| 초록 |
Intravesical therapeutic delivery has been extensively investigated for various bladder diseases. However, conventional drug carriers have a low therapeutic delivery efficiency because of the passive diffusion of drug molecules in a bladder and the rapid clearance by periodic urination. Here, we report biocompatible and bioavailable enzyme-powered polymer nanomotors which can deeply penetrate into a mucosa layer of the bladder wall and remain for a long-term period in the bladder. After injection into the bladder, urease-immobilized nanomotors became active, moving around in the bladder by converting urea into carbon dioxide and ammonia. The nanomotors resulted in the facilitated penetration to the mucosa layer of the bladder wall and the prolonged retention in the bladder even after repeated urination. The enhanced penetration and retention of the nanomotors as a drug delivery carrier in the bladder would be successfully harnessed for treating a variety of bladder diseases. |
