Week 10 Flashcards
Define ischemic. What causes myocardial ischemia?
Ischemic: tissue with deficient oxygen supply because of inadequate blood flow (reduced, not blocked. blocked = infarct)
Most common cause of myocardial ischemia is atherosclerosis of the coronary arteries. Inadequacy of blood flow is relative to tissues metabolic requirement, so sufficient flow may be possible at rest but not when stressed by exercise or emotion! Increased sympathoadrenal system = high heart rate and blood pressure = high oxygen requirement. Mental stress can constrict arteries by damaged endothelium which normally prevents constriction
What is angina pectoris? what drugs relieve this condition?
Substernal (chest) pain that may be referred to the left arm and shoulder. This is a result of myocardial ischemia that increases blood lactic acid (produced by anaerobic metabolism). Nitroglycerin (dynamite!) produces vasodilation to improve heart circulation and decreases ventricle work.
What happens when myocardial cells perform anaerobic respiration for more than a few minutes?
They cannot metabolize anaerobically for very long and prolonged ischemia causes necrosis. This sudden and irreversible injury is a myocardial infarction (heart attack). The damage is permanent as myocardial cells do not divide to replace dead cells. Noncontractile scar tissue forms at the infarct
What greater threat occurs AFTER a myocardial infarction?
Reperfusion injury. After heart becomes re-perfused with blood, larger numbers of cells die by apoptosis due to Ca2+ accumulation and production of superoxide free radicals. This leads to a great increase in the size of the infarct and weakens ventricle walls to become thin and distend under pressure
What is the effect of a myocardial infarction on an ECG?
Ischemia results in depression of the ST segment
Atherosclerotic plaques that induce thrombi, that totally block coronary artery, causes elevated ST segment
What tests would be performed to confirm presence of a myocardial infarction?
Rise in troponin I in blood (primary test!)
Creatine phosphokinase MB (CPK-MB) in blood
lactate dehydrogenase (LDH) in blood
What is the term for abnormal heart rhythms? Term for fast and slow and what normally causes each?
Arrhythmia = abnormal heart rythm (detected by ECG).
Tachycardia = faster than 100 bpm. Sympathetic nervous system during exercise or emergencies.
Bradycardia = slower than 60 bpm. Athlete’s Bradycardia result of parasympathetic inhibition of SA node.
What can cause abnormal tachycardia?
Fast pacing by the atria (e.g. drugs) and abnormally fast ectopic pacemakers
Paraoxysmal Supraventricular Tachycardia (SVT) is sporadic tachycardia that originates in the atria and produces fast heartbeat. Often treated with adenosine
Ventricular Tachycardia is when ectopic pacemakers in the ventricles are abnormally fast and cause rapid beating independent of atria. This can quickly lead to ventricular fibrillation and death.
Define flutter and fibrillation. What is the result of fibrillation in each chamber?
Flutter = coordinated rapid contractions quickly degenerates into Fibrillation = uncoordinated rapid contractions (danger!)
Atrial fibrillation makes atria ineffectual, but since ventricles fill 80% of end-diastolic volume before atrial contraction, atria fibrillation only reduces cardiac output by about 15%. The main concern is thrombi formation leading to stroke (Eddie currents have low oxygen and lead to clotting)
Ventricular fibrillation will cause death in a few minutes due to inability to pump blood and deliver oxygen to the brain/heart. Fibrillation culminates in Asystole (cessation of beating)
Normal treatment for atrial fibrillation is _______ but an alternative to drug therapy is ______
Antithrombitic and anti arrhythmia drugs, such as Warfarin
Percutaneous catheter ablation. Destroys atrial tissue around the pulmonary veins (usual source of electrical abnormality) and electrically separates this area from the surrounding tissue of the left atria
What causes ventricular fibrillation?
Circus Rhythms: continuous recycling of electrical waves. Normally prevented by refractory period of entire myocardium, but chaotic electrical activity messes this up. Focal Excitation occurs when a region outside the SA node is damaged and spontaneously depolarizes. Reentry is when an action potential can be continuously regenerated and conducted along a pathway (like around a scar) not in a refractory phase. An external shock (like a wall outlet!) in the middle of the T wave also causes fibrillation
Describe how fibrillation can be stopped
Electrical Defibrillation: electric shock depolarizes all of the myocardial cells at the same time, causing them to enter refractory state. Circus rhythms stop and SA node (hopefully) starts up normal rhythm again.
Implantable Converter-defibrillator can be implanted in a patient to detect when ventricular fibrillation occurs and deliver defibrillating shocks.
Three basic functions of lymphatic system
Transports interstitial fluid back to the blood (eventually draining in left/right subclavian veins)
Transport absorbed fat from small intestine to blood
Provide immunological defense via lymphocytes
What is fluid called once it enters the lymphatic capillaries? where is the fluid carried?
Lymph. From merging lymphatic capillaries, lymph is carried into larger lymphatic vessels called lymph ducts. The ducts empty into the thoracic duct or the right lymphatic duct which then drain into the left and right subclavian veins. Lymph is filtered through lymph nodes and then returns to the cardiovascular system.
Describe the structure of lymph ducts. How do they move fluid?
Walls have same three layers and valves as veins. Fluid is moved by peristaltic waves of contraction and by contraction of skeletal muscle. Peristaltic waves are produced by smooth muscle in the lymph ducts that contain a pacemaker that initiates action potentials and entry of Ca2+, stimulating contraction. This action increases in response to stretch of the vessel.
What is contained in the lymph nodes and lymphoid organs? name the lymphoid organs.
Lymph nodes contain phagocytic cells which remove pathogens and germinal centers to produce new lymphocytes. Tonsils, thymus, and spleen are the lymphoid organs and also contain germinal centers for lymphocyte production.
What harmful process can the lymphatic system cause? What symptom would this produce in the lymph nodes?
The lymphatic system may also help transport cancer cells and help cancer spread or metastasize. Lymph nodes are hard and not painful if cancerous. If lymph nodes are painful and swollen, that is infection.
What determines cardiac output and what is the cardiac output of each ventricle? What is total blood volume and how does that relate to the cardiac output?
Cardiac output is the volume of blood pumped peer minute and is equal to stroke volume x cardiac rate. Normal output is 5.5 L per minute in each ventricle. Output of the right and left needs to be the same, but since right (pulmonary) is a shorter circulation it has low resistance, low pressure, and high blood flow compared to systemic circulation
Total blood volume averages 5.5 L, therefore each ventricle pumps a total blood volume each minute! It takes a minute for a drop of blood to complete the systemic and pulmonary circuits.
What regulates the cardiac rate and when does this regulation occur?
Sympathetic (in atrial musculature, not SA node) and parasympathetic innervations (in SA node) which are continuously active to some degree.
(nor)Epinephrine bind Beta 1 adrenergic receptors to stimulate cAMP production and activate HCN and Ca2+ channels of pacemaker cells to increase diastolic depolarization = faster cardiac rate.
Vagus nerve releases acetylcholine to bind muscarinic receptors and open K+ channels, countering the inward Na+ diffusion and slowing diastolic depolarization = slower cardiac rate. Vagus is always active and keeps rate slower than the 90-100 bpm that it would be without vagus. Vagus = main rate determiner
What is the name for mechanisms that influence cardiac rate?
chronotropic effect. Increase in rate is a positive chronotropic effect (sympathetic innervation) and decrease in rate is a negative chronotropic effect (parasympathetic innervation)
What controls autonomic innervation of the heart?
the Cardiac Control Center in the medulla oblongata. This is in turn affected by higher brain areas and by sensory feedback from pressure receptors called Baroreceptors in the aorta and carotid arteries. Through this, a fall in blood pressure can produce an increase in heart rate
What three variables determine stroke volume
- End Diastolic Volume (EDV): the volume of blood in the ventricles at the end of diastole (before systole) also called the *Preload (workload imposed prior to contraction). Directly proportional to stroke volume
- Total Peripheral Resistance: frictional resistance or impedance to blood flow in the Arterioles. Presents impedance after ventricle contracts and is thus called an *Afterload. Inversely proportional to stroke volume
- Contractility: strength of ventricular contraction. Directly proportional to stroke volume
What causes increased total peripheral resistance? What is the effect on the heart if total peripheral resistance is high?
High arterial blood pressure = high total peripheral resistance. Can be caused by lots of things, such as vasoconstriction in the cold or atherosclerosis.
Result is an increased after load and decrease in stroke volume. Ih healthy people, ventricles will compensate by increasing contraction strength. Inability to compensate will lead to congestive heart failure
**Explain what the Frank-Starling Law of the Heart is
Strength of ventricular contraction is directly related to the end-diastolic volume. Even when the heart is removed from the body, there is still a built-in, intrinsic, property of the heart that will increase contraction strength if EDV is increased. This is one of the mechanisms for intrinsic control of contraction strength
**What are the 3 mechanisms for intrinsic control of contraction strength (ensures that contraction strength and stroke volume increase when needed)
(maybe 4? I’m not convinced the fourth is actually something different)
- Frank-Starling Law: as EDV rises so does contraction strength. High EDV causes myocardium to be increasingly stretched so actin filaments overlap with myosin only at the edges of A bands. This increases interactions between actin and myosin = more force for contraction. (unlike skeletal muscles!! resting is not ideal length)
- Stretching causes increased RyR2 sensitivity = more Ca2+ release = stronger contraction
- Anrep effect: increased NCX activity = increase Ca2+ gradually
(4. Stretched cardiac muscle is more sensitive to Ca2+)
Explain how the heart adjusts to a rise in total peripheral resistance
Rise in peripheral resistance causes decrease in stroke volume. More blood remains in ventricle and EDV is greater for the next cycle. The ventricle is stretched to a greater degree in the next cycle and contracts more strongly to eject more blood.
What effects the rate at which atria and ventricles are filled with blood?
Total blood volume and (more importantly) venous pressure. Venous pressure is the driving force for the return of blood to the heart. Venous return occurs because pressure is highest in venules and lowest at the venae cavae (at right atrium) and the pressure difference promotes blood flow to the heart. Sympathetic nerve activity (stimulates smooth muscle contraction), the skeletal muscle pump, and the respiratory pump also aid venous return.
What does compliance mean? Which vessels have greater compliance and what is the result of that characteristic? What names are given to vessels with high/low capacitance
Compliance means that pressure will cause increased distention or expansion. Veins have thinner, less muscular walls and have a higher compliance, meaning they can hold more blood. *Two thirds of total blood volume is in the veins!
Veins are thus capacitance vessels and arterioles are resistance vessels
Review the distribution of fluid in the body. *What determines distribution of water in/out tissues?
two thirds is intracellular
one third is extracellular
Of the extracellular fluid, 80% is in tissues (interstitial fluid) and 20% is in blood plasma
Blood pressure causes fluid to move from plasma to interstitial while Osmotic forces draw water from tissues to vascular system
