Episodic release of bioactive compounds plays an important role in biological systems. “On-demand” release systems which based on polymeric materials and activated by external stimuli may provide the necessary functionality. For proof of this concept, firstly an ultrasound-responsive hydrogel based on N-isopropylacrylamide (NIPAM) and N,N’-methylenebisacrylamide (MBAm) was proposed, which is suitable for triggered release of two large molecules: bovine serum albumin (BSA, 66 kDa) and dextran (3-5 kDa). It is shown that the release amount of these two large molecules increased with increasing hydrogel temperature, and the application of ultrasound further increased the release. By simply adjusting the contents of NIPAM and MBAm, the difference of BSA release between the presence and absence of ultrasound could be adjusted from 1.5 to 84 folds. There was also a positive correlation between the ultrasound intensity and release amount. These properties made the NIPAM-based hydrogel a tunable platform for focal drug delivery. Further, an injectable, biocompatible, and thermosensitive hydrogel system for ultrasound (US)-triggered drug release was investigated. An mPEG-PLGA-BOX block copolymer hydrogel was synthesized. The viscosity of 15 wt% hydrogel is 0.03 Pa*s at 25 °C (liquid form) and 34.37 Pa*s at 37 °C (gel form). Baseline and US-responsive in vitro release profile of a small molecule (doxorubicin, M.W. 580) and that of a large molecule (FITC-dextran, M.W. 20000), from the hydrogel, was tested. A constant baseline release was observed in vitro for 7 d. When triggered by US (1 MHz, continuous, 0.4 W/cm2), the release rate increased by approximately 70 times. Without US, the release rate returned to baseline. Baseline and US-responsive in vivo release profile of doxorubicin was tested by subcutaneous injection in the back of mice and rats. Following injection into the subcutaneous layer, in vivo results also suggested that the hydrogels remained in situ and provided a steady release for at least 7 d; in the presence of the US-trigger, in vivo release from the hydrogel increased by approximately 10 times. Therefore, the mPEG-PLGA-BOX block copolymer hydrogel may serve as an injectable, biocompatible, and thermosensitive hydrogel system that is applicable for US-triggered drug release. This system may be suitable for drugs which “on-demand” release is necessary, such as insulin, certain hormones or antibiotics.