Abstract
Antivascular therapy represents a proven strategy to treat angiogenesis. By applying synchronized ultrasound bursts and nanosecond laser irradiation, we developed a novel, selective, non-invasive, localized antivascular method, termed photo-mediated ultrasound therapy (PUT). PUT takes advantage of the high native optical contrast among biological tissues and can treat microvessels without causing collateral damage to the surrounding tissue. In a chicken yolk sac membrane model, under the same ultrasound parameters (1 MHz at 0.45 MPa and 10 Hz with 10% duty cycle), PUT with 4 mJ/cm2 and 6 mJ/cm2 laser fluence induced 51% (p = 0.001) and 37% (p = 0.018) vessel diameter reductions respectively. With 8 mJ/cm2 laser fluence, PUT would yield vessel disruption (90%, p < 0.01). Selectivity of PUT was demonstrated by utilizing laser wavelengths at 578 nm or 650 nm, where PUT selectively shrank veins or occluded arteries. In a rabbit ear model, PUT induced a 68.5% reduction in blood perfusion after 7 days (p < 0.001) without damaging the surrounding cells. In vitro experiments in human blood suggested that cavitation may play a role in PUT. In conclusion, PUT holds significant promise as a novel non-invasive antivascular method with the capability to precisely target blood vessels.
Highlights
Nearby healthy tissue and if it extravasates during intravenous injection
Similar to PDT and embolotherapy, AVUT requires the systemic injection of foreign particles into the blood stream, which leads to serious concerns of toxicity, efficiency, and emboli formation
A laser pulse (5-ns pulse width with 10-Hz pulse repetition rate) irradiated the target blood vessel with 532 nm light simultaneously with an ultrasound tone burst (1 MHz, 10% duty cycle, and 10-Hz pulse repetition rate)
Summary
Nearby healthy tissue and if it extravasates during intravenous injection. PDT in ophthalmic applications has been associated with choroidal infarction and acute, severe vision loss[30]. Very strict treatment time window is a major concern in clinical adaptions of both PDT and AVUT because the circulation time of photosensitizers and microbubbles is limited. This limits the clinical applicability, in high volume retinal practices, where PDT caused a significant disruption in clinic flow. Photothermolysis is a selective therapeutic technique based on optical absorption to remove tissue The shear stresses and microjets produced by oscillating bubbles in a microvessel can directly impact the physiological functions of endothelial cells, red blood cells, and platelets. Unlike PDT and AVUT which involve either photosensitizers or microbubbles, PUT is totally noninvasive and agent-free
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