Hemoglobin-based oxygen carrier preserves submaximal exercise capacity in humans.

OBJECTIVE: The objective of this study was to evaluate the exercise capacity of subjects given an autologous transfusion or a polymerized bovine hemoglobin solution to define the pharmacodynamics and pharmacokinetics of a new hemoglobin-based oxygen carrier (HBOC-201). METHODS: Six normal healthy male subjects (ages 25 to 45 years) participated in this randomized, single-blind, two-way crossover study, which took place at Upjohn Research Clinics in Kalamazoo, Mich. A radial artery catheter was inserted in each subject before serial cardiac output and pulmonary function tests and phlebotomy of 15% blood volume (750 ml plus another 250 ml for study laboratories yields 1000 ml, or about 150 gm human hemoglobin). This was followed by isovolemic hemodilution with Ringer's lactate plus an autologous blood transfusion (or HBOC-201) and 1 week later 45 gm bovine hemoglobin of HBOC-201 (or autologous transfusion). Bicycle exercise stress tests to anaerobic threshold (approximately 65% of predicted maximum aerobic capacity) were done before phlebotomy and at approximately 45 minutes after the autologous transfusion or HBOC-201 infusion. RESULTS: Subjects had similar exercise and diffusion capacity but lower lactate levels (for up to 24 hours) during HBOC-201 (which paralleled plasma HBOC-201 levels) than during autologous transfusion periods. Oxygen use (uptake) and carbon dioxide production at rest were greater during the HBOC-201 infusion than during the autologous transfusion period. The half-life of HBOC-201 was about 23 hours. CONCLUSIONS: Exercise capacity and diffusion capacity were similar after HBOC-201 and autologous transfusion. HBOC-201 resulted in greater oxygen (or uptake) and carbon dioxide production and lower lactate levels compared with autologous transfusion. Under the conditions of the study, the physiologic effects of 1 gm bovine hemoglobin of HBOC-201 were similar to 3 gm human hemoglobin from autologous transfusion.

Effects of a novel hemoglobin-based oxygen carrier on percent oxygen saturation as determined with arterial blood gas analysis and pulse oximetry.

STUDY OBJECTIVE: Hemoglobin-based oxygen carrier 201 (HBOC-201) is a polymerized hemoglobin of bovine origin being developed for use in hemorrhage during surgery or trauma. Pulse oximetry is commonly used in clinical practice to assess percent saturation of hemoglobin (Spo2). The ability to measure Spo2 in the presence of HBOC-201 will be important for the use of this compound in patient care. METHODS: We carried out a randomized, single-blind, placebo-controlled study at the Upjohn Research Clinics in Kalamazoo, Michigan, with normal, healthy adult men and women as subjects. The members of four groups of adult subjects (N=24) each received 45 g of HBOC-201 (nine each, men and women) or a control solution (Ringer's lactate) (three each, men and women). Each subject underwent phlebotomy (about 15% of estimated blood volume) followed by 3:1 hemodilution with Ringer's lactate and then either HBOC-201 or control solution. An indwelling arterial catheter in the radial artery was used for serial arterial blood gas sampling. Arterial blood gas measurements were made with a cooximeter (Instrumentation Laboratories). Fingertip pulse oximetry was used (Criticare 504-US; Criticare, Incorporated). Paired pulse oximetry and arterial blood gas sampling were made serially (at approximately hourly intervals) over 24 hours. RESULTS: The mean +/- SEM difference for Spo2 for arterial blood gas analysis compared with the pulse oximetry reading in the presence of HBOC-201 was 1.1% +/- 0.75%; in controls it was .1% +/- 0.64% (P<.001) for each) over the 24 hours after dosing. This relationship was constant despite increased concentrations of plasma hemoglobin (between 1 and 2g/dl [10 to 20 g/L]) in the HBOC-201 groups. CONCLUSION: Accurate determinations of Spo2 can be made with pulse oximetry in subjects given HBOC-201 over the normal range of Spo2.

Hematologic effects of a novel hemoglobin-based oxygen carrier in normal male and female subjects.

The objective of this study was to assess the relationship between iron metabolism and pharmacokinetics of hemoglobin-based oxygen carrier-201 (HBOC-201), a polymerized hemoglobin product of bovine origin. A randomized, single-blind, single-dose study design was used. The study was performed at the Upjohn Research Clinics in Kalamazoo, Michigan. Four groups of healthy men and women (n = 24), who either received HBOC-201 (9 men, 9 women) or a control solution (Ringer's lactate) (3 men, 3 women) participated in the study. All subjects had phlebotomy (approximately 15% blood volume) followed by 3:1 hemodilution with Ringer's lactate and an intravenous infusion of HBOC-201 (up to 45 gm or 350 ml) or control solution (Ringer's lactate). Serial arterial blood gas samples with a radial artery catheter and simultaneous pulse oximetry were done during the first 24 hours. Serial samples for serum iron, ferritin, erythropoietin, and plasma HBOC-201 levels were taken over a 1-month period. In the HBOC-201-treated groups, serum iron and ferritin levels increased. Peak serum iron and ferritin levels occurred by hours 8 (up to 220 micrograms/dl) and 48 (up to 180 ng/ml), respectively. Serum iron levels paralleled HBOC-201 concentrations. Plasma half-life of HBOC-201 was about 20 hours. Serum erythropoietin increased by twofold to sixfold over baseline (p < 0.001) at 24 hours. No urinary hemoglobin was detected in the groups with HBOC-201-treated subjects. This study demonstrates that HBOC-201 produces increases in serum iron, ferritin, and erythropoietin that closely parallel plasma levels of HBOC-201 in men and women.