Preparation and characterization of crosslinked and polymerized hemoglobin solutions

In 1982 we synthesized 2-Nor-2-formylpyridoxal 5'-phosphate (NFPLP) and subsequently showed that coupling of the beta chains of hemoglobin (Hb) by this organic phosphate compound according to Benesch et al. (1) lowers the oxygen affinity and prolongs the retention time in the circulation of rat...

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Published inBiomaterials, artificial cells, and immobilization biotechnology Vol. 20; no. 2-4; p. 233
Main Authors Bakker, J C, Berbers, G A, Bleeker, W K, den Boer, P J, Biessels, P T
Format Journal Article
LanguageEnglish
Published United States 1992
Subjects
Animals
Blood Substitutes - chemical synthesis
Blood Substitutes - chemistry
Blood Substitutes - isolation & purification
Cross-Linking Reagents
Hemoglobins - chemical synthesis
Hemoglobins - chemistry
Hemoglobins - isolation & purification
Humans
Osmotic Pressure
Oxygen
Pyridoxal Phosphate - analogs & derivatives
Viscosity
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Summary:In 1982 we synthesized 2-Nor-2-formylpyridoxal 5'-phosphate (NFPLP) and subsequently showed that coupling of the beta chains of hemoglobin (Hb) by this organic phosphate compound according to Benesch et al. (1) lowers the oxygen affinity and prolongs the retention time in the circulation of rats and rabbits with a factor 3 by prevention of excretion via the kidneys. Optimal conditions for the purification of HbNFPLP either by ion-exchange chromatography or by heat treatment were established with recoveries of 70% and 85%, respectively. By extrapolation from the data in rats and rabbits a half life of about 8 hours can be expected in the circulation of humans. However, under some conditions a further prolongation is required. The aim of further modification of HbNFPLP was to achieve a retention time of about 24 hours. Polymerization with glutaraldehyde to polyHbNFPLP resulted in a mixture of polymers of different size. We determined the optimal degree of polymerization with respect to the effects on vascular retention time, oncotic activity, viscosity and oxygen affinity. Depending on the degree of polymerization we found in rats a 5- to 7- fold increase in vascular half-life compared to native Hb. The change in oxygen affinity was found to be independent of the polymer size (P50 = 18-22 mmHg). A limiting factor for polymerization is the increase in viscosity, which was dramatic when large polymers (greater than 300 kD) were present in the preparation.
ISSN:1055-7172
DOI:10.3109/10731199209119638