Ch 22 heart

carry blood away from the heart

carry blood back to the heart

arteries and veins entering and leaving the heart

Heart valves

force of blood pushing against the inside walls of blood vessels (contraction & relaxation)

-right side of heart pumping deoxygenated blood through pulmonary arteries to lungs

-pulmonary veins carry blood to left side of heart

•Left side pumps oxygenated blood through systemic arteries to body’s cells

•Exchange nutrients, respiratory gases and wastes

•systemic veins-back to the right side of the heart

-left of midline, deep to the sternum, in mediastinum

•Right border more anteriorly

-Base of the heart: mainly the left atrium

-Superior border: great arterial vessels and superior vena cava

-Apex: inferior conical end

-Inferior border: right ventricle

-tough sac enclosing heart

-Restricts heart movements, within the thorax

•Fibrous pericardium: tough outer sac

•Serous pericardium: composed of parietal and visceral layers

•Pericardial cavity: space between serous pericardium containing serous fluid

Epicardium: visceral layer of serous pericardium and areolar connective tissue

Myocardium: cardiac muscle; thickest

Endocardium: internal surface chambers; simple squamous epithelium and areolar connective tissue

-two superior, smaller atria. (atrium singular)

-two inferior, larger ventricles

form from Anterior part of each atrium

•Blood passes from right atrium to right ventricle, pulmonary trunk, pulmonary circulation

•Blood passes from left atrium to left ventricle, aorta, systemic circulation

groove separating atria and ventricles

between the right and left ventricles

Two atrioventricular (AV) valves

Two semilunar valves at base of great arteries

Dense regular connective tissue between the atria and ventricles

- structural support

- electrical insulator

systemic circulation through three large veins:

•Superior vena cava

•Inferior vena cava

•Coronary sinus

1. divides left & right atrium

2. ridges on internal atrial wall

3. (tricuspid valve): one-way flow from right atrium to right ventricle

'right atrium

receives deoxygenated blood from right atrium

1. thick wall between right and left ventricles

2. Inner wall of each ventricle, irregular muscular ridges

'right ventricle

cone-shaped, attach to chordae tendineae (attach to atrioventricular valve, prevent cusps flipping when ventricle contracts)

'right ventricle

connects anterior papillary muscle of right ventricle to atrioventricular septum

'right ventricle

smooth funnel near top of right ventricle going to pulmonary semilunar valve (ensure 1 way flow from ventricle to pulmonary trunk)

'right ventricle

Oxygenated blood from lungs travels through pulmonary veins

opening between left atrium and ventricle

- bicuspid (two flap) or mitral valve

•shut when the left ventricle contracts

through entire systemic circulation

•Very high pressure

Aortic semilunar valve: controls flow from left ventricle to aorta

Left ventricular wall is typically three times thicker than the right

travel within coronary sulcus and supply heart wall with oxygen and nutrients

•Branch off ascending aorta just superior to aortic semilunar valve

Right marginal artery: supplies right border

Posterior interventricular artery: supplies posterior surfaces of left & right ventricles

Anterior interventricular artery: aka left anterior descending artery; supplies anterior surface of both ventricles and most of the interventricular septum

Circumflex artery: supplies the left atrium and ventricle

3 major cardiac veins drain into the coronary sinus, which drains into the right atrium

Great cardiac vein: anterior interventricular artery

Middle cardiac vein: posterior interventricular artery

Small cardiac vein: close to the right marginal artery

Same: striated with extensive capillary networks

•Less SR quantity and organization

•No terminal cisternae

•Less contact between SR and T-tubules

all connected with gap junctions

•Gap junctions are parts of intercalated discs between adjacent fibers

•Each electrical impulse is distributed immediately and spontaneously throughout the myocardium

initiates its own heartbeats

consists of specialized cells that start and propagate electrical impulses to contractile cells

-begins at the sinoatrial (SA) node (heart’s pacemaker)

-travels via gap junctions to left atrium and atrioventricular (AV) node on the floor of right atrium

•AV node delaying activation of ventricles as they fill with blood

-enters the atrioventricular (AV) bundle (bundle of His), interventricular septum

-AV bundle divides into left and right bundles (bundle branches)

- to Purkinje fibers that begin at the heart apex

posterior wall of right atrium adjacent to the opening of the superior vena cava

superiorly from the apex to all of the ventricular myocardium

is a composite tracing electrical impulses

•P wave: atrial depolarization

•QRS complex: ventricular depolarization (and atrial repolarization)

•T wave: ventricular repolarization

Heart is innervated by sympathetic and parasympathetic divisions of the autonomic nervous system

•does not initiate a heartbeat, but it can increase or decrease the rate of the heartbeat

neurons in T1–T5 spinal cord

•Preganglionic axons enter sympathetic trunk and synapse on ganglionic neurons

•Postganglionic axons project from cervical and thoracic ganglia and travel to the heart via cardiac nerves

- increases rate and force of heart contractions

-neurons in the medulla oblongata vagus nerves (CN X)

• decreases heart rate but no effect on force of contraction

cardiac cycle -time from start of one heartbeat to the start of the next. contraction and relaxation

•Contraction: systole

•Relaxation: diastole

1.Atrial contraction and ventricular filling

2.Isovolumic contraction—occurs at beginning of ventricular contraction

3.Ventricular ejection

4.Isovolumic relaxation—occurs at beginning of ventricular relaxation

5.Atrial relaxation and ventricular filling

-Decreased tissue elasticity with age often impairs heart valve function

-Decreased efficiency of heart’s conducting system can impair ability to pump extra blood needed during stress

-High blood pressure increases work required of heart and can lead to problematic hypertrophy of myocardium

Begins during Week 3

•Heart tubes form and fuse

Primitive heart is beating by day 22

Sinus venosus- becomes Superior vena cava, coronary sinus, smooth posterior wall of right atrium

Primitive atrium-Anterior muscular portions of left and right atria

Primitive ventricle-Most of left ventricle

Bulbus cordis

Trabeculated part of right ventricle- Most of right ventricle

Conus cordis-Outflow tracts from ventricles to aorta and pulmonary trunk

Truncus arteriosus-Ascending aorta, pulmonary trunk