The number of cancer patients has been increasing year by year, with approximately 60% of patients receiving radiation therapy. Radiation therapy causes the death of cancer cells, but it also affects the surrounding healthy tissue cells, resulting in a common side effect known as alopecia. However, hair is essential, and losing it not only generates psychological stress and negative emotions for patients but also affects their quality of life. Radiation-induced alopecia can be categorized into temporary alopecia and persistent alopecia. Patients with temporary alopecia usually experience hair regrowth within two to six months after the completion of radiation therapy, while patients with persistent alopecia are unable to restore their hair even six months after the completion of radiation therapy. Furthermore, regardless of temporary or persistent alopecia, the regrown hair tends to be thinner, indicating the problem of hair follicle miniaturization. This phenomenon of hair follicle miniaturization worsens over time, eventually leading to the disappearance of hair follicles and the inability to regenerate hair. Currently, there are no effective treatment methods for this issue in clinical practice. Therefore, this study aims to investigate the causes of radiation-induced hair follicle miniaturization and propose improvement methods. To simulate the phenomenon of radiation-induced hair follicle miniaturization observed in clinical practice, the experiment utilized cesium-137 (Cs-137) as the radiation source and administered different radiation doses to establish an animal model. Ultimately, a radiation dose of 20Gy was selected to investigate hair follicle miniaturization. In clinical practice, the thinning of hair serves as the basis for identifying hair follicle miniaturization. This study discovered a decrease in both the width and length of hair, indicating hair thinning and shortening, as well as hair follicle miniaturization. The investigation into the causes of hair follicle miniaturization led to the observation of a decrease in the number of dermal papilla cells. The reduction in cell numbers occurred during the dystrophic catagen, as the number of dermal papilla cells had already decreased during the dystrophic catagen and subsequent anagen (post-radiation regenerated anagen). However, cell apoptosis can be ruled out as the cause of the reduction in dermal papilla cell numbers, as no apoptosis of dermal papilla cells was observed through staining with cleaved caspase 3. The specific reasons for the decrease in dermal papilla cell numbers remain to be clarified. Additionally, tracking the proportion of hair follicle dermal stem cells (hfDSCs) replenishing the dermal papilla in aSMACreER:R26LSL-tdtomato transgenic mice revealed a decrease in this ratio. This indicates that the specialization of hfDSCs into dermal papilla cells is inhibited. Therefore, after high-dose radiation injury, the replenishment of dermal papilla cells cannot be achieved through the supplementation of hfDSCs. The Wnt signaling family plays a crucial role in hair follicle regeneration and the maintenance of hair follicle stem cells. In addition, to enhance the specialization ability of hfDSCs into dermal papilla cells, we observed the growth dynamics of dermal sheath cells and hfDSCs. From the experimental results, we found that dermal sheath cells begin to proliferate during the anagen phase and continue to proliferate until anagen III or IV. On the other hand, hfDSCs replenish the dermal papilla during anagen III. Therefore, if we aim to promote the ability of hfDSCs, it is crucial to implement interventions during early anagen.