Laser speckle contrast analysis (LASCA) technology for the semiquantitative measurement of angiogenesis in in-ovo-tumor-model.

BACKGROUND: The process of angiogenesis is a key element for tumor growth and proliferation and therefore one of the determining factors for aggressiveness and malignancy. A better understanding of the underlying processes of tumor induced angiogenesis is crucial for superior cancer treatment. Furthermore, the PeriCam perfusion speckle imager (PSI) system high resolution (HR) model by PERIMED presents a noninvasive method for semi-quantitative measurement of blood perfusion, based on laser speckle contrast analysis (LASCA). Aim of the present study was to utilize the chick chorioallantoic membrane (CAM) model as an in-ovo-tumor-model which enables rapid neovascularization of tumors while allowing real-time observation of the microcirculation via LASCA. METHODS: Fertilized chicken eggs were grafted with embryonal/alveolar rhabdomyosarcoma cells or primary sarcoma tumors. The blood perfusion was measured before and after tumor growth using LASCA. The procedure is accelerated and simplified through the integrated PIMSoft software which provides real-time graphs and color-coded images during the measurement. RESULTS: Sarcoma cells and primary sarcoma tumors exhibited satisfactory growth processes on the CAM. LASCA visualized microcirculation accurately and enabled an extensive investigation of the angiogenic potential of sarcoma cells on the CAM. We were able to show that sarcoma cells and primary sarcoma tumors induced larger quantities of neovasculature on the CAM than the controls. CONCLUSIONS: The utilization of LASCA for the investigation of tumor angiogenesis within the CAM model appears to be a highly beneficial, cost-efficient and easily practicable procedure. The proposed model can be used as a drug-screening model for individualized cancer therapy, especially with regards to anti-angiogenic agents.

Vasculogenic mimicry is associated with poor survival in patients with mesothelial sarcomas and alveolar rhabdomyosarcomas.

Increased vasculogenesis must occur for tumors to develop and be maintained. Normally, vascular networks are composed of tube structures lined with endothelial cells. However, the vascular networks that form around some highly aggressive cancers possess a distinct tubular structure, resulting from a process called vasculogenic mimicry (VM) that does not have endothelial cells. In these tubes, the tumor cells function as endothelial cells. VM has been found in several different types of cancers such as melanoma, breast cancer, prostate cancer, and ovarian cancer. We hypothesized that it also plays a role in the development and metastasis of sarcomas, which are typically aggressive tumors. We used immunohistochemical analyses and electron microscopy to identify VM channels in 81 synovial sarcomas (SSs), 37 mesothelial sarcomas (MSs), 69 alveolar rhabdomyosarcomas (ARs), and 190 melanomas, which were used as a comparison group. The presence of red blood cells in the vessels was also used as a criterion for VM. Because VM is generally believed to be associated with aggressive cancers, we tested whether the presence of VM channel correlated with patient survival. We detected VM channels in 11 of 81 SSs (13.6%), 10 of 37 MSs (27.0%), 13 of 69 ARs (18.8%), and 10 of 190 melanomas (5.3%). The VM channels were not distributed uniformly in the tumor tissues but appeared in patches. In addition, VM channels were most frequently observed in the boundary regions between the tumor and adjacent normal tissues. The tumor cells around the VM tubes frequently stained positive for collagen IV and CD31 and were also PAS-positive. In contrast, tumors that lack VM channels generally also lack these markers. Our studies of the correlation of VM with patient survival also showed that VM correlated with shorter survival in patients with MS (P=0.03), AR (P=0.03), and melanoma (P=0.04), but not with SS (P=0.76). Our studies demonstrated that VM channels are a clinically important phenotype in sarcomas and melanomas. Our findings also suggested that a subpopulation of tumor cells possess features of both endothelial cells that line the vessels and mesenchymal cells that secrete the extracellular matrix required for the vascular infrastructure.

Curcumin potentiates rhabdomyosarcoma radiosensitivity by suppressing NF-κB activity.

Ionizing radiation (IR) is an essential component of therapy for alveolar rhabdomyosarcoma. Nuclear factor-kappaB (NF-κΒ) transcription factors are upregulated by IR and have been implicated in radioresistance. We evaluated the ability of curcumin, a putative NF-κΒ inhibitor, and cells expressing genetic NF- κΒ inhibitors (IκBα and p100 super-repressor constructs) to function as a radiosensitizer. Ionizing radiation induced NF-κΒ activity in the ARMS cells in vitro in a dose- and time-dependent manner, and upregulated expression of NF-κΒ target proteins. Pretreatment of the cells with curcumin inhibited radiation-induced NF-κΒ activity and target protein expression. In vivo, the combination of curcumin and IR had synergistic antitumor activity against Rh30 and Rh41 ARMS xenografts. The greatest effect occurred when tumor-bearing mice were treated with curcumin prior to IR. Immunohistochemistry revealed that combination therapy significantly decreased tumor cell proliferation and endothelial cell count, and increased tumor cell apoptosis. Stable expression of the super-repressor, SR-IκBα, that blocks the classical NF-κB pathway, increased sensitivity to IR, while expression of SR-p100, that blocks the alternative pathway, did not. Our results demonstrate that curcumin can potentiate the antitumor activity of IR in ARMS xenografts by suppressing a classical NF-κΒ activation pathway induced by ionizing radiation. These data support testing of curcumin as a radiosensitizer for the clinical treatment of alveolar rhabdomyosarcoma. IMPACT OF WORK: The NF-κΒ protein complex has been linked to radioresistance in several cancers. In this study, we have demonstrated that inhibiting radiation-induced NF-κΒ activity by either pharmacologic (curcumin) or genetic (SR-IκBα) means significantly enhanced the efficacy of radiation therapy in the treatment of alveolar rhabdomyosarcoma cells and xenografts. These data suggest that preventing the radiation-induced activation of the NF-κΒ pathway is a promising way to improve the antitumor efficacy of ionizing radiation and warrants clinical trials.

Rapamycin-induced tumor vasculature remodeling in rhabdomyosarcoma xenografts increases the effectiveness of adjuvant ionizing radiation.

PURPOSE: Rapamycin inhibits vascular endothelial growth factor expression. Vascular endothelial growth factor is a tumor-elaborated protein that stimulates neovascularization. This inhibition can cause transient "normalization" of the generally dysfunctional tumor vasculature, resulting in improved tumor perfusion and oxygenation. We hypothesized that this may potentiate the antitumor effects of adjuvant ionizing radiation. METHODS: Mice bearing orthotopic Rh30 alveolar rhabdomyosarcomas were treated with rapamycin (5 mg/kg intraperitoneally daily ×5). Tumors were then evaluated for changes in intratumoral oxygenation, perfusion, vessel permeability, and microvessel density. Additional tumor-bearing mice were treated with 5 doses of rapamycin, irradiation (4 Gy), or 5 doses of rapamycin with irradiation administered on the first or sixth day of rapamycin treatment. RESULTS: Although tumor vessel permeability changed only minimally, microvessel density decreased (3153 ± 932 vs 20,477 ± 3717.9 pixels per high-power field), whereas intratumoral oxygenation increased significantly (0.0385 ± 0.0141 vs 0.0043 ± 0.0023 mm Hg/mm(3)) after 5 doses of rapamycin. Contrast-enhanced ultrasound demonstrated a significantly increased rate of change of signal intensity after 5 days of rapamycin, suggesting improved intratumoral perfusion. Tumor volume 14 days after treatment was smallest in mice treated with the combination of rapamycin given before irradiation. CONCLUSION: Combination therapy with rapamycin given before irradiation to normalize the tumor vasculature, thereby improving tumor oxygenation, increased the sensitivity of alveolar rhabdomyosarcoma xenografts to adjuvant irradiation.

IFN-beta restricts tumor growth and sensitizes alveolar rhabdomyosarcoma to ionizing radiation.

Ionizing radiation is an important component of multimodal therapy for alveolar rhabdomyosarcoma (ARMS). We sought to evaluate the ability of IFN-beta to enhance the activity of ionizing radiation. Rh-30 and Rh-41 ARMS cells were treated with IFN-beta and ionizing radiation to assess synergistic effects in vitro and as orthotopic xenografts in CB17 severe combined immunodeficient mice. In addition to effects on tumor cell proliferation and xenograft growth, changes in the tumor microenvironment including interstitial fluid pressure, perfusion, oxygenation, and cellular histology were assessed. A nonlinear regression model and isobologram analysis indicated that IFN-beta and ionizing radiation affected antitumor synergy in vitro in the Rh-30 cell line; the activity was additive in the Rh-41 cell line. In vivo continuous delivery of IFN-beta affected normalization of the dysfunctional tumor vasculature of both Rh-30 and Rh-41 ARMS xenografts, decreasing tumor interstitial fluid pressure, increasing tumor perfusion (as assessed by contrast-enhanced ultrasonography), and increasing oxygenation. Tumors treated with both IFN-beta and radiation were smaller than control tumors and those treated with radiation or IFN-beta alone. Additionally, treatment with high-dose IFN-beta followed by radiation significantly reduced tumor size compared with radiation treatment followed by IFN-beta. The combination of IFN-beta and ionizing radiation showed synergy against ARMS by sensitizing tumor cells to the cytotoxic effects of ionizing radiation and by altering tumor vasculature, thereby improving oxygenation. Therefore, IFN-beta and ionizing radiation may be an effective combination for treatment of ARMS.

Bevacizumab-induced tumor vessel remodeling in rhabdomyosarcoma xenografts increases the effectiveness of adjuvant ionizing radiation.

PURPOSE: Inhibition of vascular endothelial growth factor (VEGF) may effect transient "normalization" of tumor vasculature by pruning immature vessels, resulting in improved tumor perfusion and oxygenation. This may improve the efficacy of adjuvant ionizing radiation (IR). We tested this hypothesis using bevacizumab, an anti-VEGF antibody, in rhabdomyosarcoma (RMS) xenografts. METHODS: Mice bearing orthotopic alveolar RMS xenografts were treated with a single dose of bevacizumab, IR, or a combination of the two on different schedules. Tumors were then evaluated for changes in microvessel density, vessel maturity, vessel permeability, intratumoral oxygenation, as well as altered growth. RESULTS: After bevacizumab treatment, a significant decrease in tumor microvessel density and a significant increase in tumor vessel maturity, defined as the ratio of pericytes to endothelial cells, were observed, suggesting pruning of immature vessels lacking pericytes. Tumor vessel permeability was also significantly decreased and intratumoral oxygen tension increased 2 and 5 days after bevacizumab owing to a transient improvement in tumor perfusion. Treatment with IR 2 or 5 days after bevacizumab resulted in the greatest antitumor activity. CONCLUSION: Our findings support the hypothesis that VEGF inhibition with bevacizumab transiently normalizes the dysfunctional vasculature of RMS xenografts, improving tumor oxygenation and increasing tumor sensitivity to adjuvant IR.

[Alveolar rhabdomyosarcoma with massive infiltration of the bone marrow as its initial manifestation]. / Rabdomiosarcoma alveolar con infiltración masiva de medula ósea como manifestación inicial.

We report a case of alveolar rhabdomyosarcoma (AR) with massive infiltration of bone marrow at presentation, and initial diagnosis in bone marrow aspirate. A 35 year old man presented with a submandibular mass, and hematomas after mild traumatisms. Peripheral blood showed thrombocytopenia and a normocytic anaemia. Bone marrow film showed diffuse involvement by undifferentiated blasts with rhabdomyoblastic features. Subsequent biopsy of submandibular lymph node confirmed the diagnosis with positivity for specific muscle actin and desmin, and negativity for lymphoid markers. Initial presentation of AR with extensive bone marrow involvement is extremely rare, and it could lead to wrong diagnosis and treatment of acute leukaemia, with the serious consequences that this would have. Immunohistochemical study and morphologic differential features can be of great diagnostic help.