Optical measurements of intracellular oxygen concentration of rat heart in vitro

The optical characteristics of hemoglobin-free perfused rat heart have been examined in detail. Ethyl hydrogen peroxide is found to convert myoglobin into “ferryl compound” in the perfused heart, as is also seen in vitro. After pretreatment with ethyl hydrogen peroxide, a typical mitochondrial absorption spectrum, similar to that of isolated rat heart mitochondria, is obtained in perfused heart. The overall absorption spectrum of the heart obtained by the aerobic to anaerobic transition is a superposition of the mitochondrial spectrum on that of myoglobin. By comparing these spectra, it is found that measurement of cytochrome a + a₃ at 605–620 nm is possible in spite of the absorbance change due to the oxygenation-deoxygenation of myoglobin, whereas the wavelength pairs for cytochrome c at 550-540 nm, cytochrome b at 562–575 nm and cytochrome a + a₃ at 445–450 nm can not be used in the heart because of interference from the absorption change of myoglobin. The partial pressure of O₂ (P₅₀) which is required for half maximal deoxygenation (or oxygenation) of myoglobin in perfused heart is found to be 2.4 mm Hg at room temperature and the Hill constant, n, is 1.1; these values are similar to those of myoglobin purified from rat heart. The steady-state O₂ titration has been performed by using absorbancy changes of myoglobin and cytochrome a + a₃ as intracellular O₂ indicators. In the perfused heart, the percentage change of oxygenation-deoxygenation of myoglobin parallels the oxidation-reduction of cytochrome a + a₃, while the mixture of purified myoglobin and isolated mitochondria shows a deviation, reflecting the difference of O₂ affinities between myoglobin and cytochrome a + a₃. The results indicate that there may be an O₂ gradient between cytosolic and mitochondrial compartments in the hemoglobin-free perfused heart. The absorption changes of myoglobin and of cytochrome a + a₃ can be measured in a single contraction-relaxation cycle. A triple beam method was introduced to eliminate the effect of light scattering changes in these measurements. The results demonstrated that myoglobin is more oxygenated during the systolic and diastolic periods and deoxygenated in the resting period, whereas cytochrome a + a₃ is more reduced in systole and diastole and oxidized in the resting state. Changing the perfusion conditions greatly alters the time course of the events which occur during the contraction-relaxation cycle of the perfused heart.