Arterial blood pressure responses to cell-free hemoglobin solutions and the reaction with nitric oxide.

Changes in mean arterial pressure were monitored in rats following 50% isovolemic exchange transfusion with solutions of chemically modified hemoglobins. Blood pressure responses fall into three categories: 1) an immediate and sustained increase, 2) an immediate yet transient increase, or 3) no significant change either during or subsequent to exchange transfusion. The reactivities of these hemoglobins with nitric monoxide (.NO) were measured to test the hypothesis that different blood pressure responses to these solutions result from differences in .NO scavenging reactions. All hemoglobins studied exhibited a value of 30 microM-1 s-1 for both .NO bimolecular association rate constants and the rate constants for .NO-induced oxidation in vitro. Only the .NO dissociation rate constants and, thus, the equilibrium dissociation constants varied. Values of equilibrium dissociation constants ranged from 2 to 14 pM and varied inversely with vasopressor response. Hemoglobin solutions that exhibited either transient or no significant increase in blood pressure showed tighter .NO binding affinities than hemoglobin solutions that exhibited sustained increases. These results suggest that blood pressure increases observed upon exchange transfusion with cell-free hemoglobin solutions can not be the result of .NO scavenging reactions at the heme, but rather must be due to alternative physiologic mechanisms.

Hemoglobin-oxygen equilibrium curves measured during enzymatic oxygen consumption.

A rapid, new method to measure hemoglobin-oxygen equilibrium curves is described using the protocatechuic acid/protocatechuic acid 3,4-dioxygenase system [C. Bull and D.P. Ballou (1981) J. Biol. Chem. 256, 12673-12680] to deoxygenate hemoglobin solutions enzymatically. The reaction is followed by simultaneous measurements of hemoglobin spectra using a diode array spectrophotometer and oxygen tensions using a polarographic O2 microelectrode. Multicomponent analysis allows the determination of fractions of oxyhemoglobin, deoxyhemoglobin, and high-spin and low-spin methemoglobins in each spectrum collected as the reaction proceeds. Fractional saturation as a function of oxygen partial pressure is calculated as the ratio of oxyhemoglobin to oxy- plus deoxyhemoglobin. Several advantages are offered by this method: (i) Hemoglobin-O2 binding curves are obtained rapidly and reproducibly; (ii) the speed of the reaction limits methemoglobin formation by autooxidation; (iii) there is no gas-liquid interface, eliminating protein denaturation at the surface; and (iv) direct calculations of fractional saturation are made using spectral analysis, thus avoiding the assumption of a linear transition between deoxy- and oxyhemoglobin.