Nitric oxide from neuronal NOS plays critical role in cerebral capillary flow response to hypoxia

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Nitric oxide from neuronal NOS plays critical role in cerebral capillary flow response to hypoxia

Antal G. Hudetz, Hui Shen, and John P. Kampine

Departments of Anesthesiology and Physiology, Medical College of Wisconsin, Milwaukee, Wisconsin 53226

We investigated, using a direct, intravital microscopic technique, whether nitric oxide (NO) from neuronal nitric oxide synthase(nNOS) plays a role in the cerebral capillary flow response toacute hypoxia. Erythrocyte flow in subsurface capillaries of thefrontoparietal cortex of adult Sprague-Dawley rats was visualizedusing epifluorescence videomicroscopy after fluorescent labelingof red blood cells (RBC) in tracer concentrations. The velocityof labeled RBC in individual capillaries was measured off-lineusing an image analysis system. Hypoxia was produced by loweringthe inspired O₂ concentration to 15% for 5 min in control animalsand in those pretreated with the selective nNOS inhibitor 7-nitroindazole(7-NI; 20 mg/kg ip). In the control group, hypoxia increased RBCvelocity by 34 ± 8%. In the group treated with 7-NI, this responsewas reversed to a statistically significant 8 ± 3% decrease. Thisparadoxical response to hypoxia after 7-NI was observed in nearlyall capillaries. 7-NI itself decreased the baseline RBC velocityby 12 ± 4%. The cerebral hyperemic response to hypoxia was alsoassessed with the laser Doppler flow (LDF) technique. In controlanimals, hypoxia produced a 33 ± 6% increase in LDF, similar tothe increase in RBC velocity. After 7-NI treatment, the responseto hypoxia was moderately attenuated but still significant ata 19 ± 2% increase in LDF. These results support the role of NOfrom nNOS in the cerebral hyperemic response to hypoxia. Theyimply that 7-NI interfered with a physiological mechanism thatwas fundamental to cerebral capillary flow regulation and providedirect evidence that cerebral capillary perfusion may be dissociatedfrom a concurrent change in regional tissue perfusion as reflectedby LDF. In conclusion, NO from nNOS contributes to the maintenanceof RBC flow in cerebral capillaries and plays a critically importantrole in the selective regulation of cerebral capillary flow duringhypoxia.

7-nitroindazole; microcirculation; cranial window; laser Doppler; vasodilation; hyperemia; cerebral blood flow

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