Evaluation of a Stroma-Free Hemoglobin Solution for Use as a Plasma Expander

Rabiner, S. Frederick; Helbert, J.; Lopas, Harry; Friedman, Lila H.

doi:10.1084/jem.126.6.1127

Cited by 264 publications

(50 citation statements)

References 33 publications

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“…4). Previous studies have shown that the liver is also the site of removal of protein-bound heme in animals (21,22) and of free and haptoglobin-bound hemoglobin in animals (35,43,48) and man (15,16 Reutilization of heme-iron (Fig. 4).…”

Section: Disposal Of Plasma Hemementioning

confidence: 99%

Disposal of plasma heme in normal man and patients with intravascular hemolysis

Sears¹

1970

J. Clin. Invest.

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Section: Disposal Of Plasma Hemementioning

confidence: 99%

Disposal of plasma heme in normal man and patients with intravascular hemolysis

Sears¹

1970

J. Clin. Invest.

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“…Their main known disadvantages are, reduced circulation half-life, haemodynamic and gastrointestinal perturbations, probably related to nitric oxide (NO) scavenging, free radical induction, and alterations of biochemical and haematological parameters (increase in liver enzyme levels, platelet aggregation) [1][2][3].…”

Section: Mjafi 2003; 59 : 45-50mentioning

confidence: 99%

Artifical Blood

Goorha¹,

Deb²,

Chatterjee

et al. 2003

Medical Journal Armed Forces India

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Elimination of unwanted side-effects, especially transfusion-transmitted diseases (HIV and hepatitis) and leucocyte-mediated allosensitisation, is an important goal of modern transfusion medicine. The problems and high cost factor involved in collecting and storing human blood and the pending world-wide shortages are the other driving forces contributing towards the development of blood substitutes. Two major areas of research in this endeavour are haemoglobin-based oxygen carriers (HBOCs) and perfluorochemicals. Even though they do not qualify as perfect red blood cell substitutes, these 'oxygen carrying solutions' have many potential clinical and non clinical usages. These can reach tissues more easily than normal red cells and can deliver oxygen directly. These are not without adverse effects, and extensive clinical trials are being conducted to test their safety and efficacy. New understandings on the mode of action of these products will help to define their utility and application. Only after successful clinical trials can they be used for patient management, after approval by the FDA. MJAFI 2003; 59 : 45-50Key Words : Blood substitute; Haemoglobin solutions; Perfluorocarbons main advantages include availability in large volumes, storage for prolonged periods, rapid administration (without typing and cross matching) and sterilisation by pasteurisation. Their main known disadvantages are, reduced circulation half-life, haemodynamic and gastrointestinal perturbations, probably related to nitric oxide (NO) scavenging, free radical induction, and alterations of biochemical and haematological parameters (increase in liver enzyme levels, platelet aggregation) [1][2][3]. Purified haemoglobin solutionsThe first step in the pursuit for red cell substitute was

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“…Stroma-free solutions of hemoglobin have been shown to be free of toxic effects such as deterioration of kidney function and coagulation disorders (Palani et al, 1975;Rabiner et al, 1967;Relihan and Litwin, 1973). The two major disadvantages are short intravascular persistence and high oxygen affinity (Sunder-Plassmann et al, 1975).…”

Section: Discussionmentioning

confidence: 99%

Tissue PO<sub>2</sub> during Reanimation with Hemoglobin Solutions

Meßmer¹,

Jesch²,

Endrich³

et al. 1979

Eur Surg Res

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Solutions of conventional stroma-free hemoglobin (SFH) and of pyridoxylated stroma-free hemoglobin (SFH-PLP) were compared in a dog model of reanimation from severe arterial blood loss. SFH and SFH-PLP restored central hemodynamics after infusion without yielding significant differences between the experimental groups. To cope with the developing hypovolemia, Ringer’s lactate was infused 60 min after infusion of hemoglobin solution. Even though the Ringer’s lactate load amounted to about 120 ml/kg, edema formation was not encountered. Skeletal muscle oxygenation was studied by means of a multiwire platin electrode. The infusion of SFH-PLP was associated with a shift to the right of the cumulative PO₂-distribution curve, indicating better tissue oxygenation. Oxygen was not unloaded from SFH in plasma unless the oxygen extraction from red cell hemoglobin exceeded 40%. Oxygen unloading was, however, improved when SFH-PLP with low oxygen affinity was used. Thus, SFH-PLP merits further consideration as a short-term oxygen-carrying blood substitute.

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Evaluation of a Stroma-Free Hemoglobin Solution for Use as a Plasma Expander

Cited by 264 publications

References 33 publications

Disposal of plasma heme in normal man and patients with intravascular hemolysis

Disposal of plasma heme in normal man and patients with intravascular hemolysis

Artifical Blood

Tissue PO<sub>2</sub> during Reanimation with Hemoglobin Solutions

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