Solution stability of salmon calcitonin at high concentration for delivery in an implantable system.

Salmon calcitonin solutions (50 mg/mL and 100 mg/mL) were placed on stability at 37 degrees C for 1 year in a variety of solvent systems including water, ethanol, glycerol, propylene glycol (PG) and dimethyl sulfoxide (DMSO). Calcitonin degradation was monitored by RP-HPLC and size-exclusion chromatography. DMSO and pH 3.3 solutions provided optimum stability. Conformational stability was also monitored by FTIR over the 1 year time course and compared with chemical and physical stability. After 12 months at 37 degrees C, four major conformations were observed: a beta-sheet conformation (pH 3.3, pH 5.0, 70% DMSO and 70% glycerol), an aggregate conformation (pH 7.0 water), a strong alpha-helical conformation (70% EtOH, 70% PG) and a weak alpha-helical conformation (100% DMSO). No correlation between structure and chemical stability was observed in which both the beta-sheet structure (pH 3.3, water) and a loose alpha-helical structure (100% DMSO) demonstrated good stability. However, some correlation was observed between structure and physical stability, where co-solvents inducing an alpha-helical structure resulted in a decrease in gelation. These two structural states associated with improved stability and minimal gelation, indicated that gelation can be reduced or eliminated by the use of pharmaceutically acceptable co-solvents. Finally, salmon calcitonin (50 mg/mL) was formulated in 100% DMSO and delivered from a DUROS implant over 4 months. Delivery at a target dose of 18 microg/day calcitonin at 37 degrees C was confirmed.     

Steroids and steroidases XX (1). Aggregation in aqueous solution of steroids with stigmastane type C-17 side chains and its influence on their enzymic transformations

The possibility that aggregation of hydrophobic plant sterols such as β-sitosterol in aqueous solution might be one of the factors operating against facile microbial degradation of their C-17 side chains has been investigated using Δ⁵-3-ketostigmastane derivatives as model substrates. Analysis by an acid-catalyzed isomerization kinetic procedure has confirmed that they are severely aggregated even in dilute aqueous solution and that addition of large proportions of an organic solvent such as methanol is required to effect complete solvation of the steroids. However, oxygenation of the stigmastane side chain causes dramatic reductions in their aggregation tendencies. Using the Δ⁵→ Δ⁴-3-ketosteroid isomerase of $\text{P. testosteroni}$ as a representative enzyme of microbial steroid metabolism, it has been shown that although the degrees of solvation which can be achieved with unmodified stigmastane-type side chains are insufficient for enzymic isomerization to occur, the 22,23-epoxide or -diol derivatives do become good substrates when they are only marginally disaggregated. The overall results indicate that aggregation in aqueous solution of plant sterols is an important factor to be taken into account when microbiological degradation of the C-17 group is desired and that prior hydroxylation of the potential substrates should be beneficial.     

Effect of Dimethylsulfoxide on Hydrolysis of Lipase

To establish an industrially feasible reaction process, the effect of dimethylsulfoxide (DMSO) added to an aqueous solution on the hydrolysis of lipase was investigated using fluorescent substrates. Several lipases from microorganisms were improved in their hydrolysis activities against 4-methylumbelliferyl oleate by DMSO. Variation was found in the effect of DMSO depending on the species of lipase. After the high stability of the lipase from Pseudomonas fluorescens in DMSO solution was confirmed, hydrolysis by this lipase of four acyl-4-methylumbelliferones was studied kinetically at different DMSO concentrations. DMSO added to an aqueous solution increased the V_max of this lipase for a substrate with strong hydrophobicity, and decreased that value for a substrate with an opposite property. On the other hand, DMSO had a very small effect on K_m for each substrate. A fluorometric study suggested that DMSO induced a change of the chemical environment that surrounded tryptophan residues of the lipase. Such conformational change would be one of the causes of the DMSO-induced alteration of its reactive property. These results suggest that the addition of DMSO may be a novel method of ‘solvent engineering’ of this enzyme.     

Simultaneous assessment of Asp isomerization and Asn deamidation in recombinant antibodies by LC-MS following incubation at elevated temperatures

The degradation of proteins by asparagine deamidation and aspartate isomerization is one of several chemical degradation pathways for recombinant antibodies. In this study, we have identified two solvent accessible degradation sites (light chain aspartate-56 and heavy chain aspartate-99/101) in the complementary-determining regions of a recombinant IgG1 antibody susceptible to isomerization under elevated temperature conditions. For both hot-spots, the degree of isomerization was found to be significantly higher than the deamidation of asparagine-(387, 392, 393) in the conserved CH3 region, which has been identified as being solvent accessible and sensitive to chemical degradation in previous studies. In order to reduce the time for simultaneous identification and functional evaluation of potential asparagine deamidation and aspartate isomerization sites, a test system employing accelerated temperature conditions and proteolytic peptide mapping combined with quantitative UPLC-MS was developed. This method occupies the formulation buffer system histidine/HCl (20 mM; pH 6.0) for denaturation/reduction/digestion and eliminates the alkylation step. The achieved degree of asparagine deamidation and aspartate isomerization was adequate to identify the functional consequence by binding studies. In summary, the here presented approach greatly facilitates the evaluation of fermentation, purification, formulation, and storage conditions on antibody asparagine deamidation and aspartate isomerization by monitoring susceptible marker peptides located in the complementary-determining regions of recombinant antibodies.     

Mechanisms of glucagon degradation at alkaline pH

Glucagon is unstable and undergoes degradation and aggregation in aqueous solution. For this reason, its use in portable pumps for closed loop management of diabetes is limited to very short periods. In this study, we sought to identify the degradation mechanisms and the bioactivity of specific degradation products. We studied degradation in the alkaline range, a range at which aggregation is minimized. Native glucagon and analogs identical to glucagon degradation products were synthesized. To quantify biological activity in glucagon and in the degradation peptides, a protein kinase A-based bioassay was used. Aged, fresh, and modified peptides were analyzed by liquid chromatography with mass spectrometry (LCMS). Oxidation of glucagon at the Met residue was common but did not reduce bioactivity. Deamidation and isomerization were also common and were more prevalent at pH 10 than 9. The biological effects of deamidation and isomerization were unpredictable; deamidation at some sites did not reduce bioactivity. Deamidation of Gln 3, isomerization of Asp 9, and deamidation with isomerization at Asn 28 all caused marked potency loss. Studies with molecular-weight-cutoff membranes and LCMS revealed much greater fibrillation at pH 9 than 10. Further work is necessary to determine formulations of glucagon that minimize degradation and fibrillation.     

Stabilization of tubulin by deuterium oxide

Tubulin is an unstable protein when stored in solution and loses its ability to form microtubules rapidly. We have found that D2O stabilizes the protein against inactivation at both 4 and 37 degrees C. In H2O-based buffer, tubulin was completely inactivated after 40 h at 4 degrees C, but in buffer prepared in D2O, no activity was lost after 54 h. Tubulin was completely inactivated at 37 degrees C in 8 h in H2O buffer, but only 20% of the activity was lost in D2O buffer. Tubulin also lost its colchicine binding activity at a slower rate in D2O. The deuterated solvent retarded an aggregation process that occurs during incubation at both temperatures. Inactivation in H2O buffer was partially reversed by transferring the protein to D2O buffer; however, aggregation was not reversed. The level of binding of BisANS, a probe of exposed hydrophobic sites in proteins, increases during the inactivation of tubulin. In D2O, the rate of this increase is slowed somewhat. We propose that D2O has its stabilizing effect on a conformational step or steps that involve the disruption of hydrophobic forces. The conformational change is followed by an aggregation process that cannot be reversed by D2O. As reported previously [Ito, T., and Sato, H. (1984) Biochim. Biophys. Acta 800, 21-27], we found that D2O stimulates the formation of microtubules from tubulin. We also observed that the products of assembly in D2O/8% DMSO consisted of a high percentage of ribbon structures and incompletely folded microtubules. When these polymers were disassembled and reassembled in H2O/8% DMSO, the products were microtubules. We suggest that the combination of D2O and DMSO, both stimulators of tubulin assembly, leads to the rapid production of nuclei that lead to the formation of ribbon structures rather than microtubules.     

Quality assessment and analysis of Biogen Idec compound library

A subset of the compound repository for lead identification at Biogen Idec was characterized for its chemical stability over a 3-year period. Compounds were stored at 4 degrees C as 10 mM DMSO stocks, and a small subset of compounds was stored as lyophilized dry films. Compound integrity of 470 discrete compounds (Compound Set I) and 1917 combinatorial chemistry-derived compounds (Compound Set II) was evaluated by liquid chromatography/mass spectrometry from the time of acquisition into the library collection and after 3 years of storage. Loss of compound integrity over the 3 years of storage was observed across the 2 subsets tested. Of Compound Set I, 63% of samples retained > 80% purity, whereas 57% of samples from Compound Set II had purity greater than 60%. The stability of the lyophilized samples was superior to the samples stored as DMSO solution. Although storage at 4 degrees C as DMSO solution was adequate for the majority of compounds, the authors observed and quantified the level of degradation within the compound collection. Their study provides general insight into compound storage and selection of library subsets for future lead identification activities.     

Hydrolases in intracellular compartments of rat liver cells. Evidence for selective activation and/or delivery.

We used perfused rat livers to investigate the role of endosomes versus lysosomes in the hydrolysis of endocytosed material. When perfusions were performed at 37 degrees C with 125I-asialoorosomucoid, 125I-galactosylated albumin, or 125I-mannosylated albumin, there was a 15-min lag before trichloroacetic acid-soluble degradation products were detected. Furthermore, no hydrolysis was detected at 16 degrees C, indicating that there was no significant prelysosomal degradation of these proteins. Since detection by this method depends on extensive hydrolysis, we subsequently used three small synthetic molecules from which fluorescent products are generated by a single cleavage. These were 4-methylumbelliferyl sulfate, 4-methylumbelliferyl phosphate, and 4-methylumbelliferyl-beta-D-glucosaminide, which are substrates for aryl sulfatase, acid phosphatase, and beta-hexosaminidase, respectively. Using the first two compounds, hydrolysis was detected after 3 min at 37 degrees C and still occurred, albeit to a reduced extent, at 16 and 4 degrees C. This indicates that aryl sulfatase and acid phosphatase are active prelysosomally. We found a different result with 4-methylumbelliferyl-beta-D-glucosaminide. At 37 degrees C, there was a greater than 15-min lag before hydrolysis products were measured; furthermore, hydrolysis ceased at 16 degrees C, indicating that beta-hexosaminidase is active lysosomally. Taken together, these findings show that there is selective activation and/or delivery of hydrolases along the endocytic pathway.     

Stability of sonicated aqueous suspensions of phospholipids under air.

The stability of phospholipids in liposomal aqueous suspension against oxidative degradation in air was investigated using spectrophotometric indices, glutathione peroxidase reactivity and thin layer chromatography. Zwitterionic phospholipid was found to be susceptible to degradation via oxidation of polyunsaturated hydrocarbon chains and ester hydrolysis, producing oxidized lysophosphatide and free fatty acid derivatives. These products were characterized as hydroperoxides based on their reactivity with the selenium-dependent glutathione peroxidase isolated from human erythrocytes. Lecithin in Tris buffer was more resistant to hydrolysis than in water. The sonication of 8.0 mM of soybean phosphatidylcholine (SB-PC) suspension in 0.1 M Tris (pH 7.5) in the presence of air produced relatively high concentration of conjugated diene hydroperoxide, but a small amount of hydrolyzed products. Anionic phospholipids, such as egg-phosphatidylglycerol (egg-PG), demonstrated higher resistance to air oxidation than the zwitterionic lecithin, but its oxidation was promoted by sonication.     

Racemization and hydrolysis of tropic acid alkaloids in the presence of cyclodextrins

Because of the constantly increasing demand for optically pure drugs it is of great importance to elucidate factors affecting stereochemistry, in order to provide a stable formulation with a high chiral quality of the desired isomer. Therefore, the effects of cyclodextrins (CyDs) and their alkylated and hydroxyalkylated derivatives on racemization and hydrolysis of (?)-(S)-hyoscyamine and (?)-(S)-scopolamine were examined kinetically and spectroscopically (NMR). Direct methods, based on a chiral and achiral chromatographic phase system, were used to determine their degradation products and enantiomer composition during stability tests. All different CyDs, except α-CyD, retarded racemization and hydrolysis. The inclusion of the drug substances in CyDs inhibits the attack of hydroxyl ions and/or water molecules and thus retards the racemization and hydrolysis. The racemization of the tropic acid alkaloids is dependent on the pH and temperature. NMR studies were used to evidence the formation of a soluble 1:1 complex in aqueous solution. © 1993 Wiley-Liss, Inc.     

Degradation kinetics and mechanism of RH1, a new anti-tumor agent: A technical note

Summary and Conclusions  The degradation of RH1 in aqueous solution is found to be both acid and base catalyzed. The maximum stability is obtained in neutral pH but still degrades by 10% (t₉₀) after just 1 week. The stability profile at pH 5 was done, and 4 major degradation products were observed in acid solutions. LC-MS was performed and the molecular weights determined, from which a degradation mechanism was proposed. Degradation products I, II, and III form 2 isomers each depending on which aziridine group is hydrolyzed. No significant effect of light or the presence of antioxidants was observed, indicating that photodegradation and oxidation are not likely degradation reactions. Published: March 2, 2007     

Stabilization of a recombinant human epidermal growth factor parenteral formulation through freeze-drying

Development studies were performed to design a pharmaceutical composition that allows the stabilization of a parenteral rhEGF formulation in a lyophilized dosage form. Unannealed and annealed drying protocols were tested for excipients screening. Freeze-dry microscopy was used as criterion for excipients and formulation selection; as well as to define freeze-drying parameters. Excipients screening were evaluated through their effect on freeze-drying recovery and dried product stability at 50 °C by using a comprehensive set of analytical techniques assessing the chemical stability, protein conformation and bioactivity. The highest stability of rhEGF during freeze-drying was achieved by the addition of sucrose or trehalose. After storing the dried product at 50 °C, the highest stability was achieved by the addition of dextran, sucrose, trehalose or raffinose. The selected formulation mixture of sucrose and dextran could prevent protein degradation during the freeze-drying and delivery processes. The degradation rate assessed by RP-HPLC could decrease 100 times at 37 °C and 70 times at 50 °C in dried with respect to aqueous formulation. These results indicate that the freeze-dried formulation represents an appropriate technical solution for stabilizing rhEGF.     

Oxidation of tissue polysaccharides by periodic acid in dimethyl sulfoxide and its anhydrous and aqueous mixtures.

Periodic acid (1% w/v) solvated by anhydrous dimethyl sulfoxide (DMSO) readily induced a strong Schiff reaction in a variety of structures containing polysaccharides, but not glycogen. With the increasing amounts of water added to DMSO, glycogen was also oxidized, while the selective localization of other polysaccharides remained unimpaired. Periodate, solvated in the anhydrous acetic acid-DMSO mixture, rapidly induced concomitant oxidation of nucin and glycogen-containing structures. Sodium bisulfite addition derivatives of carbonyls, induced by periodate oxidation in DMSO, were stained meta- and orthochromatically with toluidine blue at controlled pH. Certain metachromatic tissue components were strongly birefringent in polarized light in contrast to the identical structures oxidized by aqueous periodate. Marked differences in staining reactions elicited in identical structures by periodate in DMSO as compared with aqueous periodate suggest that DMSO-periodate method considerably enhances the range of histochemical oxidations by periodate.     

Solvent assistance in regiospecific disulfide formation in dimethylsulfoxide

This paper describes a convenient oxidative refolding method that exploits the dual property of dimethylsulfoxide (DMSO) as an oxidant and a solvent 'chaperon' in assisting disulfide formation in peptides. Synthetic peptides with preferred secondary structures were used as models. For -sheet peptides, an active fragment of fibroblast growth factor containing the tetrapeptide Arg-Ser-Arg-Arg at a reverse turn was used. A disulfide scan consisting of 16 analogs is designed in which different pairs of amino acids on the antiparallel -sheets flanking the active determinants are replaced with cysteine. DMSO in aqueous buffer at pH 6 or 8 was found to minimize aggregation due to -sheet formation in all 16 -stranded peptides and provided monocyclic disulfide peptides within 7 h. In contrast, air oxidation required a significantly longer duration for completion under similar conditions, and only 8 of 16 peptides formed intramolecular disulfides. Rate accelerations at pH 8 were found in exo-disulfide formation involving peptides with amino terminal cysteine, irrespective of oxidation conditions. The exo-disulfide effect in accelerating disulfide formation may be useful for regiospecific disulfide formation. For -helix peptides, the two-disulfide endothelin (ET) was used as a model. DMSO in combination with trifluoroethanol (TFE) was found to favor the desired bicyclic 1,4-disulfide bridged ET (1,4-ET) over the incorrectly folded 1,3-ET. Under aqueous conditions at pH 5–11, 1,4-ET to 1,3-ET was formed in the ratio of approximately 3:1, while the use of DMSO and TFE increased the ratio to 11:1. This solvent combination may stabilize an -helical stretch found in ET and contribute to enhanced selectivity. Thus, our results show that DMSO in disulfide formation in an aqueous or helix-promoting solution may serve as an oxidant and a 'chaperon' solvent system to provide regiospecificity for oxidative disulfide formation.     

Solvent assistance in regiospecific disulfide formation in dimethylsulfoxide

Summary This paper describes a convenient oxidative refolding method that exploits the dual property of dimethylsulfoxide (DMSO) as an oxidant and a solvent ‘chaperon’ in assisting disulfide formation in peptides. Synthetic peptides with preferred secondary structures were used as models. For β-sheet peptides, an active fragment of fibroblast growth factor containing the tetrapeptide Arg-Ser-Arg-Arg at a reverse turn was used. A disulfide scan consisting of 16 analogs is designed in which different pairs of amino acids on the antiparallel β-sheets flanking the active determinants are replaced with cysteine. DMSO in aqueous buffer at pH 6 or 8 was found to minimize aggregation due to β-sheet formation in all 16 β-stranded peptides and provided monocyclic disulfide peptides within 7 h. In contrast, air oxidation required a significantly longer duration for completion under similar conditions, and only 8 of 16 peptides formed intramolecular disulfides. Rate accelerations at pH 8 were found in exo-disulfide formation involving peptides with amino terminal cysteine, irrespective of oxidation conditions. The exo-disulfide effect in accelerating disulfide formation may be useful for regiospecific disulfide formation. For α-helix peptides, the twodisulfide endothelin (ET) was used as a model. DMSO in combination with trifluoroethanol (TFE) was found to favor the desired bicyclic 1,4-disulfide bridged ET (1,4-ET) over the incorrectly folded 1,3-ET. Under aqueous conditions at pH 5–11, 1,4-ET to 1,3-ET was formed in the ratio of approximately 3:1, while the use of DMSO and TFE increased the ratio to 11:1. This solvent combination may stabilize an α-helical stretch found in ET and contribute to enhanced selectivity. Thus, our results show that DMSO in disulfide formation in an aqueous or helix-promoting solution may serve as an oxidant and a ‘chaperon’ solvent system to provide regiospecificity for oxidative disulfide formation.     

The effect of solvent environment on the conformation and stability of human polyclonal IgG in solution.

Stability of therapeutic IgG preparations is an important issue as adequate efficacy and safety has to be ensured throughout a long shelf life. To this end, denaturation and aggregation have to be avoided. In many cases sugars are applied for stabilizing IgG in relatively high concentration (5-10%). However, certain sugars (sucrose, maltose) are responsible for adverse effects including renal failure. In this work we reassessed the effect of pH and stabilizers to optimize the solvent environment and minimize the amount of additives without endangering quality and stability. Since both biological function and aggregation depend on the conformational properties of individual IgG molecules, two sensitive and rapid physical methods were introduced to assess conformational changes and structural stability as a function of pH and addition of standard stabilizers. It was observed that the conformational stability decreases with decreasing pH, while the resistance against aggregation improves. The optimum pH range for storage is 5.0-6.0, as a compromise between conformational stability and the tendency for oligomerization. Intriguingly, additives in physiologically acceptable concentration have no effect on the thermal stability of IgG. On the other hand, glucose or sorbitol, even at a concentration as low as 1%, have significant effect on the tertiary structure as revealed by near-UV-CD spectroscopy, reflecting changes in the environment of aromatic side-chains. Although, 0.3% leucine does not increase conformational stability, it decreases the aggregation tendency even more efficiently than 1% glucose or sorbitol. Both pH and storage temperature are decisive factors for the long-term stability of IgG solutions. An increase in the dimer content was observed upon storage at 5 degrees C which was partly reverted upon incubation at 37 degrees C. Storage at temperatures higher than 5 degrees C may help to maintain an optimal proportion of dimers. Regarding the known side effects, and their limited stabilizing capacity at low concentration, it is advisable to omit sugars at intravenous immunoglobulin (IVIG) formulation. Hydrophobic amino acids give promising alternatives.     

Effect of dimethylsulfoxide on hydrolysis of lipase.

To establish an industrially feasible reaction process, the effect of dimethylsulfoxide (DMSO) added to an aqueous solution on the hydrolysis of lipase was investigated using fluorescent substrates. Several lipases from microorganisms were improved in their hydrolysis activities against 4-methylumbelliferyl oleate by DMSO. Variation was found in the effect of DMSO depending on the species of lipase. After the high stability of the lipase from Pseudomonas fluorescens in DMSO solution was confirmed, hydrolysis by this lipase of four acyl-4-methylumbelliferones was studied kinetically at different DMSO concentrations. DMSO added to an aqueous solution increased the Vmax of this lipase for a substrate with strong hydrophobicity, and decreased that value for a substrate with an opposite property. On the other hand, DMSO had a very small effect on Km for each substrate. A fluorometric study suggested that DMSO induced a change of the chemical environment that surrounded tryptophan residues of the lipase. Such conformational change would be one of the causes of the DMSO-induced alteration of its reactive property. These results suggest that the addition of DMSO may be a novel method of 'solvent engineering' of this enzyme.     

Degradation of aspartic acid and asparagine residues in human growth hormone-releasing factor.

Products of the degradation of human growth hormone-releasing factor (GRF) in aqueous solutions (15-200 microM) have been isolated and fully characterized. The cleavage product, GRF(4-44)-NH2, and the isomerization product, [beta-Asp3]GRF(1-44)-NH2, from the degradation of GRF(1-44)-NH2 in acidic solution and the corresponding products, GRF(4-29)-NH2 and [beta-Asp3]GRF(1-29)-NH2, from the degradation of GRF(1-29)-NH2 have been isolated and characterized. The products, [beta-Asp8]GRF(1-44)-NH2 and [Asp8]GRF(1-44)-NH2, from the deamidation of GRF(1-44)-NH2 at pH 8.0 and the corresponding products, [beta-Asp8]GRF(1-29)-NH2 and [Asp8]GRF(1-29)-NH2, from the deamidation of GRF(1-29)-NH2 have been isolated and characterized. All the degradation products of GRF(1-44)-NH2 and GRF(1-29)-NH2 were evaluated for biological activity and found to have much lower in vitro potencies than the parent peptides. Degradation occurs at Asp3 and Asn8 and the kinetics of these various transformations versus pH and temperature have been studied. GRF is most stable at pH 4-5. At pH below the pKa of the Asp3 side-chain (pH less than 4), cleavage at Asp3-Ala4 is the major route of degradation. For pH greater than 4, isomerization of Asp3 to beta-Asp3 (iso-Asp3) predominates. The rates of cleavage and isomerization are simple first order and vary with pH, independent of buffer concentration, such that the protonated (COOH) form of Asp3 undergoes cleavage while the ionized (COO-) form isomerizes. The more rapid deamidation of Asn8 to generate beta-Asp8 and Asp8 in about a 4:1 ratio, presumably via a cyclic imide intermediate, occurs at pH greater than or equal to 5 and is general base-catalyzed. Evidence was also obtained for direct hydrolysis of protonated Asn8 in GRF(1-29)-NH2 at pH less than or equal to 2 to give exclusively [Asp8]GRF(1-29)-NH2. The deamidation of Asn8 in GRF(1-29)-NH2 at pH 8.0, 22-55 degrees C, is relatively insensitive to temperature for T less than 37 degrees C, possibly due to conformational constraints. Asp25 and Asn35 are sterically, conformationally, or otherwise hindered with respect to these changes as no degradation at these sites was observed under the conditions employed.     

Molecular structure,solution chemistry and biological properties of the novel [ImH][trans-IrCl(4)(Im)(DMSO)], (I) and of the orange form of [(DMSO)(2)H][trans-IrCl(4)(DMSO)(2)], (II), complexes

The new iridium(III) complex, imidazolium[trans(DMSO,imidazole)tetrachloroiridate(III)], (I) (DMSO=dimethyl sulfoxide), and the orange form of [(DMSO)(2)H][trans(DMSO)(2)tetrachloroiridate(III)], (II) have been prepared and characterized, both in the solid state and in solution, by X-ray diffraction and by various physicochemical techniques. Single crystal X-ray diffraction studies point out that complex (II) is isomorphous to the ruthenium(III) analogue, [(DMSO)(2)H][trans-RuCl(4)(DMSO)(2)], (III). Crystallographic data are the following: a=16.028(2) A, b=24.699(3) A, c=8.262(1) A, in space group Pbca (Z=8) for (imidazolium)[trans(DMSO,imidazole)tetrachloroiridate(III)], (I); and a=9.189(2) A, b=16.511(4) A, c=14.028(3) A, beta=100.82(2) degrees in space group P2/n (Z=4) for [(DMSO)(2)H][trans(DMSO)(2)tetrachloroiridate(III)], (II). Visible absorption spectra show that both complexes are stable for several days, at pH 7.4, at room temperature. No significant chloride hydrolysis is observed, even at high temperature (70 degrees C), over 24 h. The extreme stability of these iridium(III) complexes within a physiological buffer was further assessed by (1)H NMR; in addition, cyclic voltammetry measurements evidenced a high stability of the oxidation state +3. Preliminary biological studies show that both complexes do not bind appreciably bovine serum albumin nor inhibit significantly the proliferation of representative human tumor cell lines, suggesting that hydrolysis of coordinated chlorides is a crucial feature for the biological properties and the antitumor activity of the parent ruthenium(III) complexes.     

The fate of bilirubin-IXalpha glucuronide in cholestasis and during storage in vitro. Intramolecular rearrangement to positional isomers of glucuronic acid.

1. In aqueous solution above pH7 bilirubin-IXalpha 1-O-acylglucuronide rapidly isomerizes to the non-C-1 glucuronides by sequential migration of the bilirubin acyl group from position 1 to positions 2, 3 and 4 of the sugar moiety. The transformations are enhanced by increasing the pH. Compared with the rates at 37 degrees C the transformations are rather slow at 0 degrees C. Virtually complete inhibition is observed at values below pH6. The isomerization at 25 degrees C and pH 7.4 is not affected by the presence in the solutions of a molar excess of human serum albumin. 2. Isomerization in bile kept at 37 degrees C at pH7.7-7.8 is probably non-enzymic, as the rates of change are similar to those observed under comparable conditions for aqueous solutions of glucuronides of bilirubin-1Xalpha and of azodipyrrole. 3. Analysis without delay of normal biles of man and rats collected at 0 degrees C over a maximum period of 10 min shows that the bilirubin-IXalpha mono- and di-glucuronides consist exclusively of the 1-O-acyl isomers. 4. The mixtures of the four positional isomers of bilirubin-IXalpha glucuronide found in freshly collected biles of man and rats with cholestasis probably originate from initially synthesized 1-O-acylglucuronide by the same mechanism of sequential migration as has been observed in aqueous solutions of conjugated bilirubin-IXalpha.