Nanoparticles are widely applied in many researches and cancer therapies. Superparamagnetic iron oxide nanoparticle (SPIO) which is lesstoxic and its magnetic property is widely applied in many biological studies,such as cell labeling, cell sorting, cell therapy, magnetic resonance imaging (MRI), hyperthermia, and drug delivery. Liposome encapsulated SPIO is called L-SPIOs. Recently L-SPIOs are widely used in disease therapy because of the advantages of L-SPIOs such as they have more biological compatibility, they can be modified with targeting ligand/antibody or magnetic field to promote specific targeting, they can induce hyperthermia on alternating magnetic field to apply in cancer therapy. Angiogenesis, new blood vessels sprouting from pre-existing vessels, is essential for tumor growth,invasion and metastasis. It can be used as a biomarker for early stage tumor diagnosis and targeted therapy. To visualize angiogenesis many molecular imaging modalities have been used. In this research, we used mouse ear model to observe tumor growth, and angiogenesis easily. GEC-Chol/chol was established were used to encapsulate SPIOs to formulate L-SPIOs which is about 120~150 nm in diameter. L-SPIOs were used with its magnetic property on MRI signal to study the nanoparticles distribution in mouse ear tumor model. In addition, I use L-SPIOs to induce hyperthermia on alternating magnetic field (AMF) to treatment cancer on this mouse ear tumor model. My results showed the mouse ear tumor can be suppressed growth on 200 Oe AMF and the suppressed affect can be dependent on amount of L-SPIOs dose. With this results , I can observe tumor easily and nanoparticle distribution on mouse ear tumor model. I also observed that L-SPIOs can affect tumor growth by hyperthermia.