Fast simultaneous assessment of renal and liver function using polymethine dyes in animal models of chronic and acute organ injury.

Simultaneous assessment of excretory liver and kidney function is still an unmet need in experimental stress models as well as in critical care. The aim of the study was to characterize two polymethine-dyes potentially suitable for this purpose in vivo. Plasma disappearance rate and elimination measurements of simultaneously injected fluorescent dyes DY-780 (hepato-biliary elimination) and DY-654(renal elimination) were conducted using catheter techniques and intravital microscopy in animals subjected to different organ injuries, i.e. polymicrobial sepsis by peritoneal contamination and infection, ischemia-reperfusion-injury and glycerol-induced acute kidney-injury. DY-780 and DY-654 showed organ specific and determined elimination routes in both healthy and diseased animals. They can be measured simultaneously using near-infrared imaging and spectrophotometry. Plasma-disappearance rates of DY-780 and DY-654 are superior to conventional biomarkers in indicating hepatic or kidney dysfunction in different animal models. Greatest impact on liver function was found in animals with polymicrobial sepsis whereas glomerular damage due to glycerol-induced kidney-injury had strongest impact on DY-654 elimination. We therefore conclude that hepatic elimination and renal filtration can be assessed in rodents measuring plasma-disappearance rates of both dyes. Further, assessment of organ dysfunction by polymethine dyes correlates with, but outperforms conventional biomarkers regarding sensitivity and the option of spatial resolution if biophotonic strategies are applied. Polymethine-dye clearance thereby allows sensitive point-of-care assessment of both organ functions simultaneously.

In vivo assessment of endothelin-induced heterogeneity of hepatic tissue perfusion.

Specific vasoactive substances such as endothelin (ET) have been proposed to induce heterogeneity of tissue perfusion and thus the oxygen delivery at the sinusoidal level in the liver, but a direct method for testing this hypothesis has not been available. Our objective was to develop a method to test the hypothesis that functional heterogeneity of blood flow can be induced at the sinusoidal level by mediators such as endothelin-1, which act at the sinusoidal level. We constructed oxygen-sensitive membranes using tris (1,10-phenanthroline) ruthenium (II) chloral hydrate, a dye whose fluorescence is quenched by oxygen incorporated into a silicon rubber membrane. The membrane (less than 40 microm thick) was formed on a glass coverslip that served as the viewing window of the system for in vivo fluorescence microscopy and allowed determination of the PO2 distribution in rat liver acini during intraportal infusion of ET or phenylephrine (PE) in vivo. Heterogeneity was quantified by comparing the coefficient of variation (CV) of the fluorescence intensity within the zone 1 before, during, and after drug infusion. PE and ET doses were matched to produce a similar increase in portal pressure. PE caused a gradient of PO2 across zones, but within zone 1 no significant increase in CV was observed. In contrast, ET produced a patchy pattern of both an increase and decrease in PO2 resulting in doubling (P < 0.01) in CV of fluorescence intensities within zone 1. These results indicate that PE, which acts at presinusoidal sites, results in a homogeneous decrease in tissue PO2 within a zone, while ET, which additionally acts at sinusoidal sites, induces significant microheterogeneity of tissue PO2. The oxygen-sensitive membrane provides a useful tool for oxygen mapping in vivo.