Neisseria meningitidis is a commensal bacterium of the human nasopharynx. Occasionally, this bacterium reaches the bloodstream and causes meningitis after crossing the blood–brain barrier by an unknown mechanism. An immunohistological study of a meningococcal sepsis case revealed that neisserial adhesion was restricted to capillaries located in low blood flow regions in the infected organs. This study led to the hypothesis that drag forces encountered by the meningococcus in the bloodstream determine its attachment site in vessels. We therefore investigated the ability of N. meningitidis to bind to endothelial cells in the presence of liquid flow mimicking the bloodstream with a laminar flow chamber. Strikingly, average blood flows reported for various organs strongly inhibited initial adhesion. As cerebral microcirculation is known to be highly heterogeneous, cerebral blood velocity was investigated at the level of individual vessels using intravital imaging of rat brain. In agreement with the histological study, shear stress levels compatible with meningococcal adhesion were only observed in capillaries, which exhibited transient reductions in flow. The flow chamber assay revealed that, after initial attachment, bacteria resisted high blood velocities and even multiplied, forming microcolonies resembling those observed in the septicemia case. These results argue that the combined mechanical properties of neisserial adhesion and blood microcirculation target meningococci to transiently underperfused cerebral capillaries and thus determine disease development.
This study was designed to assess that mouse pial and cortical microcirculation can be monitored in the long term directly in the area of focal ischemia, using in vivo fluorescence microscopy. A closed cranial window was placed over the left parieto-occipital cortex of C57BL/6J mice. Local microcirculation was recorded in real time through the window using laser-scanning confocal fluorescence microscopy after intravenous injection of fluorescent erythrocytes and dextran. The basal velocity of erythrocytes through intraparenchymal capillaries was 0.53+/-0.30 mm/sec (n=121 capillaries in 10 mice). Two branches of the middle cerebral artery were topically cauterized through the window. Blood flow evaluated by laser-Doppler flowmetry in two distinct areas indicated the occurrence of an ischemic core (15.2%+/-5.9% of baseline for at least 2 h) and a penumbral zone. Magnetic resonance imaging and histology were used to characterize the ischemic area at 24 h after occlusion. The infarct volume was 7.3+/-3.2 mm(3) (n=6). Microcirculation was repeatedly videorecorded using fluorescence confocal microscopy over the next month. After the decrease following arterial occlusion, capillary erythrocyte velocity was significantly higher than baseline 1 week later, and attained 0.74+/-0.51 mm/sec (n=76 capillaries in six mice, P<0.005) after 1 month, while venous and capillary network remodeling was assessed, with a marked decrease in tortuosity. Immunohistochemistry revealed a zone of necrotic tissue into the infarct epicenter, with activated astrocytes at its border. Such long-term investigations in ischemic cortex brings new insight into the microcirculatory changes induced by focal ischemia and show the feasibility of long-term fluorescence studies in the mouse cortex.
Background and Purpose-To study whether intravascular or hemodynamic factors contribute to the marked neuroprotective effect of albumin therapy in focal cerebral ischemia, 2 complementary methods were applied: laser-scanning confocal microscopy (LSCM) and laser-Doppler perfusion imaging (LDPI). Methods-In the LSCM study, Sprague-Dawley rats were anesthetized with halothane/nitrous oxide, and a cranial window was placed over the dorsolateral frontoparietal cortex. Rats received 2-hour middle cerebral artery occlusion (MCAO) by an intraluminal suture and were treated with human albumin (1.25 g/kg; nϭ4) or saline (nϭ3) after 30 minutes of recirculation. Video images of cortical vessels were continually acquired and were digitized offline to measure diameters and fluorescent erythrocyte velocities. In the LDPI study, cortical perfusion was measured in anesthetized SpragueDawley rats that received 2-hour MCAO and were treated with albumin (2.5 g/kg; nϭ6) or saline (nϭ5) at 30 minutes after recirculation. Results-In the LSCM study, MCAO was associated with arteriolar dilation and slowing of capillary and venular erythrocyte perfusion. During the first 15 to 30 minutes of postischemic recirculation, prominent foci of vascular stagnation developed within cortical venules, associated with thrombuslike foci and adherent corpuscular structures consistent in size with neutrophils. Saline administration failed to affect these phenomena, while albumin therapy was followed by significant increases in arteriolar diameter (Ϸ12%; Pϭ0.007) and by a prompt improvement of venular and capillary erythrocyte perfusion and a partial disappearance of adherent thrombotic material. Albumin therapy increased erythrocyte flow velocity in both capillaries (288Ϯ73% versus 76Ϯ18% in the saline group; Pϭ0.023) and venules (2.7-fold [Pϭ0.001] versus 1.0-fold in the saline group [PϭNS]). In the LDPI study, cortical perfusion declined during MCAO and rose initially with recirculation (to Ϸ135% of baseline) in both groups. Mean cortical perfusion improved slightly (Ϸ14%; PϭNS) in albumin-treated animals. Conclusions-These results reveal a beneficial effect of albumin therapy in reversing stagnation, thrombosis, and corpuscular adherence within cortical venules in the reperfusion phase after focal ischemia and support its utility in the treatment of acute ischemic stroke.
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