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Understanding Adult Hemodynamics Theory, Monitoring, Waveforms and Medications Vicki Clavir RN Purpose The primary purpose of invasive hemodynamic monitoring is the early detection, identification, and treatment of life-threatening conditions such as heart failure and cardiac tamponade. By using invasive hemodynamic monitoring the nurse is able to evaluate the patient's immediate response to treatment such as drugs and mechanical support. The nurse can evaluate the effectiveness of cardiovascular function such as cardiac output, and cardiac index. Objectives Understands basic cardiac anatomy Verbalizes determinates of Cardiac Output and their relationships to each other List indications for hemodynamic monitoring Demonstrates monitor system and set up Describe pharmacologic strategies that manipulate the determinates of cardiac output Indications for Hemodynamic Monitoring: One of the obvious indications for hemodynamic monitoring is decreased cardiac output. This could be from dehydration, hemorrhage, G. I. bleed, Burns, or surgery. All types of shock, septic, cardiogenic, neurogenic, or anaphylactic may require invasive hemodynamic monitoring. Any deficit or loss of cardiac function: such as acute MI, cardiomyopathy and congestive heart failure may require invasive hemodynamic monitoring. Coronary Arteries Left Main RCARA, RV&LV Inf, Inf Septum SA node 65% AV node 80% PDA 80-90% CXLA,LV (side/back) SA node 40% AV node 20% LAD – LV (front/bottom) Septum Bundle branches Cardiac Cycle Diastole Phase Early Diastole Ventricles relax. Semilunar valves close. Atrioventricular valves open. Ventricles fill with blood. Mid Diastole Atria and Ventricles are relaxed. Semilunar valves are closed. Atrioventricular valves are open. Ventricles continue to fill with blood. Late Diastole SA node contracts. Atria contract. Ventricles fill with more blood. Contraction reaches AV node. Cardiac Cycle Systole Phase Systole Contraction passes from AV node to Purkinje fibers and ventricular cells. Ventricles contract. Atrioventricular valves close. Semilunar valves open. Blood is pumped from the ventricles to the arteries. Cardiac Cycle Electrical Conduction system SA node Atrial muscle Internodal fibers AV node AV bundle right and left bundle branches Ventricular muscle Autonomic Nervous System The autonomic nervous system stimulates the heart through a balance of sympathetic nervous system and parasympathetic nervous system innervations. – The sympathetic nervous system plays a role in speeding up impulse formation, thus increasing the heart rate – The parasympathetic nervous system slows the heart rate. The Cardiac Cycle The Cardiac Cycle • Coronary Arteries Fill The Cardiac Cycle The Cardiac Cycle Normal CO 4-8 liters Normal Cardiac Index is 2.5 to 4.5 liters Heart Rate Works with Stroke Volume Compensatory Tachycardia Bradycardia Dysrhythmias Factors Causing Low Cardiac Output Inadequate Left Ventricular Filling – Tachycardia – Rhythm disturbance – Hypovolemia – Mitral or tricuspid stenosis – Pulmonic stenosis – Constrictive pericarditis or tamponade – Restrictive cardiomyopathy Inadequate Left Ventricular Ejection – Coronary artery disease causing LV ischemia or infarction – Myocarditis, cardiomyopathy – Hypertension – Aortic stenosis – Mitral regurgitation – Drugs that are negative inotropes – Metabolic disorders Hemodynamic terms Preload- Stretch of ventricular wall. Usually related to volume. (how full is the tank?) – Frank Starling’s Law Hemodynamic terms Increased preload seen in – Increased circulating volume (too much volume) – Mitral insufficiency – Aortic insufficiency – Heart Failure – Vasoconstrictor use- (dopamine) Decreased Preload seen in – Decreased circulating volume (bleeding,3rd spacing) – Mitral stenosis – Vasodilator use ( NTG) – Asynchrony of atria and ventricles Increased Preload Decreased preload Normal Value - 2-8 mm Hg Or LVEDP PAOP = 8-12 mm Hg PAD = 10-15 mm Hg Hemodynamic terms Contractility- – How well does the ventricular walls move? How good is the pump? – Decreased due to Drugs – certain drugs will decrease contractility –Lido, Barbiturates, CCB, Betablockers Infarction, Cardiomyopathy Vagal stimulation Hypoxia Hemodynamic terms Contractility- – Increased Positive inotropic drugs –Dobutamine, Digoxin, Epinephrine Sympathetic stimulation –Fear, anxiety Hypercalcemia ( high calcium) CONTRACTILITY PRECAUTIONS Do Not use Inotropes until volume deficiency is corrected Correct Hypoxemia and electrolyte imbalance. Hemodynamic terms Afterload – resistance the blood in the ventricle must overcome to force the valves open and eject contents to circulation. X Y Hemodynamic terms Factors that increase afterload are – Systemic resistance or High Blood pressure – Aortic stenosis – Myocardial Infarcts / Cardiomyopathy – Polycythemia – Increased blood viscosity Hemodynamic terms Factors – – – – that decrease Afterload Decreased volume Septic shock- warm phase End stage cirrhosis Vasodilators Normal PVR is 120 to 200 dynes Normal SVR - 800-1200 dynes Mean Arterial Pressure MAP is considered to be the perfusion pressure seen by organs in the body. It is believed that a MAP of greater than 60 mmHg is enough to sustain the organs of the average person under most conditions. If the MAP falls significantly below this number for an appreciable time, the end organ will not get enough blood flow, and will become ischemic. Calculated MAP = 2x diastolic + systolic 3 EKG 1.PRELOADvenous blood return to the heart Controlled by; ♥.Blood Volume PRBC’s Albumin Normal Saline Diureticslasix,bumex Thiazides Ace inhibitors ♥. Venous Dilation Nitroglycerine Ca+ channel blockers clonidine (Catapress) methyldopa trimethaphan (arfonad) ↓ Dobutamine Morphine Drugs of Hemodynamics 2. CONTRACTILITYforcefulness of contractility Ca+ channel blockers Digoxin Dopamine/Dobutamine Milrinone/amrinone 3.AFTERLOAD – work required to open aortic valve and eject blood – resistance to flow in arteries ° Dopamine (at higher doses) Ace inhibitors Nipride/lesser extent Nitro Calcium channel blockers Labetalol 4. HEART RATE – 1. Beta blockers 2. Calcium channel blockers 3. Atropine 4. Dopamine 5. Dobutamine O2 O2 O2 • Factors that make up SVO2 are • Cardiac output • SaO2 • VO 2 (oxygen consumption) • Hemoglobin Causative Factors O2 Delivery Hb concentration Oxygen saturation (SaO2) Clinical Conditions - Anemia - Hemorrhage - Hypoxemia - Cardiac Output Lung disease Low FIO2 - LV dysfunction (cardiac disease, drugs) - Shock – cardiac/septic (late) - Oxygen consumption Hypovolemia Cardiac Dysrhythmias Fever, infection - Seizures, agitation - Shivering - Work of Breathing - Suctioning, bathing, repositioning - Increased SVO2 Most common cause is - Sepsis Or Wedged PA catheter Functions of PA Catheter Allows for continuous bedside monitoring of the following – Vascular tone, myocardial contractility, and fluid balance can be correctly assessed and managed. – Measures Pulmonary Artery Pressures, CVP, and allows for hemodynamic calculated values. – Measures Cardiac Output. (Thermodilution) – SvO2 monitoring (Fiber optic). – Transvenous pacing. – Fluid administration. PA Catheter RED KEEP COVERED KEEP LOCKED BLUE Clear YELLOW Markings on catheter. 1. Each thin line= 10 cm. 2. Each thick line= 50 cm. Description of PA Catheter Ports/lumens. CVP Proximal (pressure line - injectate port PA for CO)-BLUE Distal (Pressure line hook up)- Yellow Extra port - usually- Clear Thermistor – Red Cap Continuous Cardiac Output and SVO2 monitoring Indications for PA catheter The pulmonary artery catheter is indicated in patients whose cardiopulmonary pressures, flows, and circulating volume require precise, intensive management. MI – cardiogenic shock - CHF Shock - all types Valvular dysfunction Preoperative, Intraoperative, and Postoperative Monitoring ARDS, Burns, Trauma, Renal Failure PRESSURE TRANSDUCER SYSTEMS SET UP 500 ml Premixed Heparinized bag of NS PHLEBOSTATIC REFERENCE POINT Angles 45° 30° 0° ♥ Re-level the transducer with any change in the patient’s position ♥Referencing the system 1 cm above the left atrium decreases the pressure by 0.73 mm Hg ♥Referencing the system 1 cm below the left atrium increases the pressure by 0.73 mm Hg Remove cap and keep sterile Turn stopcock towards pressure bag Zero monitor Replace cap SQUARE WAVE TEST - Determines the ability of the transducer to correctly reflect pressures. - Perform at the beginning of each shift A B C Thermodilution Cardiac Outputs Cardiac Outputs reading should be within .5 of each other for averaging purposes. Except in patients with atrial fibrillation- just average 3 to 4 readings. (due to loss of atrial kick output changes from minute to minute) Cardiac Outputs should be obtained at the end of respiration - at the same point each time ARTERIAL WAVEFORM RN magazine April, 2003 - PA catheter refresher course. ALL PA measurements are calculated at end expiration because the lungs are at their most equal (negative vs. positive pressures) a, c,& v Waves and their Timing to the ECG tracing RA WAVEFORM RV WAVEFORM 22 4 Ventricular PAP DOCUMENTATION Measure at end expiration Measure pressures from a graphic tracing Measure pulmonary capillary wedge pressure at end-expiration using the mean of the a wave a wave indicates atrial contraction and falls within the P – QRS interval of the corresponding ECG complex PAW WAVEFORM WITH MECHANICAL VENTILATION PAOP/PAWP Pressure Safety Points Watch monitor during inflation and stop when you see PAOP waveform Never inject more than 1.5 ml of air or any fluid into PA port Don’t keep balloon inflated longer than 15 seconds When completed - Allow air to passively exit the balloon OVERWEDGE COMPLICATIONS OF PA CATHETER ☹ Infection ☹ Electrocution (Microshock) ☹ Ventricular Arrhythmias (Vtach.,Vfib., Cardiac Arrest) ☹ Atrial Dysrhythmias, RBBB ☹ Knotting and misplacement ☹ Hemo or Pneumothorax ☹ Cardiac valve trauma COMPLICATIONS OF PA CATHETER ☹ Catheter thromboembolism or air embolism ☹ Dissection or Laceration of subclavian artery or vein ☹ Cardiac Tamponade ☹ Pulmonary infarction ☹ Pulmonary artery injury or rupture ☹ Balloon rupture ☹ Hematoma Trouble Shooting Dampened Waveform – Flush catheter – Check transducer system for air bubbles Blood in Tubing – Look for open Stopcock – Put 300mgHg pressure in pressure bag Stuck in Wedge /PWP – Very slowly and gently pull back catheter until you see PA waveform References Pulmonary Artery Catheter Education Project @ www.pacep.org sponsored by – American Association of Critical Care Nurses American Association of Nurse Anesthetists American College of Chest Physicians American Society of Anesthesiologists American Thoracic Society National Heart Lung Blood Institute Society of Cardiovascular Anesthesiologists Society of Critical Care Medicine Hemodynamics Made Incredibly Visual – LWW publishing 2007 AACN practice alert – Pulmonary Artery Pressure Monitoring - Issued 5/2004 Handbook of Hemodynamic Monitoring – G Darovic 2nd ed. TCHP Education Consortium 2005 – A Primer for Cardiovascular Surgery and Hemodynamic Monitoring Nursebob's MICU/CCU Survival Guide-Hemodynamics in Critical Care -Hemodynamic Monitoring Overview 12/04/00