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Cardiac catheterization is the passage of a catheter through peripheral arteries or veins into cardiac chambers, the pulmonary artery, and coronary arteries and veins. Cardiac catheterization can be used to do various tests, including angiography, intravascular ultrasonography, measurement of cardiac output (CO), detection and quantification of shunts, endomyocardial biopsy, and measurements of myocardial metabolism. These tests define coronary artery anatomy, cardiac anatomy, and cardiac function to establish diagnoses and help select treatment. Cardiac catheterization is also the basis for several therapeutic interventions.
Procedure
Patients must be npo for 4 to 6 h before cardiac catheterization. Most patients do not require overnight hospitalization.
Left heart catheterization is most commonly used to assess coronary artery anatomy; it is also useful for assessing aortic BP and systemic vascular resistance, aortic and mitral valve function, and left ventricular (LV) pressure and function. The procedure is done by percutaneous femoral, radial, or brachial artery puncture, with a catheter passed into the coronary artery ostia or across the aortic valve into the LV. Catheterization of the left atrium (LA) and LV is occasionally done using transseptal perforation during right heart catheterization.
Right heart catheterization is most commonly used to assess right atrial (RA), right ventricular (RV), and pulmonary artery pressure and pulmonary artery occlusion pressure (PAOP—see Fig. 1: Cardiovascular Tests and Procedures: Diagram of the cardiac cycle, showing pressure curves of the cardiac chambers, heart sounds, jugular pulse wave, and the ECG. ; and see Approach to the Critically Ill Patient: Pulmonary artery occlusion pressure (PAOP)); PAOP approximates LA and LV end-diastolic pressure. In seriously ill patients, PAOP helps assess volume status and, with simultaneous measurements of CO, can help guide therapy. Right heart catheterization is also useful for assessing pulmonary vascular resistance, tricuspid or pulmonic valve function, intracardiac shunts, and RV pressure. Right heart pressure measurements may help in the diagnosis of cardiomyopathy, constrictive pericarditis, and cardiac tamponade when noninvasive testing is nondiagnostic. The procedure is done by femoral, subclavian, internal jugular, or antecubital vein puncture. A catheter is passed into the RA, through the tricuspid valve, into the RV, and across the pulmonary valve into the pulmonary artery (see Approach to the Critically Ill Patient: Procedure). Selective catheterization of the coronary sinus can also be done.
Specific Tests During Cardiac Catheterization
Angiography:
Injection of radiopaque dye into coronary or pulmonary arteries, the aorta, and cardiac chambers is useful in certain circumstances. Digital subtraction angiography is used for nonmoving arteries and for chamber cineangiography.
Coronary angiography via left heart catheterization is used to evaluate coronary artery anatomy in various clinical situations, as in patients with suspected coronary atherosclerotic or congenital disease, valvular disorders before valvular replacement, or unexplained heart failure.
Pulmonary angiography via right heart catheterization is used to diagnose pulmonary embolism. Intraluminal filling defects or arterial cutoffs are diagnostic. Radiopaque dye is usually selectively injected into one or both pulmonary arteries and their segments. Computed tomographic pulmonary angiography (CTPA) has largely replaced right heart catheterization for diagnosis of pulmonary embolism.
Aortic angiography via left heart catheterization is used to assess aortic regurgitation, coarctation, patent ductus arteriosus, and dissection.
Ventriculography is used to visualize ventricular wall motion and ventricular outflow tracts, including subvalvular, valvular, and supravalvular regions. It is also used to estimate severity of mitral valve regurgitation severity and determine its pathophysiology. After LV mass and volume are determined from single planar or biplanar ventricular angiograms, end-systolic and end-diastolic volumes and ejection fraction can be calculated.
Intravascular ultrasonography:
Miniature ultrasound transducers on the end of coronary artery catheters can produce images of coronary vessel lumina and walls and delineate blood flow. This technique is being increasingly used at the same time as coronary angiography.
Tests for cardiac shunts:
Measuring blood O2 content at successive levels in the heart and great vessels can help determine the presence, direction, and volume of central shunts. The maximal normal difference in O2 content is 0.5 mL/dL between the pulmonary artery and RV, 0.9 mL/dL between the RV and RA, and 1.9 mL/dL between the RA and superior vena cava. If the blood O2 content in a chamber exceeds that of the more proximal chamber by more than these values, a left-to-right shunt at that level is probable. Right-to-left shunts are strongly suspected when LA, LV, or arterial O2 saturation is low (≤ 92%) and does not improve when pure O2 (fractional inspirational O2
= 1.0) is given. Left heart or arterial desaturation plus increased O2 content in blood samples drawn beyond the shunt site on the right side of circulation suggests a bidirectional shunt.
Measurement of cardiac output and flow:
CO is the volume of blood ejected by the heart per minute (normal at rest: 4 to 8 L/min). Techniques used to calculate CO include the Fick, indicator-dilution, and thermodilution techniques (see Table 2: Cardiovascular Tests and Procedures: Cardiac Output Equations ).
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Table 2
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| Cardiac Output Equations |
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Fick technique
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Numerator is O2 absorbed by lungs (mL/min).
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Indicator-dilution technique
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Denominator is the sum of dye concentrations (C) at each time interval (t).
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Thermodilution technique
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TB – TI is the difference between body and injectate temperatures; injectate is usually dextrose or saline. Denominator is the sum of changes in temperature at each time interval (t).
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SaO2
= arterial O2 saturation (%); SvO2
= mixed venous O2 saturation (%), measured in the pulmonary artery.
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With the Fick technique, CO is proportional to O2 consumption divided by arteriovenous O2 difference.
Dilution techniques rely on the assumption that after an indicator is injected into the circulation, it appears and disappears proportionately to CO.
Usually, CO is expressed in relation to BSA as the cardiac index (CI) in L/min/m2 (ie, CI = CO/BSA—see Table 3: Cardiovascular Tests and Procedures: Normal Values for Cardiac Index and Related Measurements). BSA is calculated using DuBois height (ht)-weight (wt) equation:
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Table 3
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| Normal Values for Cardiac Index and Related Measurements |
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Measurement
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Normal Value
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SD
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O2 uptake
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143 mL/min/m2*
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14.3
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Arteriovenous O2 difference
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4.1 dL
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0.6
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Cardiac index
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3.5 L/min/m2
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0.7
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Stroke index
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46 mL/beat/m2
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8.1
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Total systemic resistance
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1130 dynes-sec-cm-5
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178
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Total pulmonary resistance
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205 dynes-sec-cm-5
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51
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Pulmonary arteriolar resistance
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67 dynes-sec-cm-5
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23
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*Varies with body mass index.
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SD = standard deviation.
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Adapted from Barratt-Boyes BG, Wood EH: Cardiac output and related measurements and pressure values in the right heart and associated vessels, together with an analysis of the hemodynamic response to the inhalation of high oxygen mixtures in healthy subjects. Journal of Laboratory and Clinical Medicine 51:72–90, 1958.
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Endomyocardial biopsy:
This procedure helps assess transplant rejection and myocardial disorders due to infection or infiltrative diseases. The biopsy catheter (bioptome) can be passed into either ventricle, usually the right. Three to 5 samples of myocardial tissue are removed from the septal endocardium. The main complication, cardiac perforation, occurs in 0.3 to 0.5% of patients; it may cause hemopericardium leading to cardiac tamponade.
Coronary artery flow measurements:
Coronary angiography shows the presence and degree of stenosis but not the functional significance of the lesion (ie, how much blood flows across the stenosis). Extremely thin guidewires are available with pressure sensors or Doppler flow sensors. Data from these sensors can be used to estimate blood flow, which is expressed as fractional flow reserve (FFR). FFR is the ratio of maximal flow through the stenotic area to normal maximal flow; an FFR of < 0.75 to 0.8 is considered abnormal. These flow estimates correlate well with the need for intervention and long-term outcome; lesions with good FFR do not seem to benefit from stenting. These flow measurements are most useful with intermediate lesions (40 to 70% stenosis) and with multiple lesions (to identify those that are clinically most significant).
Contraindications
Relative contraindications to cardiac catheterization include
Complications
Injection of radiopaque dye produces a transient sense of warmth throughout the body in many patients. Tachycardia, a slight fall in systemic pressure, an increase in CO, nausea, vomiting, and coughing may occur. Serious complications (eg, cardiac arrest, anaphylactic reactions, shock, seizures, cyanosis, renal toxicity) are rare. Rarely, bradycardia occurs when a large amount of dye is injected; asking the patient to cough often restores normal rhythm. Patients with a high Hct are susceptible to thrombosis; the Hct should be < 65% before angiography is done. Allergic reactions may include urticaria and conjunctivitis, which usually respond to diphenhydramine 50 mg IV. Bronchospasm, laryngeal edema, and dyspnea are rare reactions; they are treated with inhaled albuterol or epinephrine 0.3 to 0.4 mL sc. Anaphylactic shock is treated with epinephrine and other supportive measures. If the catheter tip contacts the ventricular endocardium, ventricular arrhythmias commonly occur, but ventricular fibrillation is rare. If it occurs, direct current (DC) cardioversion is administered immediately (see Cardiac Arrest: Defibrillation). Radiopaque dyes, all hypertonic, are excreted by the kidneys and may worsen renal insufficiency. For patients at risk, infusion of normal saline IV reduces this risk.
Mortality rate is 0.1 to 0.2%. MI (0.1%) and stroke (0.1%) may result in significant morbidity. Incidence of stroke is higher in patients > 80 yr. Dissection of a coronary artery can complicate angiography. Local vascular injury at the peripheral insertion site of catheterization can cause hemorrhage or formation of pseudoaneurysms or arteriovenous fistulas.
Last full review/revision December 2012 by Michael J. Shea, MD
Content last modified January 2013
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