The field of physical therapy is advancing and using focused ultrasound to deliver drugs into the brain gains growing interest. However, the blood-brain barrier makes it difficult for drugs to enter. Finding safe and efficient physical therapy strategies to complement drug treatments is essential. Here, the rule and molecular mechanisms of spatiotemporal opening blood-brain barrier of ultrasound were explored using a Bluetooth-controlled ultrasonic head-mounted device which was used to enhance the brain permeation of drugs for the treatment of radiation-induced brain injury. The falling-off of tight junction proteins in the blood-brain barrier was the key to spatiotemporally opening under ultrasound. Evans blue and Rhodamine B represented macromolecules and small molecules, respectively, which were intravenously injected into the circulation. Their brain permeation was promoted by brain ultrasound and the smaller molecules required the lower sound intensity that also affected the speed of drug-passing. During the blood-brain barrier restoration after ultrasound, biomarkers like enzymes and growth factors changed, which could be used for selection of dosing window. After the use of the helmet, the blood-brain barrier was restored after 24 h, and the efficacy of water-soluble drugs for the treatment of radiation brain injury was increased. It was suitable for non-invasive external use and enhanced the treating effect when cooperating with drugs. This study provides a research basis for applying ultrasound technology into physio-pharmacotherapy.