Ultrasound-sensitive thrombolytic drug selleckchem delivery combined with specific targeting is highly attractive. Targeting of clot-dissolving therapeutics can potentially decrease the frequency of complications while simultaneously increasing treatment effectiveness by concentrating the available drug at the desired site and permitting a lower systemic dose [9]. Clinical studies
support the use of ultrasound for therapy of ischemic stroke, and first trials of enhancing sonothrombolysis with microbubbles have been encouraging. A recent meta-analysis of all published clinical sonothrombolysis studies confirmed that ultrasound and tPA (with or without microbubbles) increases recanalization compared to tPA alone [10]. These observations have led to design of CLOTBUSTER, a phase III controlled clinical trial of sonothrombolysis. One emerging clinical application is sonothrombolysis of intracranial hemorrhages see more for clot evacuation using catheter-mounted transducers. As compared with MISTIE (Minimally Invasive Surgery plus T-PA for Intracerebral Hemorrhage Evacuation) and CLEAR (Clot Lysis Evaluating Accelerated Resolution
of Intraventricular Hemorrhage II) studies data, the rate of lysis during treatment for IVH and ICH was faster in patients treated with sonothrombolysis plus rt-PA versus rt-PA alone [11]. Thus, lysis and drainage of spontaneous ICH and IVH with a reduction in mass effect can be accomplished rapidly and safely through sonothrombolysis using stereotactically delivered drainage and ultrasound catheters via a bur hole. Histotripsy
is a process which fractionates soft tissue through controlled cavitation using focused, short, high-intensity ultrasound pulses. Histotripsy can be used to achieve effective thrombolysis with ultrasound energy alone at peak negative acoustic pressures >6 MPa, breaking down blood clots in about 1.5–5 min into small fragments less than find more 5 μm diameter [12]. Recent developments in using MR-guided focused ultrasound therapy through the intact skull suggest that this technology could be useful for clot lysis in humans. Experimental studies are currently being undertaken to test this possibility, both in ischemic and hemorrhagic stroke. Ultrasound and microbubbles may improve flow to the microcirculation irrespective of recanalization, thus opening new opportunities for application of sonothrombolysis in acute ischemic stroke. This was suggested by results of a study on possible adverse bioeffects [13] of 2 MHz ultrasound and microbubbles (Sonovue™) in a middle cerebral artery permanent occlusion model in rats at different steps in the cascade of tissue destruction after ischemic stroke [14]. While deleterious effects were not observed, infarctions were unexpectedly smaller in the treatment group, despite the fact that in all animals recanalization of the MCA did not occur. This suggested a beneficial effect of ultrasound and microbubbles in the microcirculation.