Hemodynamic responses to a hemoglobin bis‐tetramer and its polyethylene glycol conjugate

Abstract

The design of hemoglobin-based oxygen carriers (HBOCs) poses a significant challenge as clinical trials of many materials have reported adverse side effects that may come from the scavenging of the vasodilator nitric oxide (NO). A compensating reaction, reduction of endogenous nitrite by hemoglobin (Hb) and its derivatives, generates NO. Polyethylene glycol (PEG) conjugation of Hb enhances the rate of the reaction. Hemoglobin bis-tetramers (BT) and their PEGylated derivative (BT-PEG) bind oxygen with a degree of cooperativity and also have significantly enhanced nitrite reductase activity compared to the native protein. Circulatory evaluation will test if the properties of BT and BT-PEG are reflected in their effects in vivo. BT and BT-PEG were evaluated as infusions into healthy wild-type (WT) and diabetic (db/db) mouse models. The effects were compared to infusions of murine Hb. The materials were found not to cause significant increases in systemic blood pressure in either WT mice or db/db mice. The latter are highly sensitive to NO scavenging. Further hemodynamic measurements in WT mice indicate that while a slight increase in systemic vascular resistance (SVR) was observed after infusion of BT, the extent is not significant. No change in SVR from baseline was observed after infusion of BT-PEG. The enlarged Hb derivatives do not evoke unfavorable circulatory responses that have been noted to result from infusion of Hb derivatives. These results suggest that a compromise between the P(50) , n(50) , and nitrite reductase activity of a Hb derivative can serve as the basis for producing HBOCs that can be tested for vasoactivity.