Myocardial oxygenation and high-energy phosphate levels during graded coronary hypoperfusion

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Myocardial oxygenation and high-energy phosphate levels during graded coronary hypoperfusion

Jianyi Zhang, Kamil Ugurbil, Arthur H. L. From, and Robert J. Bache

Departments of Medicine and Radiology and Center for Magnetic Resonance Research, University of Minnesota Health Sciences Center and Minneapolis Veterans Affairs Medical Center, Minneapolis, Minnesota 55455

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

This study was performed to determine the myocyte PO₂ required to sustain normal high-energy phosphate (HEP) levels in thein vivo heart. In 10 normal dogs, myocyte PO₂ values were calculatedfrom the myocardial deoxymyoglobin resonance (Mb- $delta$ ) intensitydetermined with ¹H-NMR spectroscopy during sequential flow reductions producedby a hydraulic occluder that decreased coronary perfusion pressureto ~60, 50, and 40 mmHg and, finally, during total occlusion.Myocardial blood flow was measured with microspheres, and HEPlevels were determined with ³¹P magnetic resonance spectroscopy. During control conditions,Mb- $delta$ was undetectable. Myocardial blood flow was 1.11 ± 0.06 ml· min¹ · g¹ during basal conditions and decreased with sequential gradedocclusions to 0.78 ± 0.05, 0.58 ± 0.03, and 0.38 ± 0.04 ml · min¹ · g¹, respectively; blood flow during total occlusion was 0.07 ± 0.02ml · min¹ · g¹. Reductions of blood flow caused progressive increases of Mb- $delta$ ,which were associated with decreases of phosphocreatine (PCr),ATP, and the PCr-to-ATP ratio, as well as progressive increasesof the P_i-to-PCr ratio. There was a strong linear correlationbetween normalized blood flow and Mb- $delta$ (R² = 0.89, P < 0.01). Reductions of HEP and PO₂ were also highlycorrelated (although nonlinearly); with the assumption that myoglobinwas 90% saturated with O₂ during basal conditions and 5% saturatedduring total coronary occlusion, the intracellular PO₂ valuesfor 20% reductions of PCr and ATP were ~4.4 and ~0.9 mmHg, respectively.The data indicate that O₂ availability plays an increasing rolein regulation of oxidative phosphorylation when mean intracellularPO₂ values fall below 5 mmHg in the in vivoheart.

myocardium; blood flow; myoglobin oxygen saturation; ischemia

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

BOTH THERMODYNAMIC AND KINETIC models of oxidative phosphorylation regulation in the heart incorporate regulatory roles formyocardial ADP, P_i, NADH, and O₂ (3, 8). O₂ extraction bythe heart is greater than in most other organs, with resting coronaryvenous PO₂ commonly as low as 20-25 mmHg in the normal in vivoheart (32). Because the very high level of myocardial O₂ extractionduring basal conditions limits the ability to increase O₂ uptakeby augmenting extraction, increases of O₂ demands during exerciseor other stress must be met by parallel increases of coronaryblood flow (32). Furthermore, reductions of coronary blood flowby as little as 10-20% in the intact in vivo heart cause decreasesof contractile performance, suggesting that even modest reductionsof myocardial perfusion can result in O₂ insufficiency (31).Kreutzer and Jue (18) examined the critical O₂ level at whichO₂ availability failed to meet cellular energy demands in isolatedperfused rat hearts working at 25°C. Using ¹H-NMR spectroscopy to assess the degree of myocardial myoglobindesaturation and to calculate intracellular PO₂ during progressivedecreases of O₂ in Krebs-Henseleit perfusion buffer, they observedthat the phosphocreatine (PCr) level began to decrease at an intracellularPO₂ of ~2 mmHg and fell to 80% of the basal value at an intracellularPO₂ of 1.8 mmHg (18). Further reductions of perfusate oxygenationresulted in sharp further decreases of PCr. Since these data wereobtained in isolated hearts perfused with non-Hb-containing bufferat 25°C, it is unclear whether a similar relationship would existin the intact heart in vivo. Consequently, the present study wascarried out to examine the effect of decreasing myocyte oxygenationon myocardial high-energy phosphate (HEP) content in the intactheart in vivo. Graded reductions of coronary blood flow were producedto document the threshold level of myocyte oxygenation at whichperceptible reductions of the PCr-to-ATP ratio (PCr/ATP; correspondingto an increase of myocardial free ADP) occurred and to examinethe effect of progressive reductions of myocyte oxygenation onmyocardial HEPcontent.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Studies were performed in 10 adult mongrel dogs of either gender weighing 20-27 kg. All experimental procedures were approvedby the University of Minnesota Animal Resources Committee. Theinvestigation conformed to the Guide for the Care and Use of LaboratoryAnimals [DHHS Publ. No. (NIH) 85-23, revised 1985, Office of Scienceand Health Reports, Bethesda, MD 20892].

Experimental preparation. The dogs were anesthetized with pentobarbital sodium (30-35 mg/kg bolus followed by 4 mg · kg¹ · h¹ iv), intubated, and ventilated with a respirator with supplementalO₂ to maintain arterial blood gases within the physiological range.A heparin-filled 3.0-mm-OD polyvinyl chloride catheter was introducedinto the right femoral artery and advanced into the ascendingaorta. A left thoracotomy was performed through the fourth intercostalspace, and the heart was suspended in a pericardial cradle. Aheparin-filled 3.0-mm-OD catheter was introduced into the leftventricle (LV) through the apical dimple and secured with a purse-stringsuture. A similar catheter was inserted into the left atrium throughthe atrial appendage. A 1.5- to 2.0-cm segment of the proximalleft anterior descending (LAD) coronary artery was dissected free,and a hydraulic occluder constructed of 2.7-mm-OD polyvinyl chloridetubing was placed around the artery. A silicone-elastomer catheter(0.75 mm ID) was placed into the LAD distal to the occluder bythe method of Gwirtz (11). The region of the LV that becamecyanotic on inflation of the occluder was determined by visualinspection, and a 28-mm-diameter NMR surface coil was suturedonto the pericardium overlying the ischemic area. The pericardialcradle was then released, the heart was allowed to assume itsnormal position, and the surface coil leads were connected toa balanced tuned circuit. Animals were placed on a water-filledthermal jacket connected to a circulating water bath to maintainrectal temperature at 37-38°C and placed into themagnet.

NMR general methods. Measurements were performed in a 400-cm-bore 4.7-Tesla magnet interfaced with a SISCO (Spectroscopy Imaging Systems, Fremont,CA) console. The LV pressure signal was used to gate NMR dataacquisition to the cardiac cycle, while respiratory gating wasachieved by triggering the ventilator to the cardiac cycle betweendata acquisitions (22, 24). ³¹P- and ¹H-NMR frequencies were 81 and 200.1 MHz,respectively.

NMR deoxymyoglobin methods. The method for ¹H-NMR detection of the proximal histidyl N- $delta$ proton resonance of deoxymyoglobin (Mb- $delta$ ) has been described indetail (5). Briefly, a single-pulse collection sequence witha Gaussian pulse (1 ms) was used to selectively excite the N- $delta$ proton signal of the proximal histidyl of Mb- $delta$ . This frequency-selectivepulse provided sufficient water suppression because of the largechemical shift difference between the water resonance and Mb- $delta$ (>14 kHz). A short repetition time (TR = 35 ms) was used becauseof the short T1 value of Mb- $delta$ . Each spectrum is acquired within6 min (10,000 free induction decays). Although the short T1 ofMb- $delta$ and the fast acquisition prevent gating of data acquisitionto the cardiac cycle, signal loss as a result of heart motionwas negligible because of the inherently broad line width of theMb- $delta$ peak. The Mb- $delta$ resonance was detected at 71-72 ppm (relativeto water) and remained virtually constant during the study protocol.No other resonances were detected within a 10-ppm region. We previouslydemonstrated that because of the short T2 relaxation times ofthe $alpha$ - and $beta$ -subunits of deoxyhemoglobin, these resonances arenot NMR visible in canine myocardium in vivo at 4.7 Tesla whena 1-ms Gaussian excitation pulse is used (5). Thus Mb- $delta$ isdetected with no interference fromdeoxyhemoglobin.

Because of possible heterogeneity of myocardial perfusion and energy metabolism across the wall of the LV, the origin of thesignal detected with NMR is of importance. The relative contributionsfrom the different layers of the wall of the ventricle will dependon the radio-frequency (RF) power setting, so that only for relativelylow RF powers (i.e., powers that achieve much less than 90° rotationat the coil center) will the outer layer dominate the Mb- $delta$ signal.This condition was avoided by adjusting the RF pulse so that thewater signal detected was maximized. With such a power setting,signal contributions will tend to penetrate deeper into the LVwall. To examine the detection sensitivity profile for Mb- $delta$ alongthe $gamma$ -axis (perpendicular to the LV wall), the y-axis gradientecho was switched on using gradient-echo-image sequence to obtainthe one-dimensional profile of the water proton along the y-axisusing the identical RF pulse, pulse sequence and RF power thatwas used for the Mb- $delta$ measurements. Figure 1 illustrates a typicalsensitivity profile from a canine heart with an ~1-cm-thick LVwall; the arrow indicates the position of the surface coil. Thesedata demonstrate that the Mb- $delta$ signal originates from all layersacross the LV wall with a somewhat higher contribution from themid-to-inner layers of the LV.

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Fig. 1. Sensitivity profile for the ¹H-NMR signal across the left ventricular (LV) wall. Sensitivity for detection of ¹H nuclei is proportionate to the height of the curve. x-Axis, distance, with the epicenter of the magnet at 0.0 cm; arrow, location of the surface coil; dashed vertical lines, epicardial (Epi) and endocardial (Endo) boundaries of the LV wall. Data demonstrate that the deoxymyoglobin resonance (Mb- $delta$ ) signal originates from all layers of the LV wall, with somewhat higher contribution from the mid- to the inner myocardium.

Spatially localized ³¹P-NMR technique. ³¹P-NMR spectra were acquired in late diastole with a pulse repetition time of 6-7 s. This repetition time allowed full relaxationfor ATP and P_i resonances and ~90% relaxation for the PCr resonance.PCr resonance intensities were corrected for this minor saturation.RF transmission and signal detection were performed with a 28-mm-diametersurface coil. A capillary containing 15 µl of 3 M phosphonoaceticacid was placed at the coil center to serve as a reference. Theproton signal of the water resonance was used to homogenize themagnetic field and to adjust the position of the animal in themagnet so that the coil was at or near the magnet and gradientisocenter. This was accomplished using a spin-echo experimentwith a readout profile. The information gathered in this stepwas also utilized to determine the spatial coordinates for spectroscopiclocalization. Chemical shifts were measured relative to PCr, whichwas assigned a chemical shift of $-$ 2.55 ppm relative to 85% phosphoricacid at 0 ppm. Spatial localization across the LV wall was performedwith the RAPP-ISIS/FSW method. The technical details of this method,including voxel profiles, voxel volume, and the accuracy of spatiallocalization obtained in phantom studies and in vivo, have beenpublished elsewhere (12, 24, 26). Briefly, signal originwas restricted by using B₀ gradients and adiabatic inversion pulsesto an 18 mm × 18 mm column coaxial with the surface coil and perpendicularto the LV wall. Within this volume, the signal was further localizedby using the B₁ gradient to five voxels spanning the LV wall fromepicardium to endocardium. Each set of spatially localized transmuralspectra consisted of a total of 96 scans accumulated in a 10-minblock. Resonance intensities were quantified by using integrationroutines provided by SISCO software. The values for PCr and ATPin each voxel were normalized to those present in the basal state,and the PCr-to-ATP ratio (PCr/ATP) was determined for each voxel.P_i resonances were also measured, and the ratio of P_i to PCr (P_i/PCr)wascalculated.

The Mb- $delta$ resonance detected using the present methodology represents an unweighted average of the Mb- $delta$ content across theentire LV wall. A comparable whole wall measurement of HEP levelsdoes not exist, because the sensitivity for detection of the phosphorusresonance decreases as a function of distance from the surfacecoil. Therefore, average whole wall values of HEP were obtainedby averaging the HEP contents in the subepicardial, midwall, andsubendocardial voxels that were acquired with our spatially localizedspectroscopy technique (26). This technique corrects voxel HEPcontent measurements for the decreased sensitivity that occurswith increasing distance from the surface coil, thereby yieldingtrue average whole wall PCr and ATPcontents.

Myocardial blood flow measurements. Myocardial blood flow was measured using 15-µm-diameter microspheres labeled with ⁵¹Cr, ⁸⁵Sr, ⁹⁵Nb, and ⁴⁶Sc. Microsphere suspension containing 2 × 10⁶ microspheres was injected through the left atrial catheter, whilea reference sample of arterial blood was withdrawn from the aorticcatheter at a rate of 15 ml/min beginning 5 s before the microsphereinjection and continuing for 120 s. Radioactivity in the myocardialand blood reference specimens was determined using a gamma spectrometer(Packard Instruments, Downers Grove, IL) at window settings chosenfor the combination of radioisotopes used during the study. Activitycorrected for overlap between isotopes and for background wasused to compute blood flow as milliliters per gram of myocardiumperminute.

Myocyte oxygenation. Myocyte oxygenation was estimated from the myoglobin O₂ saturation-PO₂ relationship as follows

P<SC>o</SC><IT>2</IT><IT>=</IT>Mb-O<IT>2</IT>(P<SC>o</SC><IT>2</IT>)<IT>50</IT><IT>/</IT>Mb<IT>-&dgr;</IT> (1)

where Mb-O₂ and Mb- $delta$ are fractional contents of oxymyoglobin and deoxymyoglobin, respectively, PO₂ is the intramyocyte PO₂,and (PO₂)₅₀ is the PO₂ at which myoglobin is half-saturated withO₂ (2.38 mmHg at 37°C) (27). Therefore, if the integral of theMb- $delta$ resonance intensity measured during complete coronary occlusionrepresents total myoglobin content (in the Mb- $delta$ form), then theresonance integrals determined during other experimental conditionscan be normalized relative to this value to result in Mb- $delta$ expressedas a fractional value of total myoglobin content. The fractionalcontent of myoglobin O₂ during each experimental period can becalculated from the relationship Mb-O₂ = 1 $-$ Mb- $delta$ . The fractionalcontents of oxymyoglobin and Mb- $delta$ and the temperature-corrected(PO₂)₅₀ can then be employed to calculate intracellular PO₂ usingEq. 1. Because of continuing collateral blood flow, it is unlikelythat myoglobin would be completely deoxygenated during coronaryocclusion. Consequently, calculations were performed assumingthat the Mb- $delta$ resonance measured during coronary occlusion represented90 or 95% of the total myoglobin, and the Mb- $delta$ resonances obtainedduring the study were normalized in relation to that value. Similarly,the fractional myoglobin O₂ content in the basal state (i.e.,at a time when no Mb- $delta$ resonance was detected) could not be directlydetermined (5). On the basis of a recent report using reflectancespectroscopy in open-chest swine which demonstrated that myoglobinO₂ saturation is >92% under basal conditions, we calculated intramyocardialPO₂ values assuming that the fractional Mb- $delta$ content in the basalstate was 90 or 95%. We also carried out calculations assuminga basal Mb- $delta$ O₂ saturation of 80%, although a value this low isunlikely, since we have found that the present technique can detect~10% fractional content of Mb- $delta$ (unpublishedobservations).

Study protocol. Aortic and LV pressures were measured with fluid-filled pressure transducers positioned at midchest level and recorded onan eight-channel direct-writing recorder (Coulbourne Instrument,Lehigh Valley, PA). LV pressure was recorded at normal and highgain for measurement of end-diastolic pressure. Hemodynamic measurementsand ³¹P- and ¹H-NMR spectra were first obtained under basal conditions. Midwaythrough the 20-min data acquisition period, a microsphere injectionwas performed for determination of myocardial blood flow. Aftercompletion of baseline measurements, the hydraulic coronary occluderwas slowly inflated with a micrometer-driven syringe to reducedistal LAD pressure to ~60 mmHg (stenosis I). When a stable coronarypressure had been maintained for 5 min, ³¹P and ¹H spectra were obtained, and a microsphere injection was performed.The occluder was then further inflated to decrease distal coronarypressure to ~50 mmHg (stenosis II), and all measurements wererepeated. Measurements were then obtained at a coronary pressureof ~40 mmHg (stenosis III). Finally, the LAD was completely occluded(total occlusion), and all measurements were repeated. In threeanimals, hearts were stained with triphenyltetrazolium chlorideto ensure that the experimental protocol did not result in myocardialnecrosis. In these animals, coronary reperfusion was allowed for2 h after completion of the protocol before the hearts were harvested.The hearts were then sectioned into 1-cm-thick layers parallelto the mitral valve annulus and incubated for 15 min in 4 g oftriphenyltetrazolium chloride dissolved in 400 ml of Sörenson'sbuffer at 37°C. No evidence of infarct was observed in any ofthesehearts.

Data analysis. Hemodynamic data were measured from the chart recordings. ³¹P spectra were analyzed as described above. Transmural blood flowdistribution was determined from the microsphere measurements.Data were analyzed with one-way ANOVA for repeated measures. P< 0.05 was considered significant. When a significant result wasfound, individual comparisons were made using the method of Scheffé.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Hemodynamic and blood flow data. Hemodynamic and myocardial blood flow measurements during each experimental condition are shown in Table 1. Heart rate tendedto increase and mean aortic pressure tended to decrease with increasingstenosis severity, although these changes did not achieve statisticalsignificance. LV systolic pressure decreased significantly duringstenosis II and III, as well as during total occlusion (each P< 0.05). LV end-diastolic pressure increased significantly withapplication of stenosis I and underwent a further significantincrease during total occlusion (P < 0.05). Coronary perfusionpressure progressively decreased as the degree of stenosis wasincreased.

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Table 1. Hemodynamic measurements and myocardial blood flow

As shown in Table 1, myocardial blood flow decreased progressively in response to increasing stenosis severity, with thedecrease most severe in the subendocardial layer, as indicatedby a progressive decrease in the endocardial-to-epicardial bloodflow ratio. During complete LAD occlusion, the residual myocardialblood flow (representing collateral flow) accounted for an averageof 6% of the baseline blood flow and was directed preferentiallytoward the subepicardiallayers.

Myocyte oxygenation and HEP levels. Typical ¹H and ³¹P spectra are shown in Figs. 2 and 3. To take into account differences in absolute blood flow between animals(reflecting variations in the rate of basal state metabolism),blood flow for each individual animal was normalized to the basalstate value. As shown in Fig. 4, reductions of myocardial bloodflow produced by progressive increases in stenosis severity resultedin parallel stepwise decreases of myoglobin O₂ saturation. Therelationship between myoglobin saturation and blood flow was welldescribed by the linear regression equation shown in Fig. 4A (R² = 0.89, P < 0.01). When intracellular PO₂ was calculated fromthe Mb- $delta$ measurements, an exponential relationship was observedbetween myocardial blood flow and intracellular PO₂ (Fig. 4B).

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Fig. 2. Typical ³¹P-NMR spectra showing myocardial high-energy phosphate (HEP) and P_i resonances from 1 heart under baseline conditions (A), during coronary stenosis that reduced distal coronary pressure to 40 mmHg (B), and during total left descending coronary artery occlusion (C). 2,3-DPG, 2,3-diphosphoglycerate; PCr, phosphocreatine.

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Fig. 3. Interleaved ¹H-NMR spectra obtained from the same heart as in Fig. 1 showing myocardial Mb- $delta$ resonances under baseline conditions (A), during coronary stenosis that reduced distal coronary pressure to 40 mmHg (B), and during total left descending coronary artery occlusion (C).

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Fig. 4. Myoglobin percent saturation (A) and calculated myocyte PO₂ (B) plotted against myocardial blood flow (MBF) normalized to the prestenosis control value. It was assumed that the Mb- $delta$ resonance measuring total coronary occlusion represented 95% of the total myoglobin and that the fractional myoglobin O₂ content in the basal state was 90%.

Increasing stenosis severity resulted in progressive decreases of PCr and ATP (Fig. 2) with decreases of PCr/ATP and increasesof P_i/PCr (Table 2). The HEP abnormalities were most prominentin the subendocardium, reflecting the pattern of hypoperfusion,which was most severe in the deeper myocardial layers. Additionally,PCr/ATP decreased and P_i/PCr increased (Table 2) during ischemia,and the transmural gradient of blood flow was reversed (epicardial> endocardial; Table 1). Consistent with these findings, PCr/ATPreductions and P_i/ATP increments were greatest in the subendocardium(Table 2).

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Table 2. ³¹P-NMR measurements

The relationships of PCr and ATP with intracellular PO₂ are shown in Fig. 5. This plot was made assuming that the Mb- $delta$ resonancemeasuring total coronary occlusion represented 95% of the totalmyoglobin and that the fractional myoglobin O₂ content in thebasal state was 90%. Values for PCr decreased when intracellularPO₂ approached 5 mmHg. PO₂ values that are associated with significantreductions of HEP have been termed "critical," with the implicationthat they reflect the presence of O₂ limitation of oxidative phosphorylation(18). As shown in Table 3, the PO₂ values at which PCr wasreduced to 80% [(PO₂)₈₀] were 4.3-4.5 mmHg when myoglobin O₂ saturationwas assumed to be 90 or 95%; computed values were similar whethermyoglobin O₂ saturation during total coronary occlusion was assumedto be 5 or 10%. However, if myoglobin O₂ saturation during basalconditions was assumed to be 80%, a much lower (PO₂)₈₀ was obtainedat 2.0-2.2 mmHg. Values at which PCr was reduced to 50% [(PO₂)₅₀]of control were 1.0-1.2 when myoglobin was assumed to be 90 or95% saturated during basal conditions and 5 or 10% saturated duringtotal coronary occlusion. Substantially lower values for (PO₂)₅₀were calculated when myoglobin was assumed to be only 80% saturatedduring basal conditions (Table 3). The relationship between ATPand PO₂ is shown in Fig. 5; this plot was obtained assuming thatmyoglobin was 90% saturated during basal conditions and 5% saturatedduring total coronary occlusion. The (PO₂)₈₀ for ATP was 0.9-1.0mmHg when myoglobin was assumed to be 90 or 95% saturated duringbasal conditions but fell to 0.4-0.5 mmHg when myoglobin was assumedto be 80% saturated during basal conditions. A (PO₂)₅₀ value forATP could not be determined, because this degree of ATP reductionwas not achieved. The lower critical PO₂ for ATP than for PCris not surprising, because the fall of ATP during ischemia isbuffered by PCr through the creatine kinase reaction.

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Fig. 5. PCr (A) and ATP (B) normalized to the prestenosis control value plotted against myocyte PO₂. PCr decreased to 80% of the control value when intracellular PO₂ had decreased to 4.4 mmHg, while ATP was reduced to 80% of the control value at PO₂ of 1.1 mmHg. It was assumed that the Mb- $delta$ resonance measuring total coronary occlusion represented 95% of the total myoglobin and that the fractional myoglobin O₂ content in the basal state was 90%.

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Table 3. Critical PO₂ values for PCr and ATP

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

In a previous study using ¹H-NMR, we found that no Mb- $delta$ was visible in in vivo canine or swine myocardium operating at basalor elevated work states, despite the observation that HEP levelsfell during high work states (34). This suggested that, evenat high work states, O₂ availability was nonlimiting and indicatedthat HEP changes that occur at high workloads cannot be ascribedto O₂ limitation. The present study was carried out to definethe relationships between myocardial blood flow, myocyte PO₂,and HEP levels in in vivo myocardium under conditions where limitedO₂ availability does limit the rate of oxidativephosphorylation.

The effect of decreased O₂ availability on myocardial HEP has been reported previously in isolated working rat hearts perfusedwith Krebs-Henseleit buffer at 25°C. Using progressive reductionsof the perfusate flow rate while intracellular PO₂ was determinedfrom the degree of myoglobin oxygenation using ¹H-NMR spectroscopy, Kreutzer and Jue (19) observed that whenthe intracellular PO₂ fell to ~4 mmHg, contractile performancedecreased and myocardial lactate production occurred. At thistime, myocardial O₂ consumption and HEP remained normal. Not untilintracellular PO₂ had fallen to 2 mmHg was there a perceptibledecrease in myocardial PCr and O₂ consumption. The findings suggestedthat an increase in myocardial NADH was able to compensate forthe decreased PO₂ at PO₂ values between 4 and 2 mmHg, so thatthe PCr concentration and rate of O₂ consumption were maintained.When using ¹H-NMR measurements of the Mb- $delta$ resonance for calculation of intracellularPO₂, assumptions must be made concerning the degree of myocardialO₂ saturation during basal conditions as well as the fractionof myoglobin that is deoxygenated during total coronary occlusion.In the dog, a small amount of collateral inflow continues duringtotal arterial occlusion, so that complete myoglobin desaturationis unlikely. Within reasonable limits, the degree of myoglobinO₂ saturation assumed during total coronary occlusion had a verysmall effect on the calculated PO₂ values at which PCr fell to80 or 50% of the basal level. However, assumptions concerningthe degree of O₂ saturation during basal conditions did influencethe calculated critical PO₂ values for PCr and ATP. Thus, if myoglobinwas assumed to be 90 or 95% saturated during basal conditions,(PO₂)₈₀ values for PCr were 4.3-4.5 mmHg. However, if myoglobinwas assumed to be only 80% saturated during basal conditions,then calculated (PO₂)₈₀ values were decreased by one-half. Webelieve that the values obtained when myoglobin saturation duringbasal conditions is assumed to be 90-95% saturated are more likelyto be correct for three reasons. First, the ¹H-NMR technique utilized in this study is sufficiently sensitiveto detect a proton resonance when myoglobin is >10% desaturated.Second, using data obtained with in vivo reflectance spectroscopy,Arai et al. (1) determined that myoglobin O₂ saturation duringbasal conditions is on the order of 92%. Finally, Arai et al.observed that infusion of adenosine to increase coronary bloodflow and augment O₂ delivery resulted in no change in the myoglobinsignal, consistent with the interpretation that myoglobin O₂ saturationis >90% during basal conditions. Using the assumption that myoglobinis 90-95% saturated with O₂ during basal conditions yields valuesat which PCr was reduced to 80% [(PO₂)₈₀] and 50% [(PO₂)₅₀] of4.3-4.5 and 1.0-1.2 mmHg, respectively. These values are substantiallyhigher than in the isolated rat hearts, where a perceptible decreaseof PCr occurred only when coronary flow rates were decreased sufficientlyto reduce intracellular PO₂ below 1.5 mmHg, with (PO₂)₈₀ of 1.1mmHg and (PO₂)₅₀ of 0.5 mmHg (19). In a subsequent study fromthe same laboratory, the coronary flow rate was maintained constantwhile hypoxia was produced by reducing perfusate PO₂; in thissituation, the persistently high coronary flow rate would resultin washout of lactate and prevent acidosis (18). With this experimentalmodel, slightly higher critical PO₂ values were obtained; PCrbegan to decrease at an intracellular PO₂ of 2 mmHg, with a (PO₂)₈₀of 1.8 mmHg. Nevertheless, the intracellular PO₂ values calculatedto produce reductions of PCr were higher in the in vivo canineheart in the present study than in the isolated perfused rat hearts.It is possible that reduced metabolic rates of rat hearts perfusedat 25°C, compared with normothermic in vivo conditions, couldcontribute to a lower critical PO₂ for PCr in the perfusedhearts.

The response of myocardial HEP levels to decreased coronary perfusion could be altered by changes of myocardial O₂ demands;an active decrease of energy demands in response to O₂ limitationwould allow the heart to accommodate to the decreased O₂ availabilityand delay the development of HEP changes. Gregg (10) demonstratedthat myocardial O₂ consumption can be influenced by coronary flowand perfusion pressure. Pressure in the coronary arterial systemhas been proposed to act to distend the ventricle, thereby augmentingcontractility and O₂ consumption by increasing sarcomere length(2). In addition, Kitakaze and Marban (17) observed that,in perfused ferret hearts, changes of coronary pressure and flowresulted in parallel changes in the calcium transient, implyinga preload-independent mechanism for perfusion-related alterationsof contractile force and O₂ demands. Zündorf and colleagues (35),using isolated rat hearts in which graded hypoxia was producedby decreasing the PO₂ of the perfusate buffer, found that reducedcytochrome aa₃ was not detected until contractile performancehad fallen to 25% of control. These findings imply that decreasedO₂ availability (despite constant coronary flow) also caused adecrease of contractile performance that allowed the heart toaccommodate to the decreased O₂ availability and maintain myocardialenergybalance.

Differences in the rate and magnitude of downregulation of myocardial energy demands in response to reductions of coronaryperfusion might explain different critical PO₂ values for PCrbetween in vitro perfused hearts and in vivo hearts. There isevidence that such flow-mediated alterations of contractile performanceare more prominent in isolated perfused hearts. Thus, Marshall(20) observed that when coronary flow was decreased in isolatedrabbit hearts, tissue lactate did not increase until O₂ consumptionand developed pressure had decreased by nearly one-half, whilePCr and ATP did not decrease until O₂ consumption and systolicfunction had decreased to 20-30% of the control level. Similarly,Keller and Cannon (15), using ³¹P-NMR to measure myocardial HEP content in perfused rat hearts,found that modest reductions of coronary flow resulted in proportionatedecreases of O₂ consumption and contractile performance withoutsignificant reductions of PCr. Adaptations of energy demands inresponse to reduced coronary perfusion have also been observedin intact animals, but these appear to be of lesser magnitudeand to require a longer period of adjustment. Thus, in open-chestswine or dogs, 30-40% reductions of coronary blood flow initiallycaused a decrease of myocardial PCr, but this was followed byrecovery to near-control values within 60 min, despite persistenthypoperfusion (7, 22). This response has been termed theearly phase of myocardial hibernation. It is possible that a differencein response to decreased O₂ delivery could explain the differencein curves relating intramyocyte PO₂ to coronary perfusion betweenperfused rodent hearts and the in vivo hearts in the present study.This is supported by the finding of Kreutzer and Jue (19) inthe isolated rat heart that not until coronary flow was decreasedfrom 11 to <1 ml/min was there appearance of Mb- $delta$ or detectableloss of PCr. In contrast, in the present study a 30% reductionof coronary blood flow caused a perceptible loss of PCr. The rapidability of the isolated perfused rodent heart to decrease energydemands in response to reduced perfusion could explain a differencein critical PO₂ for PCr from the in vivo heart. An additionalconcern is whether deoxyhemoglobin present in the in vivo heartmight interfere with ¹H-NMR spectroscopic measurements of Mb- $delta$ . In a previous studyfrom this laboratory, we demonstrated that because of the shortT2 relaxation times of the $alpha$ - and $beta$ -subunits of deoxyhemoglobin,they are not NMR visible in canine myocardium with the 1-ms excitationpulse used in the present study (5).

An important question is why any O₂ limitation should occur at intramyocyte PO₂ values that far exceed the apparent Michaelis-Mentenconstant of cytochrome oxidase with respect to O₂. Chance (4)observed in isolated myocardial mitochondria that the criticalPO₂ at which oxidative phosphorylation began to decrease was ~0.01mmHg. The finding in the present study that PCr levels began todecrease when intramyocyte PO₂ fell below 5 mmHg indicates thatadditional factors must influence oxidative phosphorylation inthe intact heart. One possibility is that the high critical PO₂in the intact heart might result, in least in part, from inhomogeneitiesof O₂ availability; the observed NMR measurements could representan average of some areas of myocardium that are adequately perfusedwith some areas that are profoundly ischemic. Decreases of coronaryblood flow are known to result in increased spatial heterogeneityof perfusion (23). A flow-limiting arterial stenosis causesredistribution of perfusion away from the subendocardium so thatblood flow, HEP, and presumably myoglobin saturation are lowestin the subendocardium (25). This transmural redistribution occursduring hypoperfusion in in vivo hearts and isolated perfused rathearts (33), so that differences in perfusion pattern couldnot account for differences in the flow-PO₂ relationship betweenthe two experimental models. Furthermore, the sensitivity profilefor detection of Mb- $delta$ using the present ¹H-NMR spectroscopy system is essentially uniform across the LVwall, so that differences in the myocardial regions sampled between³¹P- and ¹H-NMR spectra could not account for differences in the criticalPO₂ values for PCr and ATP between the present in vivo and theperfused rathearts.

Inhomogeneities of O₂ availability can also occur at the cellular level. Large PO₂ gradients exist between the erythrocyteand cytosol as the result of diffusional resistance to O₂ transportin the extracellular carrier-free region (13). Furthermore,high-resolution spectrophotometric measurements performed on singlecardiac myocytes have demonstrated a steep spatial PO₂ gradientnear the sarcolemma, while PO₂ values toward the center of thecell are nearly flat (30). Takahashi et al. (29) observedthat as the extracellular PO₂ was decreased, NAD(P)H autofluorescenceand myoglobin desaturation became heterogeneous, with greatestfluorescence remote from the sarcolemma in a pattern that wasa mirror image to the local intracellular PO₂. A significant PO₂gradient between the cytosol and the inner mitochondrial membranecould explain the difference between the Michaelis-Menten constantof cytochrome oxidase for O₂ in isolated mitochondrial preparationsand the mean cytosolic PO₂ values that are associated with HEPalterations in the intact heart. However, taking into accountthe low O₂ flux density at the mitochondrial membrane, mathematicalmodels of O₂ diffusion suggest very low perimitochondrial O₂ gradients(6). This is difficult to reconcile with reports that gradedreductions of perfusate PO₂ in isolated rat cardiomyocytes resultedin parallel reductions of cytochrome aa₃ oxidation and myoglobinoxidation (coherence) (4, 14). Chance (4) and Ito et al.(14) postulated that since the mitochondrial membrane is impermeableto myoglobin, a significant PO₂ gradient can occur because O₂must diffuse passively through a myoglobin free volume beforeit can react with cytochrome oxidase. Using ³¹P-NMR measurements of HEPs, they found that the phosphorylationpotential began to decrease when myoglobin oxygenation fell to80% of control (14). These results are remarkably similar tothe present findings in the in vivo heart showing a linear relationshipbetween myocyte oxygenation andPCr.

Ischemia can cause several changes that have opposing effects on the degree of heterogeneity of PO₂. Although perfusion heterogeneityincreases when coronary flow is decreased (23), capillary recruitmentoccurs which can decrease the O₂ diffusion distance and reduceO₂ flux density (21). Since the red cell capillary transit timeis inversely proportional to the blood flow rate, it is likelythat the extracellular O₂ gradient would decrease as flow ratesare reduced by the coronary stenosis. Furthermore, simulated ischemiacaused a decrease in the magnitude of the intracellular PO₂ gradientin isolated cardiomyocytes, both as the result of a decrease inthe rate of O₂ flux into the cell and a reduction of the rateof O₂ consumption (28). Myoglobin is able to facilitate O₂ diffusionin the cytosol based on a gradient of oxymyoglobin from the sarcolemmato the core of the cell. In the present study and in the reportof Arai et al. (1), Mb- $delta$ was not detectable during controlconditions, indicating that myoglobin facilitation is not requiredto maintain O₂ availability for mitochondrial respiration. However,at the low PO₂ values that exist when flow is limited by an arterialstenosis, myoglobin-facilitated O₂ transport is likely to becomeincreasinglyimportant.

Summary. During graded reductions of coronary blood flow, perceptible loss of PCr first occurred at a mean intracellular PO₂ of ~5mmHg. Further reductions of coronary blood flow resulted in aprecipitous fall of PCr and PCr/ATP as well as progressive increasesof P_i. The data indicate that, in the normal in vivo heart, O₂availability plays an increasing role in regulation of oxidativephosphorylation when mean intracellular PO₂ values fall below5mmHg.

	ACKNOWLEDGEMENTS

This work was supported by National Heart, Lung, and Blood Institute Grants HL-33600, HL-58067, HL-50470, HL-61353, HL-57994,and HL-58840. J. Zhang is recipient of an Established InvestigatorAward from the American HeartAssociation.

	FOOTNOTES

Address for reprint requests and other correspondence: J. Zhang, University of Minnesota Health Science Center, Mayo MailCode 508, 420 Delaware St. SE, Minneapolis, MN 55455 (E-mail:zhang047{at}tc.umn.edu).

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

Received 22 March 2000; accepted in final form 4 August 2000.

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