Acylation of human hemoglobin with polyoxyethylene derivatives

Monomethoxypolyoxyethylene (Mw = 5000) was covalently linked to human hemoglobin via an amide bond formed between amino groups of the protein and a carboxylic group introduced onto the polymer. The conjugates thus obtained have a molecular size corresponding to that of a globular protein with a molecular weight of about 190 000. Their oxygen-binding properties depend upon the initial conformation of the hemoglobin and reaction pH: hemoglobin modified in the deoxy state exhibited a lower oxygen affinity than that modified in the oxy state, and the lower the reaction pH, the lower the oxygen affinity of polymer-linked hemoglobin. However, the affinity of modified hemoglobin is always higher than that of native hemoglobin. On the other hand, when deoxyHb was complexed with organic phosphates during the condensation reaction, the resulting conjugates exhibited oxygen-binding characteristics quite similar to those of native hemoglobin, i.e., the same oxygen affinity, modified cooperativity and the same alkaline Bohr effect. Finally, in order to decrease the oxygen affinity of hemoglobin conjugates, the polymer was coupled to deoxy hemoglobin previously covalently modified with pyridoxal phosphate. The oxygen affinity of such conjugates was in fact as low as that of the initial pyridoxylated hemoglobin.     

Improvement of oxygen-carrying properties of human hemoglobin by chemical modification with a benzene hexacarboxylate-monosubstituted polyoxyethylene

Benzene hexacarboxylate-monosubstituted polyoxyethylene on contact with Hb decreases its oxygen affinity, probably because it specifically interacts with the amino groups of the phosphate-binding site. This site specificity was used to direct the covalent coupling of this polymeric reagent with hemoglobin, in the vicinity of this cleft in order to obtain conjugates with low oxygen affinity and well-defined molecular weight. Such conjugates could thus be regarded as potential candidates for blood substitutes. Covalent fixation of this polymeric site-labeling reagent onto hemoglobin was carried out with the oxy and the deoxy form in the presence of a water soluble carbodiimide. It turns out that the oxygen-binding properties of the resulting hemoglobin derivatives depend on the reaction conditions, yet in all cases the oxygen affinity of the modified protein was lower than that of native hemoglobin and was no longer affected by organic phosphates. These results indicate that phosphate-binding site amines are probably involved in the covalent coupling, although in some conjugates (especially those prepared with high ratios of reagents) other amino groups participate also in the linking to the polymer. Chromatographic analysis and trypic peptide mapping of some conjugates evidenced that the -terminal valine residue was in fact the preferential binding site of hexacarboxylate-monosubstituted polyoxyethylene.     

Low oxygen affinity derivatives of human hemoglobin by fixation of polycarboxylic dextran to the oxyform

Solutions of modified adult human hemoglobin (Hb) have potential applications as physiological oxygen carriers. The chemical modification that has been the most studied during the last few years is the cross-linking of the protein between its two αβ dimers, in order, first, to hamper their diffusion through the kidney and therefore increase the plasma persistence of Hb, and second, to decrease its oxygen affinity. However, despite the cross-linking, the vascular retention time is only increased by a factor of three, and a supplementary modification of cross-linked Hb is needed in order to further improve its in vivo half-life. The Hb derivatives described in this paper were obtained by the covalent fixation of benzene tetracarboxylate-substituted dextran onto oxyHb. The resulting conjugates all exhibited a higher P₅₀ than native Hb. The experiments carried out in the presence of inositolhexaphosphate showed that the allosteric sites of Hb molecules were occupied by the polymeric reagent. The important decrease in the Bohr effect and the lack of the Cl^? effect on the oxygen-binding properties proved that the Val 1α residue was also substituted. Finally, the ability of some conjugates to unload as much O₂ as blood, together with their other properties, make them quite promising candidates as red cell substitutes. © 1993 John Wiley & Sons, Inc.     

Effect of covalent labeling of dextran-benzenehexacarboxylate on hemoglobin

The covalent fixation of benzenehexacarboxylate (BHC) onto dextran was carried out according to several reaction schemes. The polyanionic polymers thus synthesized were capable of decreasing the oxygen affinity of hemoglobin by specifically interacting with the 2,3-diphosphoglycerate (2,3-DPG) binding site of the protein. The intensity of this effect was correlated to both the chemical structure of the polyanionic polymers and the BHC content in polymer. The polyanionic polymer, containing 0.035 mol BHC/g and presenting no cross-linking between its polymer chains, possessed the best effector properties. These properties were used to direct the covalent fixation of the dextran-benzenehexacarboxylate onto the phosphate binding site of the protein. The resulting hemoglobin was mainly substituted at the same time by one or more linked BHC onto both dimers in the vicinity of the 2,3-DPG site. Thus, the modification of hemoglobin led to an increase in the hydrodynamic volume of each dimer sufficient to limit the diffusion of the conjugates through the kidney membrane, even if the conjugates had dissociated into dimers. Compared to that of free hemoglobin, the oxygen affinity of the conjugates was significantly decreased. This type of covalent conjugate exhibited general properties quite suitable for use as blood substitutes.Abbreviations used Hb hemoglobin - 2,3-DPG 2,3-diphosphoglycerate - BHC benzenehexacarboxylate - IHP inositolhexaphosphate - EDCI 3-ethyl-1-(3-dimethylaminopropyl) carbodiimide hydrochloride     

Hemoglobin-dialdehyde dextran conjugates: Improvement of their oxygen-binding properties with anionic groups

We studied the conjugates formed between hemoglobin and sulfated or unsulfated oxidized dextran. It appears that the presence of sulfated groups favors imino bond formation between the protein and the polymer, as the average molecular size of the conjugates is larger in this case. Under neutral conditions, the oxygen-binding properties of the conjugates depend on the presence or absence of oxygen during the coupling reaction. With unsulfated dextran, oxyhemoglobin leads to conjugates with increased oxygen affinity (P ₅₀/P ₅₀ native hemoglobin 0.5) compared to that of free hemoglobin (P ₅₀=4 mm Hg), whereas deoxyhemoglobin leads to conjugates with decreased oxygen affinity (P ₅₀/P ₅₀ native hemoglobin 3). The use of sulfated dextran reinforces this lowering in oxygen affinity, which indicates that sulfated dextran acts as a permanent macromolecular effector of hemoglobin (P ₅₀/P ₅₀ native hemoglobin 4). Moreover, it can be assumed that some of the linkages involve the 2,3-diphosphoglycerate binding site, as the strong effector inositol hexaphosphate has only a slight effect on the oxygen-binding properties of the conjugate prepared in the deoxy state (P ₅₀/P ₅₀ native hemoglobin close to 4.4 and 6, respectively, for unsulfated and sulfated conjugates). Although dextran substituted with benzenehexacarboxylic acid (BHC) leads to a low-oxygen-affinity conjugate when linked to oxyhemoglobin through amide bonds (P ₅₀/P ₅₀ native hemoglobin 5), oxidized dextran modified with BHC leads, with oxyhemoglobin, to a conjugate whose oxygen affinity is close to that of free hemoglobin (P ₅₀/P ₅₀ native hemoglobin 1.2).     

Facile synthesis of stable and lectin-recognizable DNA-carbohydrate conjugates via diazo coupling

Stable and lectin-recognizable DNA-carbohydrate conjugates were prepared by diazo coupling of lactose and cellobiose derivatives to fragmented salmon testes DNA. The diazo coupling is suggested to take place selectively to guanine bases since the amount of lactose moiety introduced was directly proportional to the G content of various DNAs with different G contents. According to the CD spectra, the conjugates bearing carbohydrate less than 25% content kept a typical B-type conformation similar to native DNA. The conjugates possessed higher melting temperature and stronger nuclease resistance both to exo- and endonucleases than native DNA. Gel shift assay and fluorescence binding assay showed that the DNA-lactose conjugates were specifically bound to galactose-specific lectin RCA(120) with strong binding affinity (Ka = 10(4)-10(5) M(-1)) due to glycoside cluster effect. This facile method will be a useful protocol of molecular design for cell-targeted gene therapy.     

Preparation and characterization of active site protected poly(ethylene glycol)–avidin bioconjugates

Avidin was modified with poly(ethylene glycol) in the presence of a biotin binding site protective agent synthesised by imminobiotin conjugation to branched 20 kDa PEG. Avidin was incubated with imminobiotin–PEG and reacted with high amounts of 5, 10 or 20 kDa PEG to modify the protein amino groups. Circular dichroism demonstrated that the extensive PEGylation does not alter the protein conformational structure. The affinity of avidin–PEG conjugates for biotin and biotinylated antibodies depended on the PEG size or the use of a protective agent. Avidin–PEG 10 and 20 kDa prepared in the presence of imminobiotin–PEG maintained 100% of the native affinity for biotin. The 5 kDa PEG derivative and the ones obtained without biotin site protection maintained 79–85% of the native affinity. The affinity for biotinylated antibodies decreased to 35% when the conjugation was performed without imminobiotin–PEG, while the conjugates obtained with high-molecular-weight PEGs in the presence of protective agent displayed high residual affinity. All conjugates possessed negligible antigenicity and immunogenicity. PEGylation greatly prolonged the avidin permanence in the circulation, reduced its disposition in the liver and kidneys and promoted accumulation into solid tumors. PEGylation was found to prevent the protein cell uptake, either by phagocytosis or pinocytosis.     

Consequences of chemical modifications on the free radical reactions of human hemoglobin.

Hemoglobin-based oxygen carriers (HBOCs) are candidates for use as blood substitutes and resuscitation fluids. We determined that HBOCs of specific types differ in their ability to generate or interact with free radicals. The differences do not correlate with oxygen affinity. Detailed comparisons with unmodified human hemoglobin, HbA0, were carried out with two cross-linked derivatives: HbA-FMDA, produced by the reaction of human oxyhemoglobin with fumaryl monodibromoaspirin, and HbA-DBBF, produced by the reaction of human deoxyhemoglobin with bis(3,5-dibromosalicyl) fumarate. Both derivatives had lower oxygen affinity than unmodified HbA0. As previously reported, exposure of oxyhemoglobin to H2O2 causes generation of free radicals capable of generating formaldehyde from dimethyl sulfoxide. Relative to the reaction catalyzed by 50 microM HbA (18.0 +/- 3.5 nmol/30 min/ml), the formaldehyde formation was roughly 70% for HbA-DBBF and 50% for HbA-FMDA under comparable conditions. More profound differences are exhibited at lower hemoglobin concentrations. Spectral changes of the HBOCs during the reaction differ qualitatively and occur at different rates. The HBOCs also differ in rates of hemoglobin-catalyzed NADPH oxidation and aniline hydroxylation, reactions mediated by reactive oxygen species. These results show that stereochemical differences brought about by chemical cross-linking alter the ability of HBOCs to generate radicals and to react with activated oxygen species. These studies also show that the ability of hemoglobin to produce activated species of oxygen can be enhanced or suppressed independently of oxygen affinity.     

Nitric oxide formation from the reaction of nitrite with carp and rabbit hemoglobin at intermediate oxygen saturations

The nitrite reductase activity of deoxyhemoglobin has received much recent interest because the nitric oxide produced in this reaction may participate in blood flow regulation during hypoxia. The present study used spectral deconvolution to characterize the reaction of nitrite with carp and rabbit hemoglobin at different constant oxygen tensions that generate the full range of physiological relevant oxygen saturations. Carp is a hypoxia-tolerant species with very high hemoglobin oxygen affinity, and the high R-state character and low redox potential of the hemoglobin is hypothesized to promote NO generation from nitrite. The reaction of nitrite with deoxyhemoglobin leads to a 1 : 1 formation of nitrosylhemoglobin and methemoglobin in both species. At intermediate oxygen saturations, the reaction with deoxyhemoglobin is clearly favored over that with oxyhemoglobin, and the oxyhemoglobin reaction and its autocatalysis are inhibited by nitrosylhemoglobin from the deoxyhemoglobin reaction. The production of NO and nitrosylhemoglobin is faster and higher in carp hemoglobin with high O(2) affinity than in rabbit hemoglobin with lower O(2) affinity, and it correlates inversely with oxygen saturation. In carp, NO formation remains substantial even at high oxygen saturations. When oxygen affinity is decreased by T-state stabilization of carp hemoglobin with ATP, the reaction rates decrease and NO production is lowered, but the deoxyhemoglobin reaction continues to dominate. The data show that the reaction of nitrite with hemoglobin is dynamically influenced by oxygen affinity and the allosteric equilibrium between the T and R states, and that a high O(2) affinity increases the nitrite reductase capability of hemoglobin.     

Steroid-bovine serum albumin conjugates: molecular characterization and their interaction with androgen and estrogen receptors

Conjugates of testosterone-3-carboxymethyloxime (T-3-CMO), testosterone-17-hemisuccinate (T-17-HS), 17 beta-estradiol-6-carboxymethyloxime (E-6-CMO), or 17 beta-estradiol-17-hemisuccinate (E-17-HS) and bovine serum albumin (BSA) with varying steroid:protein ratios were prepared using the mixed anhydride method. Dialysis followed by molecular filtration yielded monomer steroid-BSA conjugates with a molecular weight of 70,000 dalton, and polymer conjugates with molecular weights of 140,000 dalton and higher. When conjugates were prepared with increasing initial steroid:BSA molar ratios the ratio of the obtained conjugates increased, in parallel with a decrease in the relative amount of monomers and an increase in the mean molecular size of polymers. The molecular properties of these conjugates were studied further by polyacrylamide gel electrophoresis (PAGE) in native and denaturing conditions. In native PAGE the monomer fractions showed one main band with a mobility slightly lower than BSA and a faint band corresponding with BSA-dimers. The polymer fractions consisted of a heterogeneous population of protein oligomers with molecular weights varying from 140,000 to over a million dalton. In the presence of sodium dodecylsulphate part of the polymers dissociated into monomers. In buffered aqueous solutions the bulk of the conjugate preparation retained its molecular size and composition, although the generated covalent bonds were found to be liable to spontaneous hydrolysis. Steroid-protein conjugates were shown to contain appreciable amounts of non protein-bound steroids. Binding of T-BSA to androgen receptors in rat ventral prostate cytosol was assayed using LH-20 chromatography and sucrose gradient centrifugation analysis. Binding of E-BSA to estrogen receptors was analysed with rat uterus cytosol using the dextran coated charcoal assay and the sucrose gradient centrifugation technique. Relative binding affinities (RBA) were analyzed in competition experiments using radiolabeled ligands. It was found that the molecular size of the conjugate does not influence its interaction with steroid receptors. Steroid coupled via the 17-position show a higher RBA to receptors than the T-3 or E-6 derivatives. The RBA of T-3-BSA, T-3-CMO, T-17-BSA and T-17-HS appeared to be very low, i.e. between 0.1 and 1.7% of the RBA of dihydrotestosterone. Consequently, high concentrations of conjugate are required to saturate androgen receptor binding sites. Under these conditions involvement of type II and eventually type III binding sites, which show less ligand specificity and lower affinity, may be anticipated preventing exclusive detection of androgen receptors.(ABSTRACT TRUNCATED AT 400 WORDS)     

Influence of ligation state and concentration of hemoglobin A on its cross-linking by glycolaldehyde: functional properties of cross-linked, carboxymethylated hemoglobin

The ligation state of hemoglobin during its cross-linking by glycolaldehyde influences the ultimate oxygen affinity of the cross-linked protein. Thus, if the cross-linking is performed with carbonmonoxy-hemoglobin, the oxygen affinity increases slightly to a P50 of 7 mmHg from a P50 of 9 mmHg for unmodified hemoglobin. In contrast, when deoxyhemoglobin is cross-linked with glycolaldehyde, the oxygen affinity of the product decreases (P50 = 15 mmHg). When deoxyhemoglobin is first carboxymethylated and then cross-linked with glycolaldehyde, an even lower oxygen affinity is achieved (P50 = 23 mmHg). Carboxymethylated hemoglobin is very responsive to the presence of 5% CO2 with a P50 of 33 mmHg, which is lowered further to 42 mmHg when chloride (0.1 M) is also present. Hemoglobin carboxymethylated and cross-linked under anaerobic conditions is also responsive to the modulators CO2 and chloride with a resultant oxygen affinity of 27 mmHg. The type of cross-linking of liganded hemoglobin by the mild reagent glycolaldehyde is dependent upon the initial hemoglobin concentration. Thus, with dilute hemoglobin (45 microM in tetramer), cross-linking by glycolaldehyde (50 mM) results in about 75% of 64,000 molecular weight species (some of which are cross-linked within tetramer) and 25% of intertetrameric cross-linked species with a range of molecular weights averaging 128,000-512,000. With hemoglobin solutions of higher concentration (360 microM), the amount of the higher molecular weight species increases to about 65% with a corresponding reduction to 35% in the 64,000 molecular weight component.     

Studies on Scapharca hemoglobins. Properties of the dimeric protein reconstituted with Fe- or Co-porphyrin

A native globin from the dimeric hemoglobin, hemoglobin I, of the mollusc Scapharca inaequivalvis has been obtained with the acid-acetone method. The globin has a lower sedimentation coefficient than the native protein at neutral pH; its reconstitution product with natural heme has the same physicochemical and functional properties as the native protein. proto- and meso-cobalt hemoglobin I have been prepared and characterized. proto-Cobalt hemoglobin I binds oxygen reversibly with a lower affinity and a lower cooperativity than native hemoglobin I; thus, the changes in the functional properties brought about by substitution of iron with cobalt are similar to those observed in human hemoglobin A. The EPR spectra of deoxy-proto-cobalt hemoglobin I and of the photolysis product of oxy-meso-cobalt hemoglobin I indicate that two histidine residues are the apical heme ligands. The broad signal at g = 2.38 in deoxy-proto-cobalt hemoglobin I points to a constrained structure of the heme site in this derivative which results from a distorted coordination of the hindered proximal histidine. A similar structure has been proposed previously for the alpha chains in deoxy-cobalt hemoglobin A.     

Synthesis and active oxygen generation by new emodin derivatives and their gonadotropin-releasing hormone conjugates

In an attempt to develop efficient chemotherapeutic agents targeted at malignant cells that express receptors, we synthesized five new emodin derivatives and their gonadotropin-releasing hormone (GnRH) conjugates to be used as potential photoactive conjugates. Emodin was modified at its hydroxy groups and included different spacers for conjugation of the peptide. We used electron spin resonance (ESR) and spin trapping techniques to study the light-stimulated redox properties of the emodin derivatives and their GnRH conjugates. Upon irradiation, all new emodin derivatives and their conjugates stimulated the formation of singlet oxygen, that is, (1)O(2), and oxygen radicals, that is, O(2)(-)(*) and OH(*). However, substantial differences were found between the tested derivatives as to the efficacy of reactive oxygen species (ROS) production. Because of its superior ROS production properties, [d-Lys(6)(MeoEmo)]GnRH was selected as a leading conjugate. En-route to evaluate its targeting capacity, this potentially cytotoxic conjugate was tested in vitro to determine its hormonal activity and binding affinity to GnRH receptors.     

The CO and NO Bohr effect of human hemoglobin with and without inositolhexaphosphate.

Using NO and CO as ligands the Bohr effect of human hemoglobin has been measured with and without inositolhexophosphate. It appears that in the absence and presence of inositolhexaphosphate hemoglobin shows a distinct ligand specificity with respect to the Bohr effect. Ligation with NO is accompanied by release of a larger number of Bohr effect. It is shown that this latter result is due to the fact that the number of protons taken up upon binding of inositolhexaphosphate to ligated hemoglobin is larger for HbNO than for HbCO. It is suggested that this additional proton uptake is partially due to a restoration of the saltbridge between His 146beta and Asp 94beta upon addition of IHP.     

Effect of polyanionic polymers on haemoglobin oxygen-binding properties: application to the synthesis of covalent conjugates with low oxygen affinity

Polyanionic water-soluble polymers containing sulphate, phosphate and polycarboxylate groups were synthesized. These compounds, when simply added to haemoglobin solutions, were shown to lower the affinity of the protein for oxygen. Their influence on oxygen affinity was regarded as the result of a specific interaction of the polymer anionic groups inside the 2,3-diphosphoglycerate-binding site of deoxyhaemoglobin. On the other hand, these polymers were linked to deoxyhaemoglobin to give covalent conjugates also exhibiting an oxygen affinity lower than that of free haemoglobin in the presence of 2,3-diphosphoglycerate, its natural effector, which means that after fixation, the polyanionic polymers are still acting as effectors.     

Covalent fixation of polymer-linked benzene hexacarboxylate onto human haemoglobin.

The reaction of human deoxy and oxyhaemoglobin with a macromolecular effector, monomethoxypolyoxyethylene-linked benzene hexacarboxylate, in the presence of a water soluble carbodiimide, produces under defined conditions, the same conjugates preferentially acylated at the two valines beta 1. The oxygen affinity of both these conjugates is decreased by approximately 5-fold compared with that of native Hb (at pH 7.2, in 0.05 M Tris buffer, 25 degrees C, P50: 20.1 and 20.7 Torr versus about 4 Torr for Hb). This difference appears to be due to an overstabilization of the T state probably together with a decrease of the oxygen affinity of the R state. Addition of IHP to the conjugate solutions does not influence the P50 but addition of IHP to the reaction mixtures before the coupling limits the substitution of Hb by the macromolecular effector, to 20% (instead of 100% in absence of IHP). The cooperativity curve is shifted to the right with an Nmax of 3 at about 90% oxygen saturation, which corresponds to a potential release of 48% of oxygen at pH 7.2, 25 degrees C, between 100 and 40 Torr, compared with 40% for blood. Such kinds of conjugates especially those obtained from oxyhaemoglobin which are easily prepared, could be of a great interest as non-diffusing oxygen carriers in transfusional and perfusional fluids.     

Chemical cross-linking of hemoglobin H. A possible approach to introduce cooperativity and modification of its oxygen transport properties.

Native and reconstituted hemoglobin H molecules were cross-linked with glutaraldehyde at pH values close to the physiological. The Schiff base adducts were analysed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis before and after reduction with sodium borohydride. The major component had a molecular weight of about 31 000 which corresponded to the dimeric species of the beta subunit. In contrast to the native protein, which has very high oxygen affinity and no heme-heme interaction or 2,3-diphosphoglyceric acid effect, the modified hemoglobin H molecules showed cooperative oxygen binding, decreased oxygen affinity and a noticeable 2,3-diphosphoglyceric acid effect.     

Microinjection of ubiquitin: changes in protein degradation in HeLa cells subjected to heat-shock

Ubiquitin was radiolabeled by reaction with 125I-Bolton-Hunter reagent and introduced into HeLa cells using erythrocyte-mediated microinjection. The injected cells were then incubated at 45 degrees C for 5 min (reversible heat-shock) or for 30 min (lethal heat-shock). After either treatment, there were dramatic changes in the levels of ubiquitin conjugates. Under normal culture conditions, approximately 10% of the injected ubiquitin is linked to histones, 40% is found in conjugates with molecular weights greater than 25,000, and the rest is unconjugated. After heat-shock, the free ubiquitin pool and the level of histone-ubiquitin conjugates decreased rapidly, and high molecular weight conjugates predominated. Formation of large conjugates did not require protein synthesis; when analyzed by two-dimensional electrophoresis, the major conjugates did not co-migrate with heat-shock proteins before or after thermal stress. Concomitant with the loss of free ubiquitin, the degradation of endogenous proteins, injected hemoglobin, BSA, and ubiquitin was reduced in heat-shocked HeLa cells. After reversible heat-shock, the decrease in proteolysis was small, and both the rate of proteolysis and the size of the free ubiquitin pool returned to control levels upon incubation at 37 degrees C. In contrast, neither proteolysis nor free ubiquitin pools returned to control levels after lethal heat-shock. However, lethally heat-shocked cells degraded denatured hemoglobin more rapidly than native hemoglobin and ubiquitin-globin conjugates formed within them. Therefore, stabilization of proteins after heat-shock cannot be due to the loss of ubiquitin conjugation or inability to degrade proteins that form conjugates with ubiquitin.     

Functional aspects of hemoglobin evolution in the mammals

Summary Comparative studies of red cell 2,3 Diphosphoglycerate (DPG) and its effect on hemoglobin oxygen affinity from a taxonomically diverse set of mammals indicate two anomalous groups: members of the superfamilies Bovoidea (Actiodactyla) and Feloidea (Carnivora). In both taxa all of the individuals assayed had very low or unmeasurable quantities of DPG and red cell lysates with little, if any, DPG effect as measured by the change in oxygen affinity in the absence and presence of the phosphate. However, in both groups compensatory changes have occurred in hemoglobin structure and function so as to reduce the native oxygen affinity and thus cause them to resemble the hemoglobins of DPG-utilizing mammals as they occur in the setting of the red cell. We conclude that this parallelism of function is the result of convergent evolution.     

Modification of human hemoglobin with polyethylene glycol: A new candidate for blood substitute

Human hemoglobin was modified with polyethylene glycols. The conjugates exhibited P₅₀ values of 10–15 mmHg, those are enough to deliver oxygen from the lungs to tissues. The most remarkable characteristic is their long half disappearance time from the circulation. The longest half disappearance time of these derivatives is about 180 minutes in contrast to 45 minutes of free hemoglobin. The half disappearance time shows a good corelation not to molecular weight but to the effective molecular size, which is determined by the elution time of HPLC on a gel permeation column.