Malignant tumors, also known as cancers, have become one of the leading causes of death in companion animals in recent years, and the proportion of deaths caused by cancer in people is also high. The cancer is abnormal cell proliferation. The circulatory and lymphatic systems expand the cancer cells in the body, then transferred to other parts of the body, causing abnormal bleeding and chronic coughing, finally leading to death. The treatment methods are mainly surgery, radiation therapy, chemotherapy, etc.; however, many side effects may even cause Deepen the patient's disease. In recent years, scholars have devoted themselves to researching hot-melt technology to improve the side effects and risks caused by invasive and non-invasive surgery. However, current hot-melt technology must overcome the depth of heating due to tissue absorption and high-intensity focused ultrasound. Although the depth is enough, it will cause the side effects of skin burning. In this research, liquid gallium and magnetic particles (Iron oxide, Fe3O4) are combined to form a new state of composite particles. The gallium-based magnetic particles are heated by alternating magnetic field induction heating to treat cancer cell tumors by thermal cauterization. Iron oxide (Fe3O4) allows gallium-based magnetic particles to bring reasonable magnetic control, allowing local treatment and guidance functions in treatment. The configuration of gallium-based magnetic particles is composed of multiple iron oxides (Fe3O4) aggregated, and liquid gallium is used as its binder to adhere to numerous iron oxides. After synthesis, they are heated by induction heating with liquid gallium and iron oxide (Fe3O4). Experiment, compare the heating trend and heat generation effect of this study on gallium-based magnetic particles and measure the hysteresis curve to confirm the magnetism of gallium-based magnetic particles. The measurement results show that gallium-based magnetic particles have reduced magnetism after synthesis, but they can still be adsorbed and attracted by their magnetism. By adjusting the heating time and magnetic field, the range and effect of the thermal treatment of gallium-based magnetic particles could be controlled. In the part of animal experiments, gallium-based magnetic particles are injected into tumors. The thermal treatment effect of gallium-based magnetic particles is not better than liquid gallium, but its stability and positioning are far better than liquid gallium.