Simultaneous detection of blood volume, oxygenation, and intracellular calcium changes during cerebral ischemia and reperfusion in vivo using diffuse reflectance and fluorescence.
Du C, Koretsky AP, Izrailtyan I, Benveniste H.
Brookhaven National Laboratory, Medical Department, Upton, New York 11973-5000, USA. congwu@bnl.gov
We describe an approach to measure changes in intracellular calcium along with changes
in blood volume and oxygenation directly from the exposed rat cortex in vivo during
cerebral ischemia and reperfusion. Measurements were made using a catheter-based optical
system. The endface of a Y-shaped bifurcated fiber optic bundle was mounted on the
cortical surface. It delivered the light at three wavelengths of 548, 555, and 572 nm
to the brain through a fast monochromator coupled to a xenon lamp, and collected the
calcium-dependent fluorescence emission from Rhod2 at 589 nm (excited at 548 nm)
along with the diffuse reflections at the wavelengths of 555 and 572 nm to determine
the changes in blood volume and hemoglobin oxygenation. The feasibility of this
approach was experimentally examined by inducing transient cerebral ischemia and
reperfusion in the rat. The ischemia induced an 8.5%+/-1.7% fluorescence increase
compared with the preischemic control values. Blood volume and tissue hemoglobin
oxygenation decreased by 57.4%+/-12.6% and 47.3%+/-12.5%, respectively. All signals
normalized on reperfusion. The ischemia-induced change in Rhod2-Ca2+ fluorescence
was blocked using a calcium channel blocker, nimodipine, confirming that intracellular
changes in calcium were responsible for the fluorescence changes. Thus, changes in
cerebral hemodynamics and intracellular calcium concentration changes were measured simultaneously, facilitating
future studies of the interrelationship between neuronal activation and metabolic
and vascular processes in normal and diseased brain.
PMID: 15744244 [PubMed - indexed for MEDLINE]