Photothermal-Activatable Liposome Carrying Tissue Plasminogen Activator for Photoacoustic Image-Guided Ischemic Stroke Treatment

Ischemic stroke is a highly prevalent cause of mortality and morbidity. The only FDA-approved treatment is thrombolysis using tissue plasminogen activator (tPA), which possesses a short effective time window. Real-time recanalization monitoring is crucial to establish successful reperfusion and serves as a strong predictor of clinical outcomes. First-line clinical imaging techniques, such as computed tomography and magnetic resonance imaging, are limited in their soft-tissue resolution, scanning speed, and accessibility. Transcranial doppler ultrasound, the current gold standard for recanalization monitoring, is a blind technique and highly operator dependent. Herein, a photothermal-activatable liposome carrying tPA for photoacoustic (PA) image-guided therapy for real-time and precise recanalization monitoring of ischemic stroke is designed. The liposome containing an organic molecule with propeller structures exhibits excellent photothermal properties and significantly amplified PA signals as compared with the widely used polymer nanoparticles. Near-infrared (NIR) laser triggers rapid release of tPA for quick blood clot lysis in vitro. Administration of the liposome in a rat photothrombotic ischemia model facilitates high-resolution PA imaging for precise real-time recanalization assessment. Precisely controlled tPA release at the ischemic region is achieved by PA image-guided NIR laser irradiation, which successfully dissolves the blood clot and restores perfusion, making this design promising for translational applications.

Automated summary

This study presents a photothermal-activatable liposome for photoacoustic image-guided therapy of ischemic stroke. The technology, with strong photothermal properties and amplified photoacoustic signals, achieves rapid release of tPA using near-infrared laser and successfully restores perfusion in a rat ischemia model. Precise control of tPA release at the ischemic region is achieved through photoacoustic image-guided NIR laser irradiation, showing promise for translational applications.