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Abstract WP326: Cortical Border Zones Are More Vulnerable to Spreading Depression-Induced Capillary Flow Disturbances

Taskiran-Sag, Aslihan ; Iversen, Nina Kerting ; Gutiérrez-Jiménez, Eugenio ; [et al.]

Ovid Technologies (Wolters Kluwer Health) ; 2020

In: Stroke Vol. 51, No. Suppl_1 ( 2020-02)

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In: Stroke, Ovid Technologies (Wolters Kluwer Health), Vol. 51, No. Suppl_1 ( 2020-02)

Abstract: Cortical spreading depression (SD) is a major metabolic challenge to the brain and is followed by a unique hemodynamic response. It has been suggested that the oligemic phase of this response is accompanied by a mild to moderate capillary dysfunction. To test this hypothesis, we directly investigated microcirculatory flow changes during and after SD at the territory of major arteries as well as their hemodynamically vulnerable watershed zones. Swiss mice (n=6) under isoflurane anesthesia were tracheotomized, mechanically ventilated, and imaged under two-photon microscopy through a closed cranial window. Mean transit time (MTT), capillary transit time heterogeneity (CTH) and relative transit time heterogeneity (RTH) were calculated based on an indicator-dilution method using intravenous boluses of Texas-red dextran fluorescent dye (70,000 MW; 0.5%). Boluses were performed at the steady-state and 1 min, 5 min and 30 minutes after potassium chloride-induced SD. MTT, CTH, and RTH were estimated within the territory and border zone of major arteries to reveal any regional differences. Physiological parameters were monitored and kept within normal limits throughout the experiments. Both MTT and CTH increased following SD in the territorial zone from 1.07±0.03 to 1.67±0.15 s (mean±SEM;p 〈 0.01) and from 0.51±0.03 to 0.94±0.07 s (mean±SEM;p 〈 0.01), respectively. However, RTH was only mildly increased in this region from 0.49±0.04 to 0.59±0.06 (p=0.03). In the watershed area, all three parameters showed a more prominent increase following SD and RTH rose from 0.64±0.06 to 1.25±0.22 at 30 minutes (p=0.04). These findings provide direct experimental evidence for prolonged capillary flow disturbances induced by cortical SD, which may account for some lasting neurological symptoms after aura. The particular vulnerability of border zones to SD-induced flow disturbances may be involved in the pathogenesis of some of the white matter MRI lesions observed in migraineurs.

Type of Medium: Online Resource

ISSN: 0039-2499 , 1524-4628

URL: Article

DOI: 10.1161/str.51.suppl_1.WP326

RVK:

XA 10000

Language: English

Publisher: Ovid Technologies (Wolters Kluwer Health)

Publication Date: 2020

detail.hit.zdb_id: 1467823-8

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Improving Microcirculatory Reperfusion Reduces Parenchymal Oxygen Radical Formation and Provides Neuroprotection

Taskiran-Sag, Aslihan ; Yemisci, Muge ; Gursoy-Ozdemir, Yasemin ; [et al.]

Ovid Technologies (Wolters Kluwer Health) ; 2018

In: Stroke Vol. 49, No. 5 ( 2018-05), p. 1267-1275

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In: Stroke, Ovid Technologies (Wolters Kluwer Health), Vol. 49, No. 5 ( 2018-05), p. 1267-1275

Abstract: Reperfusion is the most significant determinant of good outcome after ischemic stroke. However, complete reperfusion often cannot be achieved, despite satisfactory recanalization. We hypothesized that microvascular protection was essential for achieving effective reperfusion and, hence, neuroprotection. To test this hypothesis, we have developed an in vivo model to differentially monitor parenchymal and vascular reactive oxygen species (ROS) formation. By comparing the ROS-suppressing effect of N-tert-butyl-α-phenylnitrone (PBN) with its blood–brain barrier impermeable analog 2-sulfo-phenyl-N-tert-butylnitrone (S-PBN), we assessed the impact of vascular ROS suppression alone on reperfusion and stroke outcome after recanalization. Methods— The distal middle cerebral artery was occluded for 1 hour by compressing with a micropipette and then recanalized (n=60 Swiss mice). ROS formation was monitored for 1 hour after recanalization by intravital fluorescence microscopy in pial vasculature and cortical parenchyma with topically applied hydroethidine through a cranial window. PBN (100 mg/kg) or S-PBN (156 mg/kg) was administered shortly before recanalization, and suppression of the vascular and parenchymal hydroethidine fluorescence was examined (n=22). Microcirculatory patency, reperfusion, ischemic tissue size, and neurological outcome were also assessed in a separate group of mice 1 to 72 hours after recanalization (n=30). Results— PBN and S-PBN completely suppressed the reperfusion-induced increase in ROS signal within vasculature. PBN readily suppressed ROS produced in parenchyma by 88%. S-PBN also suppressed the parenchymal ROS by 64% but starting 40 minutes later. Intriguingly, PBN and S-PBN comparably reduced the size of ischemic area by 65% and 48% ( P 〉 0.05), respectively. S-PBN restored the microvascular patency and perfusion after recanalization, suggesting that its delayed parenchymal antioxidant effect could be secondary to improved microcirculatory reperfusion. Conclusions— Promoting microvascular reperfusion by protecting vasculature can secondarily reduce parenchymal ROS formation and provide neuroprotection. The model presented can be used to directly assess pharmacological end points postulated in brain parenchyma and vasculature in vivo.

Type of Medium: Online Resource

ISSN: 0039-2499 , 1524-4628

URL: Article

DOI: 10.1161/STROKEAHA.118.020711

RVK:

XA 10000

Language: English

Publisher: Ovid Technologies (Wolters Kluwer Health)

Publication Date: 2018

detail.hit.zdb_id: 1467823-8

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