Involvement of lipid oxidation products in the formation of fluorescent and cross-linked proteins

Age-related fluorescent and cross-linked proteins increase with lipid oxidation of tissues. The fluorophores and cross-links have been considered to be conjugated Schiff bases between amino groups of proteins and malonaldehyde. Our recent studies showed that the fluorophores produced in the in vitro reaction of proteins with malonaldehyde are 1,4-dihydropyridine-3,5-dicarbaldehydes, whose fluorescence characteristics are similar to but not always the same as those of the age-related fluorescent substances, and that the cross-linking is due to less fluorescent conjugated Schiff bases. The in vitro reaction of proteins with oxidized lipids produces fluorescent and cross-linked proteins similar to those in the aging cells or tissues. Monofunctional aldehydes such as alkanals, alk-2-enals and alka-2,4-dienals can also participate in the formation of the fluorophores and cross-links. The fluorescent substances produced from the reaction of primary amines or proteins with these aldehydes showed spectra close to those of the age-related fluorescent substances.     

Methods for determination of aldehydic lipid peroxidation products

A complex pattern of aldehydes (alkanals, 2-alkenals, 2,4-alkadienals, 4-hydroxyalkenals) is generated by peroxidizing biological samples. Several methods based on HPLC or GC-MS have been developed to qualitatively and quantitatively measure the aldehydes in tissues, cells and cell fractions exposed to various pro-oxidative stimuli. 4-Hydroxynonenal, hexanal and propanal are, besides malonaldehyde, the most abundant aldehydes formed. The high sensitivity of the methods also allows the measurement of physiological aldehyde levels in plasma or low density lipoproteins and this could be of great importance for in vivo studies.     

Autoxidation of human low density lipoprotein: loss of polyunsaturated fatty acids and vitamin E and generation of aldehydes

The alteration of structural and biological properties of human plasma low density lipoprotein (LDL) exposed to oxidative conditions is in part ascribed to lipid peroxidation. The objective of this investigation was to measure quantitatively several parameters in oxidizing LDL indicative for lipid peroxidation. Exposure of freshly prepared EDTA-free LDL to an oxygen-saturated buffer led to a complete depletion of alpha- and gamma-tocopherol within 6 hr, thereafter lipid peroxidation commenced as indicated by the kinetics of the loss of linoleic (18:2) and arachidonic (20:4) acids, the formation of aldehydic lipid peroxidation products and fluorescent apoB. Within 24 hr of oxidation, on average 79 nmol of 18:2 (initial 345) and 12.8 nmol of 20.4 (initial 25.6) were oxidized per mg of LDL and the sample contained in total 7.1 nmol of aldehydes with the following molar distribution: 36.6% malonaldehyde, 25% hexanal, 8.9% propanal, 8.2% 4-hydroxynonenal, 7.6% butanal, 4.1% 2.4-heptadienal, 3.4% pentanal, 3.4% 4-hydroxyhexenal, and 2.5% 4-hydroxyoctenal. Malonaldehyde was predominantly (93%) in the aqueous phase, whereas the other aldehydes remained mostly (34-98%) within the LDL particle, where the total aldehyde concentration was in the range of 12 mM. Oxidized LDL exhibited a 1.6-fold enhanced electrophoretic mobility. Similarily, native LDL incubated for 5 hr with aldehydes showed increased electrophoretic mobility. At equal concentrations (5 mM) 4-hydroxynonenal was most effective, followed by 2,4-heptadienal, hexanal, and malonaldehyde. This study reports for the first time the rate and extent of the change of LDL constituents occurring during lipid peroxidation.     

Chemistry and biochemistry of 4-hydroxynonenal, malonaldehyde and related aldehydes

Lipid peroxidation often occurs in response to oxidative stress, and a great diversity of aldehydes are formed when lipid hydroperoxides break down in biological systems. Some of these aldehydes are highly reactive and may be considered as second toxic messengers which disseminate and augment initial free radical events. The aldehydes most intensively studied so far are 4-hydroxynonenal, 4-hydroxyhexenal, and malonaldehyde. The purpose of this review is to provide a comprehensive summary on the chemical properties of these aldehydes, the mechanisms of their formation and their occurrence in biological systems and methods for their determination. We will also review the reactions of 4-hydroxyalkenals and malonaldehyde with biomolecules (amino acids, proteins, nucleic acid bases), their metabolism in isolated cells and excretion in whole animals, as well as the many types of biological activities described so far, including cytotoxicity, genotoxicity, chemotactic activity, and effects on cell proliferation and gene expression. Structurally related compounds, such as acrolein, crotonaldehyde, and other 2-alkenals are also briefly discussed, since they have some properties in common with 4-hydroxyalkenals.     

Erythrocyte storage increases rates of NO and nitrite scavenging: implications for transfusion-related toxicity

Storage of erythrocytes in blood banks is associated with biochemical and morphological changes to RBCs (red blood cells). It has been suggested that these changes have potential negative clinical effects characterized by inflammation and microcirculatory dysfunction which add to other transfusion-related toxicities. However, the mechanisms linking RBC storage and toxicity remain unclear. In the present study we tested the hypothesis that storage of leucodepleted RBCs results in cells that inhibit NO (nitric oxide) signalling more so than younger cells. Using competition kinetic analyses and protocols that minimized contributions from haemolysis or microparticles, our data indicate that the consumption rates of NO increased ~40-fold and NO-dependent vasodilation was inhibited 2-4-fold comparing 42-day-old with 0-day-old RBCs. These results are probably due to the formation of smaller RBCs with increased surface area: volume as a consequence of membrane loss during storage. The potential for older RBCs to affect NO formation via deoxygenated RBC-mediated nitrite reduction was also tested. RBC storage did not affect deoxygenated RBC-dependent stimulation of nitrite-induced vasodilation. However, stored RBCs did increase the rates of nitrite oxidation to nitrate in vitro. Significant loss of whole-blood nitrite was also observed in stable trauma patients after transfusion with 1 RBC unit, with the decrease in nitrite occurring after transfusion with RBCs stored for >25?days, but not with younger RBCs. Collectively, these data suggest that increased rates of reactions between intact RBCs and NO and nitrite may contribute to mechanisms that lead to storage-lesion-related transfusion risk.     

DNA-damaging activity of biotic and xenobiotic aldehydes in Chinese hamster ovary cells

Alkaline elution was employed to study DNA damage in CHO-Kl cells treated with a series of biotic and xenobiotic aldehydes. DNA cross-linking was measured in terms of the reduction in the effect of methyl methanesulphonate on the kinetics of DNA elution and was observed in cells treated with formaldehyde, acetaldehyde, methylglyoxal and malonaldehyde. Propionaldehyde, valeraldehyde, hexanal and 4-hydroxynonenal produced DNA single-strand breaks, or lesions which were converted to breaks in alkali. Both types of DNA damage occurred in cells exposed to malealdehyde. These findings support the hypothesis of a carcinogenic effect of the aldehydic products (malonaldehyde, methylglyoxal, propionaldehyde, hexanal, 4-hydroxynonenal) released in biomembranes during lipid peroxidation.     

Separation and characterization of the aldehydic products of lipid peroxidation stimulated by carbon tetrachloride or ADP-iron in isolated rat hepatocytes and rat liver microsomal suspensions.

Carbonyl products were separated and identified in suspensions of rat liver microsomal fractions and in isolated hepatocytes, after stimulation of lipid peroxidation by incubation with the pro-oxidants CCl4 and ADP-iron. The carbonyl products were allowed to react with 2,4-dinitrophenylhydrazine, and the derivatives were extracted and separated by t.l.c. into three zones of non-polar materials, and one fraction of polar derivatives that remained at the origin. Separation of the individual non-polar hydrazones in each zone by h.p.l.c. demonstrated that zone I prepared from microsomal fraction or hepatocytes incubated with CCl4 or ADP-iron contained mainly 4-hydroxyhex-2-enal, 4-hydroxynon-2-enal and 4-hydroxynona-2,5-dienal. Zone III consisted mainly of the alkanals propanal, pentanal and hexanal, the 2-alkenals propenal, pent-2-enal, hex-2-enal, hept-2-enal, oct-2-enal and non-2-enal, the ketones butanone, pentan-2-one and pentan-3-one, and deca-2,4-dienal. Incubation of a microsomal fraction with ADP-iron was much more effective in producing malonaldehyde and other carbonyl products than an incubation with CCl4. Despite such quantitative differences, there were no obvious qualitative differences in the h.p.l.c. spectra obtained from zones I and III. However, the stoichiometric evaluation of fatty acid loss and the production of malonaldehyde and other carbonyls suggests that the pathways of lipid peroxidation triggered by CCl4 and ADP-iron are different. The accumulation of carbonyl products of lipid peroxidation in isolated hepatocytes is strongly affected by their metabolism; in particular, 4-hydroxyalkenals were found to be metabolized very rapidly. Nonetheless, both CCl4 and ADP-iron produced stimulation in the production of malonaldehyde and non-polar carbonyl production. After incubation of rat hepatocytes with CCl4 or ADP-iron it was found that approx. 50% of the total amount of non-polar carbonyls produced during incubation escaped into the external medium. This was not leakage from dead cells, as 90-95% of the hepatocytes had retained their integrity at the end of the incubation. Release of carbonyl products from cells stimulated to undergo lipid peroxidation may be a mechanism for spreading an initial intracellular disturbance to affect critical targets outside the parent cell.     

Identification by gas-liquid chromatography-mass spectrometry of low-molecular-weight products from the aqueous alkaline degradation of cellulose

Low-molecular-weight products from the degradation of pure cellulose in 0.3–0.65M sodium carbonate or hydrogencarbonate at 300° have been identified by g.l.c-m.s. Both the aqueous residual phase and the floating-oil product phase were examined, and contained essentially the same compounds, which were further characterized by the trifluoroacetyl derivatives. They consisted primarily of unsaturated aliphatic and alicyclic hydrocarbons, aldehydes, ketones, alcohols, and furans. Specifically identified were cyclopentanone, cyclohexanone, phenol, cresols, 2-ethyl- cyclopentanone, 2- or 3-methylcyclopentanone, 2,5-dimethyl-2- cyclopentenone, acrolein, 2,5-dimethyl-2,4-hexadiene, and octene. Probably present were 2,4-dimethylfuran, 2,5-diethylfuran, ethylmethylfuran, 4-octyne, and decyne. The formation of these compounds demonstrates not only the degradation of cellulose but the resynthesis of molecules with carbon-chain lengths greater than 6 atoms.     

Detection of 4-hydroxynonenal and other lipid peroxidation products in the liver of bromobenzene-poisoned mice

Lipid peroxidation in cellular membranes leads to the formation of toxic aldehydes. One product provided with particular reactivity has been identified as 4-hydroxynonenal and thoroughly studied as one of the possible mediators of the cellular injury induced by pro-oxidants. In the present study we have searched for the presence of 4-hydroxynonenal and other lipid peroxidation products in the liver of bromobenzene-poisoned mice, since under this experimental condition the level of lipid peroxidation is much greater than in the case of CCl4 or BrCCl3 hepatotoxicity. 4-Hydroxynonenal was looked for in liver extracts as either free aldehyde or its 2,4-dinitrophenylhydrazone derivative. In both cases, by means of thin-layer chromatography (TLC) and high-pressure liquid chromatography, a well resolved peak corresponding to the respective standards (free aldehyde or 2,4-dinitrophenylhydrazone derivative) was obtained. Total carbonyls present in the liver of intoxicated animals were detected as 2,4-dinitrophenylhydrazone derivatives. The hydrazones were pre-separated by TLC into three fractions according to different polarity (polar, non-polar, fraction I, and non-polar, fraction II). The amounts of carbonyls present in each fraction were determined by ultraviolet-visible spectroscopy. 'Non-polar carbonyls, fraction II' were further fractionated by TLC. The fraction containing alkanals and alk-2-enals was analyzed by high-pressure liquid chromatography and several aldehydes were identified. In addition, protein bound carbonyls were determined in the liver of bromobenzene-treated mice. The biological implications of the finding of 4-hydroxynonenal and other carbonyls in vivo in an experimental model of hepatotoxicity are discussed.     

Enhancing the in vitro and in vivo detection of aneuploidy by fluorescence in situ hybridization with the use of bromodeoxyuridine as a proliferation marker

alpha,beta-Unsaturated aldehydes are ubiquitous environmental pollutants, important industrial chemicals, have mani-fold biological functions in plants and insects and are natural products in food. They are endogenously formed in animals and humans during lipid peroxidation and arachidonic acid oxidation and are genotoxic, mutagenic and carcinogenic. Crotonaldehyde and 2-hexenal in food may contribute to general carcinogenicity in humans. The high bacterial toxicity of these compounds leads to problems in genotoxicity testing in bacterial systems. Recently, we have shown that using ethanol as solvent instead of dimethylsulfoxide (DMSO) results in an increase in the induction factors and the SOS-inducing potency of alpha,beta-unsaturated ketones in the SOS chromotest. Here, we demonstrate that utilization of ethanol as solvent also improves the testing of alpha,beta-unsaturated aldehydes. Five aldehydes out of nine tested were clearly positive in the SOS chromotest according to the criteria of Quillardet, i.e. acrolein, crotonaldehyde, 2,4-hexadienal, 2-methylacrolein and 2-ethylacrolein, three further, 2-hexenal, 2-heptenal and 2-propylacrolein showed a dose dependent increase of the induction factors which was however lower than 1.5 times that of the background. Only 2-butylacrolein did not lead to an increase in the induction factors. With DMSO as solvent only the three aldehydes acrolein, crotonaldehyde and 2,4-hexadienal showed an increase in the induction factor, which was however lower than 1.5 that of the background. Utilization of ethanol allows to establish structure genotoxicity relationships for alpha,beta-unsaturated aldehydes in the SOS chromotest. Genotoxicity decreases with increasing degree of substitution. The decreasing genotoxicities can be explained (a) by increasing bacterial toxicity due to increasing lipophilicities of the higher substituted aldehydes and (b) by decreasing reactivity due to steric hindrance by the alkyl substituents.     

Inhibition by reactive aldehydes of superoxide anion radical production in stimulated human neutrophils

alpha,beta-Unsaturated aldehydes were investigated in vitro for their ability to inhibit superoxide anion radical (O2-.) production in stimulated human polymorphonuclear leukocytes (PMN). The aldehydes investigated were (i) trans-4-hydroxynonenal and malonaldehyde (MDA), two toxic lipid peroxidation products; (ii) acrolein and crotonaldehyde, two air pollutants derived from fossil fuel combustion; (iii) trans,trans-muconaldehyde, a putative hematotoxic benzene metabolite. Preincubation of PMN with reactive aldehydes followed by stimulation with the oxygen burst initiator phorbol myristate acetate (PMA) resulted in a dose-dependent inhibition of O2-. production. The concentration at which 50% inhibition (IC50) was observed was 21 microM for acrolein, 23 microM for trans,trans-muconaldehyde, 27 microM for trans-4-hydroxynonenal and 330 microM for crotonaldehyde. A similar inhibitory effect by these aldehydes was observed in digitonin- and concanavalin A-stimulated PMN. MDA inhibited O2-. production in PMA-stimulated PMN by 100% at 10(-2) M but gave no inhibition at 10(-3) M. The standard aldehyde propionaldehyde did not inhibit O2-. production at 10(-3)-10(-6) M. Preincubation of PMN with acrolein in the presence of cysteine completely protected against the inhibitory effect of this reactive aldehyde. The results indicate that the ability of toxic aldehydes to inhibit O2-. production in stimulated PMN correlates directly with their alkylation potential which is a function of the electrophilicity of the beta carbon.     

Antimutagenic effect of volatile decomposition products from thermally oxidized linoleate

The antimutagenic effect of volatile decomposition products from thermally oxidized linoleate on mutagenesis by UV irradiation was investigated in Escherichia coli B/r WP2. When added to an agar medium, these products greatly reduced the number of Trp+ revertants. The same antimutagenic effect was observed by acrolein, 2-hexenal, 2-heptenal, 2-nonenal and 2,4-decadienal; these unsaturated aldehydes were components of volatile products.     

The reaction of DNA with lipid oxidation products, metals and reducing agents

The interaction of lipid hydroperoxides and secondary oxidation products with DNA was investigated by evaluating the fluorescence formed in the presence of metals and reducing agents. We also investigated the effect of malonaldehyde, because it has been generally considered responsible for the formation of fluorescence with DNA. However, malonaldehyde usually has been estimated by the notoriously unspecific thiobarbituric acid test. At low concentration of oxidation products (1 mM), fluorescence formation required the presence of metals and ascorbic acid. In contrast, a positive thiobarbituric acid reaction was obtained with many lipid oxidation products without metals or ascorbic acid. Monohydroperoxides from autoxidized methyl linoleate and linolenate produced the highest level of fluorescence. Hydroperoxy epidioxides of linolenate and dihydroperoxides of linoleate and linolenate were among the most active secondary products in forming fluorescence with DNA. In contrast, malonaldehyde produced very little fluorescence under our conditions. The thiobarbituric acid values did not correlate with fluorescence formation. This study showed that, in our model reaction system, DNA forms fluorescent products by the breakdown of lipid oxidation products in the presence of metals and ascorbic acid into reactive materials other than malonaldehyde. Therefore, the importance of malonaldehyde in its crosslinking properties with DNA may have been exaggerated in the literature.     

Effect of auxins on the formation of ubiquinone by tobacco plant cells in suspension culture

Ubiquinone (UQ) formation in BY-2 tobacco cells was especially promoted by a high concentration of 2,4-D. 2,4,5-T, MCP and NAA also promoted UQ formation in these cells. The UQ content in the cells cultured at high concentrations of 2,4-D was higher than that of controls throughout the culture period. The addition of 2,4-D at an early period in cell growth was very effective in promoting UQ formation, but addition at the stationary phase was ineffective. Cell growth was improved by adding phosphate to the medium but UQ content was decreased. UQ content decreased slowly during subculturing, whereas cell growth recovered gradually.     

Methyl linoleate ozonide as a substrate for rat glutathione S-transferases: reaction pathway and isoenzyme selectivity

The 9,10-mono-ozonide of methyl linoleate was shown to be a substrate for rat hepatic cytosolic, rat lung cytosolic and rat hepatic microsomal glutathione S-transferases (GST). The activities of lung cytosol and liver microsomes with methyl linoleate ozonide (MLO) were found to be high relative to the activity demonstrated by liver cytosol, as compared with their respective activities towards 1-chloro-2,4-dinitrobenzene (CDNB). Only a slight catalytic activity towards the ozonide was noticed for rat lung microsomes. Isoenzyme 2-2 exhibited the highest specific activity (208 nmol/min/mg) when isoenzymes 1-1, 1-2, 2-2, 3-3, 3-4, 4-4 and 7-7 were compared. This isoenzyme accounts for approx. 25% of cytosolic GST protein in rat lung, while in rat liver it represents approx. 9%. This may partly explain the high activity towards the ozonide noticed for rat lung cytosol. No stable conjugates were formed as products of the reaction of MLO with glutathione; although two glutathione-conjugates were noticed on TLC, they were only formed as intermediate compounds. Coupling of an aldehyde dehydrogenase assay or a glutathione reductase assay to the GST-catalyzed conjugation, demonstrated that oxidized glutathione and aldehydes are formed as the major products in the reaction. To further confirm the formation of aldehydes, the products of the GST-catalyzed reaction were incubated with 2,4-dinitrophenylhydrazine, which resulted in hydrazone formation. In conclusion, the activity of the GST towards the ozonide of methyl linoleate is similar to their peroxidase activity with lipid hydroperoxides as substrates.     

Quantification of the histochemical staining for carbonyles and DNA using 3-hydroxy-2-naphthoic acid hydrazide and fast blue B

Fixed cells and tissues pretreated with 4-hydroxynonenal were used as models for the histochemical demonstration of protein bound aldehydic groups. The aldehydes were stained with both a modification of the 2,4-dinitrophenylhydrazine method (2,4-DNPH) and the optimized staining using 3-hydroxy-2-naphthoic acid hydrazide and Fast blue B (NAH-FB). A correlation has been found between the specific microphotometric mean integrated maximum absorbance values of cells and tissues stained with 2,4-DNPH and with NAH-FB (cc = 0.999). The maximum absorbance measured after 2,4-DNPH-staining (epsilon 367 = 21,000) were 1.893 +/- 0.072 (P less than 0.01) times that of NAH-FB-staining at 550 nm. Microphotometrically determined DNA-values of different cells stained with the NAH-FB-DNA-method correlated with those determined with methods of analytical biochemistry and published by other authors.     

Autoxidation of polyunsaturated esters in water: chemical structure and biological activity of the products

When polyunsaturated esters or fatty acids are dispersed for long periods in water in the presence of air, water-soluble substances are formed in great variety. Because these short-chain products are constantly eluted by the aqueous phase and are consequently not available for further reaction in the oil phase, many intermediates of classical autoxidation can be isolated and identified. The identification of several of these compounds is described. Some of the peroxidic and nonperoxidic autoxidation products show biochemical activity-in particular, inhibition of glycolysis and of respiration during incubation with tumor cells in vitro. Minimal inhibitory concentrations of pure, isolated products have been determined for Ehrlich ascites tumor cells. Synthetic short-chain (C(4)-C(10)) hydroxylated alpha,-unsaturated aldehydes have been shown to have this action and also to cause morphological changes in these cells which quickly lead to their death. Normal cells are not affected. Possible therapeutic use of these compounds in the treatment of malignant neoplasms is discussed.     

The effect of hypoxia on red blood cells of flounder: a morphologic and autoradiographic study

Flounders were maintained in water with low oxygen content (2.6–2.7 mg 1 ^{- 1}, 30% saturation) for 2, 6 and 24 h. Hypoxia enhanced the proliferation and differentiation process among juvenile red blood cells (RBCs) in the pronephros. It was accompanied by an increase in RBCs number in blood by up to 37% (P<0.01) 6 h after adaptation. The number of dividing mature RBCs in blood during the initial period of adaptation (2 h) was 2.5 times greater (P<0.001) than in the control group. It was shown ( in vitro ) that the serum contained factors stimulating division of mature RBCs in blood during adaptation to hypoxia.     

Biotransformations of oxaliplatin in rat blood in vitro

The partitioning and biotransformations of oxaliplatin [trans-l-1,2-diaminocyclohexaneoxalatoplatinum(II)] were investigated in the blood of Wistar male rats in vitro. [3-H]-Oxaliplatin was incubated with rat blood at 37 degrees C in 5% CO2 and the concentrations of all Pt complexes containing the [3-H]-dach carrier ligand were followed for up to 12 hours. Decay for both oxaliplatin and Pt-dach in the plasma ultrafiltrate (PUF) was rapid (t 1/2 oxaliplatin = 0.68 h and t 1/2 for Pt-dach in the PUF = 0.85 h). After 9 hours, the concentration of oxaliplatin fell below the detection limit. By 4 hours, the PUF-Pt-dach reached a plateau, which was 12% of total Pt-dach. The binding of Pt-dach to red blood cells (RBCs) and plasma proteins was also very rapid (t 1/2 RBCs = 0.58 h and t 1/2 plasma proteins = 0.78 h) and reached equilibrium by 4 hours. At equilibrium, 35% of total Pt-dach was bound to plasma proteins, 12% was in the plasma ultrafiltrate, and 53% was found associated with RBCs. Of the Pt-dach associated with RBCs, 23% was bound to the RBC membrane, 58% was bound to RBC cytosolic proteins, and 19% was in the RBC cytosol ultrafiltrate. Thus, these studies confirm previous observations of oxaliplatin accumulation by rat RBCs. To better characterize the determinants of this accumulation, oxaliplatin and other Pt-dach complexes were compared with respect to both their uptake by rat RBCs and their partition coefficients in octanol and water. The rank order for the rate of uptake was ormaplatin approximately Pt(dach)Cl2 > oxaliplatin > Pt(dach)(mal); while the rank order for hydrophobicity was ormaplatin > Pt(dach)Cl2 > Pt(dach)(mal) > oxaliplatin. Thus, in general, Pt-dach complexes appeared to be taken up better by RBCs than cisplatin or carboplatin, and the hydrophobicity of most of the Pt-dach complexes appeared to correlate with uptake. However, factors other than the dach carrier ligand and hydrophobicity clearly influence uptake. The biotransformations of oxaliplatin in rat blood were characterized utilizing reverse-phase high-pressure liquid chromatography (HPLC). In the RBC cytosol, both oxaliplatin and Pt(dach)Cl2 were observed at early times, while Pt(dach)(GSH)2, Pt(dach)(Cys)2, Pt(dach)(GSH), and free dach accumulated and reached steady-state levels by 4 hours. Thus, in the RBC cytosol, only chemically unreactive biotransformation products such as free dach and Pt-dach complexes with cysteine and glutathione accumulated in significant amounts. Furthermore, only Pt(dach)(Cys)2 and free dach appeared to efflux from RBCs. Thus, RBCs do not appear to serve as a reservoir for cytotoxic Pt-dach complexes. Finally, the biotransformation products of oxaliplatin in the plasma were identified as Pt(dach)Cl2, Pt(dach)(Cys)2, Pt(dach)(GSH), Pt(dach)(Met), Pt(dach)(GSH)2, and free dach. Among these compounds, Pt(dach)Cl2 formed transiently, while Pt(dach)(Cys)2, Pt(dach)(Met), and free dach accumulated and were the major biotransformation products by 4 hours. Thus, this study has identified the major inert and reactive biotransformation products of oxaliplatin in both plasma and RBCs and thus provides the information required for detailed pharmacokinetic and biotransformation studies of oxaliplatin. [figure in text]