Cardiac Catheterization, Angiography, IVUS, and FFR

Vijay G. Divakaran, MD, MPH, and Glenn N. Levine, MD

CHAPTER 14

CARDIAC CATHETERIZATION, ANGIOGRAPHY, IVUS, AND FFR 1. W  hat are generally accepted indications for cardiac catheterization? Although recommendations are consistently evolving, those listed here are generally accepted as reasonable indications for cardiac catheterization. Cardiac catheterization is a relatively safe procedure; however, life-threatening complications can rarely occur (see later), so there needs to be a clearly thought out and documented indication for catheterization and a plan for how to use the information obtained during catheterization for patient management. n Class III-IV angina despite medical treatment or intolerance of medical therapy n High-risk results on noninvasive stress testing n Sustained (more than 30 seconds) monomorphic ventricular tachycardia or nonsustained (less than 30 seconds) polymorphic ventricular tachycardia n Sudden cardiac death survivors n Most patients with non–ST-segment elevation acute coronary syndrome (NSTE-ACS) who have high-risk features and no contraindications to early cardiac catheterization and revascularization n Systolic dysfunction and stress testing results suggesting multivessel disease and potential benefit from revascularization n Recurrent typical angina within 9 months of percutaneous coronary revascularization n For assessment of valvular dysfunction or other hemodynamic assessment when the results of echocardiography are indeterminate n As part of primary percutaneous coronary intervention (PCI) for ST-segment elevation my­ocardial infarction (STEMI) n Patients post-STEMI (with or without thrombolytic therapy) with high-risk features, depressed ejection fraction, or high-risk results on subsequent stress testing n Within 36 hours of STEMI in appropriate patients who develop cardiogenic shock n In select patients who are to undergo valve replacement or repair n In assessment and management of patients with congenital heart disease and cardiac transplant recipients 2. W  hat are the risks of cardiac catheterization? The risks of cardiac catheterization will depend to some extent on the individual patient. For “all comers,” the risk of death is approximately 1 in 1000, with the risk of myocardial infarction or stroke rarer than 1 in 1000. The risk of any major complication in “all comers” is less than 1%. These risks are summarized in Table 14-1. 3. H  ow are coronary lesions assessed? Coronary lesions are most commonly assessed in day-to-day practice based on subjective visual impression (Fig. 14-1). Lesions are subjectively given a percent stenosis, ideally based on ocular assessment of at least two orthogonal images of the lesion. Studies have shown interobserver and intraobserver variability in judging coronary stenosis from as little as 7% to as much as 50%. Quantitative coronary angiography (QCA) more objectively assesses the lesion severity than does “ocular judgment,” but is not commonly used in day-to-day practice. QCA generally grades lesions as less severe than does subjective ocular judgment of a lesion’s severity. Intravascular ultrasound (IVUS) can more accurately assess the total plaque burden and severity of a lesion than can ocular

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judgment or QCA. Fractional flow reserve (FFR) is increasingly being used to measure the severity of a lesion from a physiologic standpoint (see later). 4. W  hat is considered a “significant” stenosis? The classification of significant stenosis depends on the clinical context and what one considers “significant.” Coronary flow reserve (the increase in coronary blood flow in response to agents that

TABLE 14-1. RISKS OF CARDIAC CATHETERIZATION AND CORONARY ANGIOGRAPHY Complication

Risk (%)

Mortality Myocardial infarction

0.11 0.05

Cerebrovascular accident

0.07

Arrhythmia

0.38

Vascular complications

0.43

Contrast reaction

0.37

Hemodynamic complications

0.26

Perforation of heart chamber

0.03

Other complications

0.28

Total of major complications

1.70

Reproduced from David CJ, Bonow RO: Cardiac Catheterization. In Libby P, Bonow RO, Mann DL, Zipes DP, editors: Braunwald’s heart disease: a textbook of cardiovascular medicine, ed 8, Philadelphia, 2007, Saunders, p 461.

Figure 14-1.  Coronary angiography of the left coronary artery demonstrates an approximate 90% lesion (arrow) in the left coronary artery.

CARDIAC CATHETERIZATION, ANGIOGRAPHY, IVUS, AND FFR lead to microvascular dilation) begins to decrease when a coronary artery stenosis is 50% or more of the luminal diameter. However, basal coronary flow does not begin to decrease until the lesion is 80% to 90% of the luminal diameter. 5. W  hat is fractional flow reserve (FFR)? Physiologic assessment of blood flow through a stenotic lesion can be safely and reliably performed in the catheterization laboratory using a coronary wire with a pressure sensor at its tip. The wire is advanced across the lesion of interest, and the ratio of distal coronary pressure to proximal aortic pressure is assessed after maximal hyperemia is achieved (Fig 14-2). This ratio is called FFR. Normal

Proximal (aortic) pressure Lesion

Lesion

Pressure transducer distal to lesion

A

Proximal (aortic) pressure

Distal coronary pressure FFR = 50 / 90 = 0.55

B

Adenosine administered

Figure 14-2.  Fractional flow reserve. A, An intermediate lesion in the right coronary artery. The pressure wire is advanced distal to the lesion. B, Pressure tracings proximal to and distal to the lesion. There is a notable fall in distal perfusion pressure after administration of adenosine, indicating a hemodynamically significant lesion.

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values are close to 1, and a ratio less than 0.75 to 0.80 is taken as indicating a “physiologically significant stenosis.” Adenosine is typically used as a pharmacologic agent to achieve maximal hyperemia. 6. H  ow is FFR used to guide coronary stenting? In patients with angina, if the “culprit” lesion is visually estimated to be intermediate (50% to 70% stenosis) in severity, FFR may be used to guide management in determining if the lesion is physiologically significant. When evaluating whether a lesion warrants revascularization, use of FFR has been shown to be a clinically useful tool. Revascularization may be safely deferred for lesions with FFR greater than 0.75 to 0.80. If the FFR is less than 0.75, revascularization with percutaneous coronary intervention (PCI) or coronary artery bypass graft (CABG) is appropriate if clinically indicated. 7. D  uring cardiac catheterization, how is aortic or mitral regurgitation graded? For aortic regurgitation, an aortogram is performed in the ascending thoracic aorta above the aortic valve and the amount of contrast that regurgitates into the left ventricle is noted. For mitral regurgitation, a left ventriculogram is performed and the amount of contrast that regurgitates into the left atrium is noted. The systems used to grade the degree of regurgitation are similar for the two valvular abnormalities, and based on a 1+ to 4+ system, where 1+ is little if any regurgitation and 4+ is profound or severe regurgitation. Regurgitation of 3+ or 4+ is often considered “surgical” regurgitation, although the criteria for surgery are more complex than this (see Chapters 30 and 31 on aortic valve disease and on mitral valve disease, respectively). Table 14-2 summarizes the grading of regurgitant lesions as assessed by cardiac catheterization and “ballpark” regurgitant fractions for each degree of regurgitation. 8. W  hat is thrombolysis in myocardial infarction (TIMI) flow grade? TIMI flow grade is a system for qualitatively describing blood flow in a coronary artery. It was originally derived to describe blood flow down the infarct-related artery in patients with STEMI.

TABLE 14-2. VISUAL ASSESSMENT OF VALVULAR REGURGITATION AND APPROXIMATE CORRESPONDING REGURGITANT FRACTION*

Visual Appearance of Regurgitation

Designated Grading (Severity) of Valvular Approximate Corresponding Regurgitation Regurgitant Fraction

Minimal regurgitant jet seen. Clears rapidly from proximal chamber with each beat. Moderate opacification of proximal chamber, clearing with subsequent beats.

1+

<20%

2+

21% to 40%

Intense opacification of proximal chamber, becoming equal to that of the distal chamber.

3+

41% to 60%

Intense opacification of proximal chamber, becoming more dense than that of the distal chamber. Opacification often persists over the entire series of images obtained.

4+

>60%

*These regurgitant fraction values are dependent on numerous factors and should be taken only as rough estimates. Modified from David CJ, Bonow RO: Cardiac Catheterization. In Libby P, Bonow RO, Mann DL, Zipes DP, editors: Braunwald’s heart disease: a textbook of cardiovascular medicine, ed 8, Philadelphia, 2007, Saunders, p 458.

CARDIAC CATHETERIZATION, ANGIOGRAPHY, IVUS, AND FFR Reportedly, it was originally written down on a napkin or the back of an envelope during an airplane flight. The grades are based on observing contrast flow down the coronary artery after injection of the contrast agent, and are as follows: n TIMI grade 3: normal contrast (blood) flows down the entire artery n TIMI grade 2: contrast (blood) flows through the entire artery but at a delayed rate compared with flow in a normal (TIMI grade 3 flow) artery n TIMI grade 1: contrast (blood) flows beyond the area of vessel occlusion but without perfusion of the distal coronary artery and coronary bed n TIMI grade 0: complete occlusion of the infarct-related artery 9. W  hat is IVUS? IVUS is the direct assessment of coronary arterial wall using a flexible catheter with a miniature ultrasound probe at its tip. Upon insertion into the coronary artery, IVUS provides true cross-sectional images of the vessel, delineating the three layers of the vessel wall (Fig 14-3). IVUS may aid in the assessment of coronary stenosis, plaque morphology, and optimal stent expansion when angiographic imaging is inadequate or indeterminate. 10. W  hat are the different methods of describing the aortic transvalvular gradient in a patient undergoing cardiac catheterization for the evaluation of aortic stenosis? Three terms used to describe the gradient are illustrated in Figure 14-4 and are: n Peak instantaneous gradient: the maximal pressure difference between the left ventricular pressure and aortic pressure assessed at the exact same time n Peak-to-peak gradient: the difference between the maximal left ventricular pressure and the maximal aortic pressure n Mean gradient: the integral of the pressure difference between the left ventricle and the aorta during systole

Artery wall

Plaque

Lumen

Figure 14-3.  Intravascular ultrasound (IVUS) demonstrating plaque occluding greater than 60% of the arterial lumen. Coronary angiography had demonstrated only mild narrowing in this segment of coronary artery.

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CARDIAC CATHETERIZATION, ANGIOGRAPHY, IVUS, AND FFR

ECG

Peak-to-peak 47

200 Peak instantaneous 100

mm Hg

108

Mean 60

100

LV

Ao

Figure 14-4.  Various methods of describing the aortic transvalvular gradient. Ao, Aorta; ECG, electrocardiogram; LV, left ventricle. (From Bashore TM: Invasive cardiology: principles and techniques, Philadelphia, 1990, BC Decker, p 258.)

11. W  hich patients should be premedicated to prevent allergic reactions to iodinebased contrast agents? In patients with a history of prior true allergic reaction (e.g., hives, urticaria, or bronchoconstriction) to iodine-based contrast agents, the risk of repeat anaphylactoid reaction to contrast agents is reported to be 17% to 35%. Such patients should be premedicated before angiography. The standard regimen is 50 mg of prednisone orally (PO), 13 hours, 7 hours, and 1 hour before the procedure, and 50 mg PO of diphenhydramine 1 hour before the procedure, although a regimen of 60 mg PO of prednisone the night before and morning of the procedue, along with 50 mg PO of diphenhydramine the morning of the procedure, is also used by some. The 2011 American College of Cardiology Foundation/American Heart Association/Society for Cardiovascular Angiography and Interventions (ACCF/AHA/SCAI) guidelines do not consider allergy to fish or shellfish an indication for steroid pretreatment. 12. W  hat are the major risk factors for contrast nephropathy? Preexisting renal disease and diabetes are the two major risk factors for the development of contrast nephropathy. The risk of contrast nephropathy is also related to the amount of iodine-based contrast used during the catheterization procedure. Preprocedure and postprocedure hydration is the most established method of reducing the risk of contrast nephropathy. The 2011 ACCF/AHA/SCAI PCI guidelines suggest a regimen of isotonic crystalloid (e.g., normal saline) 1.0 to 1.5 ml/kg/hr for 3 to 12 hours before the procedure and continuing for 6 to 24 hours after the procedure. Those same guidelines conclude that treatment with N-acetylcysteine does not reduce the risk of contrast nephropathy and is not indicated. Measures of other treatments to decrease the risk of contrast nephropathy, such as sodium bicarbonate infusion or ultrafiltration, have produced heterogeneous and conflicting data. 13. W  hat are the major vascular complications with cardiac catheterization? In general, major vascular complications are uncommon with diagnostic cardiac catheterization and more common with PCI, which may require larger sheath placement, venous sheath placement, and more intense or prolonged anticoagulation. Nevertheless, practitioners and patients should be aware of the following potential vascular complications: n Retroperitoneal hematoma: This should be suspected in cases of flank, abdominal, or back pain, with unexplained hypotension, or with a marked decrease in hematocrit. Diagnosis is by computed tomography (CT) scan.

CARDIAC CATHETERIZATION, ANGIOGRAPHY, IVUS, AND FFR

n

n

n

n

P seudoaneurysm: A pseudoaneurysm results from the failure of the puncture site to seal properly. Pseudoaneurysm is a communication between the femoral artery and the overlying fibromuscular tissue, resulting in a blood-filled cavity. Pseudoaneurysm is suggested by the finding of groin tenderness, palpable pulsatile mass, or new bruit in the groin area. Pseudoaneurysm is diagnosed by Doppler flow imaging. Arteriovenous (AV) fistula: An AV fistula can result from sheath-mediated communication between the femoral artery and the femoral vein. AV fistula is suggested by the presence of a systolic and diastolic bruit in the groin area. Diagnosis is confirmed by Doppler ultrasound. Stroke: Periprocedural stroke is a rare but morbid complication of cardiac catheterization, and is often associated with unfavorable neurologic outcome. A proportion of strokes may be due to disruption and embolization of atherosclerotic material from the aorta during the procedure. Cholesterol emboli syndrome: This is a rare and potentially catastrophic complication that results from plaque disruption in the aorta, with distal embolization into the kidneys, lower extremities, and other organs.

14. W  hat are vascular closure devices? Vascular closure devices are hemostatic devices that obviate the need for prolonged compression at the arterial access site following angiography. These devices decrease the duration of bed rest and afford earlier mobility after the procedure. Vascular closure devices have not been convincingly demonstrated to decrease the risk of vascular complications, including bleeding. 15. W  hat is the difference between radial and femoral access in cardiac catheterization? Left heart catheterization and coronary angiography are commonly performed using catheters inserted through either the femoral or radial arteries. Radial access is associated with a lower incidence of vascular complications such as bleeding. 16. W  hat is intracardiac echo (ICE)? ICE is the direct imaging of cardiac structures via transvenous insertion of a miniaturized echo probe. Most commonly, the device is inserted via the femoral vein and threaded up to the right atrium. ICE is used to visualize the interatrial septum and fossa ovalis, aiding with transseptal puncture, percutaneous treatment of atrial septal defect (ASD) or patent foramen ovale (PFO), and during electrophysiologic procedures, and imaging the fossa ovalis and pulmonary veins.

BIBLIOGRAPHY, SUGGESTED READINGS, AND WEBSITES 1. Boudi FB: Coronary artery atherosclerosis. Available at: www.emedicine.medscape.com. Accessed November 30, 2012. 2. Carrozza JP: Complications of diagnostic cardiac catheterization. In Basow DS, editor: UpToDate, Waltham, MA, 2013, UpToDate. Available at: www.uptodate.com. Accessed March 26, 2013. 3. Levine GN, (chair), Bates ER, Blankenship JC, et al: 2011 ACCF/AHA/SCAI Guideline for Percutaneous Coronary Intervention. 2011 ACCF/AHA/SCAI Guideline for percutaneous coronary intervention: executive summary: a report of the American College of Cardiology Foundation/American Heart Association Task Force on Practice Guidelines and the Society for Cardiovascular Angiography and Interventions, Circulation 124:2574–2609, 2011. 4. Levine GN, Kern MJ, Berger PB, et al: Management of patients undergoing percutaneous coronary revascularization, Ann Intern Med 139:123–136, 2003. 5. Kern MJ: The cardiac catheterization handbook, ed 4, St. Louis, 2011, Mosby. 6. Scanlon PJ, Faxon DP, Audet AM, et al: ACC/AHA guidelines for coronary angiography, J Am Coll Cardiol 33:1756–1824, 1999.

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