High-resolution visualization of oxygen distribution in the liver in vivo

Markus Paxian,1 Steve A. Keller,2 Brian Cross,1 Toan T. Huynh,2 and Mark G. Clemens1

1Department of Biology, University of North Carolina, Charlotte 28223 and 2Department of Surgery, Carolinas Medical Center, Charlotte, North Carolina 28203

Submitted 24 January 2003 ; accepted in final form 20 March 2003


    ABSTRACT
 TOP
 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
Microcirculatory failure after stress events results in mismatch in oxygen supply and demand. Determination of tissue oxygen distribution in vivo may help elucidate mechanisms of injury, but present methods have limited resolution. Male Sprague-Dawley rats were anesthetized, prepared for intravital microscopy, and received intravenously the oxygen-sensitive fluorescent dye Tris(1,10-phenanthroline)ruthenium(II) chloride hydrate []. An impaired hepatic oxygen distribution was induced by either phenylephrine or hemorrhage. Intensity of fluorescence was compared with NADH autofluorescence indicating changes in the mitochondrial redox potential. Ethanol was injected to affect the NADH-to-NAD+ ratio without altering the PO2. Infusion of resulted in a heterogeneous fluorescence under baseline conditions reflecting the physiological acinar PO2 distribution. A decrease in oxygen supply due to phenylephrine or hemorrhage was paralleled by an increase in and NADH fluorescence reflecting an impaired mitochondrial redox state. Ethanol did not alter fluorescence but increased NADH fluorescence indicating independence of PO2 and redox state imaging. Intravenous administration of for intravital videomicroscopy represents a new method to visualize the hepatic tissue PO2. Combined with NADH autofluorescence, it provides additional information regarding the tissue redox state.

aminotransferase; fluorescence microscopy; in vivo imaging; hemorrage; ethanol


HEPATIC MICROCIRCULATORY FAILURE is a major determinant for the development of hepatocellular dysfunction in a number of conditions including trauma/hemorrhage, liver transplantation, endotoxemia, and sepsis. Our group has previously shown in a model of liver ischemia and reperfusion that the degree of microcirculatory failure determines the extent of lethal hepatocyte necrosis (6). Furthermore, microvascular perfusion failure in a model of hemorrhage/resuscitation affected the hepatic mitochondrial redox state (15) and was associated with an increase in hepatocellular enzyme release and hepatocyte necrosis (1, 18). Although the underlying mechanisms are not completely understood, accumulating evidence suggests a dysregulation of stress-inducible vasoactive mediators like endothelins, carbon monoxide synthase, or heme oxygenase (2, 3) as well as changes in the response of the effector cells to the mediators, which includes alteration in receptor expression or phenotypic transformation in cells (7).

Microcirculatory failure in the liver after different stress events is characterized by a perfusion heterogeneity resulting in a mismatch between oxygen supply and demand. The impaired nutritive blood flow accompanied by a reduced oxygen availability decreases cellular levels of high-energy phosphates and contributes to early and late hepatocellular injury and dysfunction after several stress events. We recently demonstrated (16) in a model of prolonged and severe hemorrhagic shock that an improved oxygen supply through the use of an artificial oxygen carrier was associated with an increased restoration of hepatocellular ATP content. Studies of tissue oxygenation focusing on the relationship between microcirculatory disturbances and oxygen transport dynamics may contribute to a better understanding of the underlying pathophysiological mechanisms.

A number of methods have been reported during the last decade measuring the oxygen distribution in tissues; however, their applicability to investigate spatiotemporal changes in tissues is restricted due to technical limitations. For instance, the frequently used microelectrodes only measure tissue PO2 at specific points and consume oxygen, and the measurement is invasive. Nuclear MRI approaches or electron paramagnetic resonance oximetry techniques are able to investigate spatiotemporal changes in tissue PO2 (19) but their resolution is too low for imaging PO2 changes within the liver microarchitecture e.g., on the level of individual hepatic sinusoids. Itoh and coworkers (11, 25) developed a fluorescent membrane on the basis of the oxygen-quenched fluorescent dye Tris(1,10-phenanthroline)ruthenium(II) chloride hydrate [], which allows in vivo visualization of the PO2 distribution around mesenteric microvasculature. These investigators showed that the fluorescence of the indicator is a direct indicator of oxygen tension. A similar oxygen-sensitive membrane was recently used by our group to determine changes in the tissue surface oxygen distribution in livers of LPS-primed rats in response to endothelin-1 (4). This system was also demonstrated to respond linearly to changes in PO2.

However, even if this technique allows a visualization of oxygen distribution with moderately high resolution on tissue surfaces, the method also possesses a number of technical shortcomings. For instance, the oxygen-sensitive membrane has to be under gastight and watertight conditions during microscopy to avoid interferences with environmental oxygen. Furthermore, after a short time of continuous photoactivation, the fluorescent membrane shows a photobleaching effect limiting a prolonged observation period. The method also does not allow visualization of changes in tissue PO2 directly, because the microscope has to be focused on the probe membrane. Subsequently, corresponding images of the tissue surface and the membrane have to be superimposed. Moreover, despite a higher resolution compared with other methods for oxygen mapping, the spatial resolution of oxygen-sensitive membranes is restricted by the diameter of the silica beads used to absorb the fluorescent dye and the thickness of the membrane. Quality of the obtained images is further restricted, because changes in fluorescence take place in the membrane and not on the tissue surface, thus requiring the membrane to be focused. Afterward, an editing of the membrane image and the corresponding tissue image is required. Therefore, we searched for a method that allows a direct visualization of the oxygen distribution in tissue combined with a high spatial resolution of the tissue being monitored.

Wilson et al. (24) used an intravenous phosphorescence oxygen probe to assess the effects of hyperventilation on oxygenation of the brain cortex of newborn piglets. A disadvantage of this method, which is based on measuring phosphorescence lifetimes, is that it requires highly specialized equipment. The use of fluorescence probes on the other hand needs only a standard fluorescence microscope.

The aim of the present study was to investigate 1) whether the intravenous infusion of the oxygen-quenching dye allows visualization of the oxygen distribution on the liver tissue surface with a high spatial resolution but without toxicity and 2) whether this method allows for detection of changes in tissue PO2 under pathophysiological conditions.


    MATERIALS AND METHODS
 TOP
 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
Materials. All reagents were purchased from Sigma-Aldrich (St. Louis, MO) if not specified otherwise.

Animals. Male Sprague-Dawley rats (220–320 g body wt) were obtained from Charles River Laboratories (Wilmington, MA). The animals were fasted overnight before preparative surgery but were allowed free access to water. The protocol was approved by the University of North Carolina at Charlotte Institutional Animal Care and Use Committee.

Animal preparation. Rats were anesthetized by intraperitoneal injection of pentobarbital sodium (50 mg/kg body wt). Anesthesia was maintained by intermittent intravenous pentobarbital application (1–3 mg/kg body wt). After rats were placed on a heating pad to maintain body temperature between 36 and 37°C, a tracheotomy was performed to facilitate spontaneous breathing of room air. The right jugular vein was cannulated for drug administration. The left carotid artery was cannulated for measurement of systemic arterial blood pressure with a standard pressure transducer (Digi-Med high-pressure analyzer; Micro-Med, Louisville, KY) and to allow withdrawal of blood samples. The transducer was connected to a Digi-Med blood pressure analyzer. A midline laparotomy was performed, and the gut was repositioned and covered with a saline-wetted cotton gauze to minimize evaporative loss during the procedure. The splenic arteries were ligated to prevent splenic congestion. The splenic vein was identified, and a PE-10 polyethelyne catheter was inserted up to the portal vein for further drug administration. For intravital microscopy, animals were turned on their left sides, and left liver lobes were gently exteriorized with the lower surface uppermost. The specimen was then positioned on a micro coverglass window on a specially constructed stage. The liver was covered with plastic wrap to prevent surface drying.

Experimental protocol. The oxygen-sensitive fluorescent dye, (Aldrich), was injected intravenously during intravital videomicroscopy for visualization of the hepatic tissue PO2. Little is known about possible side effects of after systemic administration, because the chemical, physical, and toxicological properties have not been thoroughly investigated in vivo. Therefore, several pilot experiments were performed to determine a suitable dose of that allows visualization of the tissue PO2 with a constant plasma concentration in the absence of any side effects or phototoxicity. Due to a high renal clearance rate, was continuously infused via a syringe pump (model PHD 2000; Harvard Apparatus, Holliston, MA). The following infusion regimen resulted in a constant plasma concentration and was chosen for all further experiments. The infusion started at a high flow rate of 400 nmol·kg body wt-1·min-1 for 5 min to rapidly achieve a steady-state plasma concentration. Subsequently, the infusion rate was reduced to 60 nmol·kg body wt-1·min-1 for a further 10 min, followed by 40 nmol·kg body wt-1·min-1 until the end of the experiment. While the infusion regimen was applied, blood samples were taken (0.2 ml) at different time points. After centrifugation, the plasma concentration was determined fluorometrically (excitation, 480 nm; emission, 580 nm) with a CytoFluor multiwell plate reader (PerSeptive Biosystems, Foster City, CA) using blank serum as a zero reference. The specific plasma concentration was read against a standard curve.

Furthermore, mean arterial blood pressure (MAP) and heart rate were recorded at several time points during infusion to investigate the effects of on central hemodynamics. Before and after infusion, additional blood samples (0.4 ml) were taken and serum enzyme levels of alanine aminotransferase (ALT) and lactate dehydrogenase (LDH) were determined to exclude early organ damage during infusion of . On illumination, complexes can generate oxygen free radicals as they dissipate absorbed energy by transferring an electron to oxygen. Thus in a further series of experiments, possible phototoxic effects of during intravital microscopy were investigated. Several liver areas were continuously exposed to epi-illumination at 460 nm for a period of 5 min per high-power field. Propidium iodide (50 µg/100 g body wt) was injected intravenously before and after light exposure to identify damaged cells. The number of propidium iodide-positive cells per high-power field (x40) were counted before and after epiillumination using offline video analysis.

In another series of experiments, the infusion was used for visualization of the tissue PO2 in the liver under conditions of altered oxygen supply or changes in cellular redox state resulting from metabolic response. In the same preparations, cellular redox potential was determined by using NADH autofluorescence.

In the first set of experiments, hepatic oxygen demand was increased and oxygen supply was decreased by administration of phenylephrine (PE), a short-acting selective {alpha}1-adrenoceptor agonist that augments the metabolic rate in the liver and simultaneously attenuates the hepatic blood flow. Twenty minutes after the start of infusion, PE was injected at a flow rate of 40 µmol·kg-1·min-1 via a splenic vein catheter for 10 min. Images were recorded at baseline and at several time points during and after the end of PE infusion. In a second set of experiments, tissue PO2 was decreased through reduction of the circulating blood volume. Hemorrhagic hypotension was induced by arterial blood withdrawal to a MAP of 35 ± 5 mmHg within 30 s and was maintained for 10 min. If necessary, additional blood drawings were taken to maintain low blood pressure. Shed blood was collected in syringes containing citrate-phosphate-dextrose solution (0.14/1.0 ml shed blood). After 10 min of hemorrhage, shed blood was reinjected. Intravital microscopy images were also recorded at baseline and at several time points during hemorrhage and after reinjection of the shed blood. Both treatments, PE infusion and acute hemorrhage, were expected to cause parallel changes in fluorescence as well as NADH autofluorescence due to an attenuation in tissue PO2. Therefore, we used ethanol to affect the mitochondrial redox potential without altering the hepatic PO2. After baseline microscopy images were taken, 500 mg/kg body wt ethanol was intravenously administered as a bolus injection and further images were recorded after 10 and 20 min.

Intravital videomicroscopy. The prepared rats were placed on the stage of an Olympus Ix70 inverted microscope (Olympus America, Melville, NY). The liver surface was epi-illuminated with a 100-W mercury lamp using 366 nm excitation and 450 nm emission bandpass filters for NADH autofluorescence and 480 nm excitation and 625 emission band-pass filters to visualize fluorescence. Images were viewed at either low power (x4 objective) or high power (x20 objective) recorded by a Dage-MTI charge-coupled device integrating camera (CCD 300 Camera Systems; IPS, North Reading, MA) connected to an S-VHS video recorder (JVC HR-S3911U; JVC-East Coast, Wayne, NJ) and were analyzed during video playback. These objectives produced fields on the monitor representing 1,050 x 1,270 and 220 x 250 µm, respectively. Gate time (number of frames integrated) was identical in all experiments [NADH, 8; , 64]. For real-time digital contrast enhancement, an Argus-20 image processor (Hamamatsu, Bridgewater, NJ) was used. Gain, black level, and the enhancement settings were also identical in all experiments. At each recorded time point, the liver was exposed to epi-illumination for 15 s at most. Between time points, the microscope shutter was closed to prevent photobleaching and photodamage. Fluorescence intensity was densitometrically assessed by using a commercially available software program (MetaMorph; Universal Imaging, Downingtown, PA) and was analyzed as average intensity per liver acinus.

Quantitative determination of serum enzyme levels. To assess whether intravenously injected leads to early organ damage resulting in serum enzyme release, blood samples were taken at baseline and after 1 h of infusion. Serum was prepared, and aliquots were stored at -80°C until analysis. ALT and LDH were photometrically analyzed with commercially available kits.

Statistical analysis. Data are presented as means ± SE. Differences were evaluated by ANOVA followed by post hoc multiple comparison according to the Student-Newman-Keuls method. According to the study design, either a one-way or repeated-measures ANOVA was performed by using the SigmaStat software package (Jandel Scientific, San Rafael, CA). When criteria for parametric testing were violated, the appropriate nonparametric test, i.e., Kruskal-Wallis ANOVA on ranks and Friedman test, were used. P < 0.05 was considered significant.


    RESULTS
 TOP
 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
Plasma concentration and hemodynamic response during infusion. Preliminary experiments showed that was rapidly excreted in the urine (data not shown). Therefore, a continuous infusion using a syringe pump was necessary. First, several pilot experiments were performed to determine an infusion regimen resulting in a steady state of plasma concentration within an acceptable time period. An infusion regimen started at a flow rate of 400 nmol·kg body wt-1·min-1 within the first 5 min, then 60 nmol·kg body wt-1·min-1 during the next 10 min, followed by 40 nmol·kg body wt-1·min-1 for a further 45 min, resulted in a peak in plasma concentration of 6.6 ± 0.5 µmol/l after 5 min. Ten minutes after start of the infusion, plasma concentration declined to 2.1 ± 0.1 µmol/l and reached nearly constant values between 15 and 60 min varying between 1.5 ± 0.2 and 1.7 ± 0.2 µmol/l (Fig. 1). During infusion, MAP and heart rate were continuously monitored and recorded every 5 min. Infusion at the highest flow rate (400 nmol·kg body wt-1·min-1) at the beginning resulted in a slight decrease in MAP (Fig. 2A) and heart rate (Fig. 2B) without statistical significance and full recovery after 5 min. MAP and heart rate showed almost constant levels during the whole infusion period and were not affected by .



View larger version (13K):
[in this window]
[in a new window]
 
Fig. 1. Plasma concentration (conc) of Tris(1,10-phenanthroline)ruthenium(II) chloride hydrate [] during continuous infusion. was administered according to the infusion regimen of 400 nmol·kg-1·min-1 during the first 5 min, then 60 nmol·kg-1·min-1 for a further 10 min, followed by 40 nmol·kg-1·min-1 until 60 min. During infusion, blood samples were taken at several time points and plasma was prepared. The concentration in the plasma was determined fluorometrically by measuring against a standard curve. Data represent means ± SE of 8 individual experiments.

 


View larger version (16K):
[in this window]
[in a new window]
 
Fig. 2. Effects of intravenous administration on hemodynamics. Intravenous infusion of resulted in a negligible decrease in mean arterial blood pressure (MAP) (Fig. 2A) and heart rate during the highest dose of 400 nmol·kg-1·min-1 compared with baseline values. Both parameters returned to baseline levels after lowering the dose to 60 nmol·kg-1·min-1. Blood pressure and heart rate varied in the physiological range without any statistically significant differences and was not affected by intravenously administered .

 

Intravital microscopy during infusion. Approximately 3–4 min after starting the infusion regimen, fluorescence became visible within liver tissue by intravital microscopy (Fig. 3A) and allowed visualization of differences in tissue PO2 at both low and high magnification (Fig. 3B). The intensity of fluorescence was most pronounced in pericentral areas of the liver acinus, reflecting the low PO2 of this region, and showed a gradual decrease toward periportal regions, reflecting the physiological distribution of oxygen tension in the liver acini with a decrease in PO2 from periportal to pericentral areas. The dye presented a homogenous distribution within the extracellular fluid compartment and was not restricted to the intravascular space. In contrast, fluorescence was attenuated in hepatic sinusoids or venules due to the light-absorbing effect of hemoglobin.



View larger version (106K):
[in this window]
[in a new window]
 
Fig. 3. Visualization of tissue PO2 by intravenous administration. Intravenous infusion of resulted in a marked fluorescence within the liver tissue. The heterogeneous fluorescence intensity reflects the physiological distribution of oxygen tension in the liver acinus characterized by a higher PO2 in periportal regions with a continuous decrease toward pericentral areas (A). These differences in fluorescence intensity were also evident by using a high resolution (B). Dark areas represent liver regions with a high PO2 due to an inhibition of fluorescence by molecular oxygen. Magnification, x40 (A) and x100 (B).

 

Organ damage and phototoxicity due to administration. Before starting the administration and 1 h after continuous infusion, blood samples were taken; serum enzyme release of LDH as a parameter of nonspecific organ damage and ALT as a specific parameter for hepatocellular injury were determined. Serum activity of both enzymes showed no significant differences compared with baseline levels (LDH: baseline 270.1 ± 36.3 U/l, 60 min 265 ± 37 U/l; ALT: baseline 15.2 ± 0.8 U/l, 60 min 15.3 ± 1.3 U/l). complexes have been shown to generate oxygen free radicals on illumination, causing cell damage during illumination in vitro. We then tested whether the lower concentration of used in our experiments caused photodamage during intravital microscopy. Randomly selected liver areas continuously exposed to epi-illumination for 5 min during infusion showed no increase in the number of damaged liver cells as assessed by propidium iodide injection before and after epi-illumination (propidium iodide-positive cells/high power field: baseline 1.3 ± 0.9; after 5 min epi-illumination 1.3 ± 0.9; data are means ± SE of 4 high-power fields in 6 individual experiments).

Changes in tissue PO2, redox state, and hemodynamics during PE infusion. The reduction in oxygen supply and elevation in oxygen demand by continuous infusion of 40 µmol·kg-1·min-1 PE via a splenic vein catheter for 10 min resulted in a significant increase in intensity in both fluorescence (Fig. 4, C and G) and NADH autofluorescence (Fig. 4, D and H) compared with baseline intensity (Fig. 4, A and B). An increase in brightness in either method can result from a decrease in tissue PO2. After the PE infusion had stopped, fluorescence intensity continuously decreased within the observation period (Fig. 4G). After 20 min of recovery, fluorescence in the liver tissue was slightly brighter compared with baseline images but without statistical significance. In contrast, NADH autofluorescence presented a faster decline in fluorescence intensity after the end of the short-acting PE infusion and returned to baseline intensity at the end of the observation period (Fig. 4, F and H). The administration of PE led to a significant increase in systemic MAP compared with baseline values (Fig. 5) accompanied by a slight decrease in heart rate without statistical significance (data not shown). Blood pressure and heart rate immediately returned to baseline values at the end of PE infusion and showed constant levels until the end of the experiment.



View larger version (98K):
[in this window]
[in a new window]
 
Fig. 4. Effect of phenylephrine on hepatic tissue PO2 and NADH autofluorescence. Fifteen minutes after the initial infusion, the short-acting {alpha}1-adrenoceptor agonist phenylephrine was administered for 10 min at a dose of 40 µmol·kg-1·min-1. A, C, and E: fluorescence. B, D, and F: NADH autofluorescence. A and B: baseline fluorescence. The outlined area corresponds to the approximate extent of zone 3 around one terminal hepatic venule for sake of reference. The decrease in tissue PO2 due to phenylephrine resulted in a significant increase in fluorescence intensity (C) and NADH autofluorescence (D) compared with respective baseline values [ (A), NADH (B)]. After phenylephrine infusion, fluorescence intensity continuously returned toward baseline levels (E and F), consistent with an increase in tissue PO2. G: average brightness in fluorescence in 3–5 liver acini of 8 individual experiments. H: corresponding intensity in NADH autofluorescence of the identical liver areas. Data are means ± SE. *P < 0.05 vs. baseline levels; $P < 0.05 vs. 5 min phenylephrine infusion; #P < 0.05 vs. 10 min phenylephrine infusion.

 


View larger version (12K):
[in this window]
[in a new window]
 
Fig. 5. Changes in MAP in response to phenylephrine infusion. The {alpha}1-selective adrenoceptor agonist phenylephrine was continuously infused at a rate of 40 µmol·kg-1·min-1 via a splenic vein catheter for 10 min. Phenylephrine infusion resulted in a significant increase in MAP, which returned to baseline values immediately after infusion. Data represent means ± SE for n = 8 individual experiments; *P < 0.05 vs. baseline.

 

Impact of acute hemorrhage on fluorescence and NADH autofluorescence. A decrease in hepatic oxygen supply was induced by blood withdrawal to a MAP of 35 ± 5 mmHg for 10 min, resulting in a profound increase in fluorescence (Fig. 6C) and NADH autofluorescence intensity (Fig. 6D) with a maximum at 10 min compared with respective baseline value (Fig. 6, A and B). Retransfusion of the anticoagulated shed blood led to a continuous decrease in fluorescence (Fig. 6G). Twenty minutes after retransfusion, the intensity of fluorescence was slightly increased compared with baseline levels but without statistical significance (Fig. 6E). At all time points, the intensity of fluorescence showed a heterogeneous distribution within the liver acinus with brighter pericentral areas and a gradual attenuation in brightness toward periportal liver regions. However, the intensity of NADH autofluorescence demonstrated a faster decrease after reinjection of the shed blood and reached baseline levels 5 min after the end of hemorrhage (Fig. 6, F and H).



View larger version (74K):
[in this window]
[in a new window]
 
Fig. 6. Changes in fluorescence and NADH autofluorescence during hemorrhage. MAP was reduced to 35 ± 5 mmHg by acute blood withdrawal within 30 s and was maintained for 10 min. The decrease in oxygen supply due to hemorrhage was accompanied by an increased intensity of fluorescence (C) and NADH autofluorescence (D) compared with baseline images [ (A); NADH (B)]. This effect was reversible in both fluorescence (E) and NADH autofluorescence (F) by reinjection of the anticoagulated shed blood. G: average fluorescence intensity of in 3–5 liver acini of 8 individual experiments. H: demonstrates the intensity in NADH autofluorescence of the identical liver areas. Data are means ± SE. *P < 0.05 vs. baseline levels; $P < 0.05 vs. 5 min hemorrhage; #P < 0.05 vs. 10 min hemorrhage.

 

Effect of ethanol injection on fluorescence and NADH autofluorescence. Because hemorrhage and PE administration led to an increase in both fluorescence and NADH autofluorescence, ethanol (500 mg/kg body wt) was intravenously injected to change the mitochondrial redox potential by increasing the NADH-to-NAD+ ratio without altering the hepatic tissue PO2. fluorescence showed almost no detectable changes in intensity 10 min (Fig. 7C) or 20 min (Fig. 7E) after ethanol administration compared with baseline (Fig. 7A; densitometric units: baseline 5.8 ± 1.8; 10 min 6.1 ± 1.9; 20 min 10.2 ± 3.2). In contrast, acute ethanol metabolism resulted in a profound increase in NADH autofluorescence 10 min (Fig. 7D) and 20 min (Fig. 7F) after ethanol injection compared with baseline (Fig. 7B) [densitometric units: baseline 6.6 ± 2.1; 10 min 50.1 ± 18.5 (P < 0.05 vs. baseline); 20 min 55 ± 17.6 (P < 0.05 vs. baseline); data represent means ± SE of 3–5 liver acini of 4 individual experiments].



View larger version (122K):
[in this window]
[in a new window]
 
Fig. 7. Ethanol affects NADH autofluorescence without changing the tissue PO2. Intravenous bolus injection of 500 mg ethanol/kg body wt was administered to affect the mitochondrial redox potential without altering the tissue PO2. A, C, and E: intensity in fluorescence before and after ethanol injection. B, D, and F: NADH autofluorescence. Images were taken at baseline (A and B), 10 min (C and D), and 20 min (E and F) after ethanol injection. Whereas acute ethanol metabolism had almost no effect on fluorescence intensity, reflecting an unchanged hepatic tissue PO2, NADH autofluorescence was significantly increased 10 and 20 min after bolus injection, indicating an increase in the NADH-to-NAD+ ratio.

 


    DISCUSSION
 TOP
 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
In the present study, we demonstrate a new method for visualizing the tissue oxygen distribution on the liver surface under several pathophysiological conditions in vivo. Oxygen is the essential final electron acceptor for aerobic energy metabolism. Especially in the liver, oxygen regulates metabolic zonation under normal conditions and it can be a modulator of liver disease under pathophysiological conditions (13). Perivenous hypoxia is considered a major cause for several secondary liver diseases. The microcirculatory failure in the liver after different stress events may lead to a perfusion heterogeneity resulting in an impaired nutritive blood flow and a mismatch between oxygen supply and demand (3, 7, 20). Understanding the role of oxygen in physiology and pathophysiology may be helpful in evaluating the underlying mechanisms leading to cell death and organ dysfunction after ischemia-reperfusion or in septic conditions.

A recently published study (8) investigated the interaction of the oxygen-sensitive fluorescent probe with animal cells. This report demonstrated that ruthenium(II) complexes cannot freely penetrate intact biological membranes and do not cause measurable photodamage to plasma membranes at a concentration of <=0.2 mM. Apart from this study in cultured cells, little is known about chemical, physical, and toxicological properties of and potential side effects after systemic administration in living organisms. In pilot experiments, bolus injections between 4 and 16 mM/kg body wt resulting in a theoretical plasma concentration of 0.025–0.1 mM frequently led to a drop in heart rate and respiratory arrest and was accompanied by a rapid decrease in fluorescence due to a high renal clearance rate (unpublished results). These observations led to the described infusion regimen that resulted in a constant plasma concentration in the absence of any significant hemodynamic or respiratory side effects. Phototoxicity studies of Ru(II) complexes in cultured macrophages have shown photodamage to plasma membranes in a dose-dependent manner. Whereas concentrations of 1 or 2 mM in the culture medium were accompanied by a profound increase in photodamage with extended illumination, a concentration of 0.2 mM caused no measurable photodamage (8). This is in line with our observations demonstrating no detectable photodamage during continuous epi-illumination for 5 min. In addition, the risk of -induced photodamage in our method is unlikely due to the fact that the continuous infusion resulted in a plasma concentration of ~2.0 µM.

In the present study, the fluorescence was not restricted to the vascular space, indicating a sinusoid permeability of the dye that allows an assessment of the PO2 gradient outside the microvessels in the interstitial space. In contrast, due to the light-absorbing effect of hemoglobin, the vascular space showed a negative contrast compared with the surrounding tissue. The unidirectional blood flow in the liver acinus is characterized by a continuous decrease in PO2 that is ~60–65 mmHg in the periportal blood and attenuates to ~30–35 mmHg in the perivenous blood (12). In the present study, the fluorescence images obtained under baseline conditions, demonstrating a continuous increase in fluorescence intensity from periportal to pericentral regions, indicate that the described method is sensitive enough to detect even small differences in tissue PO2.

NADH, a naturally occurring fluorophore, transfers electrons to oxygen by means of an electron transport chain located in the inner membrane of mitochondria (5). Under hypoxic conditions, with no oxygen available to accept electrons from cytochrome a, intracellular NADH accumulates. Unlike the oxidized form NAD+, NADH is highly fluorescent (10). Therefore, we compared the changes in NADH fluorescence, which reflect the extent of tissue hypoxia, with the results obtained by the approach under pathophysiological conditions. Both methods showed a profound increase in fluorescence intensity in response to decreased tissue oxygen supply either by the administration of PE or due to acute hemorrhage. After restoration of baseline conditions, intensity of fluorescence and NADH autofluorescence diminished. The decrease in NADH fluorescence intensity was quicker compared with fluorescence and reached baseline levels 20 min after the intervention had finished. In contrast, the fluorescence presented a slower decrease in intensity, and the densitometric analysis demonstrated a higher intensity compared with the baseline levels, albeit without statistical significance. Several factors may contribute to these results. The tissue PO2 in the liver could be lower compared with baseline conditions due to microcirculatory disturbances without affecting the mitochondrial redox state even after restoration of normal conditions after finishing the PE infusion or retransfusion of the shed blood. In contrast, NADH autofluorescence is subjected to a photobleaching effect on illumination. Even if the specific liver region was subjected to illumination for only 15 s at each time point, this may contribute to the quick attenuation in NADH fluorescence and the lower intensity at the end of the experiment compared with fluorescence. Although shows a photobleaching effect during illumination, it is negligible under continuous intravenous infusion, because the illuminated is constantly replaced. Despite the constant plasma concentration during infusion of as determined by plasma fluorescence activity, it has been shown that after illumination, complexes can accumulate in the regions of plasma membranes, although ruthenium(II) complexes themselves have no affinity to plasma membranes (8). Moreover, the preparation of the liver for intravital microscopy can damage capsular cells. Furthermore, during microscopy, the liver surface is in contact with the micro coverglass and may cause additional damage to the liver capsule, thus allowing to enter damaged cells and stain nucleic acids. On binding to DNA, the fluorescence of increases ~50% compared with unbound (9).

Both fluorescence and NADH autofluorescence provide information on the metabolic state in the liver tissue. Whereas the NADH fluorescence reflects the mitochondrial redox state and the activity of the mitochondrial electron transport chain, the fluorescence is directly dependent on the tissue PO2. To demonstrate the independence of these measurements, a high dose of ethanol was injected to increase the NADH-to-NAD+ ratio without affecting the tissue PO2. Oxidation of ethanol to acetaldehyde is NAD+ dependent and is catalyzed by alcohol dehydrogenase resulting in an increase in the NADH/NAD+ redox potential within the cytosol and mitochondria, with subsequent alteration in several tissue metabolites (17). Although hypoxia seems to be involved in alcohol-induced liver injury (22), the present study merely shows that the NADH-to-NAD+ ratio was affected during the first 10 min after ethanol administration without any significant changes in tissue PO2. This confirms our conclusion that the simultaneous use of both fluorometric techniques in studies of tissue oxygenation/microcirculatory failure provide additional information regarding underlying pathophysiological mechanisms. It allows a differentiation between disturbances in oxygen supply and oxygen utilization. For instance, a normal tissue oxygen supply assessed by fluorescence accompanied by an increased NADH fluorescence suggests a rate of NAD+ reduction that exceeds energy demand.

In conclusion, the intravenous administration of for intravital videomicroscopy represents a new and simple method for visualizing the hepatic tissue PO2 with a high resolution in vivo. In combination with NADH autofluorescence, the developed method provides information on the oxygen distribution, the metabolic state, and the mitochondrial redox potential within tissue.


    ACKNOWLEDGMENTS
 
GRANTS

This study was supported by National Institute of Diabetes and Digestive and Kidney Diseases Grant DK-38201 and Deutsche Forschungsgemeinschaft Grant PA-864 1-1.


    FOOTNOTES
 

Address for reprint requests and other correspondence: M. G. Clemens, Professor and Chair, Dept. of Biology, Univ. of North Carolina, 9201 Univ. City Blvd. Charlotte, NC 28223 (E-mail: mgclemen{at}email.uncc.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.


    REFERENCES
 TOP
 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 

  1. Bauer I, Bauer M, Pannen BH, Leinwand MJ, Zhang JX, and Clemens MG. Chronic ethanol consumption exacerbates liver injury following hemorrhagic shock: role of sinusoidal perfusion failure. Shock 4: 324-331, 1995.[ISI][Medline]
  2. Bauer M, Bauer I, Sonin NV, Kresge N, Baveja R, Yokoyama Y, Harding D, Zhang JX, and Clemens MG. Functional significance of endothelin B receptors in mediating sinusoidal and extrasinusoidal effects of endothelins in the intact rat liver. Hepatology 31: 937-947, 2000.[ISI][Medline]
  3. Bauer M, Pannen BH, Bauer I, Herzog C, Wanner GA, Hanselmann R, Zhang JX, Clemens MG, and Larsen R. Evidence for a functional link between stress response and vascular control in hepatic portal circulation. Am J Physiol Gastrointest Liver Physiol 271: G929-G935, 1996.[Abstract/Free Full Text]
  4. Baveja R, Zhang JX, and Clemens MG. In vivo assessment of endothelin-induced heterogeneity of hepatic tissue perfusion. Shock 15: 186-192, 2001.[ISI][Medline]
  5. Chance B. The identification and control of metabolic states. Behav Sci 15: 1-23, 1970.[ISI][Medline]
  6. Chun K, Zhang J, Biewer J, Ferguson D, and Clemens MG. Microcirculatory failure determines lethal hepatocyte injury in ischemic/reperfused rat livers. Shock 1: 3-9, 1994.[ISI][Medline]
  7. Clemens MG, Bauer M, Pannen BH, Bauer I, and Zhang JX. Remodeling of hepatic microvascular responsiveness after ischemia/reperfusion. Shock 8: 80-85, 1997.[ISI][Medline]
  8. Dobrucki JW. Interaction of oxygen-sensitive luminescent probes and with animal and plant cells in vitro. Mechanism of phototoxicity and conditions for non-invasive oxygen measurements. J Photochem Photobiol B 65: 126-144, 2001.[CrossRef]
  9. Friedman AE, Kumar CV, Turro NJ, and Barton JK. Luminescence of ruthenium(II) polypyridyls: evidence for intercalative binding to Z-DNA. Nucleic Acids Res 19: 2595-2602, 1991.[Abstract]
  10. Gosalvez M, Thurman RG, Chance B, and Reinhold HS. Indication of hypoxic areas in tumours from in vivo NADH fluorescence. Eur J Cancer 8: 267-269, 1972.[ISI][Medline]
  11. Itoh T, Yaegashi K, Kosaka T, Kinoshita T, and Morimoto T. In vivo visualization of oxygen transport in microvascular network. Am J Physiol Heart Circ Physiol 267: H2068-H2078, 1994.[Abstract/Free Full Text]
  12. Jungermann K and Kietzmann T. Zonation of parenchymal and nonparenchymal metabolism in liver. Annu Rev Nutr 16: 179-203, 1996.[CrossRef][ISI][Medline]
  13. Jungermann K and Kietzmann T. Oxygen: modulator of metabolic zonation and disease of the liver. Hepatology 31: 255-260, 2000.[ISI][Medline]
  14. Lubbers DW. Oxygen electrodes and optodes and their application in vivo. Adv Exp Med Biol 388: 13-34, 1996.[Medline]
  15. Pannen BH, Kohler N, Hole B, Bauer M, Clemens MG, and Geiger KK. Protective role of endogenous carbon monoxide in hepatic microcirculatory dysfunction after hemorrhagic shock in rats. J Clin Invest 102: 1220-1228, 1998.[Abstract/Free Full Text]
  16. Paxian M, Rensing H, Geckeis K, Bauer I, Kubulus D, Spahn DR, and Bauer M. Perflubron emulsion in prolonged hemorrhagic shock: influence on hepatocellular energy metabolism and oxygen-dependent gene expression. Anesthesiology. 98: 1391-1399, 2003.[ISI][Medline]
  17. Peters TJ and Preedy VR. Metabolic consequences of alcohol ingestion. Novartis Found Symp 216: 19-34, 1998.[Medline]
  18. Rensing H, Bauer I, Datene V, Patau C, Pannen BH, and Bauer M. Differential expression pattern of heme oxygenase-1/heat shock protein 32 and nitric oxide synthase-II and their impact on liver injury in a rat model of hemorrhage and resuscitation. Crit Care Med 27: 2766-2775, 1999.[CrossRef][ISI][Medline]
  19. Robertson PW and Hart BB. Assessment of tissue oxygenation. Respir Care Clin N Am 5: 221-263, 1999.[Medline]
  20. Sair M, Etherington PJ, Curzen NP, Winlove CP, and Evans TW. Tissue oxygenation and perfusion in endotoxemia. Am J Physiol Heart Circ Physiol 271: H1620-H1625, 1996.[Abstract/Free Full Text]
  21. Schneider BH, Hill MR, and Prohaska OJ. Microelectrode probes for biomedical applications. Am Biotechnol Lab 8: 17-23, 1990.[ISI][Medline]
  22. Thurman RG, Ji S, and Lemasters JJ. Alcohol-induced liver injury. The role of oxygen. Recent Dev Alcohol 2: 103-117, 1984.[Medline]
  23. Towner RA, Sturgeon SA, Khan N, Hou H, and Swartz HM. In vivo assessment of nodularin-induced hepatotoxicity in the rat using magnetic resonance techniques (MRI, MRS and EPR oximetry). Chem Biol Interact 139: 231-250, 2002.[CrossRef][ISI][Medline]
  24. Wilson DF, Pastuszko A, DiGiacomo JE, Pawlowski M, Schneiderman R, and Delivoria-Papadopoulos M. Effect of hyperventilation on oxygenation of the brain cortex of newborn piglets. J Appl Physiol 70: 2691-2696, 1991.[Abstract/Free Full Text]
  25. Yaegashi K, Itoh T, Kosaka T, Fukushima H, and Morimoto T. Diffusivity of oxygen in microvascular beds as determined from PO2 distribution maps. Am J Physiol Heart Circ Physiol 270: H1390-H1397, 1996.[Abstract/Free Full Text]




This Article
Abstract
Full Text (PDF)
All Versions of this Article:
286/1/G37    most recent
00041.2003v1
Alert me when this article is cited
Alert me if a correction is posted
Citation Map
Services
Email this article to a friend
Similar articles in this journal
Similar articles in ISI Web of Science
Similar articles in PubMed
Alert me to new issues of the journal
Download to citation manager
Search for citing articles in:
ISI Web of Science (1)
Google Scholar
Articles by Paxian, M.
Articles by Clemens, M. G.
Articles citing this Article
PubMed
PubMed Citation
Articles by Paxian, M.
Articles by Clemens, M. G.


HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS
Visit Other APS Journals Online
Copyright © 2004 by the American Physiological Society.