Vascular targeting tumor therapy: non-invasive contrast enhanced ultrasound for quantitative assessment of tumor microcirculation.

The aim of the study was to quantitatively assess tumor microcirculation upon vascular targeting tumor therapy by non-destructive contrast enhanced ultrasonography (CEUS) and to validate this technology by correlation with high-resolution intravital fluorescence microscopy (IVM). Subcutaneous Lewis Lung carcinomas (LLC-1) carcinomas were established in mice. A-MEL-3 melanomas were grown in dorsal skinfold chambers of hamsters to permit bimodal imaging of tumor microcirculation by CEUS and IVM.

Vascular targeting by EndoTAG-1 enhances therapeutic efficacy of conventional chemotherapy in lung and pancreatic cancer.

Cationic lipid complexed paclitaxel (EndoTAG-1) is a novel vascular targeting agent for the treatment of cancer. Here, the aim was to investigate intratumoral drug distribution after EndoTAG-1 therapy and analyze the impact of EndoTAG-1 scheduling on antitumoral efficacy. The therapeutic effect of EndoTAG-1 in combination with conventional gemcitabine or cisplatin therapy was evaluated in L3.

Static magnetic fields impair angiogenesis and growth of solid tumors in vivo.

Exposure to static magnetic fields (SMFs) results in a reduced blood flow in tumor vessels as well as in activation and adherence of platelets. Whether this phenomenon may have a significant functional impact on tumors has not been investigated as yet. The aim of our study was to evaluate the effects of prolonged exposure to SMFs on tumor angiogenesis and growth.

Contrast enhanced MRI and intravital fluorescence microscopy indicate improved tumor microcirculation in highly vascularized melanomas upon short-term anti-VEGFR treatment.

Anti-angiogenic therapy by blocking VEGF signalling combined with standard chemotherapy is a novel strategy for clinical cancer treatment. The mechanisms for enhanced antitumoral effects are still a matter of controversial debate. Tumor vessel "normalization" upon anti-angiogenic therapy leading to improved drug delivery has been proposed as possible mechanism.

Static magnetic fields induce blood flow decrease and platelet adherence in tumor microvessels.

Red blood cell flow in capillaries is reduced during exposure to strong static magnetic fields (SMFs). Intratumoral microcirculation is characterized by tortuous microvessels with chaotic architecture and by irregular, sluggish blood flow with unstable rheology. It was the aim of this study to analyze SMF exposure effects on tumor microcirculation with regard to interactions of corpuscular blood components with tumor microvessel walls.