Using gene editing technology to enable humans to adapt and live in high-radiation environments is a complex and challenging task. Here are some possible research directions and ideas: 1. **Study radiation resistance genes**: First, it is necessary to identify genes that are particularly effective in high-radiation environments. For example, some microorganisms and plants are able to survive in extreme environments, and studying their genomes may reveal genes that contribute to radiation resistance. 2. **Gene editing technology**: Using gene editing tools such as CRISPR-Cas9, scientists can genetically modify human cells to introduce or enhance the expression of these radiation-resistant genes. 3. **Enhance DNA repair mechanisms**: Radiation causes DNA damage, so improving the cell's DNA repair ability is a key goal. Genes related to DNA repair can be edited so that cells can repair damage more effectively when exposed to radiation. 4. **Antioxidant response**: Radiation causes oxidative stress and increases the production of free radicals, so enhancing the cell's antioxidant capacity is also an important part. This can be done by increasing the expression level of enzymes related to antioxidant synthesis through gene editing. 5. **Assess ethics and safety**: Before conducting gene editing to enhance radiation adaptability, its ethics and safety need to be assessed. A lot of preliminary research may be needed to ensure that gene editing does not cause other health problems. 6. **Animal experiments and clinical trials**: Before clinical application, experiments can be conducted on animal models to understand the effects of gene editing and possible side effects. 7. **Public health strategies**: In addition to gene editing, the risk to humans in high-radiation environments can be reduced by improving environmental control, increasing radiation shielding, and developing radiation monitoring technology. In short, although the use of gene editing technology to enhance human survival in high-radiation environments is a cutting-edge scientific field, it involves many complex bioethical and technical challenges. Before this goal can be achieved, a lot of basic research and ethical considerations are needed.