National Cancer Institute


Treatment options for children with vascular tumors are limited and efficacy has not been validated in prospective clinical trials. Historically therapies have been mostly to palliate symptoms. Get detailed information about the types of vascular tumors in this clinician summary.

This PDQ cancer information summary for health professionals provides comprehensive, peer-reviewed, evidence-based information about the treatment of childhood vascular tumors. It is intended as a resource to inform and assist clinicians who care for cancer patients. It does not provide formal guidelines or recommendations for making health care decisions.

This summary is reviewed regularly and updated as necessary by the PDQ Pediatric Treatment Editorial Board, which is editorially independent of the National Cancer Institute (NCI). The summary reflects an independent review of the literature and does not represent a policy statement of NCI or the National Institutes of Health (NIH).

Childhood Vascular Tumors Treatment

Notes on Vascular Malformations

While information about vascular malformations is covered at the beginning of this summary, the remainder of this summary focuses on neoplasms, not malformations.

Although not considered neoplasms, many vascular malformations are caused by targetable somatic mutations; this discovery means that pediatric oncologists will be asked to be involved in management of these lesions. Therefore, it is important for oncologists to have some understanding of the biology and clinical management of common vascular malformations.

Vascular malformations are distinguished from vascular tumors by their low cell turnover and lack of invasiveness. They tend to grow in proportion to the child and are generally stable in adulthood. Nonetheless, endothelial cells isolated from vascular malformations have been found in vitro to have some tumor-like behaviors, such as increased growth, migration, and resistance to apoptosis.

In the International Society for the Study of Vascular Anomalies (ISSVA) classification, vascular malformations are subdivided according to vessel type. High-flow lesions, arteriovenous malformations are the most aggressive type, but they are relatively rare. Low-flow lesions may be venous, lymphatic, or mixed. The symptoms in patients with low-flow malformations most often relate to the bulk of the lesion, episodic thrombosis, or bleeding, which causes pain. In patients with large lesions, there is a risk of pulmonary embolism. Capillary malformations include port-wine stains and a number of less common lesions. Treatment for patients with both high-flow and low-flow malformations is usually either surgery, endovascular intervention, or some combination of the two; ideally, a multidisciplinary vascular anomalies team is involved in the treatment of patients. Only a low level of evidence supports the choice of treatment between these options, and the recurrence rates for large lesions are relatively high.

Patients with low-flow malformations are the most likely to present for oncological treatment; this will normally occur after conventional treatments have failed. Approximately one-third to one-half of venous malformations result from somatic or, rarely, germline mutations in the TEK (or TIE2) gene. Another one-third of venous malformations, and nearly all lymphatic malformations, are caused by somatic mutations in PIK3CA. In most cases, PIK3CA mutations are identical to canonical cancer mutations. Lesions harboring PIK3CA mutations are frequently associated with overgrowth of adjacent tissues, as seen in patients with Klippel-Trénaunay syndrome. Sirolimus has been used to target the phosphatidylinositol 3-kinase (PI3K) pathway in low-flow malformations, leading to symptomatic improvement in many patients. It is unclear whether treatment reduces the size of lesions because there is usually considerable fluctuation in size, and treatment generally begins when lesions are enlarged. The use of sirolimus in venous and lymphatic malformations is supported by level 3 evidence (case series or other observational study designs). Both PIK3CA- and TEK-mutated lesions appear to respond equally to treatment with sirolimus. Phase III clinical trials are under way (e.g., NCT02638389 and NCT03987152). A 2018 study reported promising level 3 evidence for the use of the PI3K inhibitor BYL719 to treat patients who have lesions with a PIK3CA mutation.

There is currently no evidence to support the use of targeted therapies in patients with arteriovenous malformations. The finding that most of these malformations appear to be caused by somatic mutations in the mitogen-activated protein (MAP) kinase pathway, including gain of function mutations in MAP2K1, KRAS, and BRAF, along with limited in vitro data, suggests that MEK pathway inhibition may soon have a role in treating patients with these aggressive, highly symptomatic, and sometimes fatal lesions.

References

  1. Mulliken JB, Glowacki J: Hemangiomas and vascular malformations in infants and children: a classification based on endothelial characteristics. Plast Reconstr Surg 69 (3): 412-22, 1982.
  2. Lokmic Z, Mitchell GM, Koh Wee Chong N, et al.: Isolation of human lymphatic malformation endothelial cells, their in vitro characterization and in vivo survival in a mouse xenograft model. Angiogenesis 17 (1): 1-15, 2014.
  3. Wassef M, Blei F, Adams D, et al.: Vascular Anomalies Classification: Recommendations From the International Society for the Study of Vascular Anomalies. Pediatrics 136 (1): e203-14, 2015.
  4. van der Vleuten CJ, Kater A, Wijnen MH, et al.: Effectiveness of sclerotherapy, surgery, and laser therapy in patients with venous malformations: a systematic review. Cardiovasc Intervent Radiol 37 (4): 977-89, 2014.
  5. Soblet J, Limaye N, Uebelhoer M, et al.: Variable Somatic TIE2 Mutations in Half of Sporadic Venous Malformations. Mol Syndromol 4 (4): 179-83, 2013.
  6. Luks VL, Kamitaki N, Vivero MP, et al.: Lymphatic and other vascular malformative/overgrowth disorders are caused by somatic mutations in PIK3CA. J Pediatr 166 (4): 1048-54.e1-5, 2015.
  7. Keppler-Noreuil KM, Rios JJ, Parker VE, et al.: PIK3CA-related overgrowth spectrum (PROS): diagnostic and testing eligibility criteria, differential diagnosis, and evaluation. Am J Med Genet A 167A (2): 287-95, 2015.
  8. Adams DM, Trenor CC, Hammill AM, et al.: Efficacy and Safety of Sirolimus in the Treatment of Complicated Vascular Anomalies. Pediatrics 137 (2): e20153257, 2016.
  9. Hammer J, Seront E, Duez S, et al.: Sirolimus is efficacious in treatment for extensive and/or complex slow-flow vascular malformations: a monocentric prospective phase II study. Orphanet J Rare Dis 13 (1): 191, 2018.
  10. Venot Q, Blanc T, Rabia SH, et al.: Targeted therapy in patients with PIK3CA-related overgrowth syndrome. Nature 558 (7711): 540-546, 2018.
  11. Couto JA, Huang AY, Konczyk DJ, et al.: Somatic MAP2K1 Mutations Are Associated with Extracranial Arteriovenous Malformation. Am J Hum Genet 100 (3): 546-554, 2017.

General Information About Childhood Vascular Tumors

Vascular anomalies are a spectrum of rare diseases classified as vascular tumors or malformations. An updated classification system was adopted at the General Assembly of the International Society for the Study of Vascular Anomalies (ISSVA, April 2014) and further additions were added in 2018 (ISSVA, May 2018). Generally, vascular tumors are proliferative, while malformations enlarge through expansion of a developmental anomaly without underlying proliferation.

Growth and/or expansion of vascular anomalies can cause clinical problems such as disfigurement, chronic pain, recurrent infections, coagulopathies (thrombotic and hemorrhagic), organ dysfunction, and death. Individuals often experience progressive clinical symptoms with worsening quality of life.

In the past, limited treatment options were available and efficacy was not validated in prospective clinical trials. Historically, therapies consisted of interventional and surgical procedures used to palliate symptoms. New drugs such as propranolol and sirolimus are now available for the treatment of patients with complex conditions, and additional targeted therapies are in development. The first prospective clinical trial using propranolol for infantile hemangioma has been published, as well as the first prospective clinical trial that studied the effectiveness of sirolimus for complicated vascular anomalies.

With a prevalence of 4% to 5%, infantile hemangiomas are the most common benign tumors of infancy. Other vascular tumors are rare. The classification of these tumors has been difficult, especially in the pediatric population, because of their rarity, unusual morphologic appearance, diverse clinical behavior, and the lack of independent stratification for pediatric tumors. In 2013, The World Health Organization (WHO) updated the classification of soft tissue vascular tumors. Pediatric tumors were not independently stratified and the terminology was mostly left unchanged, but the intermediate category of tumors was divided into locally aggressive and rarely metastasizing. The ISSVA classification of tumors is based on the WHO classification (refer to Tables 1 and 2) but the ISSVA classification uses more precise terminology and phenotypes that have been agreed upon by the members of ISSVA.

Table 1. 2013 World Health Organization Classification of Vascular Tumors

Category Vascular Tumor TypeaAdapted from Fletcher et al.BenignHemangioma Epithelioid hemangiomaAngiomatosisLymphangioma Intermediate (locally aggressive) Kaposiform hemangioendotheliomaIntermediate (rarely metastasizing)Retiform hemangioendothelioma Papillary intralymphatic angioendotheliomaComposite hemangioendotheliomaKaposi sarcomaMalignantEpithelioid hemangioendothelioma Angiosarcoma of soft tissue

Table 2. 2018 International Society for the Study of Vascular Anomalies (ISSVA) Classification of Vascular Tumorsa

Category Vascular Tumor Type (Causal Genes)aAdapted from ISSVA Classification of Vascular Anomalies. ©2018 International Society for the Study of Vascular Anomalies. Available at "issva.org/classification." Accessed June 2018. bRefer to the ISSVA classification 2018 for benign vascular tumors 2.cTufted angioma and kaposiform hemangioendothelioma are a spectrum of the same entity and will be discussed together.Benign (type 1b)Infantile hemangioma/hemangioma of infancyCongenital hemangioma (GNAQ/GNA11)—Rapidly involuting (RICH)—Non-involuting (NICH)—Partially-involuting (PICH) Tufted angiomac Spindle cell hemangioma (IDH1/IDH2)Epithelioid hemangioma (FOS)Pyogenic granuloma (also known as lobular capillary hemangioma) (BRAF/RAS/GNA14)OthersLocally aggressive or borderlineKaposiform hemangioendothelioma (KHE) (GNA14)Retiform hemangioendotheliomaPapillary intralymphatic angioendothelioma (PILA), Dabska tumorComposite hemangioendotheliomaPseudomyogenic hemangioendothelioma (FOSB)Polymorphous hemangioendotheliomaHemangioendothelioma not otherwise specifiedKaposi sarcomaOthersMalignant Angiosarcoma (MYC: postradiation therapy)Epithelioid hemangioendothelioma (EHE) (CAMTA1/TFE3)Others

The quality of evidence regarding childhood vascular tumors is limited by retrospective data collection, small sample size, cohort selection and participation bias, and heterogeneity of the disorders.

References

  1. International Society for the Study of Vascular Anomalies: ISSVA Classification of Vascular Anomalies. Milwaukee, Wi: International Society for the Study of Vascular Anomalies, 2018. Available online. Last accessed June 17, 2020.
  2. Wassef M, Blei F, Adams D, et al.: Vascular Anomalies Classification: Recommendations From the International Society for the Study of Vascular Anomalies. Pediatrics 136 (1): e203-14, 2015.
  3. Léauté-Labrèze C, Hoeger P, Mazereeuw-Hautier J, et al.: A randomized, controlled trial of oral propranolol in infantile hemangioma. N Engl J Med 372 (8): 735-46, 2015.
  4. Adams DM, Trenor CC, Hammill AM, et al.: Efficacy and Safety of Sirolimus in the Treatment of Complicated Vascular Anomalies. Pediatrics 137 (2): e20153257, 2016.
  5. Fletcher CDM, Bridge JA, Hogendoorn P, et al., eds.: WHO Classification of Tumours of Soft Tissue and Bone. 4th ed. Lyon, France: IARC Press, 2013.

Benign Tumors

Benign vascular tumors include the following:

  • Infantile hemangioma.
  • Congenital hemangiomas.
  • Benign vascular tumors of the liver.
  • Spindle cell hemangioma.
  • Epithelioid hemangioma.
  • Pyogenic granuloma (lobular capillary hemangioma).
  • Angiofibroma.
  • Juvenile nasopharyngeal angiofibroma.

    Juvenile nasopharyngeal angiofibroma is not included in the World Health Organization or the International Society for the Study of Vascular Anomalies classification of vascular tumors. It is included here because growing evidence reveals vascular differentiation and proliferation in these tumors with response to vascular remodeling and antiproliferative agents.

Infantile Hemangioma

Incidence and epidemiology

Infantile hemangiomas (IH) are the most common benign vascular tumor of infancy, occurring in 4% to 5% of infants. The true incidence is unknown. They are not usually present at birth and are diagnosed most commonly at age 3 to 6 weeks. The lesion proliferates for an average of 5 months, stabilizes, and then involutes over several years.

Infantile hemangiomas are more common in females, non-Hispanic white patients, and premature infants. Multiple hemangiomas are more common in infants who are the product of multiple gestations. Infantile hemangiomas are associated with advanced maternal age, placenta previa, pre-eclampsia, and other placental anomalies.

Biology

Most infantile hemangiomas occur sporadically. However, they may rarely be caused by an abnormality of chromosome 5 and present in an autosomal dominant pattern. In a study that evaluated inheritance patterns of infantile hemangiomas, 34% of patients had a family history of infantile hemangioma, most commonly in a first-degree relative.

The exact mechanism that causes the initial proliferation of blood vessels followed by involution of the vascular component of hemangioma and replacement of fibrofatty tissue is unknown.

Several cell types have been isolated from hemangiomas: progenitor/stem cells (HemSC), endothelial cells (HemEC), and pericytes (HemPericytes). HemSC represent a small percentage of proliferating hemangioma cells and have the ability for self renewal and multilineage differentiation. These cells differentiate into endothelial cells, adipocytes, and pericytes. When HemSC are implanted into immunodeficient mice, hemangioma-like lesions form and then spontaneously regress, similar to infantile hemangioma. This suggests that infantile hemangioma proliferation occurs during vasculogenesis (the formation of new blood vessels from angioblasts), as opposed to angiogenesis (the formation of new blood vessels from existing blood vessels).

In the proliferative phase, the HemEC are plump and metabolically active, resembling fetal endothelial cells. Evaluation of infantile hemangioma endothelial cells suggest that they are clonal in nature.

HemPericytes surround the vasculature, are abundant in the proliferative phase, and express markers of pericytes and smooth muscle cells, such as neural-glial antigen 2 (NG2), platelet-derived growth factor receptor beta (PDGFR-beta), calponin, alpha smooth muscle actin (SMA), and NOTCH3. These cells are proangiogenic, as they express increased vascular endothelial growth factor A (VEGF-A), decreased angiopoietin-1 (ANGPT1), increased proliferation, increased vessel formation in vivo, and decreased ability to suppress proliferation.

Mast cells are found largely in the early involuting phase. They are also found in small numbers in the proliferative phase and at the end of involution. Their role is unknown but they have been shown to play a role in other skin tumors such as basal cell carcinoma, squamous cell carcinoma, and melanoma.

During proliferation, provasculogenic factors are expressed, such as VEGF, fibroblast growth factor (FGF), CD34, CD31, CD133, lymphatic vessel endothelial hyaluronan receptor 1 (LYVE1), and insulin-like growth factor 2 (IGF-2). During involution, infantile hemangiomas express increased apoptosis. During this phase, there are also increased mast cells and levels of metalloproteinase, as well as upregulation of interferon and decreased basic FGF (bFGF). Throughout proliferation and involution, endothelial cells in infantile hemangioma express a particular phenotype showing positive staining for GLUT1 and placenta-associated antigens (Fc-gamma receptor II, merosin, Lewis Y antigen). These markers are absent in normal capillaries and in other vascular tumors such as congenital hemangioma and vascular malformations. Placental chorionic villi share these same markers; however, no relationship between hemangiomas and placental chorionic villi has been found.

Hypoxia appears to have a critical role in the pathogenesis of hemangiomas. There is an association of hemangiomas with placental hypoxia, which is increased in prematurity, multiple pregnancies, and placental anomalies. Multiple targets of hypoxia are demonstrated in proliferating hemangiomas, including VEGF-A, GLUT1, and IGF-2. The hypothesis suggests that a proliferating hemangioma is an attempt to normalize hypoxic tissue that occurred in utero.

Clinical presentation

Most infantile hemangiomas are not present at birth but precursor lesions such as telangiectasia or faint discoloration of the skin or hypopigmentation can often be seen. The lesion can be mistaken as a bruise from birth trauma or as a capillary malformation (port-wine stain) (refer to Figure 1).

Photos showing an infantile hemangioma premonitory mark; the photos on the left show a precursor lesion (faint color with halo). The photos on the right show a hemangioma after proliferation (slightly raised with a brighter central color).Figure 1. The photos on the left depict the precursor lesion (faint color with halo). The photos on the right depict the hemangioma after proliferation (slightly raised with a brighter central color). Credit: Israel Fernandez-Pineda, M.D.

Infantile hemangiomas can be superficial in the dermis, deep in the subcutaneous tissue, combined, or in the viscera. Combined lesions are common. They are most common in the head and neck but can be anywhere on the body.

Infantile hemangioma can be characterized as follows:

  • Local: Most lesions are localized and noted to be in a well-defined area without evidence of a geometric pattern.
  • Segmental: These hemangiomas demonstrate a cutaneous pattern. Several studies have evaluated the distributions of these hemangiomas and found the following four distinct patterns or segments:
    • Segment 1 involves the lateral forehead, anterior temporal scalp, and the lateral frontal scalp.
    • Segments 2 and 3 are located over the maxillary and mandibular area.
    • Segment 4 covers the medial frontal scalp, nose, and philtrum.

    Two papers have noted this observation and suggest the involvement of neural crest derivatives in facial hemangioma development. Segmental hemangiomas commonly occur in females and are more likely associated with complications and other syndromes. (Refer to the Syndromes associated with infantile hemangioma section of this summary for information about PHACE syndrome.)

  • Multiple: More than one lesion, but noted in the past as greater than five lesions, because of the increased risk of visceral involvement (mostly the liver). Usually characterized by solitary localized lesions.

The cutaneous appearance of infantile hemangiomas is usually red to crimson, firm, and warm in the proliferative phase. The lesion then lightens centrally and becomes less warm and softer; it then flattens and loses its color. The process of involution can take several years and once involution has occurred, regrowth is uncommon. In two patients treated with growth hormone, regrowth after involution was noted. On further investigation, growth hormone receptors were found on the infantile hemangioma cells. Although preliminary, this may advance the research into the etiology of hemangioma growth.

Permanent sequelae, such as telangiectasia, anetodermal skin, redundant skin, and a persistent superficial component, can occur after hemangioma involution (refer to Figure 2). In a retrospective cohort study of 184 hemangiomas, the overall incidence of significant sequelae was 54.9%. Sequelae were more common in combined hemangiomas, hemangiomas with a step or abrupt border, and cobblestone surface hemangiomas. Furthermore, this study revealed that the average age to hemangioma involution was 3.5 years.

Photographs showing different types of hemangioma sequelae, pre-progression and post-progression.Figure 2. Examples of different types of sequelae. A, deep hemangioma that regressed without sequelae; B, superficial hemangioma that left only telangiectasia; C, mixed hemangioma that left anetodermic skin; D, mixed hemangioma that left redundant skin; and E, mixed hemangioma that left fibrofatty tissue. Reproduced with permission from JAMA Dermatology. 2016. 152 (11): 1239–1243. Copyright © (2016) American Medical Association. All rights reserved.

Diagnostic and staging evaluation

Infantile hemangiomas are usually diagnosed by the history and clinical appearance. Biopsy is rarely needed and performed only if there is an atypical appearance and/or atypical history and presentation. Imaging is not usually necessary, but if there is a deeper lesion without a cutaneous component, ultrasonography is beneficial for diagnosis because it reveals a well-circumscribed, hypoechoic, high flow lesion with a typical Doppler wave characteristic. Additionally, infants with five or more cutaneous hemangiomas should undergo ultrasonography of the liver to scan for hepatic hemangioma.

Infantile hemangioma with minimal or arrested growth

Infantile hemangioma with minimal or arrested growth (IH-MAG) is a variant of hemangioma that can be confused with capillary malformation because of their unusual characteristics. These hemangiomas are mostly fully formed at birth and are characterized by telangiectasia and venules with light and dark areas of skin coloration (refer to Figure 3). They resolve spontaneously and are pathologically GLUT1 positive. They are mainly located on the lower body but can be present in the head and neck area; if they are segmental, they can be associated with PHACE syndrome. Associated soft tissue hypertrophy may persist through childhood.

Photographs showing (A) presentation and (B) resolution of an infantile hemangioma in patient 4 (upper left and right photos), and (C) presentation and (D) resolution of an infantile hemangioma in patient 5 (bottom left and right photos).Figure 3. Patient 4 at (A) presentation and (B) resolution. Patient 5 at (C) presentation and (D) resolution. Ma, E. H., Robertson, S. J., Chow, C. W., and Bekhor, P. S. (2017), Infantile Hemangioma with Minimal or Arrested Growth: Further Observations on Clinical and Histopathologic Findings of this Unique but Underrecognized Entity. Pediatr Dermatol, 34: 64–71. doi:10.1111/pde.13022. Used with permission.

Airway infantile hemangioma

Airway infantile hemangiomas are usually associated with segmental hemangiomas in a bearded distribution, which may include all or some of the following—the preauricular skin, mandible, lower lip, chin, or anterior neck. It is important for an otolaryngologist to proactively assess lesions in this distribution before signs of stridor occur. The incidence of an airway infantile hemangioma increases with increased area of bearded involvement. Airway infantile hemangioma can occur without skin lesions. A retrospective study of the Vascular Anomaly Database at the Children's Hospital of Pittsburgh analyzed 761 cases of infantile hemangioma. Thirteen patients (1.7%) had subglottic hemangiomas; of those 13 patients, 4 patients (30%) had bearded distributions, 2 patients (15%) had cutaneous hemangiomas, and 7 patients (55%) had no cutaneous lesions. (Refer to the Propranolol therapy section of this summary for information about the treatment of airway infantile hemangiomas.)

Ophthalmologic involvement of hemangiomas

Periorbital hemangiomas can cause visual compromise. This usually occurs with hemangiomas of the upper medial eyelid but any hemangioma around the eye that is large enough can distort the cornea or obstruct the visual axis. The clinician should be aware of subcutaneous periocular hemangiomas, as these lesions can extend into the orbit, causing exophthalmos or globe displacement with only limited cutaneous manifestations. Issues with these lesions include astigmatism from direct pressure of the growing hemangioma, ptosis, proptosis, and strabismus. One of the leading causes of preventable blindness in children is stimulus-deprivation amblyopia caused by hemangioma obstruction. All periorbital hemangiomas or those with any possibility of potential visual impairment should have an ophthalmologic evaluation.

Infantile hemangiomas can occur in the conjunctiva (refer to Figure 4). These hemangiomas can be associated with other ophthalmologic abnormalities and are treated with oral or topical beta-blockers.

Photographs showing different types of infantile hemangiomas involving the conjunctiva.Figure 4. Proposed classification of infantile hemangiomas involving the conjunctiva. Theiler M, Baselga E, Gerth-Kahlert C, et al. Infantile hemangiomas with conjunctival involvement: An underreported occurrence. Pediatr Dermatol. 2017;34:681–685. https://doi.org/10.1111/pde.13305 Copyright © 2017 John Wiley & Sons, Inc.

Syndromes associated with infantile hemangioma

Syndromes associated with infantile hemangioma include the following:

  • PHACE syndrome:PHACE syndrome represents a spectrum of diseases and is defined by the presence of a large segmental infantile hemangioma, usually on the face or head, but can include the neck, chest, or arm, in association with one or more congenital malformations (refer to Figure 5). PHACE syndrome is more common in girls and in full-term, normal birth weight and singleton infants. The syndrome is not rare among patients with infantile hemangiomas. A prospective study of 108 infants with large facial hemangiomas observed that 31% of patients had PHACE syndrome.

    Photograph showing a large segmental hemangioma (plaque-like) in a bearded distribution on the right side of the face.Figure 5. A large segmental infantile hemangioma (plaque-like) in a bearded distribution. This patient has an increased risk of PHACE syndrome, airway infantile hemangioma, and ulceration. A tracheostomy was placed secondary to a very diffuse airway hemangioma. Credit: Denise Adams, M.D. Garzon MC, Epstein LG, Heyer GL, et al.: PHACE Syndrome: Consensus-Derived Diagnosis and Care Recommendations. J Pediatr 178: 24-33.e2, 2016. PMID: 27659028

    Consensus criteria for definite and possible PHACE syndrome were updated at an expert panel meeting, as follows:

    • Posterior fossa abnormalities. Anomalies include posterior fossa malformations, including Dandy-Walker complex, cerebellar hypoplasia, atrophy, and dysgenesis/agenesis of the vermis. Effects of these anomalies include developmental delays and pituitary dysfunction.
    • Hemangioma.
      • A large segmental hemangioma over the face or scalp with a surface area of 22 cm2 or greater (5 cm × 4.5 cm).
      • One major criterion of PHACE is a large segmental hemangioma of the neck, upper trunk or trunk, and proximal upper extremity.

      Infants with two major criteria of PHACE (e.g., supraumbilical raphe and coarctation of the aorta) but lacking cutaneous infantile hemangioma should undergo complete evaluation for PHACE.

    • Arterial abnormalities. Cerebrovascular anomalies can include carotid artery abnormalities (including tortuosity) and absence, dilation/aneurysm, or narrowing of cerebral vessels. These anomalies, especially the carotid anomalies, can lead to progressive arterial occlusion and even stroke. The risk categories are as follows:
      • Low risk: Arterial anomalies frequently seen in a general screening population. It also includes findings that have either no or very minimal clinical impact on patient outcome, even if rarely seen in the general population. Examples are persistent embryonic arteries, anomalous arterial origin or course, and circle of Willis variants.
      • Intermediate risk: Includes patients with nonstenotic dysgenesis, including patients with ectatic or segmentally enlarged arteries. It also includes patients with a narrowing or occlusion of arteries proximal to the circle of Willis, with no perceived hemodynamic risk. An evaluation of the patency of the circle of Willis is essential.
      • High risk: This category includes patients with one or more of the following:
        • Significant narrowing (>25%) or occlusion of principal cerebral vessels within or above the circle of Willis that results in an isolated circulation.
        • Tandem or multiple arterial stenoses associated with complex blood flow that may potentially result in diminished cerebral perfusion. Patients with cerebrovascular stenosis in the setting of coarctation of the aorta are likely at higher risk of transient and permanent neurologic ischemic events.
        • Imaging findings in the brain parenchyma suggestive of chronic or silent ischemia, or progressive steno-occlusive disease. These parenchymal brain magnetic resonance imaging (MRI) findings include existing infarction, chronic or border zone ischemic changes, and presence of lenticulostriate collateral dilation or pial collaterals.
    • Cardiac abnormalities.
      • Aortic arch anomalies observed in PHACE syndrome are unusually complex, with involvement of the transverse and descending aorta arch. The arch obstruction is most often long-segment. The obstruction is frequently characterized by areas of arch narrowing with adjacent segments of marked aneurysmal dilatation.
    • Eye abnormalities. Ophthalmologic anomalies can include microphthalmos, retinal vascular abnormalities, persistent fetal retinal vessels, exophthalmos, coloboma, and optic nerve atrophy. These abnormalities are rare and occur in 7% to 10% of patients.

    Diagnosis of PHACE requires clinical examination, cardiac evaluation with echocardiogram, ophthalmologic evaluation, and MRI/magnetic resonance angiogram (MRA) of the head and neck. All patients with intermediate-risk and high-risk central nervous system (CNS) findings should be monitored by a neurologist. Coarctation of the aorta requires immediate cardiology consultation and a cardiac MRI/MRA may be warranted. Patients need to be monitored for short-term and long-term effects. There are specific recommendations for follow-up imaging depending on risk category.

    Other issues include speech and language delay, dysphagia, hearing loss (conductive and sensorineural), early-onset migraines, endocrine abnormalities, dental anomalies, and psychological issues.

    A report of two patients with retro-orbital infantile hemangioma and arteriopathy suggested a possible new presentation of PHACE syndrome. For patients with proptosis, globe deviation, and strabismus, an MRI/MRA is recommended. Further workup for PHACE may be needed on the basis of CNS findings.

  • LUMBAR/PELVIS/SACRAL syndrome: Infantile hemangiomas located over the lumbar or sacral spine may be associated with genitourinary, anorectal anomalies, or neurological issues such as tethered cord. The following criteria have been used to describe segmental infantile hemangioma syndrome in the lumbar, pelvic, and sacral areas. This syndrome has been described in the literature using several acronyms.
    • Lower-body hemangioma and other cutaneous defects.
    • Urogenital anomalies or ulceration.
    • Myelopathy.
    • Bony deformities.
    • Anorectal malformations or arterial anomalies.
    • Renal anomalies.
    • Perineal hemangioma.
    • External genital malformations.
    • Lipomyelomeningocele.
    • Vesicorenal abnormalities.
    • Imperforate anus.
    • Skin tag.
    • Spinal dysraphism.
    • Anogenital.
    • Cutaneous.
    • Renal and urologic anomalies Associated with an angioma of Lumbosacral localization.

    Segmental lesions over the gluteal cleft and lumbar spine need to be evaluated with either ultrasonography or MRI, depending on the age of the patient. In several studies, ultrasonography evaluations have failed to identify some spinal abnormalities that were later found on MRI evaluation.

Multiple hemangiomas

Infants with more than five infantile hemangiomas need to be evaluated for visceral hemangiomas. The most common site of involvement is the liver, in which multiple or diffuse lesions can be noted. Often these lesions are asymptomatic, but in a minority of cases, symptoms such as heart failure secondary to large vessel shunts, compartment syndrome, or profound hypothyroidism can occur because of the expression of iodothyronine deiodinase by the hemangioma cells. Multiple or diffuse liver hemangiomas can occur in the absence of skin lesions. (Refer to the Benign Vascular Tumors of the Liver section of this summary for more information.) Other rare potential complications of visceral hemangiomas, dependent on specific organ involvement, include gastrointestinal hemorrhage, obstructive jaundice, and CNS sequelae, caused by mass effects.

infantile hemangioma

Treatment of infantile hemangioma

The decision to treat patients with hemangiomas is based on several factors such as the size of the lesions, type of hemangioma, location, presence or risk of complications, possibility of scarring or disfigurement, the age of the patient, and the stage of growth of the hemangioma. This is individualized among patients, and careful considerations of the risks and benefits of treatment are important.

The American Academy of Pediatrics has published clinical practice guidelines. An early therapeutic intervention was noted to be critical for complicated infantile hemangiomas to prevent medical complications and permanent disfigurement. The timing of interventions was noted to be best in the first 1 to 3 months of age. Photos have been used to triage low-risk versus high-risk infantile hemangiomas, and a scoring system has been used for primary care physicians to encourage early referral to hemangioma specialists. The guidelines specified hemangioma specialists as those practitioners with expertise in the management and care of hemangiomas who have knowledge of risk stratification and treatment options. These providers consisted of experts in the fields of dermatology, hematology/oncology, pediatrics, plastic surgery, general surgery, otolaryngology, and ophthalmology.

Treatment options for infantile hemangioma include the following:

  1. Propranolol therapy.
  2. Selective beta-blocker therapy.
  3. Corticosteroid therapy.
  4. Pulsed dye laser therapy. Usually reserved for ulcerated infantile hemangiomas and residual lesions, such as telangiectasia after the proliferative period. Pulsed dye laser therapy helps with pain from ulcerative infantile hemangiomas. The use of pulsed dye laser therapy as upfront treatment for infantile hemangiomas is controversial.
  5. Excisional surgery. With the advent of new medical treatments, the use of surgery is reserved for ulcerated lesions, residual lesions, large periocular lesions that interfere with vision, and facial lesions with aesthetic impact that do not respond to medical therapy.
  6. Topical beta-blocker therapy.
  7. Combined therapy for complicated hemangiomas.

Propranolol therapy

Propranolol, a nonselective beta-blocker, is the first-line therapy for infantile hemangiomas. Potential mechanisms of action include vasoconstriction and/or decreased expression of VEGF and bFGF, leading to apoptosis. Specific mechanisms of action are under investigation. Two studies suggested that the activity of propranolol on hemangiomas is not secondary to beta blockade but may be related to the ability of the R+ enantiomer of propranolol to inhibit endothelial cell markers through inhibition of SOX18 or the down regulation of other genes, such as ANGPT2.

The use of propranolol was first noted in two infants treated for cardiac issues in Europe. A change in color, softening, and decrease in hemangioma size was noted. Since that time, the results of a randomized controlled trial have been reported. In 2014, the U.S. Food and Drug Administration (FDA) approved the drug propranolol hydrochloride for the treatment of proliferating infantile hemangioma.

There are many other published reports about the efficacy and safety of propranolol. Lack of response to treatment is rare. Propranolol therapy is usually used during the proliferative phase but has been effective in patients older than 12 months with infantile hemangiomas.

Evidence (propranolol therapy):

  1. In a large industry-sponsored randomized trial, 456 infants aged 5 weeks to 5 months with a proliferating infantile hemangioma of at least 1.5 cm received either a placebo or propranolol (1 mg/kg per day or 3 mg/kg per day) for 3 or 6 months. After interim analysis of the first 188 patients who completed 24 weeks of trial treatment, the regimen of 3 mg/kg per day for 6 months was selected for the final efficacy analysis.[Level of evidence: 1iDiv]
    • Of patients who received the selected regimen, 88% showed improvement by week 5, compared with 5% of patients who received the placebo.
    • Adverse events occurred infrequently.
  2. In 635 infants with infantile hemangioma, the overall response rate was 91% after 2 mg/kg per day, with most patients showing regression and only 2% with side effects, none of which were severe.[Level of evidence: 3iiiDiv]
  3. A meta-analysis that evaluated 5,130 patients from 61 studies concluded that propranolol was more effective and safer than were other treatments for infantile hemangioma.
  4. Airway infantile hemangioma lesions are rare; thus, there are limited prospective studies. A meta-analysis of 61 patients noted a trend of decreased treatment failure with increased dosing strategies, which is consistent with the use of higher doses of propranolol in these patients (3 mg/kg/day). The analysis also suggested that the concurrent use of steroids and propranolol may have reduced efficacy in patients with segmental airway hemangiomas, but previous treatment with steroids had no deleterious effect. Additional prospective studies are needed to validate these findings.

Several expert consensus panel recommendations have been reported including recommendations from the FDA and the European Medicines Agency after a randomized controlled trial of oral propranolol in infantile hemangioma patients led to FDA approval.

One paper assessed the safety of outpatient administration of propranolol and evaluated the need for monitoring. In this study, 783 patients with 1,148 office visits were evaluated. No symptomatic bradycardia or hypotension was noted. Blood pressure evaluation was unreliable. The results suggested that outpatient evaluation may not be necessary for standard-risk patients with infantile hemangioma.

Consensus panel recommendations include the following:

  • Initiation of treatment: Treatment should be undertaken in consultation with a pediatric vascular anomaly specialist with expertise in the diagnosis and treatment of pediatric vascular tumors and in the use of propranolol in children. An expert consensus panel suggested that hospitalization for initiation of oral propranolol be considered in the following circumstances:
    • Infant aged 4 weeks or younger (corrected for gestational age).
    • Infant of any age with inadequate social support.
    • Infant of any age with comorbid conditions affecting the cardiovascular or respiratory system, including symptomatic airway infantile hemangiomas.
    • Infant of any age with conditions affecting blood glucose maintenance.

    The pretreatment evaluation (inpatient or outpatient) includes the following:

    • History, with focus on cardiovascular and respiratory abnormalities (e.g., poor feeding, dyspnea, tachypnea, diaphoresis, wheezing, heart murmur) and family history of heart block or arrhythmia.
    • Physical examination including cardiac and pulmonary assessment and measurement of heart rate.
    • No need for echocardiogram or electrocardiogram for standard-risk patients. Two studies found no contraindication to beta-blocker therapy in 6.5% to 25% of patients who had electrocardiogram abnormalities. Electrocardiogram should be considered in children with heart rate lower than normal for age and history of arrhythmia or arrhythmia detected during examination.
    • Family history of congenital heart disease or maternal history of connective tissue disease.
  • Dosing: The dosing used is generally 1 mg/kg per day to 3 mg/kg per day divided into two or three doses. Starting dose varies depending on risk factors and location of initiation. Outpatients and inpatients are initially started at a dose of 0.5 mg/kg per day to 1 mg/kg per day and increased over time. Initially, dosing of three times per day is recommended for infants younger than 5 weeks and for patients with PHACE syndrome.
  • Monitoring: Monitoring varies depending on the institution. However, oral propranolol peaks at 1 to 3 hours after administration and most centers measure heart rate and blood pressure 1 and 2 hours after each dose with initiation and then when the dose is increased by at least 0.5 mg/kg per day. Parent and patient education includes when to hold the medication, signs of hypoglycemia, feeding necessity through the night, and when to call the physician with issues, such as illness, that may interfere with oral intake or lead to dehydration or respiratory problems.
  • Contraindications: Propranolol treatment is contraindicated in infants and children with the following:
    • Sinus bradycardia.
    • Hypotension.
    • Heart block greater than first degree.
    • Heart failure.
    • Asthma.
    • Hypersensitivity.
    • PHACE syndrome. PHACE syndrome with CNS arterial disease and/or coarctation of the aorta may be a relative contraindication. A decision to treat should be made in consultation with neurology and cardiology.
  • Adverse effects: Adverse effects of propranolol include the following:
    • Hypoglycemia.
    • Hypotension.
    • Bradycardia.
    • Sleep disturbance.
    • Diarrhea/constipation.
    • Cold extremities.

    These complications have been reported in several studies, and severe complications have been rare. The risk of these complications is increased in patients with comorbidities and concomitant diseases, including diarrhea, vomiting, and respiratory infections. The need for close monitoring and possible periods of drug discontinuation should be considered during periods of illness.

    A retrospective review of 1,260 children with infantile hemangiomas who were treated with propranolol identified 26 patients (2.1%) with side effects that required discontinuation of propranolol. Severe sleep disturbance was the most common reason for propranolol cessation, accounting for 65.4% of cases. In total, 23 patients received atenolol and 3 patients received prednisolone as second-line therapy. In the multivariate analysis, only younger age (95% confidence interval [CI], 1.201–2.793; P = .009) and lower body weight (95% CI, 1.036–1.972; P = .014) were associated with intolerable side effects.

  • Duration of treatment: There are no consensus guidelines for the treatment duration of propranolol. In a prospective, multi-institutional study that assessed efficacy and safety of propranolol in high-risk patients, the administration of propranolol for a minimum of 6 months, up to a maximum of age 12 months, increased treatment success; dosing of propranolol was 3 mg/kg per day. Treatment results were sustained for up to 3 months after discontinuation of therapy. Efficacy and safety of propranolol in this study were similar to those reported in other studies.
  • Rebound growth after propranolol therapy: Rebound refers to the growth of infantile hemangiomas after propranolol cessation. A multi-institutional, retrospective review of 997 patients with infantile hemangiomas found a rebound rate of 25.3% in 912 patients with adequate data. On univariate analysis, the factors associated with rebound included discontinuation of treatment before age 9 months, female sex, location on head/neck, segmental pattern, and deep or mixed skin involvement. On multivariate analysis, only deep infantile hemangiomas and female sex were significantly related.
  • Late growth of infantile hemangiomas: Growth of a hemangioma can occur in patients older than 3 years, and growth as late as age 8.5 years has been reported. Associated risk factors include segmental morphology, large hemangiomas, PHACE syndrome, and deep cutaneous and subcutaneous lesions in the head and neck.

Selective beta-blocker therapy

Because of the nonselective and lipophilic nature of propranolol with the ability to cross the blood-brain barrier, other beta-blockers are being used for the treatment of infantile hemangiomas. In two small comparison studies, there was no difference in efficacy between propranolol and atenolol. In a retrospective study using nadolol, similar results were seen. A prospective study of 76 infants treated with atenolol noted efficacy and safety similar to propranolol.[Level of evidence: 3iiDiv] Additional studies are needed to assess differences between the toxicities of these agents and the toxicities of propranolol.

There is some suggestion that the more selective beta-blockers have fewer side effects. A study has suggested that the R(+) enantiomer of propranolol, carried over in drug synthesis rather than the anti–beta-adrenergic L(-)enantiomer (commercially available drug is a racemic mixture), may carry the therapeutic anti-infantile hemangioma effect.

Corticosteroid therapy

Before propranolol, corticosteroids were the first line of treatment for infantile hemangiomas. They were first used in the late 1950s but were never approved by the U.S. FDA. Corticosteroid therapy has become less popular secondary to the acute and long-term side effects of steroids (gastrointestinal irritability, immunosuppression, adrenocortical suppression, cushingoid features, and growth failure).

Corticosteroids (prednisone or methylprednisolone) are used at times when there is a contraindication to beta-blocker therapy or as initial treatment while a patient is started on beta-blocker therapy.

Topical beta-blocker therapy

Topical beta-blockers are used mainly for the treatment of small, localized, superficial hemangiomas as an alternative to observation. They have also been used in combination with systemic therapy in complicated hemangiomas or to prevent rebound in a hemangioma being tapered off of systemic treatment. The same precautions (assessment of comorbidities and family history), as noted previously for propranolol, should be followed for topical beta-blockers. Systemic absorption (plasma and urine) of timolol is variable and prescreening for normal cardiac, pulmonary, and endocrine issues are essential, as well as a recent medical history and physical examination. Cautious administration is necessary for ulcerated and deep hemangiomas because higher plasma concentrations of timolol can be seen.

The topical timolol that is used is the ophthalmic gel-forming solution 0.5%. One drop is applied to the hemangioma two times per day until stable response is achieved.

This treatment has limited side effects, but infants with a postmenstrual age of younger than 44 weeks and weight at treatment initiation of less than 2,500 grams may be at risk of adverse events, including bradycardia, hypotension, apnea, and hypothermia. Close monitoring of temperature, blood pressure, and heart rate in premature and low birth weight infants with infantile hemangiomas at initiation of and during therapy with topical timolol is necessary.

Evidence (topical beta-blocker therapy):

  1. In a multicenter, retrospective, cohort study, 731 children with predominantly superficial hemangiomas were treated with topical timolol 0.5% twice daily. Ninety-two percent of patients showed significant improvement in color, and 77% of patients showed improvement in size, extent, and volume. Topical timolol is generally well tolerated. However, data on its safety are limited.

Combined therapy for complicated hemangiomas

Combined therapy is considered either at initiation of treatment in complicated lesions in which there is functional impairment or organ compromise or used at the end of systemic therapy to prevent regrowth of the hemangioma rebound. Further investigation of efficacy and safety is needed for these regimens.

Evidence (combined therapy for complicated hemangiomas):

  1. A prospective randomized study that compared propranolol and 2 weeks of steroid therapy with propranolol alone revealed a decrease in the size of the hemangioma at 2, 4, and 8 weeks but no statistical difference in the size at 6 months.
  2. A prospective randomized study that compared timolol and propranolol with propranolol alone reported a decrease in color of the infantile hemangioma in the timolol group but no difference in overall size of the infantile hemangioma between the two treatment groups.
  3. Topical therapy with timolol combined with oral propranolol has been used.[Level of evidence: 3iiDiv]
infantile hemangioma

Treatment options under clinical evaluation for infantile hemangiomas

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Congenital Hemangiomas

Congenital hemangiomas are benign vascular tumors that proliferate in utero. Development of these lesions is complete at birth. Histologically, these lesions are GLUT1 negative, unlike infantile hemangiomas. They are usually cutaneous, but can be found in the viscera. Complications include hemorrhage, transient heart failure, and transient coagulopathy.

To the clinician unfamiliar with these lesions, congenital hemangiomas can be difficult to diagnose. Diagnostic criteria include a purpuric lesion fully formed at birth, frequently with a halo around the lesion, with high flow noted on ultrasound imaging. Essential to the diagnosis is observation of decrease in size over time or stability. These lesions do not enlarge unless there is hemorrhage into the tumor.

Somatic activating mutations of GNAQ and GNA11 have been found to be associated with congenital hemangiomas. Additional research is necessary to assess the significance of these findings, as this may aid in diagnosis and pathophysiology.

Congenital hemangiomas are divided into the following three forms:

  • Rapidly involuting congenital hemangiomas (RICH). These lesions are large high-flow lesions that are completely formed at birth but rapidly involute by 12 to 15 months. They can ulcerate and bleed and can cause transient heart failure and mild coagulopathy. After involution, usually some residual changes in the skin are present (refer to Figure 6). In a retrospective case series of congenital hemangiomas, several high-risk ultrasound findings were noted for RICH. Venous lakes were associated with cardiac failure, and an increased risk of bleeding was noted with venous lakes and venous ectasia. Infants with RICH should be evaluated with ultrasonography and monitored closely if these high-risk features are noted.

    Photographs showing a cutaneous congenital hemangioma on the inner right thigh at birth (left panel), 1 month (middle panel), and 1 year (right panel).Figure 6. Typical appearance of a cutaneous congenital hemangioma at birth. Note the pedunculated mass. This RICH lesion involuted over time but some residual skin changes remained. Credit: Denise Adams, M.D.

  • Partial involuting congenital hemangiomas (PICH). These lesions are completely formed at birth and involute only partially.
  • Non-involuting congenital hemangiomas (NICH). These lesions are formed at birth and never involute. Depending on the location of the lesions and whether they cause functional impairment, the lesions may need to be removed surgically.

Benign Vascular Tumors of the Liver

In the literature, vascular liver tumors are usually classified as liver hemangioendotheliomas, a broad classification no longer in use. These tumors are classified according to their clinical characteristics and radiologic assessment.

Lesions are usually divided into the following three categories:

  • Focal vascular lesions (congenital hemangiomas).
  • Multiple liver lesions (infantile hemangiomas).
  • Diffuse liver lesions (infantile hemangiomas).

On MRI, vascular liver tumors are hyperintense on T2 imaging and hypointense on T1 imaging, with postcontrast imaging demonstrating early peripheral enhancement with eventual diffuse enhancement.

Focal vascular lesions (congenital hemangiomas)

Focal lesions of the liver are usually congenital hemangiomas (RICH or NICH) (refer to Figure 7). RICH can present with symptoms of heart failure and mild to moderate coagulopathy, but are typically detected by antenatal ultrasonography or as an asymptomatic mass in the newborn period.

Treatment options for focal vascular lesions include the following:

  1. Supportive management. Most lesions are asymptomatic and can be monitored through involution using ultrasonography.
  2. Embolization is considered for severe symptomatic shunting that is unresponsive to treatment for congestive heart failure. These procedures need to be performed by interventional radiologists with expertise in vascular anomalies.
  3. Surgery. Patients with massive focal symptomatic hepatic congenital hemangioma unresponsive to supportive management or radiological intervention may be surgical candidates for resection. This is a rare circumstance and needs to be evaluated by an interdisciplinary vascular anomaly team.

No medication has proven to be an effective treatment for these lesions, and infants need to be supported during this initial period until involution begins. These lesions may be diagnosed prenatally. In rare situations, maternal treatment with medications such as steroids appeared to be effective but, more likely, natural involution may have been responsible.

MRI image of a single liver lesion (intrahepatic congenital hemangioma).Figure 7. Single liver lesion (intrahepatic congenital hemangioma). MRI image of a congenital hemangioma. Note the central enhancement, which is typical for an intrahepatic congenital hemangioma. Credit: Denise Adams, M.D.

Multiple liver lesions (infantile hemangiomas)

Multifocal hepatic lesions are infantile hemangiomas. Multifocal lesions may not need to be treated if the patient is asymptomatic, and they typically follow the same proliferative and involution course as cutaneous hemangiomas. These lesions are monitored closely and if there is growth, propranolol therapy should be considered. If propranolol is needed, doses of up to 2 mg/kg per day are effective.

Diffuse liver lesions (infantile hemangiomas)

Diffuse liver lesions are very serious (refer to Figure 8). Complications include hypothyroidism caused by the expression of iodothyronine deiodinase, high-output or congestive heart failure, and abdominal compartment syndrome.

CT image of diffuse liver lesions.Figure 8. Diffuse liver lesions with classical imaging on CT. Note the peripheral enhancement in early contrast phase. Credit: Denise Adams, M.D.

Treatment options for diffuse liver lesions may include the following:

  1. Propranolol: Beta-blockers are the most common treatment for diffuse and some multifocal infantile hemangiomas of the liver. Treatment doses of 2 to 3 mg/kg per day are indicated.
  2. Thyroid hormone replacement: Thyroid hormone replacement therapy must be aggressive if hypothyroidism is diagnosed; treatment with higher doses of hormones may be needed because the deficiency is caused by the aggressive consumption of the hormone by the tumor.
  3. Chemotherapy: Steroids, cyclophosphamide, and vincristine have been used to treat diffuse liver infantile hemangioma.
  4. Transplant: If a patient does not respond to medical management, a transplant may be indicated. Transplant is considered only for patients with severe diffuse lesions who have multisystem organ failure and there is insufficient time for effective pharmacologic therapy.

There have been isolated reports of malignancy in patients with diffuse hepatic infantile hemangiomas. It is not clear if all cases were transformation of a benign lesion to a malignant phenotype; however, if the lesion does not respond to standard therapy, biopsy should be considered. Further evaluation and consensus is needed to assess whether these patients need to be monitored over a longer period of time with liver ultrasonography. (Refer to the Angiosarcoma of the Soft Tissue section of this summary for more information.)

The differential diagnosis of vascular liver lesions always includes malignant liver tumors; thus, alpha-fetoprotein (AFP) should be included in the initial lab work. AFP is very high in all newborns, but will rapidly fall to normal levels in several months. AFP levels should rapidly diminish, but failure to do so or a rising trend of AFP should elicit concern for hepatoblastoma. There are no prospective studies investigating AFP elevation in hemangioma. Some hypervascular hepatoblastomas in neonates with congestive heart failure have been mistaken for infantile hemangiomas. Other tumors in the differential diagnosis include angiosarcoma, metastatic neuroblastoma, and mesenchymal hamartomas. If there is any question about the diagnosis, a biopsy is recommended, although bleeding is a risk of the procedure.

Spindle Cell Hemangioma

Clinical presentation

Spindle cell hemangiomas, initially called spindle cell hemangioendotheliomas, often occur as superficial (skin and subcutis), painful lesions involving distal extremities in children and adults. The tumors appear as red-brown or bluish lesions that can begin as a single nodule and develop into multifocal painful lesions over years. The lesions can be seen in Maffucci syndrome (cutaneous spindle cell hemangiomas occurring with cartilaginous tumors, enchondromas) and Klippel-Trénaunay syndrome (capillary/lymphatic/venous malformations), generalized lymphatic anomalies, lymphedema, and organized thrombus. In Maffucci syndrome, spindle cell hemangiomas are associated with IDH1 or IDH2 mutations.

These tumors are well circumscribed, occasionally contain phleboliths, and consist of cavernous blood spaces alternating with areas of nodular spindle cell proliferation. A significant percentage of spindle cell hemangiomas are completely intravascular. The vein containing the tumor is abnormal, as are blood vessels apart from the tumor mass.

Treatment of spindle cell hemangioma

There is no standard treatment for spindle cell hemangioma because it has not been studied in clinical trials. Surgical removal is usually curative, although there is a risk of recurrence.

Epithelioid Hemangioma

Clinical presentation

Epithelioid hemangiomas (EH) are benign lesions that usually occur in the skin and subcutis but can occur in other areas such as the bone, with focal and multifocal lesions. Epithelioid hemangiomas may be a reactive process, as they can be associated with local trauma and can develop in pregnancy. Patients usually present with local swelling and pain at the involved site. In the bone, they present as well-defined lytic lesions that involve the metaphysis and diaphysis of long bones. They can have a mixed lytic and sclerotic pattern of bone destruction.

On pathologic evaluation, they have small caliber capillaries with eosinophilic, vacuolated cytoplasm and large oval, grooved, and lobulated nuclei. The endothelial cells are plump and are mature, well-formed vessels surrounded by multiple epithelioid endothelial cells within abundant cytoplasm. They lack cellular atypia and mitotic activity. In 58 cases of epithelioid hemangiomas, 29% were found to have FOS gene rearrangements noted more in cellular epithelioid hemangiomas and intraosseous lesions compared with those in the skin, soft tissue, and head and neck. This genetic abnormality can be helpful in distinguishing epithelioid hemangiomas from other malignant epithelioid vascular tumors.

A single-institution report reviewed 11 patients with epithelioid hemangiomas (median age, 14.4 years) who were diagnosed between 1999 and 2017. Lesions occurred in the lower extremities (five patients), skull (three patients), pelvis (two patients), and spine (one patient). Five patients had multifocal disease. Patients presented with localized pain and neurologic symptoms, including cranial nerve injury. No significant cytologic atypia was noted, and the endothelial cells were positive for CD31 and ERG, and negative for cytokeratin and CAMPTA1. Median follow-up was 1.5 years. Various modalities of treatments were used, including surgery, endovascular embolization, cryoablation, and medical management. One patient received sirolimus, and another patient received interferon; the lesions of both patients shrank within the first year of follow-up. The youngest patient, aged 2.5 years, had multifocal skull lesions that regressed partially by 1 year later without treatment.

Treatment of epithelioid hemangioma

There is no standard treatment for epithelioid hemangioma because it has not been studied in clinical trials. Treatment consists of curettage, sclerotherapy, and resection, or rarely, radiation therapy.

Pyogenic Granuloma (Lobular Capillary Hemangioma)

Clinical presentation

Pyogenic granulomas (PG), known as lobular capillary hemangiomas, are benign reactive lesions that can present at any age, including infancy, although it is most common in older children and young adults. They can present as single or multiple lesions. These lesions can arise spontaneously, in sites of trauma, or within capillary and arteriovenous malformations. Pyogenic granulomas have also been associated with medications including oral contraceptives and retinoids. Most occur as solitary growths, but multiple (grouped) or rarely disseminated lesions have been described. These lesions appear as small or large, smooth or lobulated vascular nodules that can grow rapidly, sometimes over weeks to months and have a tendency to bleed profusely. These lesions are usually cutaneous, but deep-seated/subcutaneous pyogenic granulomas have been reported and mimic other vascular lesions.

Pyogenic granuloma can be associated with capillary malformations. The pathogenesis of pyogenic granulomas associated with capillary malformations and those that are sporadic are unknown. A study investigated ten patients with pyogenic granulomas arising from a capillary malformation and found eight with BRAF c.1799T>A mutations, one with an NRAS c.182A>G mutation, and one with a GNAQ c.548G>A mutation. This GNAQ mutation was also found in the underlying capillary malformation. In 25 patients with pyogenic granulomas and no capillary malformation, 3 patients had BRAF c.1799T>A mutations and 1 patient had a KRAS c.37G>C mutation. These genetic findings will help with future treatment modalities for this benign vascular tumor.

Histologically, these lesions are composed of capillaries and venules with plump endothelial cells separated into lobules by fibromyxoid stroma. Some untreated lesions eventually atrophy, become fibromatous, and slowly regress.

Treatment of pyogenic granuloma

Full-thickness excision is the treatment with the lowest recurrence rate (around 3%), but curettage, laser photocoagulation, or cryotherapy can also be used. A small case series of four patients with acquired ocular surface pyogenic granulomas were treated with topical timolol 0.5% twice daily for 21 days. In all cases, complete resolution with no recurrence occurred for at least 3 months. More studies are needed to validate these findings. A study of 22 patients with pyogenic granulomas who were treated with topical 1% propranolol ointment with occlusion found that 59% of patients achieved complete responses (mean, 66 days), 18% of patients had stable disease, and 22% of patients did not respond to the treatment. In this study, only skin toxicity was assessed. The authors did not comment on the penetrance of the propranolol formulation or include a safety evaluation of the side effects such as hypoglycemia and the effects on heart rate or blood pressure.

Angiofibroma

Clinical presentation

Angiofibromas are rare, benign neoplasms in the pediatric population. Typically, they are cutaneous lesions associated with tuberous sclerosis, appearing as red papules on the face.

Treatment of angiofibroma

Excision of the tumor, laser treatments, and topical treatments, such as sirolimus, have been used.

A prospective, randomized, placebo-controlled trial of sirolimus gel showed significant improvement in 60% of the patients assigned to receive sirolimus. A second prospective, multicenter, randomized, double-blind, vehicle-controlled study with six monthly clinic visits enrolled 179 patients with tuberous sclerosis complex–related facial angiofibromas. This study also showed a statistically and clinically significant improvement in patients treated with a topical formulation containing 0.3 g per 30 g (1%) of rapamycin.

Juvenile Nasopharyngeal Angiofibroma

Clinical presentation

Juvenile nasopharyngeal angiofibromas (JNA) account for 0.5% of all head and neck tumors. While juvenile nasopharyngeal angiofibromas have not classically been included among vascular tumors, histologically, these tumors appear to be vascular tumors, with cells expressing vascular endothelial marker CD31, as well as VEGFA and VEGFR1. Despite their benign-appearing histology, juvenile nasopharyngeal angiofibromas can be locally destructive, spreading from the nasal cavity to the nasopharynx, paranasal sinuses, and orbit skull base, with intracranial extension. Some publications have suggested a hormonal influence on juvenile nasopharyngeal angiofibroma, with emphasis on the molecular mechanisms involved.

Treatment of juvenile nasopharyngeal angiofibroma

Surgical excision is the treatment of choice but this can be challenging because of the extent of the lesion. A single-institution retrospective review of juvenile nasopharyngeal angiofibromas identified 37 patients with lateral extension. Anterior lateral extension to the pterygopalatine fossa occurred in 36 patients (97%) and further to the infratemporal fossa in 20 patients (54%). In 16 patients (43%), posterior lateral spread was observed (posterior to the pterygoid process and/or between its plates). The recurrence rate was 29.7% (11 of 37 patients). The recurrence rate in patients with anterior and/or posterior lateral extension was significantly higher than in patients with anterior lateral extension only.

Juvenile nasopharyngeal angiofibromas have also been treated with radiation therapy, chemotherapy, alpha-interferon therapy, and sirolimus.

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Intermediate Tumors (Locally Aggressive)

Kaposiform Hemangioendothelioma and Tufted Angioma

Kaposiform hemangioendothelioma (KHE) and tufted angioma are rare vascular tumors that typically occur during infancy or early childhood but have been reported in adults. Both tumors are thought to be a spectrum of the same disease, because both can be locally aggressive and cause Kasabach-Merritt phenomenon, a serious life-threatening coagulopathy characterized by profound thrombocytopenia and hypofibrinogenemia. They are discussed here as a single entity, kaposiform hemangioendothelioma.

Incidence

The exact incidence of kaposiform hemangioendothelioma is unknown but is estimated to be 0.07 cases per 100,000 children per year. This lesion affects both sexes equally, with most developing in the neonatal period, one-half presenting at birth, and others presenting during childhood or adulthood.

Pathology

Kaposiform hemangioendothelioma is characterized by sheets of spindle cells with an infiltrative pattern in the dermis, subcutaneous fat, and muscle. There are often areas of fibrosis, with dilated thin-walled vessels infiltrated around the areas of spindle cells. Mixed within these areas are nests of rounded epithelioid cells of vascular origin and aggregates of capillaries with round or irregularly shaped lumens containing platelet-rich fibrin thrombi. There are usually abnormal lymphatic spaces, either within or at the periphery of the lesion. The rate of mitosis is variable but usually low. Tufted angioma is characterized by multiple, discrete lobules of tightly packed capillaries (tufts) scattered in the dermis and sometimes in the subcutis, so called cannonball pattern. Mitoses are rare.

The pathogenesis is poorly understood. There is some evidence that kaposiform hemangioendothelioma may be derived from lymphatic endothelium, as the spindle cell expresses the vascular markers CD31 and CD34, the vascular endothelial growth factor receptor-3 (VEGFR-3) (a receptor required for lymphangiogenesis), and the lymphatic markers D2-40 and PROX1. There is no evidence of association with human herpesvirus 8 infection as is present in Kaposi sarcoma. Genomic data are limited. There have been reports of a small number of patients with GNA14 mutations but not in all cases.

Angiopoietin-2 (Ang-2): High serum levels of Ang-2 have been found in high-risk patients with kaposiform hemangioendothelioma and kaposiform lymphangiomatosis. The Ang-2 levels have also been noted to decrease in response to therapy with sirolimus and raises the possibility of an effect on the endothelial cells of the kaposiform hemangioendothelioma tumor. Ang-2 is produced and stored in the endothelial cells and acts as a TEK tyrosine kinase antagonist. Ang-2 can promote neovascularization in conjunction with VEGF, and in humans, Ang-2 is greatly increased in vascular remodeling that occurs with sepsis, inflammation, and lymphangiogenesis. These levels have been used for the diagnosis of vascular tumors and assessment of response to therapy.

Clinical presentation

Kaposiform hemangioendothelioma most frequently involves the extremities and less frequently involves the trunk and head and neck area. Most lesions involve the skin (refer to Figure 9). Deeper lesions (retroperitoneum, thoracic cavity, and muscle) can appear as a bluish-purpuric hue on the skin, whereas superficial lesions can be firm, purpuric or ecchymotic, and painful. Lesions are usually unifocal and growth is expansive and contiguous. Local lymph nodes may be involved, but there are no reports of distant metastasis. Rare multifocal presentations have been reported, mostly in the bone.

Photograph showing a Kaposiform hemangioendothelioma lesion on the right side of the face and neck.Figure 9. Kaposiform hemangioendothelioma with Kasabach-Merritt phenomenon. The lesion is indurated, firm, and warm with petechiae and purpura. Credit: Denise Adams, M.D.

Fifty to seventy percent of patients with kaposiform hemangioendothelioma develop Kasabach-Merritt phenomenon (KMP), which is a life-threatening complication characterized by profound thrombocytopenia (range, 3,000/µL–60,000/µL) and profound hypofibrinogenemia (<1 g/L). D-dimer and fibrin degradation products are elevated. Severe anemia can occur secondary to tumor sequestration. Severe hemorrhage is rare; however, trauma (biopsy, surgical procedure), ulceration, infection, or delay in initiating treatment may induce progression to disseminated intravascular coagulation, serious bleeding, and even death. Aggressive replacement of blood products, especially platelets, can increase the size of the lesion, causing significant pain and should only be considered with active bleeding and under the direction of a vascular anomalies specialist. The risk of developing Kasabach-Merritt phenomenon is highest in patients with congenital lesions, lesions larger than 8 cm, and when kaposiform hemangioendothelioma arises in the retroperitoneum or mediastinum. The mortality rate is unclear but it has been reported to be as high as 30%.

Diagnostic evaluation

The diagnosis is based on the combination of clinical, histologic, and imaging features. Laboratory evaluation is essential for the diagnosis of Kasabach-Merritt phenomenon. Whenever possible, histologic confirmation should be obtained, because prolonged therapy is often needed. However, if clinical and imaging findings are highly suggestive of the diagnosis, deferring biopsy may be an option but this decision should be reached via an interdisciplinary discussion and approach.

Magnetic resonance imaging (MRI) is the preferred imaging modality, especially for kaposiform hemangioendothelioma with Kasabach-Merritt phenomenon and large lesions. T1-weighted sequences typically show a poorly circumscribed soft tissue mass with soft tissue and dermal thickening and diffuse enhancement with gadolinium. T2-weighted sequences show a diffuse increased signal, with stranding in the subcutaneous fat. Gradient sequences show mildly dilated vessels in and around the soft-tissue mass.

For small and superficial lesions, ultrasonography can be useful for diagnosis and can distinguish tufted angioma from kaposiform hemangioendothelioma. Kaposiform hemangioendothelioma has a more infiltrative pattern, while tufted angioma is more superficial. Tufted angiomas are well defined and hyperechoic, while kaposiform hemangioendotheliomas have ill-defined borders and mixed echogenicity. Kaposiform hemangioendotheliomas also have an increased vascular density than do tufted angiomas.

Treatment of kaposiform hemangioendothelioma and tufted angioma

Treatment varies according to size, location, presence of symptoms, and severity of coagulopathy; there is no evidence-based standard of care. Kaposiform hemangioendothelioma and tufted angioma that are not complicated and are localized can be treated with surgical excision, pulse-dye laser, or topical agents (steroids, sirolimus, or tacrolimus). Observation is also an option for patients with low-risk tumors (i.e., no Kasabach-Merritt phenomenon, small tumor size, asymptomatic). Spontaneous regression and/or stability has been noted for kaposiform hemangioendothelioma and tufted angioma.

Surgical excision may be possible for lesions that have failed medical management or are life threatening. Embolization may be performed in conjunction with surgery or medical therapy; usually it is a temporizing measure.

Patients who have Kasabach-Merritt phenomenon and/or functional compromise and are symptomatic need aggressive therapy. An American and Canadian multidisciplinary expert panel published guidelines for the management of complicated kaposiform hemangioendothelioma. A number of treatment therapies have been reported but none have been uniformly effective.

The most common treatment option for kaposiform hemangioendothelioma has traditionally been steroid therapy with or without vincristine or other agents; however, many institutions are now using the mTOR inhibitor sirolimus, with or without steroid therapy, as primary treatment for high-risk patients. Steroid therapy has not been effective as a single agent for complicated kaposiform hemangioendothelioma, even at high doses. Patients treated with steroid therapy have a response rate of 10% to 20% and a significant number of side effects. Steroid therapy is currently being used in combination therapy with vincristine or sirolimus.

The following is a summary of treatment options for complicated kaposiform hemangioendothelioma:

Vincristine

Vincristine was shown to have a hematologic response and reduction in tumor volume in patients with high-risk kaposiform hemangioendothelioma. Furthermore, in a retrospective review of 37 children with kaposiform hemangioendothelioma whose lesions did not respond to steroids, 26 of the lesions achieved complete remission, with platelet counts reaching normal levels within 7.6 (± 5.2) weeks after vincristine treatment.[Level of evidence: 3iiiDiv] Vincristine monotherapy in other studies has not been shown to be effective. In 2013, consensus guidelines for the management of complicated kaposiform hemangioendothelioma proposed, on the basis of available evidence, the use of vincristine with or without steroids as the first-line therapy. Successful management of patients with kaposiform hemangioendothelioma who were treated with vincristine and ticlopidine has also been reported.

Sirolimus

Secondary to promising case reports, case series, and a prospective clinical trial, sirolimus may be considered an alternative first-line therapy for kaposiform hemangioendothelioma. There are limited studies investigating the effect of sirolimus on kaposiform hemangioendothelioma/tufted angioma without Kasabach-Merritt phenomenon.

Reports that support the use of sirolimus include the following:

  1. A prospective study that assessed the efficacy and safety of sirolimus for the treatment of complicated vascular anomalies treated 13 patients with kaposiform hemangioendothelioma.
    • In patients with kaposiform hemangioendothelioma and Kasabach-Merritt phenomenon, ten of ten patients had partial responses, with normalization of their platelet count and fibrinogen at the end of 6 and 12 courses.
    • Of the three patients with kaposiform hemangioendothelioma without Kasabach-Merritt phenomenon, one patient with multifocal bony disease had disease progression, whereas the other two patients experienced partial responses by the end of course 12.
    • Side effects were minimal in this group of young patients, and no patient with kaposiform hemangioendothelioma required a dose adjustment or was removed from the study secondary to toxicity of sirolimus.
  2. A retrospective study of sirolimus therapy in patients who had nearly all received previous other treatments reported a complete response rate of 73%. All patients assessed as having Kasabach-Merritt phenomenon had recovery of platelet counts between 1 day and 3 weeks (mean, 1.3 weeks).
    • One death occurred in this study from a respiratory infection in a child with multifocal disease involving the thoracic cavity, with pleural effusion. Biopsy was not routinely used in this study to confirm diagnosis, raising the possibility that this child had an unrecognized complex lymphatic anomaly.
  3. A multicenter, retrospective cohort study analyzed 52 Chinese patients with progressive kaposiform hemangioendothelioma. Thirty-seven patients (71%) had Kasabach-Merritt phenomenon. Those without Kasabach-Merritt phenomenon received sirolimus alone, and 21 of the patients with Kasabach-Merritt phenomenon received a combination of sirolimus and prednisone.
    • Overall, 96% and 98% of patients demonstrated improvement in notable symptoms and/or had improved complications at 6 and 12 months, respectively.
  4. A single case report of a child with kaposiform hemangioendothelioma who developed recurrence of pain and fibrosis years after initial therapy and was treated with sirolimus for 26 months observed the following:
    • The patient's contracture and range of motion improved, the lesion shrank, and the child was well 2 years later.

Dosing of sirolimus: Most high-risk patients (kaposiform hemangioendothelioma with Kasabach-Merritt phenomenon) are treated with sirolimus blood levels of 8 to 10 ng/ml.

Supportive care and close monitoring of infants on sirolimus

A case report described two children with kaposiform hemangioendothelioma and Kasabach-Merritt syndrome who died of pulmonary infections after treatment with sirolimus. Another child who received sirolimus and prednisolone developed Pneumocystis jirovecii pneumonia. P. jirovecii pneumonia prophylaxis and close monitoring of patients on sirolimus (especially infants) is encouraged.

Propranolol therapy

Propranolol therapy has been reported as a treatment option for kaposiform hemangioendothelioma. Its use is based on the positive results of propranolol for other more benign vascular tumors. Results have been mixed, with a report of improved effectiveness using higher doses of propranolol. Preliminary results indicate that propranolol should be reserved for patients with kaposiform hemangioendothelioma without Kasabach-Merritt phenomenon and with smaller, less complicated lesions.

Long-term outcomes

Even with therapy, these lesions do not fully regress and can recur; worsened symptomatology (pain, inflammation) can occur with age, especially around the time of puberty.

Long-term effects include chronic pain, lymphedema, heart failure, and orthopedic issues. These lesions prove to be a difficult dilemma for the practitioner because they have a varied clinical spectrum and response to therapy.

Treatment options under clinical evaluation for kaposiform hemangioendothelioma

Information about National Cancer Institute (NCI)–supported clinical trials can be found on the NCI website. For information about clinical trials sponsored by other organizations, refer to the ClinicalTrials.gov website.

References

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Intermediate Tumors (Rarely Metastasizing)

Intermediate vascular tumors (rarely metastasizing) include the following:

  • Pseudomyogenic hemangioendothelioma.
  • Retiform hemangioendothelioma.
  • Papillary intralymphatic angioendothelioma.
  • Composite hemangioendothelioma.
  • Kaposi sarcoma.

Pseudomyogenic Hemangioendothelioma

Incidence and outcome

Pseudomyogenic hemangioendothelioma is a rare, newly designated, distinct vascular tumor. It is characterized as an intermediate-grade tumor with moderately aggressive local spread and rare distant metastatic disease.

Pathology and biology

Pseudomyogenic hemangioendothelioma is characterized by loose fascicles of plump spindle and epithelioid cells with abundant eosinophils, cytoplasm, and coexpression of keratins and endothelial markers. The etiology for this tumor is unclear, although a balanced translocation t(7;19) resulting in the SERPINE1-FOSB fusion gene has been reported.

Clinical presentation and diagnostic evaluation

The tumor usually presents in young men aged 20 to 50 years. Multifocal disease occurs in 70% of patients. Sites of involvement include the dermis, subcutis, and bones. Patients usually present with pain or a soft tissue mass.

Treatment of pseudomyogenic hemangioendothelioma

Most patients are treated with surgery, including amputation for multifocal bony disease. In reported cases, chemotherapy has produced responses. Recently, the mammalian target of rapamycin (mTOR) inhibitors have been considered as treatment options. An additional case report noted efficacy of sirolimus with the addition of zoledronic acid in a patient with multifocal bony disease.

Retiform Hemangioendothelioma

Pathology and clinical presentation

Retiform hemangioendotheliomas are slow growing, exophytic, flat tumors found in young adults and occasionally children. They are usually located in the limbs and trunk. Histologically, they are located in the dermis and subcutaneous tissue. Vessels exhibit a pattern resembling the rete testis and are lined by protruding endothelial cells. They do not express lymphatic markers but stain positive for endothelial markers.

Prognostic factors

Local recurrences are common, but distinct metastases are extremely rare.

Treatment of retiform hemangioendothelioma

Surgical excision with adequate surgical tumor margins and monitoring for local recurrence is the treatment for this tumor. There are case reports of the use of radiation therapy and chemotherapy for inoperable and recurrent tumors.

Papillary Intralymphatic Angioendothelioma

Pathology and clinical presentation

Papillary intralymphatic angioendothelioma, also known as Dabska tumor, can occur in the adult and pediatric population. The lesions occur in the dermis and subcutis on all body parts and there have been some reports of lymph node involvement. They can be large or small raised purplish firm nodules.

Pathologically, they reveal intravascular growth of well-differentiated endothelial cells in a columnar configuration. They have thickened hyaline walls with hobnailed endothelium. Vascular endothelial growth factor receptor type 3, a marker for lymphatic endothelium, is positive in most cases. There is minimal cytologic atypia. Some are associated with vascular malformations.

Treatment of papillary intralymphatic angioendothelioma

Surgical excision is the treatment of choice.

Composite Hemangioendothelioma

Pathology and clinical presentation

Composite hemangioendothelioma is a very rare vascular tumor classified as intermediate because of the combined benign and malignant vascular components. Usually, combined epithelioid and retiform variants are noted but some tumors have three components (epithelioid, retiform, and spindle cell). Angiosarcoma foci have been noted. Pathology reveals positivity for CD31, factor VIII, and vimentin. Rarely, D-240 is positive with a Ki-67 index of approximately 20%.

This tumor usually occurs in the dermis and subcutis of the distal extremities but has been found in other areas such as the head, neck, and mediastinum. They have been reported in all age groups.

Prognostic factors

Composite hemangioendotheliomas recur locally and rarely metastasize. Regional lymph nodes are the most likely site of metastasis and require imaging evaluation for surveillance.

Treatment of composite hemangioendothelioma

Surgical removal is the treatment of choice, although radiation therapy and chemotherapy have been used for metastatic disease.

Kaposi Sarcoma

Pathology and clinical presentation

Kaposi sarcoma (KS) is a rare malignant vascular tumor associated with a viral etiology (human herpesvirus 8). The skin lesions were first described in 1872 by Moritz Kaposi. The incidence has increased worldwide secondary to the HIV-AIDS epidemic. It is an extremely rare diagnosis in children. Epidemic and iatrogenic forms of Kaposi sarcoma in children result from profound acquired T-cell deficiency that results from HIV infection and rare immune disorders.

A retrospective study has investigated the presentation of Kaposi sarcoma in children in endemic areas of Africa. Children usually present with cutaneous lesions, lymphadenopathy, and intrathoracic and oral lesions. Cutaneous lesions initially appear as red, purple, or brown macules, later developing into plaques and then nodules.

Kaposi sarcoma is exceedingly rare in the pediatric population and is usually associated with immunocompromised states such as HIV infection or solid organ transplant.

Treatment of Kaposi sarcoma

Children with Kaposi sarcoma have responded to treatment with chemotherapy regimens, including bleomycin, vincristine, and taxanes, although there are no prospective clinical trials. Other treatment options have been based on adult studies (see below).

Because Kaposi sarcoma is rare in the pediatric population, there are no evidence-based studies. Even in adults, the evidence and quality of studies are poor, and it is difficult to recommend particular treatment regimens. Fifty-six Malawian children aged 3 to 12 years with Kaposi sarcoma were treated with six courses of vincristine, bleomycin, and oral etoposide. This was a high-risk population because 48 of the patients (86%) were HIV positive, of whom 36 (77%) were on antiretroviral therapy. Quality of life improved in 45 patients (80%). Eighteen patients (32%) had a complete remission. At 12 months, the overall survival rate was 71%, and the event-free survival rate was 50%.[Level of evidence: 3iiA]

In a systematic review of treatment for classic Kaposi sarcoma, 26 articles published from 1980 to 2010 were reviewed; articles describing populations at high risk secondary to previous transplantation and endemic and epidemic Kaposi sarcoma were excluded. All articles had a minimum of five patients per intervention. A greater than 50% decrease in the size of the lesions or lymphedema was considered a response. The quality of the articles was considered poor, primarily because of lack of uniform staging criteria and variable means of assessing response. The following response rates for systemic treatments were noted:

  • Pegylated doxorubicin: 71% to 100%.
  • Vinca alkaloids: 58% to 90%.
  • Etoposide: 74% to 76%.
  • Taxanes: 93% to 100%.
  • Gemcitabine: 100%.
  • Vinblastine and bleomycin: 97%.
  • Interferon alfa-2: 71% to 100%.

For local therapies, the following response rates were reported:

  • Intralesional vincristine: 62%.
  • Intralesional interferon alfa-2: 50% to 90%.
  • Imiquimod: 56%.
  • Radiation therapy: 63% to 93%.

(Refer to the PDQ summary on Kaposi Sarcoma Treatment for information about the treatment of Kaposi sarcoma in adults.)

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  8. Ozeki M, Nozawa A, Kanda K, et al.: Everolimus for Treatment of Pseudomyogenic Hemangioendothelioma. J Pediatr Hematol Oncol 39 (6): e328-e331, 2017.
  9. Danforth OM, Tamulonis K, Vavra K, et al.: Effective Use of Sirolimus and Zoledronic Acid for Multiosteotic Pseudomyogenic Hemangioendothelioma of the Bone in a Child: Case Report and Review of Literature. J Pediatr Hematol Oncol 41 (5): 382-387, 2019.
  10. El Darouti M, Marzouk SA, Sobhi RM, et al.: Retiform hemangioendothelioma. Int J Dermatol 39 (5): 365-8, 2000.
  11. Colmenero I, Hoeger PH: Vascular tumours in infants. Part II: vascular tumours of intermediate malignancy [corrected] and malignant tumours. Br J Dermatol 171 (3): 474-84, 2014.
  12. Keiler SA, Honda K, Bordeaux JS: Retiform hemangioendothelioma treated with Mohs micrographic surgery. J Am Acad Dermatol 65 (1): 233-5, 2011.
  13. Hirsh AZ, Yan W, Wei L, et al.: Unresectable retiform hemangioendothelioma treated with external beam radiation therapy and chemotherapy: a case report and review of the literature. Sarcoma 2010: , 2010.
  14. Enjolras O, Mulliken JB, Kozakewich HPW: Vascular tumors and tumor-like lesions. In: Mulliken JB, Burrows PE, Fishman SJ, eds.: Mulliken & Young's Vascular Anomalies: Hemangiomas and Malformations. 2nd ed. New York, NY: Oxford University Press, 2013, pp 259-324.
  15. Tamhankar AS, Vaidya A, Pai P: Retiform hemangioendothelioma over forehead: A rare tumor treated with chemoradiation and a review of literature. J Cancer Res Ther 11 (3): 657, 2015 Jul-Sep.
  16. Dabska M: Malignant endovascular papillary angioendothelioma of the skin in childhood. Clinicopathologic study of 6 cases. Cancer 24 (3): 503-10, 1969.
  17. Fanburr-Smith JC: Papillary intralymphatic angioendothelioma. In: Fletcher CDM, Bridge JA, Hogendoorn P, et al., eds.: WHO Classification of Tumours of Soft Tissue and Bone. 4th ed. Lyon, France: IARC Press, 2013, pp 148.
  18. Neves RI, Stevenson J, Hancey MJ, et al.: Endovascular papillary angioendothelioma (Dabska tumor): underrecognized malignant tumor in childhood. J Pediatr Surg 46 (1): e25-8, 2011.
  19. Shang Leen SL, Fisher C, Thway K: Composite hemangioendothelioma: clinical and histologic features of an enigmatic entity. Adv Anat Pathol 22 (4): 254-9, 2015.
  20. Mahmoudizad R, Samrao A, Bentow JJ, et al.: Composite hemangioendothelioma: An unusual presentation of a rare vascular tumor. Am J Clin Pathol 141 (5): 732-6, 2014.
  21. Tateishi J, Saeki H, Ito K, et al.: Cutaneous composite hemangioendothelioma on the nose treated with electron beam. Int J Dermatol 52 (12): 1618-9, 2013.
  22. Soldado F, Fontecha CG, Haddad S, et al.: Composite vascularized fibular epiphyseo-osteo-periosteal transfer for hip reconstruction after proximal femoral tumoral resection in a 4-year-old child. Microsurgery 32 (6): 489-92, 2012.
  23. Jackson CC, Dickson MA, Sadjadi M, et al.: Kaposi Sarcoma of Childhood: Inborn or Acquired Immunodeficiency to Oncogenic HHV-8. Pediatr Blood Cancer 63 (3): 392-7, 2016.
  24. Dow DE, Cunningham CK, Buchanan AM: A Review of Human Herpesvirus 8, the Kaposi's Sarcoma-Associated Herpesvirus, in the Pediatric Population. J Pediatric Infect Dis Soc 3 (1): 66-76, 2014.
  25. El-Mallawany NK, Kamiyango W, Slone JS, et al.: Clinical Factors Associated with Long-Term Complete Remission versus Poor Response to Chemotherapy in HIV-Infected Children and Adolescents with Kaposi Sarcoma Receiving Bleomycin and Vincristine: A Retrospective Observational Study. PLoS One 11 (4): e0153335, 2016.
  26. Rees CA, Keating EM, Lukolyo H, et al.: Mapping the Epidemiology of Kaposi Sarcoma and Non-Hodgkin Lymphoma Among Children in Sub-Saharan Africa: A Review. Pediatr Blood Cancer 63 (8): 1325-31, 2016.
  27. Macken M, Dale H, Moyo D, et al.: Triple therapy of vincristine, bleomycin and etoposide for children with Kaposi sarcoma: Results of a study in Malawian children. Pediatr Blood Cancer 65 (2): , 2018.
  28. Régnier-Rosencher E, Guillot B, Dupin N: Treatments for classic Kaposi sarcoma: a systematic review of the literature. J Am Acad Dermatol 68 (2): 313-31, 2013.
  29. Tsao MN, Sinclair E, Assaad D, et al.: Radiation therapy for the treatment of skin Kaposi sarcoma. Ann Palliat Med 5 (4): 298-302, 2016.
  30. Singh NB, Lakier RH, Donde B: Hypofractionated radiation therapy in the treatment of epidemic Kaposi sarcoma--a prospective randomized trial. Radiother Oncol 88 (2): 211-6, 2008.
  31. Lebbe C, Garbe C, Stratigos AJ, et al.: Diagnosis and treatment of Kaposi's sarcoma: European consensus-based interdisciplinary guideline (EDF/EADO/EORTC). Eur J Cancer 114: 117-127, 2019.

Malignant Tumors

Malignant vascular tumors include the following:

  • Epithelioid hemangioendothelioma.
  • Angiosarcoma of the soft tissue.

Epithelioid Hemangioendothelioma

Incidence and outcome

This tumor was first described in soft tissue by Weiss and Enzinger in 1982. Epithelioid hemangioendotheliomas can occur at younger ages, but the peak incidence is in the fourth and fifth decades of life. The tumors can have an indolent or very aggressive course, with an overall survival rate of 73% at 5 years. There are case reports of patients with untreated multiple lesions who have a very benign course compared with other patients who have a very aggressive course. Some pathologists have tried to stratify patients to evaluate risks and adjust treatment, but more research is needed.

A multi-institutional case series reported on 24 patients aged 2 to 26 years with epithelioid hemangioendothelioma.[Level of evidence: 3iiiDii] Most patients presented with multiorgan disease. Progression was seen in 63% of patients, with a mean time to progression of 18.4 months (range, 0–72 months).

The presence of effusions, tumor size larger than 3 cm, and a high mitotic index (>3 mitoses/50 high-power fields) have been associated with unfavorable outcomes.

Histopathology and molecular features

A WWTR1-CAMTA1 gene fusion has been found in a large percentage of patients; less commonly, a YAP1-TFE3 gene fusion has been reported. These fusions are not directly targetable with current medicines. Monoclonality has been described in multiple liver lesions, suggesting a metastatic process.

Histologically, these lesions are characterized as epithelioid lesions arranged in nests, strands, and trabecular patterns, with infrequent vascular spaces. Features that may be associated with aggressive clinical behavior include cellular atypia, one or more mitoses per 10 high-power fields, an increased proportion of spindled cells, focal necrosis, and metaplastic bone formation.

The number of pediatric patients reported in the literature is limited.

Clinical presentation and diagnostic evaluation

Common sites of involvement are liver alone (21%), liver plus lung (18%), lung alone (12%), and bone alone (14%). Clinical presentation depends on the site of involvement, as follows:

  • Liver: Hepatic nodules have central vascularity on ultrasound, contrast-enhancing lesions by computed tomography, and low T1 signal and moderate T2 signal on magnetic resonance imaging. These may be incidental findings in asymptomatic patients, but most patients commonly present with signs or symptoms of cholestasis, including pruritus, jaundice, or scleral icterus.
  • Lung: Pulmonary epithelioid hemangioendothelioma may be an asymptomatic finding on chest x-ray or be associated with pleuritic pain, hemoptysis, anemia, and fibrosis.
  • Bone: Bone metastasis may be associated with pathologic fracture. On x-rays, they are well-defined osteolytic lesions and can be multiple or solitary.
  • Soft tissue: Thirty percent of soft tissue cases are associated with metastases, and when present, can have a very aggressive course, with limited response to chemotherapy.
  • Skin: Cutaneous lesions can be raised and nodular or can be warm, red-brown plaques.
childhood epithelioid hemangioendothelioma

Treatment of epithelioid hemangioendothelioma

Treatment options for epithelioid hemangioendothelioma include the following:

  1. Observation.
  2. Surgery.
  3. Immunotherapy.
  4. Targeted therapy.
  5. Chemotherapy.
  6. Radiation therapy.

For indolent cases, observation is warranted. For more aggressive cases, multiple medications have been used, including interferon, thalidomide, sorafenib, pazopanib, and sirolimus. The most aggressive cases are treated with angiosarcoma-type chemotherapy. Surgery is performed when resection is possible. Liver transplant has been used with aggressive liver lesions, both with and without metastases.

A multi-institutional case series reported on 24 patients aged 2 to 26 years with epithelioid hemangioendothelioma.[Level of evidence: 3iiiDii] Three patients who were treated with sirolimus achieved stable disease or a partial response for more than 2.5 years.

Patients or families who desire additional disease-directed therapy should consider entering trials of novel therapeutic approaches because no standard agents have demonstrated clinically significant activity.

Regardless of whether a decision is made to pursue disease-directed therapy at the time of progression, palliative care remains a central focus of management. This ensures that quality of life is maximized while attempting to reduce symptoms and stress related to the terminal illness.

childhood epithelioid hemangioendothelioma

Treatment options under clinical evaluation for epithelioid hemangioendothelioma

Information about National Cancer Institute (NCI)–supported clinical trials can be found on the NCI website. For information about clinical trials sponsored by other organizations, refer to the ClinicalTrials.gov website.

The following is an example of a national and/or institutional clinical trial that is currently being conducted:

  1. NCT03148275 (Trametinib in Treating Patients with Epithelioid Hemangioendothelioma That Is Metastatic, Locally Advanced, or Cannot Be Removed by Surgery): This is a phase II trial assessing the efficacy of trametinib, with patient-reported outcomes as secondary aims.

Current Clinical Trials

Use our advanced clinical trial search to find NCI-supported cancer clinical trials that are now enrolling patients. The search can be narrowed by location of the trial, type of treatment, name of the drug, and other criteria. General information about clinical trials is also available.

Angiosarcoma of the Soft Tissue

Incidence

Angiosarcoma is a rare (accounting for 2% of sarcomas), aggressive, vascular tumor that can arise in any part of the body, but is more common in soft tissues. Angiosarcoma has an estimated incidence of 2 cases per 1 million people; in the United States, it annually affects approximately 600 people who are typically aged 60 to 70 years.

Angiosarcomas are extremely rare in children and it is unclear if the pathophysiology of this tumor is different in the pediatric population. Cases have been reported in neonates and toddlers, with presentation of multiple cutaneous lesions and liver lesions, some of which are GLUT1 positive. Most angiosarcomas involve the skin and superficial soft tissue, although the liver, spleen, and lung can be affected; bone is rarely affected.

Risk factors

Established risk factors include the following:

  • Vinyl chloride exposure.
  • Radiation exposure.
  • Chronic lymphedema from any cause, including Stewart-Treves syndrome.

Histopathology and molecular features

Angiosarcomas are largely aneuploid tumors. The rare cases of angiosarcoma that arise from benign lesions such as hemangiomas have a distinct pathway that needs to be investigated. MYC amplification is seen in radiation-induced angiosarcoma. KDR-VEGFR2 mutations and FLT4-VEGFR3 amplifications have been seen with a frequency of less than 50%.

Histopathologic diagnosis can be very difficult because there can be areas of varied atypia. The common feature is an irregular network of channels in a dissective pattern along dermal collagen bundles. There is varied cellular shape, size, mitosis, endothelial multilayering, and papillary formation. Epithelioid cells can also be present. Necrosis and hemorrhage are common. Tumors stain for factor VIII, CD31, and CD34. Some liver lesions can mimic infantile hemangiomas and have focal GLUT1 positivity. Nomenclature of these liver lesions has been difficult and confusing with use of outdated terminology proposed in 1971 (e.g., type I hemangioendothelioma: infantile hemangioma; type II hemangioendothelioma: low-grade angiosarcoma; type III hemangioendothelioma: high-grade angiosarcoma).

childhood angiosarcoma

Treatment of angiosarcoma of the soft tissue

Treatment options for angiosarcoma of the soft tissue include the following:

  1. Surgery (localized disease).
  2. Radiation therapy (localized cutaneous disease in adults).
  3. Surgery, chemotherapy, and radiation therapy (metastatic disease).

Localized disease can be cured by aggressive surgery. Complete surgical excision appears to be crucial for the long-term survival of patients with angiosarcoma and lymphangiosarcoma despite evidence of tumor shrinkage in some patients who were treated with local or systemic therapy. A review of 222 patients (median age, 62 years; range, age 15–90 years) showed an overall disease-specific survival (DSS) rate of 38% at 5 years. The 5-year DSS rate was 44% in 138 patients with localized, resected tumors but only 16% in 43 patients with metastases at diagnosis. Data on liver transplant for localized angiosarcomas are limited.[Level of evidence: 3iiA]

Localized disease, especially cutaneous angiosarcoma, can be treated with radiation therapy. Most of these reported cases are in adults.

Multimodal treatment with surgery, systemic chemotherapy, and radiation therapy is used for metastatic disease, although it is rarely curative. Disease control is the objective in metastatic angiosarcoma, with published progression-free survival between 3 months and 7 months and a median overall survival (OS) of 14 months to 18 months. In both adults and children, 5-year OS rates between 20% and 35% are reported.

In one child diagnosed with angiosarcoma secondary to malignant transformation from infantile hemangioma, response to treatment with bevacizumab, a monoclonal antibody against vascular endothelial growth factor, combined with systemic chemotherapy, has been reported. A report of eight cases of liver angiosarcoma in children highlighted the misuse of the term hemangioendothelioma and the importance of early diagnosis and treatment of these tumors.

Biologic agents that inhibit angiogenesis have shown activity in adults with angiosarcoma.

Patients or families who desire additional disease-directed therapy should consider entering trials of novel therapeutic approaches because no standard agents have demonstrated clinically significant activity.

Regardless of whether a decision is made to pursue disease-directed therapy at the time of progression, palliative care remains a central focus of management. This ensures that quality of life is maximized while attempting to reduce symptoms and stress related to the terminal illness.

childhood angiosarcoma

Treatment options under clinical evaluation for angiosarcoma of the soft tissue

Information about National Cancer Institute (NCI)–supported clinical trials can be found on the NCI website. For information about clinical trials sponsored by other organizations, refer to the ClinicalTrials.gov website.

The following is an example of a national and/or institutional clinical trial that is currently being conducted:

  1. NCT02834013 (Nivolumab and Ipilimumab in Treating Patients With Rare Tumors): This is a phase II study of nivolumab and ipilimumab to treat patients with rare tumors. Immunotherapy with monoclonal antibodies such as nivolumab and ipilimumab may help the body's immune system attack the cancer and may interfere with the ability of the tumor cells to grow and spread.

Current Clinical Trials

Use our advanced clinical trial search to find NCI-supported cancer clinical trials that are now enrolling patients. The search can be narrowed by location of the trial, type of treatment, name of the drug, and other criteria. General information about clinical trials is also available.

References

  1. Mehrabi A, Kashfi A, Fonouni H, et al.: Primary malignant hepatic epithelioid hemangioendothelioma: a comprehensive review of the literature with emphasis on the surgical therapy. Cancer 107 (9): 2108-21, 2006.
  2. Haro A, Saitoh G, Tamiya S, et al.: Four-year natural clinical course of pulmonary epithelioid hemangioendothelioma without therapy. Thorac Cancer 6 (4): 544-7, 2015.
  3. Sardaro A, Bardoscia L, Petruzzelli MF, et al.: Epithelioid hemangioendothelioma: an overview and update on a rare vascular tumor. Oncol Rev 8 (2): 259, 2014.
  4. Dong K, Wang XX, Feng JL, et al.: Pathological characteristics of liver biopsies in eight patients with hepatic epithelioid hemangioendothelioma. Int J Clin Exp Pathol 8 (9): 11015-23, 2015.
  5. Adams DM, Hammill A: Other vascular tumors. Semin Pediatr Surg 23 (4): 173-7, 2014.
  6. Xiao Y, Wang C, Song Y, et al.: Primary epithelioid hemangioendothelioma of the kidney: the first case report in a child and literature review. Urology 82 (4): 925-7, 2013.
  7. Reich S, Ringe H, Uhlenberg B, et al.: Epithelioid hemangioendothelioma of the lung presenting with pneumonia and heart rhythm disturbances in a teenage girl. J Pediatr Hematol Oncol 32 (4): 274-6, 2010.
  8. Cournoyer E, Al-Ibraheemi A, Engel E, et al.: Clinical characterization and long-term outcomes in pediatric epithelioid hemangioendothelioma. Pediatr Blood Cancer 67 (2): e28045, 2020.
  9. Daller JA, Bueno J, Gutierrez J, et al.: Hepatic hemangioendothelioma: clinical experience and management strategy. J Pediatr Surg 34 (1): 98-105; discussion 105-6, 1999.
  10. Ackermann O, Fabre M, Franchi S, et al.: Widening spectrum of liver angiosarcoma in children. J Pediatr Gastroenterol Nutr 53 (6): 615-9, 2011.
  11. Stacchiotti S, Provenzano S, Dagrada G, et al.: Sirolimus in Advanced Epithelioid Hemangioendothelioma: A Retrospective Case-Series Analysis from the Italian Rare Cancer Network Database. Ann Surg Oncol 23 (9): 2735-44, 2016.
  12. Semenisty V, Naroditsky I, Keidar Z, et al.: Pazopanib for metastatic pulmonary epithelioid hemangioendothelioma-a suitable treatment option: case report and review of anti-angiogenic treatment options. BMC Cancer 15: 402, 2015.
  13. Raheja A, Suri A, Singh S, et al.: Multimodality management of a giant skull base hemangioendothelioma of the sphenopetroclival region. J Clin Neurosci 22 (9): 1495-8, 2015.
  14. Ahmad N, Adams DM, Wang J, et al.: Hepatic epithelioid hemangioendothelioma in a patient with hemochromatosis. J Natl Compr Canc Netw 12 (9): 1203-7, 2014.
  15. Otte JB, Zimmerman A: The role of liver transplantation for pediatric epithelioid hemangioendothelioma. Pediatr Transplant 14 (3): 295-7, 2010.
  16. Cioffi A, Reichert S, Antonescu CR, et al.: Angiosarcomas and other sarcomas of endothelial origin. Hematol Oncol Clin North Am 27 (5): 975-88, 2013.
  17. Jeng MR, Fuh B, Blatt J, et al.: Malignant transformation of infantile hemangioma to angiosarcoma: response to chemotherapy with bevacizumab. Pediatr Blood Cancer 61 (11): 2115-7, 2014.
  18. Dehner LP, Ishak KG: Vascular tumors of the liver in infants and children. A study of 30 cases and review of the literature. Arch Pathol 92 (2): 101-11, 1971.
  19. Ferrari A, Casanova M, Bisogno G, et al.: Malignant vascular tumors in children and adolescents: a report from the Italian and German Soft Tissue Sarcoma Cooperative Group. Med Pediatr Oncol 39 (2): 109-14, 2002.
  20. Deyrup AT, Miettinen M, North PE, et al.: Pediatric cutaneous angiosarcomas: a clinicopathologic study of 10 cases. Am J Surg Pathol 35 (1): 70-5, 2011.
  21. Elliott P, Kleinschmidt I: Angiosarcoma of the liver in Great Britain in proximity to vinyl chloride sites. Occup Environ Med 54 (1): 14-8, 1997.
  22. Lezama-del Valle P, Gerald WL, Tsai J, et al.: Malignant vascular tumors in young patients. Cancer 83 (8): 1634-9, 1998.
  23. Fata F, O'Reilly E, Ilson D, et al.: Paclitaxel in the treatment of patients with angiosarcoma of the scalp or face. Cancer 86 (10): 2034-7, 1999.
  24. Lahat G, Dhuka AR, Hallevi H, et al.: Angiosarcoma: clinical and molecular insights. Ann Surg 251 (6): 1098-106, 2010.
  25. Orlando G, Adam R, Mirza D, et al.: Hepatic hemangiosarcoma: an absolute contraindication to liver transplantation--the European Liver Transplant Registry experience. Transplantation 95 (6): 872-7, 2013.
  26. Sanada T, Nakayama H, Irisawa R, et al.: Clinical outcome and dose volume evaluation in patients who undergo brachytherapy for angiosarcoma of the scalp and face. Mol Clin Oncol 6 (3): 334-340, 2017.
  27. Dickson MA, D'Adamo DR, Keohan ML, et al.: Phase II Trial of Gemcitabine and Docetaxel with Bevacizumab in Soft Tissue Sarcoma. Sarcoma 2015: 532478, 2015.
  28. Scott MT, Portnow LH, Morris CG, et al.: Radiation therapy for angiosarcoma: the 35-year University of Florida experience. Am J Clin Oncol 36 (2): 174-80, 2013.
  29. North PE, Waner M, Mizeracki A, et al.: A unique microvascular phenotype shared by juvenile hemangiomas and human placenta. Arch Dermatol 137 (5): 559-70, 2001.
  30. Boye E, Yu Y, Paranya G, et al.: Clonality and altered behavior of endothelial cells from hemangiomas. J Clin Invest 107 (6): 745-52, 2001.
  31. Ravi V, Patel S: Vascular sarcomas. Curr Oncol Rep 15 (4): 347-55, 2013.
  32. Grassia KL, Peterman CM, Iacobas I, et al.: Clinical case series of pediatric hepatic angiosarcoma. Pediatr Blood Cancer 64 (11): , 2017.

Special Considerations for the Treatment of Children With Cancer

Cancer in children and adolescents is rare, although the overall incidence of childhood cancer has been slowly increasing since 1975. Children and adolescents with cancer should be referred to medical centers that have a multidisciplinary team of cancer specialists with experience treating the cancers that occur during childhood and adolescence. This multidisciplinary team approach incorporates the skills of the primary care physician, a surgeon experienced in vascular tumors, a pathologist, radiation oncologists, pediatric oncologists, rehabilitation specialists, pediatric nurse specialists, social workers, and others to ensure that children receive treatment, supportive care, and rehabilitation that will achieve optimal survival and quality of life. (Refer to the PDQ summaries on Supportive and Palliative Care for specific information about supportive care for children and adolescents with cancer.)

Guidelines for pediatric cancer centers and their role in the treatment of pediatric patients with cancer have been outlined by the American Academy of Pediatrics. At these pediatric cancer centers, clinical trials are available for most types of cancer that occur in children and adolescents, and the opportunity to participate in these trials is offered to most patients and families. Clinical trials for children and adolescents with cancer are generally designed to compare potentially better therapy with therapy that is currently accepted as standard. Most of the progress made in identifying curative therapies for childhood cancers has been achieved through clinical trials. Information about ongoing clinical trials is available from the NCI website.

Dramatic improvements in survival have been achieved for children and adolescents with cancer. Between 1975 and 2010, childhood cancer mortality decreased by more than 50%. Childhood and adolescent cancer survivors require close monitoring because cancer therapy side effects may persist or develop months or years after treatment. (Refer to the PDQ summary on Late Effects of Treatment for Childhood Cancer for specific information about the incidence, type, and monitoring of late effects in childhood and adolescent cancer survivors.)

References

  1. Smith MA, Altekruse SF, Adamson PC, et al.: Declining childhood and adolescent cancer mortality. Cancer 120 (16): 2497-506, 2014.
  2. Corrigan JJ, Feig SA; American Academy of Pediatrics: Guidelines for pediatric cancer centers. Pediatrics 113 (6): 1833-5, 2004.

Changes to This Summary (06/24/2020)

The PDQ cancer information summaries are reviewed regularly and updated as new information becomes available. This section describes the latest changes made to this summary as of the date above.

This summary was comprehensively reviewed.

This summary is written and maintained by the PDQ Pediatric Treatment Editorial Board, which is editorially independent of NCI. The summary reflects an independent review of the literature and does not represent a policy statement of NCI or NIH. More information about summary policies and the role of the PDQ Editorial Boards in maintaining the PDQ summaries can be found on the About This PDQ Summary and PDQ® - NCI's Comprehensive Cancer Database pages.

About This PDQ Summary

Purpose of This Summary

This PDQ cancer information summary for health professionals provides comprehensive, peer-reviewed, evidence-based information about the treatment of childhood vascular tumors. It is intended as a resource to inform and assist clinicians who care for cancer patients. It does not provide formal guidelines or recommendations for making health care decisions.

Reviewers and Updates

This summary is reviewed regularly and updated as necessary by the PDQ Pediatric Treatment Editorial Board, which is editorially independent of the National Cancer Institute (NCI). The summary reflects an independent review of the literature and does not represent a policy statement of NCI or the National Institutes of Health (NIH).

Board members review recently published articles each month to determine whether an article should:

  • be discussed at a meeting,
  • be cited with text, or
  • replace or update an existing article that is already cited.

Changes to the summaries are made through a consensus process in which Board members evaluate the strength of the evidence in the published articles and determine how the article should be included in the summary.

The lead reviewers for Childhood Vascular Tumors Treatment are:

  • Denise Adams, MD (Children's Hospital Boston)
  • Julie Blatt, MD (University of North Carolina)
  • Louis S. Constine, MD (James P. Wilmot Cancer Center at University of Rochester Medical Center)
  • Holcombe Edwin Grier, MD
  • Paul A. Meyers, MD (Memorial Sloan-Kettering Cancer Center)
  • Thomas A. Olson, MD (Aflac Cancer and Blood Disorders Center of Children's Healthcare of Atlanta - Egleston Campus)
  • Alberto S. Pappo, MD (St. Jude Children's Research Hospital)
  • Stephen J. Shochat, MD (St. Jude Children's Research Hospital)

Any comments or questions about the summary content should be submitted to Cancer.gov through the NCI website's Email Us. Do not contact the individual Board Members with questions or comments about the summaries. Board members will not respond to individual inquiries.

Levels of Evidence

Some of the reference citations in this summary are accompanied by a level-of-evidence designation. These designations are intended to help readers assess the strength of the evidence supporting the use of specific interventions or approaches. The PDQ Pediatric Treatment Editorial Board uses a formal evidence ranking system in developing its level-of-evidence designations.

Permission to Use This Summary

PDQ is a registered trademark. Although the content of PDQ documents can be used freely as text, it cannot be identified as an NCI PDQ cancer information summary unless it is presented in its entirety and is regularly updated. However, an author would be permitted to write a sentence such as “NCI’s PDQ cancer information summary about breast cancer prevention states the risks succinctly: [include excerpt from the summary].”

The preferred citation for this PDQ summary is:

PDQ® Pediatric Treatment Editorial Board. PDQ Childhood Vascular Tumors Treatment. Bethesda, MD: National Cancer Institute. Updated . Available at: https://www.cancer.gov/types/soft-tissue-sarcoma/hp/child-vascular-tumors-treatment-pdq. Accessed . [PMID: 26844334]

Images in this summary are used with permission of the author(s), artist, and/or publisher for use within the PDQ summaries only. Permission to use images outside the context of PDQ information must be obtained from the owner(s) and cannot be granted by the National Cancer Institute. Information about using the illustrations in this summary, along with many other cancer-related images, is available in Visuals Online, a collection of over 2,000 scientific images.

Disclaimer

Based on the strength of the available evidence, treatment options may be described as either “standard” or “under clinical evaluation.” These classifications should not be used as a basis for insurance reimbursement determinations. More information on insurance coverage is available on Cancer.gov on the Managing Cancer Care page.

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More information about contacting us or receiving help with the Cancer.gov website can be found on our Contact Us for Help page. Questions can also be submitted to Cancer.gov through the website’s Email Us.

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