Anatomy and Physiology I - Chapter 10
Cardiac Muscle Tissue
- Striated (striped), branching, and 1 nucleus per cell. - Have specialized junctions between cells called intercalated discs. - Have absolute refractory period, stays aerobic.
Cardiac Cycle
A complete heartbeat consisting of contraction and relaxation of both atria and both ventricles. Right and left atria go through systole and diastole together at the same time and ventricles also work together with each other.
Pericardium
A fluid-filled, double-walled membrane surrounding the heart. Makes up the pericardial sac (parietal pericardium) and epicardium (visceral pericardium).
Atrial Systole
After the SA node fires, the atria depolarize and contract together, creating a decrease in volume and higher pressure in the atria than the ventricles. The increase in pressure pushes blood through AV valves into the ventricles. Pressure of the blood from atria's contracting forces the AV valves to open.
Pericardial sac (parietal pericardium)
Anchors the heart to great vessels (aorta and venae cavae), the posterior wall of the thorax, sternum and diaphragm. Has a tough outer fibrous layer that does not allow for expansion.
Brachial Artery
Artery typically used in measuring blood pressure.
Atrial Diastole
Atria repolarize and relax, elastic fibers in the walls of the atria return to shape, volume increases and pressure decreases. Blood pressure in the superior and inferior venae cavae and pulmonary veins is greater than in the atria, causing blood to rush into the right and left atria.
Four phases of the cardiac cycle
Atrial Systole, Atrial Diastole, Ventricular Systole, and Ventricular Diastole.
Tendinous Chords
Attaches cusps of AV valves to the papillary muscle, anchoring the valves to the muscle.
Aortic Valve
Blood is forced through this valve when leaving the left ventricle.
Left Ventricle
Blood leaves the left atrium and enters this chamber of the heart.
Pulmonary Valve
Blood leaves the right ventricle through this valve.
Left Atrium
Blood returns from the lungs to this structure within the heart.
Pulmonary Circulation
CO2 is unloaded, O2 is loaded.
Deoxygenated Blood
Carbon dioxide-rich/Oxygen-poor blood that enters the right atrium of the heart from the superior and inferior venae cavae.
Angina Pectoris
Cardiac disorder characterized by heaviness or pain in the chest caused by temporary or reversible myocardial ischemia.
Myocardial Infarction
Cardiac disorder characterized by the death of myocardial tissue due to ischemia.
Atherosclerosis
Cardiovascular disorder characterized by the buildup of fatty deposits with in arterial walls.
Venous Return
Causes blood to move through the veins back to the heart. Aided by pressure gradient, gravity, thoracic pump, cardiac suction, and skeletal muscle pump.
Tunica Interna
Composed of simple squamous epithelial tissue and fibrous tissue, very smooth and secretes a chemical to repel platelets so blood can flow easily through the vessel.
Systole
Contraction of the heart.
Negative Chronotropic Effect
Decreases heart rate. Example includes potassium.
Epicardium (visceral pericardium)
Delicate layer composed of simple squamous epithelial tissue over loose areolar connective tissue, in direct contact with the surface of the heart.
Intercalated Discs
Enable fast transmission of electrical impulses from one cell to another.
Heart Rate x Stroke Volume
Equation used to calculate cardiac output. (Ex: HR 115 beats/min x Stroke Volume of 95 = 10,925 ml/min)
Effects of aging and hypertension on the Cardiovascular System
Increased vascular resistance, decreased stroke volume, and thicker, less elastic vessels prone to atherosclerosis.
Positive Chronotropic Effects
Increases heart rate. Examples are Caffeine, norepinephrine, epinephrine, nicotine, and thyroid hormone.
Pulse Pressure
Indicates a surge of pressure that small arteries must withstand with each ventricular contraction. Determined by the equation systolic pressure minus diastolic pressure. Increases as stroke volume increases.
Endocardium
Inner lining of the four chambers of the heart, composed of simple squamous epithelial tissue over loose areolar connective tissue.
Conducting Arteries
Largest of the arteries, carry blood away from the heart, have a thicker tunica media. Include the pulmonary arteries, common carotid, and aorta
Systematic Circulation
O2 is unloaded, CO2 is loaded
Ventricular Systole
Once the conduction system has carried out electrical impulses from the AV node to purkinje fibers, ventricles depolarize and contract together. Papillary muscles also contract pulling on the tendinous cords to ensure AV valves stay closed and prevent backflow to the atria. Contraction of the ventricles decrease volume and increase pressure in the ventricles, causing blood to be pushed through the pulmonary and aortic valves.
Semilunar Valves
Pulmonary and Aortic Valves
Diastole
Relaxation of the heart.
Pulmonary Veins
Returns blood from the lungs to the heart.
Tunica Externa
Serves as an anchor for vessels to surrounding tissue, and provide passage for nerves and small vessels supplying blood to the external wall.
Capillaries
Smallest of all blood vessels. Allow the exchange of fluids and other materials between tissue and blood.
Resistance Arteries
Smallest of the arteries. Examples are arterioles
Sinoatrial (SA) Node
Structure located in the right atrium that starts a heartbeat, sends an electrical impulse to stimulate the atria to contract. Considered the "pacemaker" of the heart.
Atrioventricular (AV) Bundle
Structure that carries the electrical impulse from the AV node toward the apex of the heart.
Purkinje Fibers
Structure that fans out from the end of the AV bundle to the wall of the ventricles.
Coronary Sulcus
Structure that marks the separation of the atria from the ventricles.
Atrioventricular (AV) Node
Structure that sends the electrical impulse to stimulate the ventricles to contract.
Interatrial Septum
Structure that separates the right and left atria.
Interventricular Septum
Structure that separates the right and left ventricles.
Pulmonary Trunk
Structure that takes blood from the right ventricle to the lungs to pick up oxygen.
Aorta
Structure that takes oxygenated blood from the heart to the rest of the body.
Chronotropic Factor
Term used to describe anything that changes the heart rate.
Vagal Tone
Term used to describe the ability of the autonomic nervous system to control the pace of the SA node through the vagus nerve.
Cardiac Output
Term used to describe the amount of blood ejected by each ventricle each minute.
Stroke Volume
Term used to describe the amount of blood ejected from the ventricle per beat. Affected by preload, contractility, and afterload.
Preload
Term used to describe the amount of tension in the myocardium of the ventricular walls.
Cardiac Reserve
Term used to describe the difference between the cardiac output of the heart at rest and the maximum cardiac output the heart can achieve.
Frank Starling Law of the Heart
Term used to describe the fact that the heart must pump out the amount of blood it receives.
Afterload
Term used to describe the pressure in the pulmonary trunk and aorta during diastole.
Ectopic Focus
Term used when any other part of the conduction system other than the SA node is setting the pace of the heart.
Heart -> Arteries -> Capillaries -> Veins
The correct sequence of vessels that blood travels as it leaves the heart
120/72 mm/Hg
The normal blood pressure for a 20-30 year old.
Pulmonary Arteries
The pulmonary trunk splits into this structure, taking blood to the lungs, where it absorbs oxygen and drops off carbon dioxide.
Right and Left Ventricles
Two inferior chambers of the heart, pump blood out of the heart.
Right and Left Atria
Two superior chambers of the heart, receive blood.
Atrioventricular (AV) Valves
Type of valve that separates the atria from the ventricles.
Bicuspid (Mitral) Valve
Valve that lies between the left atrium and the left ventricle. Blood leaves the left atrium and passes through this valve to the left ventricle.
Tricuspid Valve
Valve that lies between the right atrium and the right ventricle. Blood leaves the right atrium and passes through this valve to the right ventricle.
Ventricular Diastole
Ventricles repolarize and relax, elastic fibers in ventricle walls return ventricles to shape, and increase volume and decrease pressure in the ventricles. Pressure is now higher in the atria, causing blood to move through AV valves from the atria to the ventricles.
Arteries
Vessels that carry blood away from the heart.
Veins
Vessels that carry blood towards the heart. Have valves to prevent backflow of blood.
P Wave
Wave on the ECG that shows depolarization of the atria.
T Wave
Wave on the ECG that shows repolarization of the ventricles.
P, Q, R, S, and T waves
Waves on an ECG.
Q, R, and S Waves
Waves on the ECG that shows depolarization of the ventricles.
