Abstract
In this study we present a novel imaging method that combines high resolution cerebral blood flow imaging with a highly flexible map of absolute pO(2). In vivo measurements of pO(2) in animals using phosphorescence quenching is a well established method, and is preferable over electrical probes which are inherently invasive and are limited to single point measurements. However, spatially resolved pO(2) measurements using phosphorescence lifetime quenching typically require expensive cameras to obtain images of pO(2) and often suffer from poor signal to noise. Our approach enables us to retain the high temporal resolution and sensitivity of single point detection of phosphorescence by using a digital micromirror device (DMD) to selectively illuminate arbitrarily shaped regions of tissue. In addition, by simultaneously using Laser Speckle Contrast Imaging (LSCI) to measure relative blood flow, we can better examine the relationship between blood flow and absolute pO(2). We successfully used this instrument to study changes that occur during ischemic conditions in the brain with enough spatial resolution to clearly distinguish different regions. This novel instrument will provide researchers with an inexpensive and improved technique to examine multiple hemodynamic parameters simultaneously in the brain as well as other tissues.
Highlights
The ability to quantitatively image oxygenation levels in tissue is important for a number of tissues and physiological conditions
Speckle contrast imaging has been shown to be a powerful method for full field imaging of blood flow [1,2], while multi-spectral reflectance imaging has improved the spatial resolution of traditional spectroscopy [3,4,5,6]
Upon application of the ET-1 to the lateral craniotomy, the downstream blood flow decreased over the entire field of view, as illustrated by the speckle contrast images before (Fig. 2(b)) and 5 minutes after ET-1 application (Fig. 2(c))
Summary
The ability to quantitatively image oxygenation levels in tissue is important for a number of tissues and physiological conditions. Speckle contrast imaging has been shown to be a powerful method for full field imaging of blood flow [1,2], while multi-spectral reflectance imaging has improved the spatial resolution of traditional spectroscopy [3,4,5,6]. Despite these improvements, the majority of optical imaging techniques are still limited to relative measurements. The majority of optical imaging techniques are still limited to relative measurements This prevents a thorough analysis of the important role of baseline conditions and fair comparisons across trials
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