Angiogenesis and vascular survival ability in ovarian adenocarcinomas

This study was designed to investigate the prognostic relevance of ovarian tumour angiogenesis in terms of tumour angiogenic activity (TAA) and vascular survival ability (VSA), i.e. the ability of newly formed vessels to survive once incorporated into the main tumour mass. TAA was assessed at the edge of the invading tumour, while VSA was evaluated in inner tumour areas, always in comparison with the invading edge. A series of 46 ovarian grade-1 adenocarcinomas of the endometrioid and the serous cell type was assessed. Endothelial cells were revealed after using a standard immunohistochemical technique and the CD31 antibody. Vascular density was, in general, higher at the periphery of the tumour than in the inner tumour areas, although in both cases, a rich vascular supply was associated with a poor survival. By combining counts at the tumour edge versus inner tumour areas (edvin), four groups of tumour vascularity emerged: edvin type 1 (low TAA/low VSA), edvin type 2 (low TAA/high VSA), edvin type 3 (high TAA/low VSA) and edvin type 4 (high TAA/high VSA). Edvin type-4 tumours were related to the most unfavourable prognosis. It is concluded that VSA and TAA are complementary procedures in assessing ovarian tumour vasculature and, therefore, prognosis, and by combining the two parameters, a more precise impression of the state of vascularisation in the ovary is obtained, which may prove useful in designing anti-angiogenic therapies.     

Tumour angiogenic activity and vascular survival ability in bladder carcinoma

BACKGROUND: Tumour angiogenic activity (TAA) is an important prognostic factor in many human tumours, including transitional cell carcinomas of the urinary bladder. The new tumour vessels are formed in the invading tumour front. This peripheral tumour area is internalised as soon as the growing tumour forms a new front. AIMS: To investigate and compare TAA with the ability of the tumour vasculature to survive (VSA) in inner tumour areas. METHODS: Fifty one cystectomy specimens with transitional cell carcinoma of the urinary bladder were studied. Sections were stained immunohistochemically for endothelial cells and proliferation activity, using the monoclonal antibodies CD31 and MIB-1, respectively. TAA was studied at the invading tumour edge-designated as the mean number of blood vessels in three "hot spots" at this site. VSA was assessed by comparing the vascular density in peripheral and inner tumour areas. RESULTS: High TAA at the invading tumour edge significantly correlated with lymph node involvement, but not with patient survival. Extensive lymphocytic infiltration was more frequent in tumours with high TAA. VSA was significantly higher in tumours of high proliferation index, high histological grade, advanced T stage, and poor prognosis. However, there was no association with metastasis to regional lymph nodes. CONCLUSION: VSA and TAA provide a more complete profile of the tumour vasculature and are associated with aggressive tumour behaviour in transitional cell carcinomas of the urinary bladder. The qualitative information provided by VSA may be important for the identification of angiogenic tumours with differential responses to various antiangiogenic treatments.     

'Invading edge vs. inner' (edvin) patterns of vascularization: an interplay between angiogenic and vascular survival factors defines the clinical behaviour of non-small cell lung cancer

Neo-angiogenesis during neoplastic growth involves endothelial mitogenic and migration stimuli produced by cancer or tumour stromal cells. Although this active angiogenesis takes place in the tumour periphery, the process of vessel growth and survival in inner areas and its clinical role remain largely unexplored. The present study compared the microvessel score (MS) as well as the single endothelial cell score (ECS) in the invading edge and in inner areas of non-small cell lung carcinomas (NSCLCs). Three different patterns of vascular growth were distinguished: the edvin (edge vs. inner) type 1, where a low MS was observed in both peripheral and inner tumour areas; the edvin type 2, where a high MS was noted in the invading front but a low MS in inner areas; and the edvin type 3, where both peripheral and inner tumour areas had a high MS. The ECS was high in the invading edge in edvin type 2 and 3 cases and was sharply decreased in both types in inner areas, suggesting that endothelial cell migration is unlikely to contribute to the angiogenic process in areas away from the tumour front. Expression of the vascular endothelial growth factor (VEGF) and of thymidine phosphorylase (TP) was associated with a high MS in the invading edge. VEGF was associated with a high MS in inner areas (edvin 3), while TP expression was associated with edvin type 2, showing that VEGF (and not TP) contributes to the preservation of the inner vasculature. Both edvin type 2 and 3 cases showed an increased incidence of node metastasis, but edvin type 3 cases had a poorer prognosis, even in the N1-stage group. The present study suggests that tumour factors regulating angiogenesis and vascular survival are not identical. A possible method is reported to quantify these two parameters by comparing the MS in the invading edge and inner areas (edvin types). This observation may contribute to the evaluation of the effectiveness of different therapeutic approaches, namely vascular targeting vs. anti-angiogenesis.     

Differential assessment of angiogenic activity and of vascular survival ability (VSA) in breast cancer

Recent reports provide evidence that some growth factors behave as inhibitors of the apoptosis of the endothelial cells, bringing forward the concept of vascular survival as a post-angiogenesis process. At least two different vasculature development processes occur within a tumor: the angiogenic (formation of new vessels) and the vascular survival pathway, which is devoted to the preservation of the newly-formed vessels in layers that lose contact with the adjacent normal tissue. We developed a method to assess these processes in tissue samples. We noted that differences among tumors may exist not only in the tumor angiogenic activity (TAA) but also in the vascular survival ability (VSA). One third of the highly angiogenic breast cancer cases examined had a poor ability to maintain high vessel density in inner tumor areas. Both parameters are independently related to prognosis, while VSA was directly related to tumor dimensions and node involvement. Patients with high TAA and VSA had a particularly poor prognosis. It is suggested that although cancer angiogenic activity is important for the local invasion and dissemination into vessels and lymphatics, the VSA may be important for the effective formation of viable tumor foci in lymph nodes or distant organs. Recognition and quantification of the vascular survival ability in human tumors may significantly improve the prognostic value of the assessment of tumor vasculature, and may help to stratify patients for clinical trials with novel anti-angiogenic or angiotoxic drugs. Elucidation of the pathways may provide additional targets for antiangiogenic therapy. This revised version was published online in July 2006 with corrections to the Cover Date.     

LYVE-1 immunohistochemical assessment of lymphangiogenesis in endometrial and lung cancer

AIMS/METHODS: Normal and malignant pulmonary and endometrial tissues were analysed for lymphatic vessels to assess the process of lymphangiogenesis and its role at these sites, using specific immunostaining for LYVE-1 and the panendothelial marker CD31. RESULTS: Lymphatics were clearly demonstrated in some normal tissues (myometrium, bronchial submucosa, and intestinal submucosa), but not in others (endometrium and alveolar tissue). LYVE-1 positive lymphatic vessels were detected at the tumour periphery of endometrial and lung carcinomas, but not within the main tumour mass. Double staining for LYVE-1 and the MIB1 proliferation marker revealed a higher proliferation index in lymphatic endothelial cells at the invading front of endometrial carcinomas, compared with myometrial areas distal to the tumour. Lung and endometrial carcinomas did not have an intratumorous lymphatic network. CONCLUSIONS: Although lymphangiogenesis may occur at the invading tumour front, incorporated lymphatics do not survive. Therefore, the dissemination of cancer cells through the lymphatics may occur by invasion of peripheral cancer cells into the adjacent normal lymphatics, or through shunts eventually produced at the invading tumour front as a consequence of active angiogenesis and lymphangiogenesis.     

Proliferating fibroblasts at the invading tumour edge of colorectal adenocarcinomas are associated with endogenous markers of hypoxia, acidity, and oxidative stress

BACKGROUND: Stroma frequently forms at sites of active tumour invasion, and may be important for tumour growth and progression. The term "stromatogenesis" is used to describe this unique process that involves host peritumorous fibroblasts and is very different to reactive fibrosis. AIMS/METHODS: To investigate the activation status of host fibroblasts at the invading tumour edge, assessed as MIB1 proliferation index and thymidine phosphorylase (TP) expression. Results were related to vascular density and certain properties of invading cancer cells-MIB1 proliferation activity, TP expression, expression of endogenous markers of hypoxia (hypoxia inducible factor-1alpha; HIF1alpha) and acidity (lactate dehydrogenase-5; LDH5). Standard immunohistochemical techniques were applied to 150 colorectal adenocarcinomas. RESULTS: Normal fibroblasts at the tumour edge had a median MIB1 index of 2%-significantly higher than normal submucosal fibroblasts (0.3%) and significantly lower than cancer cells (40%). Normal peritumorous fibroblasts with a proliferation rate above the median strongly expressed TP and were supported by an increased vascular network. Cancer cells close to these fibroblasts had a high MIB1 proliferative index, high HIF1alpha and LDH5 reactivity, and a clear trend to extramural extension. All associations were significant. CONCLUSIONS: These results suggest that activated fibroblastic status at the invading tumour front sets the stage for stromatogenesis and new blood vessel formation, facilitating deep transmural invasion in colorectal adenocarcinomas. This complicity of peritumorous fibroblasts in the overall aggressiveness/invasive and metastatic ability of colorectal tumours, occurring within the framework of cancer-stromal cell interactions, is probably favoured by the altered microenvironmental conditions of hypoxia and acidity.     

Presence of vascular adventitial fibroblastic cells in diffuse-type gastric carcinomas

AIM: To investigate morphological changes in the tumour vessel adventitia, particularly the distribution of vascular adventitial fibroblastic cells (VAFCs)--namely, CD34 positive fibroblastic cells just outside the vascular media--in diffuse-type gastric carcinomas. METHOD: In total, 18 surgically resected advanced typical diffuse-type gastric carcinomas and their normal tissues were examined. Immunostaining for CD34, CD31, high molecular weight caldesmon (HCD), and cytokeratin 8 (CAM5.2) was performed to detect VAFCs. VAFCs are positive for CD34 but negative for CD31, and are located just outside the vascular media (HCD positive vascular smooth muscle bundle). The areas just outside the vascular media in the whole maximum tumour cut surface were assessed, except the tumour growing edge, which was confirmed by immunostaining with CAM5.2. CD34 positive and CD31 negative cells just outside the vascular media were defined as VAFCs. RESULTS: VAFC containing vessels were seen in 17 of the 18 diffuse carcinoma tissues. Vessels lacking VAFCs were also detected in these 17 tumours. In contrast, all of the vessels lacked VAFCs in the remaining tumour. In the 18 samples of normal tissue, all of the vessels contained VAFCs. CONCLUSIONS: These results suggest that the presence of VAFCs is associated with the infiltration of diffuse scattered gastric carcinoma cells.     

Intravascular (”intimal”) epithelioid angiosarcoma: clinicopathological and immunohistochemical analysis of three cases

Angiosarcomas are rare malignant mesenchymal tumours, characterized morphologically by anastomosing vascular channels lined by atypical and proliferative active endothelial cells. An epithelioid cytomorphology of tumour cells is often seen focally in angiosarcoma, whereas purely epithelioid angiosarcomas are rare. Although angiosarcomas show a vascular differentiation they are almost never confined to pre-existing blood vessels. We describe three cases of intravascular epithelioid angiosarcoma arising in the carotid artery of a 60-year-old man, in the infrarenal part of the abdominal aorta and both renal arteries of a 69-year-old woman, and in the abdominal aorta of a 68-year-old man. In all cases malignant tumour tissue was found incidentally after disobliteration of thrombosed vessels. Histologically, purely epithelioid angiosarcoma composed of solid sheets of epithelioid tumour cells was seen; immunohistochemistry confirmed the endothelial differentiation of neoplastic cells. The reported cases show that angiosarcoma can occasionally arise within a pre-existing vessel. Received: 18 May 1999 / Accepted: 8 June 1999     

Increase in immunoreactivity for endothelin-1 in blood vessels of rat liver metastases: experimental sarcoma and carcinoma

Using electron immunocytochemistry, blood vessels in the normal rat liver and in 2 different animal models of liver metastases: (1) Hooded Lister rat with MC28 tumour, a sarcoma, and (2) nude rat with HT29 tumour, a carcinoma, were investigated for the presence of endothelin-1. In the normal livers, small subpopulations of vascular endothelial cells displayed discrete immunoreactivity for endothelin-1. In the livers with malignant tumours, there was a substantial increase in endothelin-1-immunoreactive endothelial cells in vessels located at the tumour periphery. In the controls, antibody to endothelin-1 also labelled sporadically some fibroblast/fibroblast-like cells associated with the blood vessels. In contrast, intense immunoreactivity for endothelin-1 was frequently associated with the tumour cells and/or fibroblast cells in both types of tumour examined.     

Vascular depressions

The notion of vascular depression (VD) includes depressive disorders resulting from organic cerebral lesions of vascular genesis. Two types of VD are distinguished: post-stroke VD (PSD) and VD proper (SDP). VD develops in case of clinically manifest (neurologic) lesions in cerebral vessels that simultaneously act as psychogenic (nosogenic) factors. SDP is associated with clinically latent vascular disorders ("silent" infarctions and white matter ischemia). VD is characterized by multiple phenomenological convergence of vascular signs and symptoms inherent in both PSD and SDP. Whatever the type of VDs, they are associated with frequent cognitive problems with a variety of dynamic patterns, viz. reversible, relatively stable, and progressing.     

The microvasculature of the 7,12-dimethylbenz(a)anthracene (DMBA)-induced rat mammary tumour

Summary We examined the microvasculature of the 7,12-dimethylbenz(a)anthracene (DMBA)-induced rat mammary tumour by scanning electron microscopy of corrosion casts. An elaborate vascular envelope predominantly consisting of sinusoidal and venular vessels was formed around each tumour nodule. These vessels exhibited various abnormal features, whereas arterioles appeared normal. The abnormal vessels possessed many globular outpouches, possibly representing the site of angiogenesis. An additional capillary layer was seen in the marginal boundary between the tumour and host tissue. The lack of centrifugally extruding vessels in this layer may indicate a poor potency for vascular spread of tumour cells into the adjacent normal tissue. Looplike or glomerular ingrowths were frequently found on the inner aspect of the vascular capsule, which eventually developed into a dense intranodular plexus. Intranodular vessels often showed focal narrowing, tapering and/ or rupturing, possibly due to increased tissue pressure caused by proliferating tumour cells. Those surrounding necrotic portions were extremely dilated with occasional periodic varicosities. The features may be associated with the lessening of the tissue pressure resulting from tumour cell collapse.     

Hostile takeover: how tumours hijack pre‐existing vascular environments to thrive

An increasing body of evidence suggests that solid tumours do not require the generation of new blood vessels, i.e. angiogenesis, to successfully grow, and to colonize normal tissue. Instead, many tumour cells make the best use of what they find: pre‐existing blood vessels of the host. In these cases, the host vasculature is incorporated by the growing tumour, resulting in a new organ consisting of malignant and non‐malignant cell types. In consequence, pre‐existing vessels are exploited by the tumour for optimal access to oxygen and nutrients. In this perspective article, the argument is made that tumour cells might gain even more: that is, access to the very special microenvironment of the perivascular niche. Here, specific cues for invasion, metastasis, survival, stem‐like features, dormancy and, potentially, also immune escape exist – for non‐malignant and malignant cells alike. The consequence of the hijacking of normal blood vessels and their perivascular niches by tumours is that antiangiogenic agents have little chance to work, and that tumour cells are better protected from the adverse effects of cytotoxic and targeted therapies. Thus, disturbing vascular hijacking could make tumours less resistant to established therapies. Concepts of how to do this are just starting to be explored. Copyright © 2017 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

Thymidine phosphorylase expression in endometrial carcinomas

Thymidine phosphorylase (TP) is a potent angiogenic molecule shown to induce endothelial cell migration and proliferation. We investigated the expression of TP in a series of 156 endometrial carcinomas, using immunohistochemical methods. Histopathological parameters of known prognostic significance and the molecular factors of p53, bcl-2 and angiogenesis were also assessed. Thymidine phosphorylase was expressed in cancer cells, stromal fibroblasts and myometrial cells. The pattern of TP staining was nuclear or mixed nuclear/cytoplasmic, and only exceptionally was purely cytoplasmic. An exclusively cytoplasmic staining was documented for the tumour-associated foamy macrophages. Cancer cell reactivity was rather limited; only 3.2% of endometrial carcinomas expressed TP in more than 50% of the neoplastic cell population and only 12% expressed the enzyme in more than 10% of the cancer cells. By contrast, TP reactivity was frequent in the fibroblasts of the tumour supporting stroma and the fibroblasts/myometrial cells at the invading tumour front, where approximately 1/3 of the cases expressed TP in more than 50% of the respective constituent cells. A high TP reactivity in the stromal fibroblasts was significantly associated with the presence of foamy macrophages and an intense lymphocytic response. A high TP reactivity at the invading tumour front was significantly associated with an intense lymphocytic response and the adverse prognostic parameters of high tumour grade, deep myometrial invasion, advanced stage of disease and the non-endometrioid carcinomas. There was no significant association of cancer cell TP reactivity with any of the parameters studied, including nuclear p53 accumulation, cytoplasmic/perinuclear bcl-2 expression, microvessel density (MVD) and prognosis. Similarly, no relationship was established between fibroblastic or fibroblastic/myometrial TP reactivity and MVD. It is concluded that TP is not a major angiogenic factor in endometrial carcinomas. However, a prominent TP activity at the invading tumour front, which is probably induced by cytokines of histiocytic and lymphocytic origin, may promote tumour invasion and progression.     

Tumour versus patient: vascular and tumour survival versus prognosis

The concept that malignant solid tumour growth depends on angiogenesis is widely recognized. For some tumour types, there is a measurable range of vascularity and the link between prognosis and increased vascular density, best observed at the hotspots at the edge, is now established. What is less discussed are the corollaries: that tumour invasion requires tissue destruction; that the neovasculature must be not only protected but also sustained, especially at the tumour edge; that for tumour survival the edge is the future and the centre is history; and that angiogenesis is essential not only for tumour growth but also for tumour invasion. Different patterns of vascular density in tumour edge and centre have been observed, and these are linked to lymphatic spread and prognosis. The variation is attributable to differing interactions between endothelium and the tumour cell that dictate vascular and tumour survival; this may become relevant to anti-angiogenesis therapies.     

Capsular intravascular endothelial hyperplasia: a peculiar form of vasoproliferative lesion associated with thyroid carcinoma

AIMS: Florid vasoproliferative processes are uncommon in the thyroid gland. We report three cases of an unusual vasoproliferation involving the capsular blood vessels of thyroid carcinoma. METHODS AND RESULTS: The histological diagnoses of the three cases were made on conventional histological sections. Two cases were minimally invasive follicular carcinomas and one case was an encapsulated variant of papillary carcinoma. Some blood vessels in the tumour fibrous capsule were filled with spindly cellular proliferations forming irregular vascular clefts and papillae. Immunohistochemical studies for CD31, CD34 and muscle-specific actin confirmed that the spindly cells were mostly endothelial cells variably supported by pericytes. CONCLUSION: This peculiar intravascular endothelial hyperplasia by itself should not be mistaken for vascular invasion by tumour, but evidence of malignancy must be diligently sought by extensive sampling because the lesion has thus far been consistently associated with malignant thyroid neoplasms.     

Platelet-derived growth factor receptor-beta is induced during tumor development and upregulated during tumor progression in endothelial cells in human gliomas.

BACKGROUND: Endothelial cells proliferate during brain development, are quiescent in normal adult brain but proliferate again under pathologic conditions such as glioma growth. The vascular phenotype of low grade glioma is comparable to normal brain, however high grade gliomas are focally highly vascularized and there is associated prominent endothelial cell proliferation. The mechanisms of this change in vascular phenotype are unknown but there is evidence that growth factors play an important role in this process as well as in normal angiogenesis and vascular differentiation. EXPERIMENTAL DESIGN: To investigate whether endothelial cells become activated during tumorigenesis and progression of human gliomas by a platelet-derived growth factor (PDGF) dependent pathway, we analyzed platelet-derived growth factor receptor-beta (PDGFR-beta) expression by in situ hybridization and immunocytochemistry in normal human brain, astrocytoma (grade II), anaplastic oligo-astrocytoma (grade III), and glioblastoma multiforme (grade IV). RESULTS: PDGFR-beta mRNA was not detectable in the vessels of normal human brain, but was expressed in the vasculature of low and high grade gliomas, particularly in endothelial cell proliferations in glioblastomas. The expression of the receptor in the tumor microvessels, was confirmed by double immunofluorescence in which the staining appeared to be in the endothelial cells. Primary cultures of endothelial cells derived from glioblastoma multiforme maintained receptor expression for 2 days in vitro, whereas it was not detectable in vitro in endothelial cells derived from normal brain. Tumor cells in all grades of glioma expressed very little PDGFR-beta mRNA in situ. CONCLUSIONS: Our results indicate that the malignant phenotype in human glial tumors is associated with an upregulation of the PDGFR-beta on endothelial cells of vessels which vascularize the tumor. These findings may contribute to our understanding of the mechanisms that regulate vessel growth and differentiation in normal and pathologic states.     

Localization of vascular endothelial growth factor-D in malignant melanoma suggests a role in tumour angiogenesis

Expression of angiogenic and lymphangiogenic factors by tumours may influence the route of metastatic spread. Vascular endothelial growth factor (VEGF) is a regulator of tumour angiogenesis, but studies of the inhibition of solid tumour growth by neutralizing anti-VEGF antibodies indicated that other angiogenic factors may be involved. VEGF-D may be an alternative regulator because like VEGF it is angiogenic and it activates VEGF receptor-2 (VEGFR-2), an endothelial cell receptor which is a key signalling molecule in tumour angiogenesis. This study reports the generation of monoclonal antibodies to the receptor-binding domain of VEGF-D and the use of these antibodies to localize VEGF-D in malignant melanoma. VEGF-D was detected in tumour cells and in vessels adjacent to immunopositive tumour cells, but not in vessels distant from the tumours. These findings are consistent with a model in which VEGF-D, secreted by tumour cells, activates endothelial cell receptors and thereby contributes to the regulation of tumour angiogenesis and possibly lymphangiogenesis. In addition, VEGF-D was detected in the vascular smooth muscle, but not the endothelium, of vessels in adult colon. The endothelium of these vessels was negative for VEGFR-2 and VEGFR-3. As VEGF receptors can be up-regulated on endothelium in response to vessel damage and ischaemia, these findings of a specific localization of VEGF-D in smooth muscle of the blood vessels suggest that VEGF-D produced by vascular smooth muscle could play a role in vascular repair by stimulating the proliferation of endothelial cells.     

Is extraembryonic angiogenesis in the chick embryo controlled by the endoderm?

Summary The area vasculosa of the chick embryo is subdivided into two concentric zones: the inner transparent area pellucida vasculosa (AVP) and the less transparent surrounding area opaca vasculosa (AOV). The different optical properties of these zones are caused by the different morphology of the endoderm, which consists of flat cells in the APV and of high-prismatic cells containing large yolk vacuoles in the AOV. The present study describes how this endodermal subdivision of the area vasculosa is related to the development of the extraembryonic vascular pattern. By injection of ink into the vascular system of chick embryos at stages 12 to 20 (Hamburger and Hamilton 1951 HH), it has been demonstrated that the vascular net of the area vasculosa from stage 14 (HH) onwards develops into different patterns in APV and AOV. The small loops of uniform capillary vessels of stage 13 (HH) are widened due to the rapid expansion of the extraembryonic mesoderm. In the AOV from stage 14 (HH) onwards numerous small blood vessels sprout into the enlarged intervascular spaces. This process is maximal at stage 17 (HH). In contrast, the blood vessels of the APV remain largely unbranched. These findings suggest that the development of the extraembryonic vascular pattern is controlled by the endodermal pattern. To test this hypothesis, both zones (APV and AOV) were examined by light microscopy, transmission and scanning electron microscopy, in vivo observations and by treatment with bromodeoxyuridine (BrdU). TEM examinations show that the ultrastructural organization of the APV mesoderm is different from that of the AOV: The splanchnopleuric cells of the APV form a continuous cover around the endothelial cells connected by numerous desmosomes, whereas the splanchnopleuric cells of the AOV are frequently separated by gaps. The largest gaps are seen in the small blood vessels at stage 17 (HH). These results should be considered in relation to the dynamic changes in the vascular pattern of the AOV. The endodermal cells of APV and AOV are two different populations. In vivo observation of the endodermal transition from APV to AOV detected no transformations of APV cells into AOV cells or vice versa. The borderline between the zones is stable.The AOV endoderm, having been overgrown by the expanding mesoderm, stops proliferating almost completely, whereas the proliferation of the APV endoderm is unaffected by contact with the mesoderm. The rate of its proliferation is approximately as high as that of the AOV prior to contact with the expanding mesoderm (results after treatment with BrdU). The contact of the basal side of the AOV endoerm with mesoderm is closer than that of the APV. In the AOV the basal compartments of endodermal cells show numerous small coated vesicles, probably exocytotic in nature.The transition between zones in the endoderm was found to be formed by small vaulted cells bearing microvilli on their surface. These cells probably are daughter cells of the primary hypoblast cells, which have been withdrawn to the margin of the APV by the invading endoblast.     

Re-publication of: Metastases and the normalization of tumour blood vessels by ICRF 159: a new type of drug action

Profound modification of the structure and arrangement of the blood vessels has been shown in tumours after treatment with ICRF 159. X-ray angiography, carbon black (Pelikan ink) labelling, and intravital staining with lissamine green were used to demonstrate the changes. Alteration of the morphology of the blood vessels at the edge of a tumour may affect the escape of malignant cells and the rate of blood flow (and thus the concentration of anticancer drugs) through the tumour.     

Vascularization of cutaneous melanoma involves vessel co-option and has clinical significance

This study was undertaken to determine the role and the fate of the peritumoural vascular plexus during the vascularization of human malignant melanoma (hMM) and in an appropriate murine melanoma model system. The prognostic significance of the vascularity of different tumour areas was also evaluated. Despite morphometry revealing several-fold higher microvessel densities (MVDs) in the peritumoural tissue than at the centre of the tumour, the development of visceral metastases of hMM was exclusively correlated with the MVD of the tumour centre. Furthermore, the 5-year survival of the patient group with low tumour centre MVD (<30/mm(2), n=29) was 100%, compared to 1/16 patients alive with high tumour centre MVD (>30/mm(2), n=16). Morphometric analysis and three-dimensional reconstruction of vessel networks of both human and murine melanomas showed clearly that the peritumoural vascular plexus present at the melanoma base is continuously being incorporated into the growing tumour mass. Once vessels become incorporated, sprouting ceases and the proliferating endothelial cells (EC) take part only in vessel dilatation. Moreover, the immunohistochemical and ultrastructural characterization of microvessels demonstrated that the pericyte coverage of endothelial tubes was complete in all of the investigated areas, in both human and murine melanomas.