold” and blood gas parameters with
increasing intensity of exercise to
VO2 max. VCO2 is the volume
of expired CO2; PaO2 is the
partial pressure of oxygen in
arterial blood; P2CO2 is the
partial pressure of carbon dioxide
in arterial blood (modified from
Berne et al.).

VO2 (L/min)

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