Deck 22: A: Physiology of the Cardiovascular System

Premature contractions,or extra systoles,often occur with lack of sleep,too much caffeine or nicotine,alcoholism,or heart damage.

Because of the high concentration of protein in plasma,a decrease in the red blood cell count will cause an increase in blood viscosity.

Residual volume refers to the blood that remains in the ventricle after the ejection period.

A heart murmur is one type of abnormal sound.

Tachycardia is normal during sleep and in conditioned athletes while they are awake (but at rest).

The T wave reflects repolarization of the atria.

The vasomotor control mechanism regulates changes in the diameter of arteries.

Grief tends to make the heart beat faster.

Valvular insufficiency can cause heart murmurs.

Operation of the Starling law ensures that when the amount of blood returned to the heart is increased,stroke volume automatically increases to pump it out.

Cardiac output and peripheral resistance are directly proportional to arterial blood volume.

Two important baroreceptors are located in the aorta and the carotid artery.

In order for all the cells of the body to survive,blood supplies to all cells must be equal.

Under abnormal conditions,the AV node or the Purkinje fibers may act as ectopic pacemakers.

Emotional stress can influence heart rate by creating impulses that go from the cerebrum to the cardiac centers via the hypothalamus.

Diastasis is associated with the rapid filling of the ventricles.

The blood-pumping action of respirations and skeletal muscle contractions are both important factors promoting the return of venous blood to the heart.

If the heart rate drops and the stroke volume increases,cardiac output will always show a decrease.

An increase in blood temperature tends to slow down heart rate.

Cardiac output is determined by multiplying stroke volume and heart rate.

At rest,most of the body's blood supply resides in the pulmonary loop.

The popliteal pulse point is found on the anterior surface of the elbow.

The pressure gradient in the ventricles exceeds the pressure in the pulmonary artery and aorta.

The greater the cross-sectional area of a vessel,the greater the speed of the blood flow.

To stop arterial bleeding,pressure must be applied between the damaged artery and the heart.

Tachycardia refers to a heart rate of more than 100 beats per minute.

Under resting conditions,the SA node fires at an intrinsic rhythmical rate of 80 to 85 beats per minute.

The atrial natriuretic hormone mechanism promotes water retention,thus increasing total plasma volume.

Blood viscosity is highly variable in healthy individuals under resting conditions.

The term ischemia refers to abnormal heart sounds.

Venous pulse is just as significant clinically as arterial pulse.

Hypoxic conditions act as the major stimulant to chemoreceptors.

The contraction phase of the cardiac cycle refers to diastole.

The volume of blood circulated per minute is equal to the difference between the mean arterial pressure and the central venous pressure,divided by the resistance.

Pacemaker cells in the heart possess intrinsic rhythm.

The pulse wave is associated with left ventricular diastole.

The resting cardiac output from the left ventricle is about 5 liters.

Diastolic pressure is the force of blood pushing against artery walls when the ventricles are contracting.

The velocity of blood flow slows in the capillaries in association with an increase in total cross-sectional area.

The capillaries perform the transport function of the circulatory system.

In a healthy adult,blood pressure at the union of the vena cavae and right atrium is about 80 mm Hg.

In electrocardiography,only the contraction of the cardiac muscle causes a deflection.

The difference between systolic and diastolic pressures is termed pulse pressure.

Stroke volume and systolic discharge mean the same thing.

Heart sounds are made by the closing of AV and semilunar valves.

If the stroke volume remains constant,parasympathetic stimulation of the heart will cause an increase in cardiac output.

Because the ECG is not a direct measure of contraction,an ECG deflection could be recorded without the actual contraction of the heart muscle occurring.

A larger than normal U wave could indicate a high level of potassium in the blood.

In an ECG,both the deflections themselves and the interval between deflections can provide information about the electrical conduction through the heart.

During the normal cardiac cycle,there is never a time when both the atria and ventricles are relaxed.

A U wave on an ECG is an indication of damage to ventricular myocardial cells.

The normal rhythm of the heart is set by the ectopic pacemaker.

The stress-relaxation effect occurs in all blood vessels but is most important in the arteries.

The P wave is named as such because it measures a positive deflection in the ECG.

Parasympathetic control of the heart depends on the glossopharyngeal nerve (cranial nerve IX).

Velocity of blood is relatively constant as blood flows from the aorta toward the capillaries.

Exercise has little effect on cardiac output.

The conduction system of the heart is composed of specialized motor neurons that are embedded in the heart muscle.

Blood vessels can hold much more blood than is present in the body.

If a pulse were taken at the popliteal and dorsalis pedis arteries at the same time,it would be felt at the popliteal artery first.

Anger and fear have opposite effects on the heart rate.

Bleeding that occurs at a relatively slow,steady rate would indicate that the damaged blood vessel is most likely a vein.

Blood viscosity is caused by both red blood cells and the protein concentration of the blood.

The "pump" of the "respiratory pump" that moves blood to the central veins is the diaphragm.

Local vasodilation or reactive hyperemia can be caused by the release of endothelin by the blood vessels.

Venous valves would not be necessary in the jugular veins of the neck.

Hemodynamics is the term used to describe a collection of mechanisms that influence the active and changing circulation of the blood.

Osmotic pressure tends to move plasma out of the capillary and into the tissues.

The Fick law of the heart says that,within limits,the longer the heart fibers are at the beginning of a contraction,the stronger the contraction will be.

As the elasticity of the artery wall decreases,the magnitude of the pulse wave increases.

Because the circulatory system is a closed system filled with fluid,the pulse wave is felt at the same time in any part of the body.

The AV node of the heart is known as the pacemaker.

The first Korotkoff sound indicates the diastolic blood pressure.

Because of their small diameter,capillaries account for almost all the resistance to blood flow in the circulatory system.

As the action potential enters the AV node by way of the internodal bundles,the speed of the conduction increases to stimulate ventricular contraction.

As arterial blood pressure decreases,the number of impulses from the carotid baroreceptors to the medulla decreases.

The arterial pulse is caused by the ventricles of the heart; the venous pulse is caused by the atria of the heart.

Hydrostatic pressure tends to decrease from the arterial end of the capillary to the venous end of the capillary.

An increase in arterial blood pressure causes an increase in parasympathetic impulses to the heart and blood vessels.