Anatomy and Function of the Heart • Overview: Double Pump • Goal: Push blood through vessels • Atria and Ventricles, Heart Valves, Great Vessels • Fetal Circulation • Cardiac Muscle and Heart Attacks • Control of Heart Rhythm Larry M. Frolich, Ph.D., Yavapai Col
26
Embed
Anatomy and Function of the Heart Overview: Double Pump Goal: Push blood through vessels Atria and Ventricles, Heart Valves, Great Vessels Fetal Circulation.
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Transcript
Anatomy and Function of the Heart
• Overview: Double Pump• Goal: Push blood through vessels • Atria and Ventricles, Heart Valves, Great Vessels• Fetal Circulation• Cardiac Muscle and Heart Attacks• Control of Heart Rhythm
Larry M. Frolich, Ph.D., Yavapai College
• Pulmonary Circuit: Right side of heart pumps blood to lungs to pick up oxygen
• Systemic Circuit: Left side of heart pumps blood to rest of body to deliver oxygen
• Schematic does not show left/right symmetry for most of circulatory system
Overview—Double Pump
Goal—push blood through vessels to capillaries• Pulmonary circuit—right side of
heart pumps blood through pulmonary arteries to capillaries
• Oxygen diffuses into blood and RBC’s in lungs at alveoli surrounded by capillaries
• Pulmonary veins return blood to left side of heart
• Systemic left side of heart pumps blood through systemic arteries to capillaries
• Oxygen diffuses out of blood and into interstitial fluid around cells making oxygen available for cellular metabolism. This is the grand goal of the circulatory system—where the real action happens
• Besides oxygen, water, glucose and other nutrients are delivered; CO2, waste products are picked up
• Systemic veins return blood to right side of heart
Heart Board Drawing
• Apex• Ventral view—ventricles• Interventricular sulcus—between right and left ventricles• Right ventricle leads right into pulmonary trunk (to lungs)• Left ventricle leads into aorta (to systemic circulation)
emerging behind pulmonary trunk• Auricle of right atrium• Pulmonary veins entering right atrium on posterior
surface• IVC, SVC enter left atrium on posterior surface
Another View
Right Atrium• Receives low O2 veinous
blood from body (return of systemic circulation– Superiorly SVC (superior
vena cava– Inferiorly IVC (inferior vena
cava)– Thin muscular wall
• At atrial systole, the right atrium contracts pushing blood into right ventricle passing through open right A-V valve (tricuspid valve)
• Fossa ovalis is remnant of foramen ovale that shunts fetal blood into left atrium
Right Ventricle• Receives blood passing through
open A-V valve from right atrium• At ventricular systole, the right
ventricle contracts pushing blood into the pulmonary trunk passing through the open right semi-lunar valve (pulmonary valve)
• As the ventricle begins to contract, the blood pushes against the cusps of the A-V valve causing it to snap shut preventing blood from back-flowing into the right atrium (“lub…”)
• The papillary muscles then contract and pull on the chordae tendinae attached to the valve cusps so they don’t get over-extended into the atrium
• As ventricle relaxes into diastole, the right semilunar valve (pulmonary valve) snaps shut keeping blood from back-flowing back into the ventricle (“…dub”)
Left Atrium• Receives high O2 veinous
blood from lungs (return of systemic circulation– Pulmonary veins—2 from
left lung, 2 from right lung• At atrial systole, the left
atrium contracts pushing blood into left ventricle passing through open left A-V valve (bicuspid or mitral valve)
Left Ventricle• Receives blood passing through
open A-V valve from left atrium• At ventricular systole, the left
ventricle contracts pushing blood into the aorta passing through the open left semi-lunar valve (aortic valve)
• As the ventricle begins to contract, the blood pushes against the cusps of the A-V valve causing it to snap shut preventing blood from back-flowing into the left atrium (“lub…”)
• The papillary muscles then contract and pull on the chordae tendinae attached to the valve cusps so they don’t get over-extended into the atrium
• As ventricle relaxes into diastole, the left semilunar valve (aortic valve) snaps shut keeping blood from back-flowing back into the ventricle (“…dub”)
Animation of heart and blood flow
• Fetal Circulation• No circulation to lungs—why?
– Foramen ovale shunts blood from right atrium to left atrium
– Ductus arteriosum shunts blood from pulmonary artery to aortic arch
• Circulation must go to placenta– Umbilical aa., vv.
• Come directly off of aorta as it leaves the heart from large high pressure aorta to small left and right coronary arteries
• Heart attack is loss of blood supply to heart muscle
• Blockage usually occurs in first two centimeters of coronary arteries
• Treatment can be angioplasty, stint, bypass
Cardiac Muscle
• Usually 1 nucleus, sometimes several• Much thinner than skeletal muscle (20 um versus 100 um)• Intercalated disks pass action potential from cell to cell—most cells have no direct
motor neuron connection• Energy source is mostly lipids• Calcium to trigger actin-myosin cross-bridge formation and muscle cell contraction
comes from outside cell as part of action potential as well as from sarcoplasmic reticulum
A and P I Tissue Review—3 types of muscle tissue
Control of heart rhythm• Heart receives
visceral motor innervation
– Sympathetic (speeds up)
– Parasympathetic (slows down)
• Input is from chemoreceptors and baroreceptors
Input on blood pressure to brain• Chemoreceptors
– aortic bodies, carotid bodies– Sense CO2, pH, O2
• Barroreceptors– stretch receptors sense blood
pressure pushing on vessel wall – aortic sinus, carotid sinus
Bonus A and P I Review:Cranial Nerve that carries aortic receptor input to brain? Cranial Nerve that carries carotid receptor input to brain?
X. Vagus
IX. Glossopharyngeal
Reflexive output: heart rate• Baro- and chemo-receptor
input arrives to medulla oblongata (A and P I review!)
• Autonomic motor output (A and P I review) to AV node of heart – Sympathetic will speed heart
rate (where do sympathetic neurons originate? What is path to heart?
– Parasympathetic will slow heart (where do parasympathetic neurons originate? What is path to heart?)
• Bonus (common sense physiology!): Will blood vessels constrict or dilate with sympathetic response?
A and P I ReviewSympathetic = “fight or flight” = NE (norepinephrine)Parasympathetic = calming = ACH (acetylcholine)
Electrocardiogram• Surface electrodes
measure sum total of action potentials in cardiac muscle
• Distinct wave forms for atrial, ventricular depolarization
• Intervals as well as wave forms important in interpretation