Objective: To assess magnetic resonance imaging (MRI) features of coronary microembolization in a swine model induced by small-sized microemboli, which may cause microinfarcts invisible to the naked eye.
Materials and Methods: Eleven pigs underwent intracoronary injection of small-sized microspheres (42 μm) and catheter coronary angiography was obtained before and after microembolization. Cardiac MRI and measurement of cardiac troponin T (cTnT) were performed at baseline, 6 hours, and 1 week after microembolization. Postmortem evaluation was performed after completion of the imaging studies.
Results: Coronary angiography pre- and post-microembolization revealed normal epicardial coronary arteries. Systolic wall thickening of the microembolized regions decreased significantly from 42.6 ± 2.0% at baseline to 20.3 ± 2.3% at 6 hours and 31.5 ± 2.1% at 1 week after coronary microembolization (p < 0.001 for both). First-pass perfusion defect was visualized at 6 hours but the extent was largely decreased at 1 week. Delayed contrast enhancement MRI (DE-MRI) demonstrated hyperenhancement within the target area at 6 hours but not at 1 week. The microinfarcts on gross specimen stained with nitrobluetetrazolium chloride were invisible to the naked eye and only detectable microscopically. Increased cTnT was observed at 6 hours and 1 week after microembolization.
Conclusion: Coronary microembolization induced by a certain load of small-sized microemboli may result in microinfarcts invisible to the naked eye with normal epicardial coronary arteries. MRI features of myocardial impairment secondary to such microembolization include the decline in left ventricular function and myocardial perfusion at cine and first-pass perfusion imaging, and transient hyperenhancement at DE-MRI.

1 Falk E, "Unstable angina with fatal outcome: dynamic coronary thrombosis leading to infarction and/or sudden death. Autopsy evidence of recurrent mural thrombosis with peripheral embolization culminating in total vascular occlusion" 71 : 699-708, 1985

2 Landis JR, "The measurement of observer agreement for categorical data" 33 : 159-174, 1977

3 Chen ZW, "TNF-α-induced cardiomyocyte apoptosis contributes to cardiac dysfunction after coronary microembolization in mini-pigs" 18 : 1953-1963, 2014

4 Breuckmann F, "Systematic analysis of functional and structural changes after coronary microembolization: a cardiac magnetic resonance imaging study" 2 : 121-130, 2009

5 Hori M, "Role of adenosine in hyperemic response of coronary blood flow in microembolization" 250 (250): H509-H518, 1986

6 Asanuma T, "Relationship between progressive microvascular damage and intramyocardial hemorrhage in patients with reperfused anterior myocardial infarction: myocardial contrast echocardiographic study" 96 : 448-453, 1997

7 Topol EJ, "Recognition of the importance of embolization in atherosclerotic vascular disease" 101 : 570-580, 2000

8 Jeremy RW, "Progressive failure of coronary flow during reperfusion of myocardial infarction: documentation of the no reflow phenomenon with positron emission tomography" 16 : 695-704, 1990

9 Porto I, "Plaque volume and occurrence and location of periprocedural myocardial necrosis after percutaneous coronary intervention: insights from delayed-enhancement magnetic resonance imaging, thrombolysis in myocardial infarction myocardial perfusion grade analysis, and intravascular ultrasound" 114 : 662-669, 2006

10 Kotani J, "Plaque gruel of atheromatous coronary lesion may contribute to the no-reflow phenomenon in patients with acute coronary syndrome" 106 : 1672-1677, 2002

11 Huber AM, "Phase-sensitive inversion-recovery MR imaging in the detection of myocardial infarction" 237 : 854-860, 2005

12 Kellman P, "Phase-sensitive inversion recovery for detecting myocardial infarction using gadolinium-delayed hyperenhancement" 47 : 372-383, 2002

13 Dörge H, "Perfusion-contraction mismatch with coronary microvascular obstruction: role of inflammation" 279 : H2587-H2592, 2000

14 Rodrigues de Avila LF, "Perfusion impairment in patients with normal-appearing coronary arteries: identification with contrast-enhanced MR imaging" 238 : 464-472, 2006

15 Litchfield RL, "Noninvasive tests for cardiac risk stratification. Which ones are most prognostic?" 115 : 30-36, 2004

16 Carlsson M, "Myocardial microinfarction after coronary microembolization in swine: MR imaging characterization" 250 : 703-713, 2009

17 Kaul S, "Microvasculature in acute myocardial ischemia: part II: evolving concepts in pathophysiology, diagnosis, and treatment" 109 : 310-315, 2004

18 Gerber BL, "Microvascular obstruction and left ventricular remodeling early after acute myocardial infarction" 101 : 2734-2741, 2000

19 Carlsson M, "Magnetic resonance imaging quantification of left ventricular dysfunction following coronary microembolization" 61 : 595-602, 2009

20 Saeed M, "MRI quantification of left ventricular function in microinfarct versus large infarct in swine model" 29 : 159-168, 2013

21 Hong Yun, "Isolated Noncompaction of Ventricular Myocardium: a Magnetic Resonance Imaging Study of 11 Patients" 대한영상의학회 12 (12): 686-692, 2011

22 Möhlenkamp S, "Intramyocardial blood volume, perfusion and transit time in response to embolization of different sized microvessels" 57 : 843-852, 2003

23 Jin H, "Influence of applying nitroglycerin in whole-heart free-breathing 3D coronary MR angiography" 194 : 927-932, 2010

24 Henriques JP, "Incidence and clinical significance of distal embolization during primary angioplasty for acute myocardial infarction" 23 : 1112-1117, 2002

25 Carlsson M, "Heterogeneous microinfarcts caused by coronary microemboli: evaluation with multidetector CT and MR imaging in a swine model" 254 : 718-728, 2010

26 Skyschally A, "Glucocorticoid treatment prevents progressive myocardial dysfunction resulting from experimental coronary microembolization" 109 : 2337-2342, 2004

27 West JW, "Effects of selective coronary embolization on coronary blood flow and coronary sinus venous blood oxygen saturation in dogs" 10 : 722-738, 1962

28 Selvanayagam JB, "Effect of distal embolization on myocardial perfusion reserve after percutaneous coronary intervention: a quantitative magnetic resonance perfusion study" 116 : 1458-1464, 2007

29 Heiberg E, "Design and validation of Segment--freely available software for cardiovascular image analysis" 10 : 1-, 2010

30 Carlsson M, "Coronary microembolization causes long-term detrimental effects on regional left ventricular function" 45 : 205-214, 2011

31 Skyschally A, "Coronary microembolization" 101 : 373-382, 2006

32 Edelman RR, "Contrast-enhanced MR imaging of the heart: overview of the literature" 232 : 653-668, 2004

33 Jiang L, "Cardiomyocyte apoptosis is associated with increased wall stress in chronic failing left ventricle" 24 : 742-751, 2003

34 Poon M, "Cardiac magnetic resonance imaging: a “one-stop-shop” evaluation of myocardial dysfunction" 17 : 663-670, 2002

35 Finn JP, "Cardiac MR imaging: state of the technolo" 241 : 338-354, 2006

36 Sakuma H, "Assessment of coronary arteries with total study time of less than 30 minutes by using whole-heart coronary MR angiography" 237 : 316-321, 2005

37 Baumgart D, "Acute plaque rupture and myocardial stunning in patient with normal coronary arteriography" 346 : 193-194, 1995

38 De Bruyne B, "Abnormal epicardial coronary resistance in patients with diffuse atherosclerosis but “Normal” coronary angiography" 104 : 2401-2406, 2001