This case demonstrates a casuistically rare form of association between fibromuscular dysplasia of the coronary arteries and pulmonary artery atresia.
FMD is a rare disease with a variety of pathological changes in the affected arteries and all cases require detailed investigation. Analysis of individual cases is very important for explanation of the general pathological concepts. The aim of our researсh was to analyze a rare case of fibromuscular dysplasia of the coronary arteries and compare it with the literature.
A child was born via spontaneous vaginal delivery with a birth weight of 3400 g and body length of 51 cm. The Apgar score was 8. After birth, the childs condition became worse. We detected muscular hypotonia, hyporeflexia, cyanosis, and a rough systolic murmur at the second left intercostal space. With each passing hour, the signs of heart failure increased. On the second day of life, the child died.
Clinical diagnosis of the cyanotic congenital heart defect was tetralogy of Fallot and transposition of main vessels.
Necropsy examination revealed central cyanosis. The heart weighed 40 g (normal weight - 21 g); there was a spherical heart shape due to left ventricular dilatation. The volume of the right heart chambers were less than half of the left. Over the course of the coronary arteries, there were multiple rounded protrusions that resembled a string of beads; their diameter ranged from 0.3 to 1.0 cm. The largest protrusion originated from the proximal left anterior descending coronary artery, the smallest from the posterior descending artery. The protrusions were formed by a significantly thick and dense wall with marked narrowing of the coronary artery lumen. The largest protrusion, 1.0 cm, represented an aneurysm with a lumen diameter of 0.5 cm and wall thickness of 0.25 cm. In serial cross-sections of the myocardium, we intramural vessels with a dense white wall. The oval window was covered by a thin, tense membrane that formed the valve that opened into the left atrium. In the right ventricle, the access to the pulmonary artery was absent. The mouth of the pulmonary artery was replaced by dense light gray tissue. A narrow blind end of the trunk of the pulmonary artery was located 0.5 cm above the atrioventricular ring. The pulmonary artery expanded gradually and branched typically. Other arteries were formed correctly.
Histopathological study of the coronary arteries revealed pronounced vascular wall fibrosis that formed a cushion and dramatically narrowed the star-shaped lumen. We determined smooth muscle cell hyperplasia in the subintimal layer and pronounced proliferation of collagen fibers in the intima and media. The connective tissue in the adventitia and periadventitia formed muff-like structures (Figure 1A,B). The distribution of the layers missing in the vascular wall presented an array of disparate elastic fibers with multiple fragmentations, lysis and hypochromia. The periadventitia was separated by hyperchromic elastic fibers and presented beams of the arranged collagen fibers (Figure 2A,B). The aneurysm was constructed of dense irregular connective tissue structures - multidirectional collagen fibers and numerous thin hypochromic and split elastic fibers (Figure 3). In other sections the aneurysm, the wall was twisted and irregularly thickened (Figure 4). Intramural arteries of the heart presented a muff-like form of periadventitia fibrosis, and hyperplasia of muscle fibers in the media (Figure 5). The myocardium presented fragmentation in the cardiomyocytes, contractures and interstitial edema.
Pathology diagnosis of the congenital heart defect was pulmonary artery atresia and fibromuscular dysplasia of the coronary arteries with multiple aneurysms.
Development of FMD in infants has been described extremely rarely. It is known that FMD is a disease of women aged 40-60 years. In this case, we can think of innate disease, proven by the combination of FMD and congenital heart defect in a newborn baby. Some cases of FMD in twins and family members have been published[8,19]. Some studies
noted the combinations of FMD and pheochromocytoma[20], ergotism, α1-antitrypsin deficiency syndrome, Ehlers- Danlos syndrome type IV[21], Alport syndrome[4], cystic medionecrosis, Marfan syndrome, and coarctation of the aorta[22]. There was no family history or other factors of the disease in the described case.
FMD of the coronary arteries typically manifests as dissection with the development of ischemic complications. Aneurysms as a complication of FMD are often described mainly in the kidney, gastric and splenic artery[1,3,4-6]. In this case, the coronary arteries revealed no evidence of dissection.
In this case, the pathological changes implicate all layers of the coronary arteries walls and spread to periadventitia. The pathological classification scheme for fibromuscular lesions proposed by Harrison and McCormack in 1971[2,23] and supplemented by Stanley et al. (1975)[24] is based on the arterial layer intima, media, or adventitia in which the lesion predominates. Intimal fibroplasia occurs in less than 10 percent of patients with arterial fibrodysplasia[23,24]. Angiographically, it may appear as a focal, concentric stenosis; a long, smooth narrowing similar to that seen in large-artery vasculitides such as giantcell arteritis or Takayasus arteritis[3]; or a redundancy of the artery. Medial fibroplasia, which is characterized by its classic string of beads appearance, represents the most common dysplastic lesion[23,24]. Typically, the beading is larger than the normal caliber of the artery and is located in the middle-to-distal portion of the artery. Histologically, there is involvement of the media, whereas the intima, internal elastic lamina, and adventitia are preserved. The lesion of perimedial fibroplasia is characterized by a homogeneous collar of elastic tissue at the junction of the media and the adventitia. The elastic elements of the media and intima appear normal. Perimedial fibroplasia is diagnosed when focal stenoses and, occasionally, multiple constrictions are observed, often with a robust collateral network. The beads are usually less numerous than in medial fibroplasia and are typically smaller in diameter than the normal caliber of the artery Medial hyperplasia accounts for less than 1 percent of arterial stenoses and may be indistinguishable angiographically from intimal fibroplasia[25]. Adventitial (periarterial) hyperplasia is the rarest type of fibrodysplastic lesion[23,24]. Although there is currently limited angiographic information, sharply localized, tubular areas of stenosis have been observed.
We have described changes in the coronary arteries that did not fit any of the above-mentioned types of FMD. It can be interpreted as combination of four types of fibroplasia: intimal, medial, adventitial and periarterial. This phenomenon has not yet been described in any review of FMD.
Another feature of the case is affection of the coronary arteries of a different caliber from the main trunk to intramural branches. FMD of the coronary arteries was not a major factor of thanatogenesis. Child death was caused by a severe congenital heart defect incompatible with life.
In conclusion, the feature of this case is casuistically rare form of a combination between fibromuscular dysplasia involving the coronary arteries and congenital heart defect - pulmonary artery atresia. This case demonstrates innate FMD and presents a total coronary artery lesion with the formation of aneurysms.
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