We present a catheter-based optical diffusion and fluorescence(ODF)probe to study the functional changes of the brain in vivo.This ODF probe enables the simultaneous detection ofthe multi-wavelength absorbance and fl...We present a catheter-based optical diffusion and fluorescence(ODF)probe to study the functional changes of the brain in vivo.This ODF probe enables the simultaneous detection ofthe multi-wavelength absorbance and fluorescence emission from the living rat brain.Our previous studies,including a transient stroke experiment of the rat brain as well as the brainresponse to cocaine,have established the feasibility of simultaneously determining changes incerebral blood volume(CBV),tissue oxygenation(StO2)and intracellular calcium([Ca^(2+)]i,using the fluorescence indicator Rhod2).Here,we present our preliminary results of somatosensory response to electrical forepaw stimulation obtained from the rat cortical brain by using theODF probe,which indicate that the probe could track brain activation by directly detecting[Ca^(2+)]i along with separately distinguishing CBV and StO2 in real time.The changes of CBV,StO2 and[Ca^(2+)]i are comparable with the blood-oxygen-level-dependent(BOLD)response tothe stimulation obtained using functional magnetic resonance imaging(fMRI).However,thehigh temporal resolution of the optical methodology is advanced,thus providing a new modalityfor brain functional studies to understand the hemodynamic changes that underlie the neuronalactivity.展开更多
基金NIH Grants K25-DA021200,Laboratory Directed Research Development(LDRD)Grant(04-066)of Brook-haven National Laboratory,and by Department of Energy Office of Science and Biological Research.
文摘We present a catheter-based optical diffusion and fluorescence(ODF)probe to study the functional changes of the brain in vivo.This ODF probe enables the simultaneous detection ofthe multi-wavelength absorbance and fluorescence emission from the living rat brain.Our previous studies,including a transient stroke experiment of the rat brain as well as the brainresponse to cocaine,have established the feasibility of simultaneously determining changes incerebral blood volume(CBV),tissue oxygenation(StO2)and intracellular calcium([Ca^(2+)]i,using the fluorescence indicator Rhod2).Here,we present our preliminary results of somatosensory response to electrical forepaw stimulation obtained from the rat cortical brain by using theODF probe,which indicate that the probe could track brain activation by directly detecting[Ca^(2+)]i along with separately distinguishing CBV and StO2 in real time.The changes of CBV,StO2 and[Ca^(2+)]i are comparable with the blood-oxygen-level-dependent(BOLD)response tothe stimulation obtained using functional magnetic resonance imaging(fMRI).However,thehigh temporal resolution of the optical methodology is advanced,thus providing a new modalityfor brain functional studies to understand the hemodynamic changes that underlie the neuronalactivity.