Primary Vascular Tumors




INTRODUCTION



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Peripheral vascular tumors are rare, yet some physicians encounter patients with these tumors regularly and most physicians encounter them at least several times in the course of their practice. The clinical significance of vascular tumors ranges from trivial to cosmetically and psychosocially burdensome to life threatening. Some have characteristic clinical manifestations while many are found incidentally but have characteristic imaging findings. However, rare lesions and variable clinical presentations can result in delayed or misdiagnosis. This chapter will provide an overview of primary vascular tumors, emphasizing those affecting arteries and capillaries.




CLASSIFICATIONS



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Primary vascular neoplasms are defined as those arising from vascular elements, such as endothelial cells and pericytes. Most involve the microvasculature and manifest in the skin, but others affect deep structures and occasionally manifest in large vessels.



Historically, clinicians and pathologists have used conflicting descriptions and schemes in classifying vascular tumors and vascular malformations (VM). In some cases, different labels have been used to describe the same disease while in other cases the same label has been applied to vastly different diseases.



In 1982, Mulliken and Glowacki1 published a classification system based on endothelial characteristics and biologic behavior, in part to address this confusion (Table 50-1). A subsequent revision of their classification system broadened the category of vascular tumors of infancy to include pyogenic granuloma, tufted angioma, kaposiform hemangioendothelioma (KH), and hemangiopericytoma.2 This revised classification has become the standard for distinguishing hemangiomas from VM and is the official classification schema of the International Society for the Study of Vascular Anomalies.




TABLE 50-1.Classification of Primary Vascular Tumors



Despite the current acceptance of this standard, imprecise terminology remains widespread in the scientific literature.3 Furthermore, pathologists, who are often unaware of a patient’s clinical presentation, still use histopathologic diagnoses and classify vascular lesions by the type of vessel that predominates (arterial, venous, or lymphatic). In contrast, clinicians often make the diagnosis without relying on biopsy or histopathology.




BENIGN NEOPLASMS



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Hemangioma



Hemangiomas are benign tumors of vascular endothelium and, by far, the most common form of primary vascular tumor. They most commonly affect the skin, but can occur in nearly any organ (Table 50-2). Hemangiomas are often without clinical significance, but they can cause complications such as disfigurement, ulceration, bleeding, organ failure, and death. Most hemangiomas present early in life. In some cases, hemangiomas are inherited as part of rare syndromes. Newly diagnosed superficial hemangiomas are uncommon after 30 years of age, but deep hemangiomas are often discovered incidentally in adults during imaging studies.




TABLE 50-2.Distribution of 570 Hemangiomas



Hemangiomas have often been confused with VM.1 The clinical distinction between hemangiomas and VM is not always initially apparent, but the diagnosis usually becomes clear with time. There are several features that distinguish hemangiomas from VM. Hemangiomas are more common in Caucasians than other races, more common in females than males, have early growth that is disproportionate to that of the patient, are composed of immature hyperplastic endothelial cells, have increased numbers of mast cells, and have upregulated expression of proliferative cell markers (see Pathophysiology below) (Table 50-3).




TABLE 50-3.Differentiating Vascular Anomalies



In contrast to hemangiomas: VM have equal sex distribution, are often present and fully formed at birth, grow proportionately with the child, are composed of mature and often combined arterial, venous, or lymphatic vascular elements, have normal numbers of mast cells, have no increase in proliferative cell markers, and unlike hemangiomas, endothelial cells from VM do not grow in tissue culture.



Pathophysiology


Although theories abound, the etiology of hemangiomas and the mechanisms that control their proliferation and involution are not well understood. At least four general theories predominate, as discussed below.



Chorionic Villi. There is strong evidence of a relationship between hemangiomas and placental chorionic villi. The gene expression profiles of hemangiomas and placentae are similar and they share a tissue-specific marker called GLUT-1.4 It has been hypothesized that hemangiomas represent the embolization of placental tissue to the fetus.5 However, contrary to popular belief, it has recently been shown that chorionic villous sampling is probably not a contributing factor to the development of hemangiomas.6



Angiogenesis. Hemangiomas have long been thought to represent a localized derangement of angiogenesis (the growth of new vessels from existing vessels). As evidence for this theory, proliferating hemangiomas have upregulated expression of angiogenic factors, such as vascular endothelial growth factor (VEGF), basic fibroblast growth factor (BFGF), fibroblast growth factor (FGF), and type-IV collagenase.7,8,9 Furthermore, therapy directed at inhibiting angiogenesis, such as corticosteroids and interferons, is often effective in causing involution of hemangiomas.



Vasculogenesis. More recently, however, some have argued that hemangiomas are mediated not by angiogenesis, but instead, by an error in vasculogenesis (the formation of blood vessels from angioblasts). This theory postulates that hemangiomas represent an incomplete maturation of the endothelial component of the fetal vasculature. The supporters of this theory point to the clonality of proliferating hemangioma endothelial cells.10,11



Immune-Mediated. Immunohistochemical staining suggests a causal role for hematopoietic cells of myeloid origin.12 Expression of specific clusters of differentiation (CD83, CD32, CD14, CD15), possibly triggered by local tissue hypoxia, have been demonstrated in hemangioma endothelial cells.



The evidence for these differing putative mechanisms suggests either a multifactorial process or the presence of different disease entities under the umbrella diagnosis of “hemangioma.”



Pathologic Classifications


Hemangiomas are classified by pathologists as being capillary, cavernous, or pyogenic granuloma (lobular capillary hemangioma).13 However, the American Academy of Dermatology refers to capillary hemangiomas as “superficial hemangiomas” and cavernous hemangiomas as “deep hemangiomas.”14 Hemangiomas that involve both superficial and deep tissue are called combined (or compound) lesions.



Capillary Hemangioma. Capillary (“strawberry”) hemangiomas represent the major common form of hemangioma. Most often, they are located in the skin or subcutaneous tissue. Grossly, these lesions appear red to purple in color (Figure 50-1). Histologically, one sees a proliferation of capillary-sized vessels surrounding a feeder vessel (Figure 50-2). This architecture has been referred to as “lobular” and has also been used to describe pyogenic granuloma and epithelioid hemangioma. The sine qua non of capillary hemangiomas is the presence a proliferating phase and an involuting phase.




FIGURE 50-1.


Capillary (superficial) Hemangioma. (A) Periorbital. (B) Nasal (late state of resolution). (C) Hip (early stage of resolution).






FIGURE 50-2.


Capillary hemangioma (hematoxylin and eosin [stain]).


Courtesy of Madhu Dahiya, M.D., Department of Pathology, Loyola University Medical Center and Stritch School of Medicine, Maywood, IL.





Cavernous Hemangioma. Cavernous (deep) hemangiomas are less common than capillary (superficial) hemangiomas. They are generally larger, less well circumscribed, and more likely to involve deep structures, such as solid organs (e.g., liver). Grossly, they appear as indistinct purplish-blue nodules or masses in the skin (Figure 50-3). Histologically, they appear as massively engorged capillary hemangiomas (Figure 50-4), but unlike capillary hemangiomas, cavernous hemangiomas tend not to involute or do so more slowly and incompletely. They are also more likely to cause local tissue destruction.




FIGURE 50-3.


Combined hemangioma with resolution of superficial component, revealing deep (cavernous) component.






FIGURE 50-4.


Cavernous hemangioma (hematoxylin and eosin [stain]).


Courtesy Madhu of Dahiya, M.D., Department of Pathology, Loyola University Medical Center and Stritch School of Medicine, Maywood, IL.





Many cavernous hemangiomas are discovered incidentally on imaging studies. Both computed tomography (CT) and magnetic resonance (MR) imaging show an enhancing heterogeneous mass resulting from fibrous, vascular and fat components. There may be erosion of adjacent bones. The most characteristic imaging findings, however, are phleboliths, which are small rounded calcifications or ring calcifications of venous walls or thrombi. Phleboliths are found in up to one-third of cavernous hemangiomas (Figures 50-5 and 50-6).15 Complex hemangiomas with thrombus, hemosiderin, and hyalinization may resemble neoplasms.




FIGURE 50-5.


Retroperitoneal hemangioma or KH with phleboliths. (A) Abdominal radiograph shows cluster of calcified phleboliths (arrow). (B) CT shows heterogeneous lesion containing phleboliths (arrow). Retroperitoneal hemangiomas are rare, but round and circular calcifications in masses anywhere in the body suggest vascular lesions.






FIGURE 50-6.


Adrenal hemangioma. (A) Radiograph shows left shows left kidney (K) displaced caudally by suprarenal mass (arrow) with small irregular calcifications. (B) CT shows the large heterogeneous adrenal hemangioma containing multiple phleboliths. These multiple small well-defined phleboliths shown by CT are typical findings in hemangiomas and other vascular tumors.





Pyogenic Granuloma. See next section.



Pediatric Hemangiomas


Hemangioma of infancy (HOI) is the most common soft tissue tumor in the pediatric population, occurring in nearly 10% of Caucasian infants. Although the etiology and pathophysiology of hemangiomas remains unclear (see above), a number of risk factors have been identified (Table 50-4). Of those affected, 20% have multiple lesions.16 The vast majority of HOI occur sporadically, although familial autosomal dominant cases have been reported.17




TABLE 50-4.Risk Factors: Infantile Hemangiomas



Most HOI are superficial (capillary type). Many are not evident at birth, in contrast to VM, but become noticeable within the first few days or months of life. HOI can involve nearly any organ, but most are cutaneous on the head and neck (Figure 50-1A and 50-1B) (Table 50-2). Superficial hemangiomas appear as red papules, nodules, or plaques. Deep tissue hemangiomas often have a bluish hue (Figure 50-3).



Hemangiomas are characterized by a phase of proliferation followed by phase of involution and regression. They typically grow to maximal size by age 6 to 18 months and their growth is disproportionate to that of the infant. With few exceptions, they range in size from a few millimeters to several centimeters in diameter. Most will spontaneously involute. As a general rule, approximately 10% involute per year after 1 year of age. By 7 years of age, 75% to 90% will have involuted. However, even when a lesion fully involutes and regresses, a residual hypopigmented scar with redundant skin is evident in 50% of cases. The risk of scarring increases with larger combined lesions, and with lesions of the nose, ear, lip, or breast.



Congenital Hemangiomas. Congenital hemangiomas are rare and of two types: Rapidly involuting congenital hemangioma (RICH) and noninvoluting congenital hemangioma (NICH).18 RICH is similar to HOI but is fully developed at birth, lacks female preponderance, and pursues a course of rapid involution. Imaging studies can aid in making a diagnosis and differentiating this tumor from other entities, but occasionally biopsy is necessary. Accurate diagnosis of RICH is important in order to avoid unnecessary interventional therapy for this rapidly regressing lesion. NICH is so called because it is fully formed at birth and never involutes. Enjolras et al.19 published a series of 53 patients and found that all NICH lesions were single, averaged 5 cm in size, and more than 40% were on the head and neck.



Hemangiomatosis. Most hemangiomas are single and cutaneous, but 20% of patients will have more than one lesion.16 Hemangiomatosis is a syndrome that mostly affects neonates and is defined by the presence of multiple small hemangiomas (≥5 lesions).13,20 Most cases are confined to the skin. Sometimes, hundreds of lesions are present and envelop an entire extremity (Figure 50-7).




FIGURE 50-7.


Hemangiomatosis. (A) Angiogram shows a large angiomatous lesion of the left ankle. (B) CT shows markedly enlarged left thigh with subcutaneous angiomatous tissue. (C) Pelvic CT shows angiomatous subcutaneous tissue of left body wall and within pelvis displacing B: bladder. All organs can be involved in addition to soft tissue and bones. The prognosis is largely determined by the presence and extent of visceral involvement.





A more severe variant can result in significant morbidity and rarely mortality because of systemic involvement.21,22 In order of decreasing frequency, the liver, GI tract, brain, and lung may be affected. Hepatomegaly, congestive heart failure (CHF) and anemia appear early in severely affected infants, and death may result from heart failure. Despite its potentially aggressive nature, there are no reports of hemangiomatosis progressing to malignancy, and it remains a benign lesion that is often histologically identical to other common manifestations of hemangioma. Ultrasound (US) is a useful imaging modality for screening infants with more than five cutaneous hemangiomas for visceral lesions. Tumors in patients with hemangiomatosis recur in 90% of cases, so treatment should be as conservative as possible.22



Syndromes. Aside from hemangiomatosis, there are several other rare clinical syndromes associated with hemangiomas (Table 50-5).13 Gorham disease (vanishing bone disease) is a syndrome of massive osteolysis that can occur with hemangiomatosis. Maffucci syndrome is a nonhereditary mesodermal dysplasia that manifests with multiple cavernous hemangiomas and enchondromas, most of which affect the phalanges and long bones (Figure 50-8). Patients with blue rubber bleb nevus syndrome (Bean syndrome), Peutz-Jeghers syndrome, and Klippel-Trenaunay-Weber syndrome may have multiple bowel hemangiomas that bleed and cause iron-deficient anemia. PHACE syndrome affects multiple organ systems and is discussed separately (see below). The Kasabach-Merritt syndrome (KMS) is a consumptive coagulopathy associated with specific hemangiomas, especially KH and tufted angioma (see below). Contrary to reports in older literature, KMS is rarely, if ever, associated with infantile hemangioma.




TABLE 50-5.Clinical Syndromes Associated with Vascular Tumors




FIGURE 50-8.


Maffucci syndrome (enchondromatosis with hemangiomas). (A) Hand radiograph shows extensive bone and soft tissue deformities caused by enchondromas. (B) Arteriogram shows numerous soft tissue hemangiomas. Lesions are unilateral in one-half of patients. The hands are the most common site of involvement. Malignant transformation as high as 20% has been reported, usually after 40 years of age and most often chondrosarcoma, but many other neoplasms, including AS, also occur.





Complications and Regionally Important Lesions. Most hemangiomas are asymptomatic. However, lesions affecting the face often cause psychosocial distress (Figure 50-1A and Figure 50-1B). An additional 10% of pediatric hemangiomas will result in structural, coagulopathic, or metabolic complications (Table 50-6).




TABLE 50-6.Complications of Hemangiomas



psychologic issues. Psychosocial distress, both for the patient and the family, is the most common complication of pediatric hemangiomas. Much has been published on this topic.14,16,23,24 These issues are best dealt with by educating the parents and patient as to the natural course of the disease, explaining the treatment plans, and discussing reasonable expectations. Frequent and regular office follow-up is often necessary. Contact with other families through support groups and via the Internet may also be helpful.



ulceration and bleeding. Ulceration and bleeding are common complications of rapidly proliferating cutaneous hemangiomas and those located in areas of friction and pressure, such as the intertriginous areas.25 These lesions are generally painful, susceptible to secondary infection and often result in larger residual scaring and discoloration.



soft tissue lesions. Soft tissue hemangiomas may present as a mass, with pain and discomfort, or as an incidental finding on an imaging study. Functional impairment may arise when a hemangioma interferes with a vital structure. Physical examination findings are often subtle. Generally, there is no discoloration of the overlying skin. The size of the lesion cannot be reliably assessed by palpation. Thrills and bruits are rarely present. Therefore, imaging studies (e.g., plain films, CT, MR, US, angiography) are especially useful in establishing the diagnosis (Figures 50-9,50-10,50-11,50-12). Biopsy should be performed if there is uncertainty regarding the diagnosis, particularly if there is a question of malignancy.




FIGURE 50-9.


Hemangioma of forearm. Round and circular (arrows) calcifications of this soft tissue mass are highly suggestive of vascular lesion.






FIGURE 50-10.


Hemangioma of thumb. (A) Radiograph shows soft tissue mass adjacent to thumb. (B) Angiogram shows hypervascularity and stain of mass.






FIGURE 50-11.


Hemangioma of hand. (A) Radiograph shows metacarpals and phalanges displaced by soft tissue mass with phleboliths (arrows). (B) Arteriogram early image shows large abnormal vessels. (C) Arteriogram late image shows persistent faint vascular opacification. Phleboliths suggest a primary vascular lesion, and lack of early venous fillings favors a hemangioma rather than an AV malformation.






FIGURE 50-12.


Soft tissue hemangioma of the neck (arrow) shown by sagittal T2-weighted MR image.





skeletal lesions. Hemangiomas are the most common benign vascular tumor of bone in children and adults, but constitute only 1% of bone tumors.26,27 Most skeletal hemangiomas occur in the vertebrae (Figure 50-13) and skull (Figure 50-14) and are asymptomatic. Most of these tumors are discovered incidentally on routine imaging tests where they have a characteristic appearance. Appendicular skeletal lesions (Figure 50-15) are much less common, difficult to diagnose on imaging studies, and more likely to present with pain, swelling, or pathologic fracture.28




FIGURE 50-13.


Hemangioma of lumbar vertebra. (A) Bone scan shows nonspecific uptake in lumbar vertebra (arrow). (B) Lateral radiograph shows characteristic vertical bony striations. (C) CT shows vertical striations in cross section as characteristic dots within the low attenuation lesion (arrow) in right side of vertebral body. While the bone scan is nonspecific, the characteristic radiographic and CT findings are easily recognized.






FIGURE 50-14.


Hemangioma of calvaria. (A) Lateral skull radiograph shows characteristic stellate trabecular pattern (arrows). (B) CT shows expansile lesion (arrow) with intact inner and outer table and abnormal diploic space trabeculae. Calvarial hemangiomas have a stellate “sunburst” appearance as a result of periosteal spicules that radiate from their center.






FIGURE 50-15.


Hemangioma of tibia. (A) Bone scan shows nonspecific focal tibial uptake (arrow). (B) Radiographs show focal tibial abnormality (arrows). Hemangiomas of the calvaria and vertebra have characteristic appearances but long bone lesions are rare and have varied, nonspecific bone manifestations.





periorbital lesions. Periorbital hemangiomas are among the most complicated lesions, as the visible portion often represents only the tip of the iceberg (Figure 50-1A). Periorbital hemangiomas can compromise visual axis maturation, resulting in a range of functional disabilities.29,30 Patients may present with exophthalmos, proptosis, astigmatism, ptosis, strabismus, or visual impairment. MR is useful to assess the extent of the lesion and potential compromise to vital structures. Vision may be compromised by even small lesions so early pediatric ophthalmologic consultation is crucial.



upper airway lesions. Hoarseness or stridor in an infant patient of 6 to 12 weeks of age may herald a subglottic hemangioma.31 Patients at highest risk for this complication have hemangiomas affecting the “beard” region of the face, which corresponds to the cranial nerve V3 trigeminal distribution (preauricular, anterior neck, chin, and lower lip). Early consultation with ENT is advisable. Bronchoscopy may be necessary to establish the diagnosis and/or treat the lesion.



PHACE syndrome. The PHACE syndrome (Online Mendelian Inheritance in Man [OMIM] No. 606519) describes patients with: (1) Posterior fossa malformation; (2) Hemangioma; (3) Arterial abnormalities (including coarctation of the Aorta); (4) Cardiac defects; and (5) Eye abnormalities (Figure 50-16).32,33,34 It is thought to be caused by an unknown embryonic insult that occurs during the first trimester of gestation. However, a strong female predominance exists, suggesting X-linked inheritance, but no familial cases have been reported.




FIGURE 50-16.


A large segmental facial hemangioma, as seen in the PHACE syndrome.





Infants with PHACE syndrome present a spectrum of anomalies and disease severity. The diagnosis should be considered in any infant presenting with a large plaque-like lesion on the face. The vascular lesion, which is a true hemangioma, can be confused with the port wine stain (a VM) associated with the Sturge-Weber syndrome. Affected patients require an extensive work-up and consultation with a dermatologist, ophthalmologist, neurologist, cardiologist, and radiologist familiar with the syndrome.



MR of the head and neck should be considered to evaluate for posterior fossa abnormalities (e.g., the Dandy-Walker complex, cerebellar hypoplasia, and abnormalities of the vermis). Cerebral vascular compromise and stroke can result from compression of the carotid arteries or circle of Willis by hemangioma.35,36,37 Carotid and vertebral anomalies are best evaluated by MR angiography or traditional (invasive) angiography with digital subtraction. The aortic arch can be evaluated by CT angiography, MR angiography, or more invasively by angiography. Transthoracic echocardiography should be performed to evaluate for congenital heart disease, such as atrial septal defect, or ventricular septal defect.



visceral lesions. In the general population, most visceral hemangiomas occur in the absence of cutaneous hemangiomas. However, in the pediatric population, the presence of large or multiple (≥5) cutaneous hemangiomas is a significant risk factor for the presence of visceral (especially hepatic) and brain hemangiomas. US is an effective noninvasive and relatively inexpensive method for screening the abdomen. In patients younger than 5 months of age, US may also be used to screen for the presence of brain hemangiomas.



The liver is the most common site of visceral hemangiomas (affecting 5% of the general population), and hemangioma is the most common benign hepatic tumor. Most liver hemangiomas are without clinical significance and are discovered incidentally during abdominal imaging studies (Figures 50-17 and 50-18). Most liver hemangiomas have characteristic imaging findings on CT, MR, and US (Figure 50-19A, 50-19B, 50-19C and 50-19D). Angiography is rarely used to establish the diagnosis, but classically shows highly vascular lesions with parallel arterial feeders and late venous stain. Technetium-99 m-labeled red blood cell (RBC) nuclear imaging can also be helpful when the diagnosis is in doubt based on other imaging studies (Figure 50-19E and 50-19F).38




FIGURE 50-17.


Liver hemangioma; Single level CT before and after intravenous contrast material. Hemangioma (arrow) on 1st image prior to intravenous contrast material is low attenuation. Next five images after IV contrast injection show peripheral hypervascular foci that increase and then the hemangioma becomes isodense and finally hyperdense compared to the liver. Liver hemangiomas, incidental findings in 5% of the general population, must be distinguished from significant lesions. Well-defined focal collections of intravenous contrast material in peripheral slow flow sites of a hemangioma on CT, MR, nuclear medicine RBC study, and angiography are diagnostic. Uniform circumferential enhancement and delayed centripetal uniform enhancement are not.






FIGURE 50-18.


Liver hemangioma; MR. (A) T1-weighted image shows focal low signal lesion (arrow). (B) T1-weighted image after IV contrast shows characteristic peripheral, discrete foci of intense enhancement (arrows).






FIGURE 50-19.


Large liver hemangioma—CT, MR, US, liver spleen scan, and RBC spleen scan. (A) CT shows only a single site of dense enhancement (white arrow) in this large lobulated lesion (black arrow). (B) T1-weighted MR shows large lobulated low signal lesion. (C) T2-weighted MR shows characteristic uniform high signal of lesion. (D) US shows suggestive but nonspecific echogenicity of lesion (arrows). (E) Liver spleen scan shows large defect at site of lesion (arrow). (F) RBC scan shows diagnostic delayed uptake of lesion (arrow) Large liver hemangiomas may not show diagnostic imaging features because large vascular spaces do not accumulate enough contrast to show characteristic discrete focal peripheral enhancement. Small (<1 cm) hemangiomas show only uniform hypervascularity that is not diagnostic either.





When significant arterial–venous shunting occurs within a liver hemangioma, high-output CHF may result. Massive liver hemangiomas sometimes compress adjacent structures, such as renal veins and the inferior vena cava (IVC), causing abdominal compartment syndrome. In very rare instances, liver hemangiomas can cause a consumptive hypothyroidism as a result of high expression of the thyroid hormone inactivating enzyme type-3 iodothyronine deiodinase (D3).39



The presence of iron-deficient anemia or bowel obstruction in the pediatric population should prompt the consideration of gastrointestinal (GI) hemangioma. GI hemangiomas may present focally within the bowel wall, diffusely as intestinal hemangiomatosis, or as an extrinsic abdominal or pelvic cavernous hemangioma with direct invasion of the GI tract.40 In these cases, a gastroenterology consult is warranted. The diagnosis may be established with endoscopy, tomographic imaging of the abdomen and pelvis (e.g., CT, MR), or angiography. GI hemangiomas are often associated with clinical syndromes (Table 50-5) and, when encountered, should raise the possibility of blue rubber bleb nevus syndrome (Bean syndrome), Klippel-Trenaunay-Weber syndrome, or Peutz-Jeghers syndrome.41



Congestive Heart Failure. High-output CHF as a result of arteriovenous (AV) shunting is an occasional complication of hemangiomas. In these cases, the offending lesion(s) is most often hepatic (see above). These patients should be evaluated by a cardiologist. An initial evaluation should include an electrocardiogram (ECG), an echocardiogram, a chest X-ray and basic laboratory work. Cardiac catheterization is often unnecessary in patients younger than 30 years of age, but may be useful in establishing the severity of the shunt. The liver, and potentially other viscera, should be evaluated for hemangioma by imaging studies (US, CT, MR, nuclear).

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Jan 1, 2019 | Posted by in CARDIOLOGY | Comments Off on Primary Vascular Tumors

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