BACKGROUND: Areas of microvascular proliferation have been observed in a subpopulation of symptomatic congenital vascular malformations later in life. We investigated whether this angiogenic response is followed by a stage of maturation. METHODS: Resections of vascular malformations (n = 15), infantile hemangiomas (IHs) (n = 8) and pyogenic granulomas (PGs) (n = 5) were studied. Histopathologically, all lesions were screened for presence of foci of immature and/or mature microvessels. These areas were further studied immunohistochemically for differential expression of several angiogenic factors, cell cycle-dependent proteins, p53 and active caspase3. Immunostains were scored semiquantitatively. RESULTS: Immature microvessel areas were present in five vascular malformations (all of the arteriovenous type), five IHs and five PGs; these lesions also contained transitions between immature and mature microvessels. Conglomerates of mature microvessels were found in 19 cases (6 vascular malformations, 5 PGs and 8 IHs). Expression of vascular endothelial growth factor-A, angiopoietin-1, Ki-67, p16 and p21/27 ratios were overall significantly lower in mature areas than in immature areas including those in vascular malformations. P53 and caspase3 expression was scarce in all lesions. CONCLUSIONS: Microvascular areas in vascular malformations appear to follow the same pattern of vascular proliferation and maturation as seen in other microvascular lesions of skin and soft tissue.
BACKGROUND: Areas of microvascular proliferation have been observed in a subpopulation of symptomatic congenital vascular malformations later in life. We investigated whether this angiogenic response is followed by a stage of maturation. METHODS: Resections of vascular malformations (n = 15), infantile hemangiomas (IHs) (n = 8) and pyogenic granulomas (PGs) (n = 5) were studied. Histopathologically, all lesions were screened for presence of foci of immature and/or mature microvessels. These areas were further studied immunohistochemically for differential expression of several angiogenic factors, cell cycle-dependent proteins, p53 and active caspase3. Immunostains were scored semiquantitatively. RESULTS: Immature microvessel areas were present in five vascular malformations (all of the arteriovenous type), five IHs and five PGs; these lesions also contained transitions between immature and mature microvessels. Conglomerates of mature microvessels were found in 19 cases (6 vascular malformations, 5 PGs and 8 IHs). Expression of vascular endothelial growth factor-A, angiopoietin-1, Ki-67, p16 and p21/27 ratios were overall significantly lower in mature areas than in immature areas including those in vascular malformations. P53 and caspase3 expression was scarce in all lesions. CONCLUSIONS: Microvascular areas in vascular malformations appear to follow the same pattern of vascular proliferation and maturation as seen in other microvascular lesions of skin and soft tissue.
Authors: Anand S Patel; Joshua M Schulman; Beth S Ruben; William Y Hoffman; Christopher F Dowd; Ilona J Frieden; Christopher P Hess Journal: Pediatr Radiol Date: 2015-04-28
Authors: Amalia Mulia Utami; Siham Azahaf; Onno J de Boer; Chantal M A M van der Horst; Lorine B Meijer-Jorna; Allard C van der Wal Journal: J Clin Transl Res Date: 2021-07-30