Interventional Cardiology. Группа авторов

Interventional Cardiology - Группа авторов


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4.6 This 80‐year‐old obese female was admitted for angiography following a recent worsening of angina. She had a previous history of myocardial infarction. Preceding this presentation her angina symptoms had been stable for many years and were not previously investigated with angiography. A coronary ostium could not be engaged at the left aortic sinus. The left anterior descending (LAD), circumflex, and right coronary arteries originated from a single right‐sided ostium. The right coronary artery (RCA) (black arrows, a–d) was occluded distally. The left anterior descending (LAD) (white arrows, a–c) was critically stenosed proximal to a large diagonal and the circumflex (gray arrows, b–d) was critically stenosed in its mid course. The catheter partially obscures the LAD in (a) and the circumflex in (d).

Schematic illustration of these views were taken during primary angioplasty performed in a 41-year-old male who presented with an acute inferolateral myocardial infarction. Schematic illustration of optimal angiographic views for specific segments in the circumflex and right coronary are indicated with a green tick mark. Schematic illustration of 47-year-old male with known coronary disease presented with deteriorating angina and reversible ischemia in the anterior territory on perfusion imaging.

      Once the anomalous coronary vessel has been intubated the standard views are often sufficient for the mid and distal vessel if the heart has a normal position and orientation (Figures 4.2 and 4.3), while the views for the proximal vessel and ostium may need to be modified depending on the origin and course.

      Knowledge of ventricular function is essential to interpret the clinical relevance of coronary disease and planning appropriate treatment. Many patients have a contemporary assessment of left ventricular function by non‐invasive testing, which provides similar or superior definition of the left ventricular cavity volume and global and regional wall motion, with the advantage that most of them can also dynamically study wall thickness and tissue characteristics (echocardiography, magnetic resonance imaging, nuclear imaging) when attending for coronary angiography [1]. These modalities provide more information on the function and morphology of the left ventricle than conventional ventriculography and can obviate the need for further assessment. Ventriculography should be performed in the catheter laboratory if left ventricular function has not been assessed recently. The RAO view is standard, although an additional LAO view could be considered if assessment of the postero‐lateral wall, usually supplied by the circumflex, is likely to influence management.

      The guidelines for management of heart transplant recipients consider coronary angiography the gold standard method to detect cardiac allograft vasculopathy, which ranges from 42% at 5 years to 50% at 10 years. These patients do not experience typical angina due to the the denervation of the transplanted heart [9].

      In patients with orthotopic heart transplant the coronary angiography is technically difficult due to the presence of the aortotomy with anomalous implantation of the coronary ostia and to the position of the allograft. A transfemoral approach is usually preferred and its superiority was confirmed in a small, randomized study. [10]

       Interactive multiple choice questions are available for this chapter on www.wiley.com/go/dangas/cardiology

      References

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      2 2 Secco GG, Agostoni PF. Coronary interventions: 5F versus 6F to 7F. In: Bertrand O, Rao S. (eds) Best Practice for Transradial Approach in Diagnostic Angiography and Intervention. Wolters Kluwer: 2015.

      3 3 Israeli Z., Lavi S., Pancholy S.B., et al. Radial versus femoral approach for saphenous vein grafts angiography and interventions. Am Heart J 2019 Apr; 210:1–8

      4 4 Cha KS, Kim MH. Feasibility and safety of concomitant left internal mammary arteriography at the setting of the right transradial coronary angiography. Catheter Cardiovasc Interv 2002; 56(2):188–195.

      5 5 Akpinar I, Sayin MR, Karabag T, et al. Differences in sex, angiographic frequency, and parameters in patients with coronary artery anomalies: single‐center screening of 25 368 patients by coronary angiography. Coron Artery Dis 2013; 24:266–271.

      6 6 Yuksel S, Meric M, Soylu K, et al. The primary anomalies of coronary artery origin and course: a coronary angiographic analysis of 16,573 patients. Exp Clin Cardiol 2013; 18:121–123.

      7 7 Earls JP. Coronary artery anomalies. Tech Vasc Interv Radiol. 2006 Dec; 9(4):210–7.

      8 8 Angelini P, Uribe C. Anatomic spectrum of left coronary artery anomalies and associated mechanisms of coronary insufficiency. Catheter Cardiovasc Interv. 2018 Aug 1; 92(2):313–321

      9 9 Kittleson MM. and Kobashigawa JA. Cardiac Transplantation Current Outcomes and Contemporary Controversies. JACC: Heart Failure 5:12, December 2017

      10 10 Scalone G, Brugaletta S, Martín‐Yuste V, et al. RAndomized Comparison of raDIal vs. femorAL Access for Routine Catheterization of Heart Transplant Patients (RADIAL‐heart transplant study). Transplant Proc. 2014 Dec; 46(10):3262–7

      11 11 Lowry RW, Bitar JN, Grinstead WC, et al. Heterotopic heart transplantation: catheterization, endomyocardial biopsy,


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