Background and Purpose-New treatment strategies for acute ischemic stroke must be evaluated in the context of effective reperfusion. Minocycline is a neuroprotective agent that inhibits proteolytic enzymes and therefore could potentially both inactivate the clot lysis effect and decrease the damaging effects of tissue-type plasminogen activator (t-PA). This study aimed to determine the effect of minocycline on t-PA clot lysis and t-PA-induced hemorrhage formation after ischemia. Methods-Fibrinolytic and amidolytic activities of t-PA were investigated in vitro over a range of clinically relevant minocycline concentrations. A suture occlusion model of 3-hour temporary cerebral ischemia in rats treated with t-PA and 2 different minocycline regimens was used. Blood-brain barrier basal lamina components, matrix metalloproteinases (MMPs), hemorrhage formation, infarct size, edema, and behavior outcome were assessed. Results-Minocycline did not affect t-PA fibrinolysis. However, minocycline treatment at 3 mg/kg IV decreased total protein expression of both MMP-2 (Pϭ0.0034) and MMP-9 (Pϭ0.001 for 92 kDa and Pϭ0.0084 for 87 kDa). It also decreased the incidence of hemorrhage (Pϭ0.019), improved neurologic outcome (Pϭ0.0001 for Bederson score and Pϭ0.0391 for paw grasp test), and appeared to decrease mortality. MMP inhibition was associated with decreased degradation in collagen IV and laminin-␣1 (Pϭ0.0001). Conclusions-Combination treatment with minocycline is beneficial in t-PA-treated animals and does not compromise clot lysis. These results also suggest that neurovascular protection by minocycline after stroke may involve direct protection of the blood-brain barrier during thrombolysis with t-PA. (Stroke. 2009;40:3028-3033.)
Background and purposeThe role of autophagy in response to ischemic stroke has been confusing with reports that both enhancement and inhibition of autophagy decrease infarct size and improve post-stroke outcomes. We sought to clarify this by comparing pharmacologic modulation of autophagy in two clinically relevant murine models of stroke.MethodsWe used rapamycin to induce autophagy, and chloroquine to block completion of autophagy, by treating mice immediately after stroke and at 24 hours post-stroke in two different models; permanent Middle Cerebral Artery Ligation (MCAL), which does not allow for reperfusion of distal trunk of middle cerebral artery, and Embolic Clot Middle Cerebral Artery Occlusion (eMCAO) which allows for a slow reperfusion similar to that seen in most human stroke patients. Outcome measures at 48 hours post-stroke included infarct size analysis, behavioral assessment using Bederson neurological scoring, and survival.ResultsChloroquine treatment reduced the lesion size by approximately 30% and was significant only in the eMCAO model, where it also improved the neurological score, but did not increase survival. Rapamycin reduced lesion size by 44% and 50% in the MCAL and eMCAO models, respectively. Rapamycin also improved the neurological score to a greater degree than chloroquine and improved survival.ConclusionsWhile both inhibition and enhancement of autophagy by pharmacological intervention decreased lesion size and improved neurological scores, the enhancement with rapamycin showed a greater degree of improvement in outcomes as well as in survival. The protective action seen with chloroquine may be in part due to off-target effects on apoptosis separate from blocking lysosomal activity in autophagy. We conclude pharmacologic induction of autophagy is more advantageous than its blockade in physiologically-relevant permanent and slow reperfusion stroke models.
Aims Current thrombolytic therapies rely upon exogenous plasminogen activators (PA) to effectively lyse clots, thereby restoring blood flow and preventing tissue and organ death. Yet, these PAs may also impair normal hemostasis which may lead to life-threatening bleeding, including intracerebral hemorrhage. Thus, the aim of this current study is to develop new thrombus-targeted fibrinolytic agents that harness the multifunctional theranostic capabilities of nanomaterials, potentially allowing for the generation of efficacious thrombolytics while minimizing deleterious side effects. Materials and Methods A thrombus-targeted nano-fibrinolytic agent (CLIO-FXIII-PEG-tPA) was synthesized using a magnetofluorescent crosslinked dextran-coated iron oxide (CLIO) nanoparticle platform that was conjugated to recombinant tissue plasminogen activator (tPA). Thrombus-targeting was achieved by derivatizing the nanoparticle with an activated factor XIII (FXIIIa)-sensitive peptide based on the amino terminus of α2-antiplasmin. Human plasma clot binding ability of the targeted and control agents was assessed by fluorescence reflectance imaging. Next, the in vitro enzymatic activity of the agents was assessed by S2288-based amidolytic activity, and an ELISA D-dimer assay for fibrinolysis. In vivo targeting of the nanoagent was next examined by intravital fluorescence microscopy of murine arterial and venous thrombosis. The fibrinolytic activity of the targeted nanoagent compared to free tPA was then evaluated in vivo in murine pulmonary embolism. Results In vitro, the targeted thrombolytic nanoagent demonstrated binding to fresh frozen plasma (FFP) clots superior to control nanoagents (ANOVA p < 0.05). On a weight (mg) basis, the S2288 amidolytic efficiency of the targeted nanoagent was approximately 15% reduced compared to free tPA. When normalized by S2288-based activity, targeted, control, and free tPA samples demonstrated equivalent in vitro fibrinolytic activity against human plasma clots, as determined by ELISA D-dimer assays. The FXIIIa targeted fibrinolytic nanoagent efficiently bound the margin of intravascular thrombi as detected by IVFM. In in vivo fibrinolysis studies normalized for activity, the FXIIIa-targeted agent lysed pulmonary emboli with similar efficacy as free tPA (p>0.05). Conclusions The applicability of a FXIIIa-targeted thrombolytic nanoagent in the treatment of thromboembolism was demonstrated in vitro and in vivo. Future studies are planned to investigate the safety profile and overall efficacy of this class of nanoagents, and to further optimize their thrombus-targeting profile and lytic action.
BackgroundMinocycline provides neurovascular protection reducing acute cerebral injury. However, it is unclear whether minocycline is effective in females. We tested minocycline in both sexes and aged animals using a novel embolic stroke model in mice that closely mimics acute thromboembolic stroke in humans.MethodsFive groups of mice were subjected to thromboembolic stroke: adult males, aged males, adult females, aged females, and adult ovariectomized females. They were treated with phosphate saline (vehicle) or minocycline (6 mg/kg) immediately after stroke onset. Behavioral outcomes, infarct volumes and cerebral blood flow were assessed. The effect of minocycline on expression and activity of MMP-9 was analyzed.ResultsThe model resulted in reproducible infarct in the experimental groups. As expected, adult females were significantly more resistant to cerebral ischemic injury than males. This advantage was abolished by aging and ovariectomy. Minocycline significantly reduced the infarct volume (P < 0.0001) and also improved neurologic score (P < 0.0001) in all groups. Moreover, minocycline treatment significantly reduced mortality at 24 hours post stroke (P = 0.037) for aged mice (25% versus 54%). Stroke up-regulated MMP-9 level in the brain, and acute minocycline treatment reduced its expression in both genders (P < 0.0001).ConclusionIn a thromboembolic stroke model minocycline is neuroprotective irrespective of mouse sex and age.
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