products. Considerable effort has been made to develop blood substitutes or artificial blood, but these products deal only with the oxygen‐delivery function. Thus, more appropriate terms are hemoglobin or red cell substitutes [160].
The ideal acellular red cell substitute would not require crossmatching or blood typing, could be stored preferably at room temperature for a long period, would have a reasonable intravascular life span and thereafter be excreted promptly, and would be free of toxicity or disease transmission. Two approaches have been used: perfluorocarbons, compounds in which oxygen is highly soluble, and free hemoglobin solutions using either human or animal hemoglobin [161]. Hemoglobin chemically binds oxygen, whereas perfluorocarbons have a carbon backbone with fluorine substitutions that have solubility for oxygen 20 times greater than water. The physiologic benefit of this high solubility for oxygen has been demonstrated dramatically by the survival of mice completely immersed in a solution of well‐oxygenated perfluorocarbons.
Hemoglobin can be prepared in solution by lysis of red cells. If the remaining cell stroma is removed, the stroma‐free hemoglobin is nonantigenic. However, stroma‐free hemoglobin in solution has a short intravascular life span and has a low P50 (the point at which 50% is saturated). Thus, research has focused on modifying the structure of the hemoglobin molecule (cross‐linking or polymerization) or binding hemoglobin to other molecules to overcome these two problems [161]. Outdated human red cells, bovine hemoglobulin, and recombinant DNA‐produced hemoglobin have been used as sources of hemoglobin. The potential difficulties with hemoglobin‐based oxygen carriers are rapid clearance of the hemoglobin, hypertensive effects, change in the oxygen dissociation curve, hemoglobin metabolites, immunogenicity, and bacterial sepsis [161].
Five products are or have undergone clinical trials: Polyheme (Northfield Laboratories, Evanston, IL, USA), HemAssist (Baxter Healthcare Corporation, Round Lake, IL, USA), Hemopure (Biopure Corporation, Cambridge, MA, USA), Hemolink (Hemosol, Mississauga, ON, Canada), and Sanguinate (Prolong Pharmaceuticals, LLC, South Plainfield, NJ, USA) [162, 163].
Development of HemAssist has been discontinued after randomized trials demonstrated safety problems [164, 165]. Hemopure was used successfully in a patient with severe autoimmune hemolytic anemia [166] and in a patient with sickle cell disease with acute chest syndrome who refused blood transfusion [167]. However, clinical trials of these products have come to a stop [168, 169]. Currently, the FDA has approved expanded access study for Hemopure (compassionate use) for patients with life‐threatening anemia when a transfusion is not an option [170, 171].
In a careful study, 8 patients with severe anemia (hemoglobin levels of 1.2–4.5 g/dL) who refused a blood transfusion received the perfluorocarbon product and were compared with 15 patients who did not [172]. The amount of oxygen delivered by the perfluorocarbon was not clinically significant, and the patients did not benefit. The major observation in this study was the ability of all the patients to tolerate remarkably low hemoglobin levels and the lack of the need for increased arterial oxygen content in the 15 control patients who had hemoglobin levels of approximately 7 g/dL. Fluosol products are not available, nor are they undergoing clinical trial.
Potential clinical uses and impact of hemoglobin substitutes
If a hemoglobin‐based oxygen carrier was developed, it is not likely that it will replace most red cell transfusions. The substitutes might be used for immediate restoration of oxygen delivery, such as in trauma or in other urgent situations involving massive blood loss where red cells are not available quickly, but the short intravascular half‐life of these substitutes makes them impractical for long‐term red cell replacement (for instance, in patients with chronic anemia). Because blood typing and crossmatching would not be necessary, the substitutes might be carried in emergency vehicles, stocked in emergency departments, or used by the military or civilians in situations where access to blood is limited. Other potential uses of hemoglobin substitutes include organ perfusion and preservation prior to transplantation and improving oxygen delivery to tissues that have an impaired blood supply. Unfortunately, it does not appear that a hemoglobin‐based blood substitute [24] will be available soon, and the long‐awaited “blood substitute” is not close to reality.
References
1 1. Jobes DR, Sesok‐Pizzini D, Friedman D. Reduced transfusion requirement with use of fresh whole blood in pediatric cardiac surgical procedures. Ann Thorac Surg 2015; 99(5):1706–1711.
2 2. Manno CS, Hedberg KW, Kim HC, et al. Comparison of the hemostatic effects of fresh whole blood, stored whole blood, and components after open heart surgery in children. Blood 1991; 77(5):930–936.
3 3. Mou SS, Giroir BP, Molitor‐Kirsch EA, et al. Fresh whole blood versus reconstituted blood for pump priming in heart surgery in infants. N Engl J Med 2004; 351(16):1635–1644.
4 4. Spinella PC, Perkins JG, Grathwohl KW, et al. Warm fresh whole blood is independently associated with improved survival for patients with combat‐related traumatic injuries. J Trauma Inj Infect Crit Care 2009; 66(Suppl):S69–S76.
5 5. Shackelford SA, del Junco DJ, Powell‐Dunford N, et al. Association of prehospital blood product transfusion during medical evacuation of combat casualties in Afghanistan with acute and 30‐day survival. JAMA 2017; 318(16):1581.
6 6. Guyette FX, Sperry JL, Peitzman AB, et al. Prehospital blood product and crystalloid resuscitation in the severely injured patient. Ann Surg 2019. Available from: http://dx.doi.org/10.1097/SLA.0000000000003324.
7 7. Seheult JN, Anto V, Alarcon LH, et al. Clinical outcomes among low‐titer group O whole blood recipients compared to recipients of conventional components in civilian trauma resuscitation. Transfusion 2018; 58(8):1838–1845.
8 8. Cotton BA, Podbielski J, Camp E, et al. A randomized controlled pilot trial of modified whole blood versus component therapy in severely injured patients requiring large volume transfusions. Ann Surg 2013; 258(4):527–533.
9 9. Sperry J. Pragmatic prehospital group O whole blood early resuscitation trial (PPOWER). NCT03477006. Available from: https://clinicaltrials.gov/ct2/show/NCT03477006 [cited 28 October 2019].
10 10. Spinella PC, Pidcoke HF, Strandenes G, et al. Whole blood for hemostatic resuscitation of major bleeding. Transfusion 2016; 56:S190–S202.
11 11. Spinella PC, Cap AP. Whole blood. Curr Opin Hematol 2016; 23(6):536–542.
12 12. Strandenes G, Berséus O, Cap AP, et al. Low titer group O whole blood in emergency situations. Shock 2014; 41:70–75.
13 13. Becker GA, Tuccelli M, Kunicki T, et al. Studies of platelet concentrates stored at 22 C and 4 C. Transfusion 1973; 13(2):61–68.
14 14. Rous P. The preservation of living red blood cells in vitro: I. Methods of preservation. J Exp Med 1916; 23(2):219–237.
15 15. Loutit JF, Mollison PL. Disodium‐citrate–glucose mixture as a blood preservative. BMJ 1943; 2(4327):744–745.
16 16. Simon E. Red cell preservation: further studies with adenine. Blood 1962; 20:485–491.
17 17. Benesh R, Benesh R. The influence of organic phosphates on the oxygenation of hemoglobin. Fed Proc 1967; 121:96–102.
18 18. Chanutin A, Curnish RR. Effect of organic and inorganic phosphates on the oxygen equilibrium of human erythrocytes. Arch Biochem Biophys 1967; 121(1):96–102.
19 19. Benesch R, Benesch RE. Intracellular organic phosphates as regulators of oxygen release by haemoglobin. Nature 1969; 221(5181):618–622.
20 20. Högman CF, Hedlund K, Zetterström H. Clinical usefulness of red cells preserved in protein‐poor mediums. N Engl J Med 1978; 299(25):1377–1382.
21 21. Högman CF. Additive system approach in blood transfusion: birth of the SAG and Sagman systems. Vox Sang 1986; 51(4):339–340.
22 22.