Phosphonylation of purified human, canine and porcine cholinesterase by soman. Stereoselective aspects

Cholinesterases (EC 3.1.1.8, acylcholine acylhydrolase) from the sera of man, dog and pig were purified 400-600-fold using a combination of ion-exchange and affinity chromatography. In a first approach, phosphonylation by soman was studied by using the half-resolved epimers C(+)P(+/-)-soman and C(-)P(+/-)-soman. The degradation of soman at the nanomolar level was followed in time by determining the remaining soman by capillary gas chromatography with NP detection. In the three sera investigated the P-(-)-epimer phosphonylates at a higher rate than its corresponding P(+)-counterpart and the stereoselectivity is greater for the C(+)-epimers than for the C(-)-epimers. Individual soman isomers were isolated from C(+)- and C(-)-epimers and quantified by gas chromatography. Second-order rate constants were determined for the phosphonylation of purified cholinesterase by isolated soman isomers. The C(+)P(-)-isomer has the highest phosphonylation rate for the three species; the other toxic isomer, C(-)P(-), has a five to ten-fold lower rate. The overall stereoselectivity is more marked in human cholinesterase than in canine. Porcine serum cholinesterase is phosphonylated by the P(-)-isomers at a slightly higher rate than the human enzyme.     

In vitro degradation of the stereoisomers of soman in guinea-pig, mouse and human skin

The fate of the four stereoisomers of soman [C(-)P(+), C(+)P(+), C(+)P(-) and C(-)P(-)] was studied by incubating 10 microM C(+/-)P(+/-)-soman at pH 7.4 and 37 degrees for various periods in the presence or absence of homogenates (1:10 and 1:20 w/v) of guinea-pig, mouse or human skin. The remaining concentrations of the soman isomers were determined gas chromatographically. Similar rates of spontaneous (non-enzymatic) hydrolysis (K = 0.005 min-1) were found for the four isomers of soman. Hydrolysis of the toxic (C(+/-)P(-)-isomers is not accelerated in the presence of the skin homogenates. In contrast, the non-toxic C(+/-)P(+)-isomers are enzymatically hydrolysed. As the amount of proteins present in the homogenates varied the rate constants for enzyme hydrolysis per protein concentration were calculated. Except for the high hydrolysis rate constant of greater than 0.127/min.g.l for C(+)P(+) in human skin, these values were almost similar (0.031-0.045/min.g.l) for the skin homogenates tested. Irreversible binding sites for the four soman-stereoisomers are only found in homogenates of mouse skin; 122-195 pmol soman-isomer are bound per mg protein. After preincubation of mouse homogenate with 10 microM soman during 18 hr at 0-4 degrees no further binding of the isomers was detected. It is concluded that skin of the three species tested does not contain enzymes that degrade the toxic C(+/-)P(-)-isomers of soman, whereas phosphorylphosphatase activity for the C(+/-)P(+)-isomers is present in the skin of all three species. Binding sites for all four soman isomers are only present in mouse skin.     

Stereoselective hydrolysis of soman in human plasma and serum

The contribution of various human serum and plasma fractions to the total hydrolysis rate constants of the four isomers of soman is studied. Spontaneous hydrolysis (as measured in buffer) occurs at a faster rate for the C(+)P(+)- and C(-)P(-)-isomers. A stereoselectively catalyzed hydrolysis of soman occurs in serum fractions IV and V (albumin). In fraction V the C(+)P(+)- and C(-)P(-)-isomers are hydrolyzed at a faster rate than their respective epimers, while in fraction IV-1 a stereoselective effect towards C(+)P(+)-soman is found. All the forementioned contributions, however, are negligible in comparison with the stereoselective enzymatic hydrolysis of the P(+)-isomers. The latter reaction is characterized by a significant lowering of the activation energy as compared with the spontaneous hydrolysis of the P(+)-isomers. Such a lowering in activation energy is not found for the hydrolysis of the P(-)-isomers in whole serum or plasma; hence it can be concluded that a phosphorylphosphatase hydrolyzes the P(+)-isomers in a stereoselective way, the P(-)-isomers either not being affected by this (these) enzyme(s) or the mechanism of catalysis being fundamentally different. This conclusion is in agreement with the observations on the influence of Hg2+ on the hydrolysis of soman in serum; the hydrolysis of the P(+)-isomers is significantly inhibited by 1 mM of Hg2+ while the P(-)-hydrolysis is unaffected by this concentration of Hg2+. The action of some potential inhibitors on this phosphorylphosphatase activity was studied. Iodoacetate did not inhibit nor did Ba2+, Sr2+, Co2+ or Mn2+ show a significant effect on the hydrolysis of the P(+)-isomers. On the other hand the hydrolytic activity in serum was nearly completely inhibited by EDTA but restored upon addition of Ca2+. These findings suggest that this enzymatic activity can be classified as an arylesterase (paraoxonase). Finally, the influence of pH on the hydrolytic activity shows a different pattern for C(+)P(+)- and C(-)P(+)-soman, which may suggest that more than one enzyme is involved in the degradation of soman.     

Hydrolysis of the four stereoisomers of soman catalyzed by liver homogenate and plasma from rat, guinea pig and marmoset, and by human plasma

Stereoselective hydrolysis at pH 7.5 and 37 degrees of C(+/-)P(+/-)-soman by liver homogenate and plasma from rat, guinea pig and marmoset, and by human plasma is studied by using the four single stereoisomers. The fast hydrolysis of the C(+/-)P(+)-isomers is monitored titrimetrically, whereas the decay of the much slower reacting C(+/-)P(-)-isomers is followed by gas chromatographic determination of the residual concentration. Values of Km and Vmax are evaluated for the enzymatic hydrolysis of the two relatively nontoxic C(+/-)P(+)-isomers. The plasma enzymes have a high affinity for these isomers (Km: 0.01-0.04 mM); the Km values of the liver enzymes vary between 0.04 and 0.7 mM. Except for rat liver homogenate, only first-order rate constants can be obtained for catalyzed hydrolysis (kc) of the highly toxic C(+/-)P(-)-isomers: most measurements with C(+/-)P(-)-isomer concentrations greater than 0.3 mM are complicated by epimerization to C(+/-)P(+)-isomers, which may conceal enzyme saturation with the C(+/-)P(-)-isomers. The first-order rate constants of catalyzed hydrolysis (Vmax/Km or kc) by all liver homogenates and plasmata decrease in the order: C(+)P(+)- greater than C(-)P(+)- much greater than C(-)P(-)- greater than C(+)P(-)-soman. The highest P(+)-/P(-)-stereoselectivity is found for rat plasma. Rat liver homogenate is more potent than the other liver homogenates in catalyzing the hydrolysis of both the C(+/-)P(+)- and the C(+/-)P(-)-isomers. Rat plasma shows the highest activity for degradation of the C(+/-)P(+)-isomers, but is approximately as active as marmoset and human plasma for degradation of the C(+/-)P(-)-isomers.     

Stereoisomers of soman (pinacolyl methylphosphonofluoridate): inhibition of serum carboxylic ester hydrolase and potentiation of their toxicity by CBDP (2-(2-methylphenoxy)-4H-1,3,2-benzodioxaphosphorin-2-oxide) in mice

The interaction of C(+/-)P(+/-)-soman (pinacolyl methylphosphonofluoridate) and its individual stereoisomers with serum carboxylic-ester hydrolase and potentiation of their toxicity by a carboxylic-ester hydrolase inhibitor CBDP (2-(2-methylphenoxy)-4H-1,3,2-benzodioxaphosphorin-2-oxide) was investigated. C(+/-)P(+/-)-Soman and the individual stereoisomers all inhibited purified mouse serum carboxylic-ester hydrolase to different degrees. C(+/-)P(+/-)-Soman and the C(-)P(-)- and C(+)P(-)-isomers had Ki values of 30.6, 18.7, and 35.7 nM, respectively, and C(-)P(+)- and C(+)P(+)-isomers had Ki values of 1412 and 2523 nM, respectively. In toxicity experiments CBDP (0.5 mg/kg; iv 1 hr prior to soman) pretreatment potentiated the toxicity of C(+/-)P(+/-)-, C(+)P(-)-, and C(-)P(-)-soman to a similar degree. Thus, it appears that the toxic stereoisomers of soman have a similar affinity for mouse serum carboxylic-ester hydrolase, and CBDP pretreatment does not enhance selectively the toxicity of one stereoisomer over the other.     

In vitro degradation of the four isomers of soman in human serum

Starting from racemic soman (1,2,2-trimethylpropyl methylphosphonofluoridate), the degradation of its four stereoisomers in human serum (25 degrees, pH 8.8), has been studied at the nM level. Phosphylation of serum proteins is eliminated by preincubation of the serum with soman. A capillary gas chromatographic method with nitrogen-phosphorous detection allows the separation of the diastereoisomers. The total hydrolysis (enzymatic and non-enzymatic) rate constants of the isomers can then be resolved indirectly on the basis of the important rate difference between P(+) and P(-) isomers. The enzymatic hydrolysis rate constants are obtained by subtracting, for each isomer, the spontaneous (non-enzymatic) rate constant from the total hydrolysis rate constant. The non-enzymatic part of the hydrolysis is obtained from experiments in serum ultrafiltrate (30,000 NMWL). Enzymatic hydrolysis of C(+) P(+) soman occurs so rapidly that only a lower limit of the rate constant can be given. The other enzymatic rate constants are 0.016 min-1 for C(+)P(-), 0.74 min-1 for C(-)P(+) and 0.028 min-1 for C(-)P(-).     

Isolation, anticholinesterase properties, and acute toxicity in mice of the four stereoisomers of the nerve agent soman

The four stereoisomers of the nerve agent pinacolyl methylphosphonofluoridate (soman), designated as C(+)P(+), C(+)P(-), C(-)P(+), and C(-)P(-), have different toxicologic properties due to stereospecific interactions in living organisms. We report the isolation of these stereoisomers with more than 99% optical purity. This result was realized by means of (i) complete optical resolution of pinacolyl alcohol, (ii) synthesis of C(+)- and C(-)-soman from the (+)- and (-)-enantiomers of the alcohol, (iii) optimalization of conditions for stereospecific inhibition of alpha-chymotrypsin with the P(-)-isomers of C(+)- and C(-)-soman, followed by isolation of the C(+)P(+)- and C(-)P(+)-isomers, (iv) isolation of the C(+)P(-)- and C(-)P(-)-isomers after incubation of C(+)- and C(-)-soman, respectively, in rabbit plasma, which hydrolyzes stereospecifically the P(+)-isomers. The bimolecular rate constants for inhibition of electric eel acetylcholinesterase (AChE) at pH 7.7, 25 degrees C, are at least 3.6 X 10(4) larger for the P(-)- than for the P(+)-isomers. The enzyme inhibited with C(+)P(-)-soman is much more effectively reactivated with the oximes HI-6, HGG-42, and obidoxime than AChE inhibited with C(-)P(-)-soman. The LD50 values (sc, mice) are in accordance with the P(-)/P(+) ratio of inhibition rates of AChE, i.e. 99, 38, greater than 5000, greater than 2000, 214, 133, and 156 micrograms/kg for C(+)P(-)-, C(-)P(-)-, C(+)P(+)-, C(-)P(+)-, C(+)-, C(-)-soman, and "soman", respectively. The relative LD50 values of the C(-)P(-)- and C(+)P(-)-isomers do not correspond with the small differences in their rates of inhibition of AChE, indicating that such small rate ratios may be overruled by other stereospecific effects, e.g., in vivo rates of detoxification.     

Toxicokinetics of the four stereoisomers of the nerve agent soman in atropinized rats—Influence of a soman simulator

The toxicokinetics of the four stereoisomers of C(+/-)P(+/-)-soman were investigated in anesthetized, atropinized, and artificially ventilated rats at iv doses of 6 (495 micrograms/kg) and 3 LD50. By integration of a thermodesorption/cold trap injector into our GLC analysis, the soman stereoisomers could be followed in rat blood down to a minimum detectable concentration, i.e., 1.5 pg/ml (8.3 pM), 55-fold lower than that published previously. This new detection limit is probably near or below the minimum concentration relevant for survival. Whereas C(+)P(+)-soman disappears in vivo from rat blood within 0.25 min, the toxicokinetics of C(-)P(+)-soman could be described by a two-compartment model, with a biological half-life of 1-1.5 min. The extremely toxic C(+/-)P(-)-isomers could be followed in rat blood for greater than 4 and 2 hr at doses of 6 and 3 LD50, respectively. The toxicokinetics of the P(-)-isomers are best described with a three-compartment model, with terminal half-lives of 40-64 and 16-22 min at doses of 6 and 3 LD50, respectively. Administration of a 13.6-fold molar excess of the soman simulator 1,2,2-trimethylpropyl dimethylphosphinate (PDP) 10 min prior to administration of 6 LD50 of C(+/-)P(+/-)-soman reduces the terminal half-lives of the C(+/-)P(-)-isomers to the values measured at the dose of 3 LD50 without PDP pretreatment. Previous investigations showed that, without PDP pretreatment, rats suffer from endogenous reintoxication 4-6 hr after initially successful therapy, at C(+/-)P(+/)-soman doses greater than or equal to 6 LD50. Both this reintoxication phenomenon due to the presence of toxicologically significant C(+/-)P(-)-soman levels up to 4 hr after intoxication and its antagonism via PDP pretreatment can be understood on the basis of our toxicokinetic measurements. This shows that such investigations can contribute to insight into the toxicology of C(+/-)P(+/-)-soman and to a better treatment of intoxications with this agent.     

Stereospecific reactivation by some Hagedorn-oximes of acetylcholinesterases from various species including man, inhibited by soman

Reactivation by bispyridinium mono-oximes (Hagedorn-oximes) and some classical oximes (0.03 or 1mM) was studied in vitro of rat, bovine and human erythrocyte acetylcholinesterase and of electric eel acetylcholinesterase inhibited by soman. Relative reactivating potencies of the oximes are similar for the three inhibited erythrocyte enzymes. In general, Hagedorn-oximes are more potent than the classical oximes. Among the Hagedorn-oximes, HI-6 is the most potent reactivator for the three inhibited enzymes. Relative reactivating potencies for the inhibited erythrocyte acetylcholinesterases and electric eel acetylcholinesterase, however, clearly differ. Since the reactivation experiments were carried out with racemic soman, a mixture of the two inhibited enzymes may be formed, which may cause additional problems in the comparison of various results. In order to get more detailed information on differences between human erythrocyte and electric eel acetylcholinesterase, reactivation of these enzymes inhibited with the P(-)-isomers of C(+)- and C(-)-soman were studied separately. Reactivation appeared to be dependent on the chirality of the alpha-carbon atom in the pinacolyl group. HI-6 is by far the most potent reactivator for the human enzyme inhibited by the two P(-)-isomers. It is suggested that electric eel acetylcholinesterase is not a reliable model for in vitro testing of therapeutic potencies of oximes against soman intoxication in mammals. Rate constants of aging of the four acetylcholinesterases inhibited with racemic soman and of the human and eel enzyme inhibited by the P(-)-isomers of C(+)- and C(-)-soman were also determined. The aging of the inhibited rat enzymes proceeds remarkably slowly (t1/2 = 21 min). The rate of aging is not affected by the chirality on the alpha-carbon atom in the pinacolyl group. Consequences of the present results are discussed in view of extrapolation of reactivation data of a series of reactivators to their relative therapeutic effect, ultimately in man. It is speculated that the more rapid aging of the human inhibited enzyme may hamper oxime-therapy in man more seriously than in rat.     

Toxicokinetics of soman in cerebrospinal fluid and blood of anaesthetized pigs

The toxicokinetics of the four stereoisomers of the nerve agent C(±)P(±)-soman was analysed in cerebrospinal fluid (CSF) and blood in anaesthetized, spontaneously breathing pigs during a 90-min period after injection of soman. The pigs were challenged with different intravenous (i.v.) doses of C(±)P(±)-soman corresponding to 0.75–3.0 LD₅₀ (4.5, 9.0 and 18 μg/kg in a bolus injection and 0.45 μg/kg per min as a slow infusion). Artificial ventilatory assistance was given if, after soman intoxication, the respiratory rate decreased below 19 breaths/min. Blood samples were taken from a femoral artery and CSF samples from an intrathecal catheter. The concentrations of the soman isomers were determined by gas chromatography coupled with high resolution mass spectrometry. All four isomers of soman were detected in both blood and CSF samples. The relatively non-toxic C(±)P(+) isomers disappeared from the blood stream and CSF within the first minute, whereas the levels of the highly toxic C(±)P(−) isomers could be followed for longer, depending on the dose. Concurrently with the soman analyses in blood and CSF, cholinesterase (ChE) activity and cardiopulmonary parameters were measured. C(±)P(−) isomers showed approx. 100% bioavailability in CSF when C(±)P(±)-soman was given i.v. as a bolus injection. In contrast, C(±)P(−) isomers displayed only 30% bioavailability in CSF after slow i.v. infusion of soman. The ChE activity in blood decreased below 20% of baseline in all groups of pigs irrespective of the soman dose. The effect of soman intoxication on the respiratory rate, however, seems to be dose-dependent and the reason for ventilatory failure and death. Artificial ventilation resulted in survival of the pigs for the time-period studied. Received: 3 March 1998 / Accepted: 5 May 1998     

Development of a physiologically based model for the toxicokinetics of C(±)P(±)-soman in the atropinized guinea pig

A physiologically based model was developed which describes the in vivo toxicokinetics of the highly reactive nerve agent C(±)P(±)-soman at doses corresponding to 0.8–6 LD₅₀ in the atropinized guinea pig. The model differentiates between the summated highly toxic C(±)P(−)-soman stereoisomers at supralethal doses and the individual nontoxic C(±)P(+)-isomers. Several toxicant-specific parameters for the soman stereoisomers were measured in guinea pig tissue homogenates. Cardiac output and blood flow distribution were measured in the atropinized, anesthetized, and artificially ventilated guinea pig. The model was validated by comparison of the time courses for the blood concentrations of the two pairs of stereoisomers in the guinea pig after i.v. bolus administration with the blood concentrations predicted by the model. The predictions put forward for the summated C(±)P(−)-isomers are in reasonable agreement with the experimental data obtained after doses corresponding to 2 and 6 LD₅₀. In view of large differences in the rates of hydrolysis of the C(±)P(+)-isomers, these two isomers had to be differentiated for satisfactory modeling of both isomers. In order to model the toxicokinetics of C(±)P(−)-soman at a dose of 0.8 LD₅₀, the almost instantaneous elimination of the C(+)P(−)-isomer at that dose had to be taken into account. The sensitivity of the predictions of the model to variations in the parameters has been studied with incremental sensitivity analysis. The results of this analysis indicate that extension to a model involving four individual stereoisomers is desirable in view of large differences in the biochemical characteristics of the two C(±)P(−)- and C(±)P(+)-isomers. Received: 8 July 1996 / Accepted: 30 October 1996     

Interaction of the four stereoisomers of soman (pinacolyl methylphosphonofluoridate) with acetylcholinesterase and neuropathy target esterase of hen brain

Dilute solutions in cold dry ethyl acetate of 98-100% pure specimens of each of the four stereoisomers of soman were tested against enzymes in hen brain homogenate at 37 degrees and pH 8.0. Rate constants for progressive inhibition of acetylcholinesterase were 10(7)-10(8)/mole/min for both P(-) isomers and less than 10(5) for both P(+) isomers. All isomers inhibited neuropathy target esterase non-progressively to some degree. Rate constants for progressive inhibition of neuropathy target esterase were 2.7-3.8 X 10(5)/mole/min for C(-) P(+) and 2-6 X 10(4) for the others. Forced reactivation by KF was 90% initially and aging was slow in each case. Spontaneous reactivation of inhibited neuropathy target esterase was substantial during 18 hr for both P(-) isomers but not for P(+). By comparison of rate constants for the two enzymes we predict that pure P(+) isomers may cause delayed neuropathy in hens dosed at about unprotected LD50: prophylaxis and therapy against acute cholinergic effects would have to raise LD50 1000-fold before birds could tolerate potentially neuropathic doses of P(-) isomers.     

Further evidence for the effect of pinacolyl dimethylphosphinate on soman storage in muscle tissue

Diaphragms isolated from rats 60 or 120 min after the intravenous injection of 6 X LD50 soman were incubated with electric eel acetylcholinesterase. As calculated from the enzyme inhibition, detectable amounts of P(-)-soman (1,2-dimethylpropyl methylphosphonofluoridate) were released from the diaphragm into the medium even 120 min post-injection. This release was reduced by additional pretreatment of the rats with pinacolyl dimethylphosphinate, providing further evidence that this compound prevents the storage of soman in diaphragm tissue.     

Binding and hydrolysis of soman by human serum albumin

Human plasma and fatty acid free human albumin were incubated with soman at pH 8.0 and 25 degrees C. Four methods were used to monitor the reaction of albumin with soman: progressive inhibition of the aryl acylamidase activity of albumin, the release of fluoride ion from soman, 31P NMR, and mass spectrometry. Inhibition (phosphonylation) was slow with a bimolecular rate constant of 15 +/- 3 M(-1) min (-1). MALDI-TOF and tandem mass spectrometry of the soman-albumin adduct showed that albumin was phosphonylated on tyrosine 411. No secondary dealkylation of the adduct (aging) occurred. Covalent docking simulations and 31P NMR experiments showed that albumin has no enantiomeric preference for the four stereoisomers of soman. Spontaneous reactivation at pH 8.0 and 25 degrees C, measured as regaining of aryl acylamidase activity and decrease of covalent adduct (pinacolyl methylphosphonylated albumin) by NMR, occurred at a rate of 0.0044 h (-1), indicating that the adduct is quite stable ( t1/2 = 6.5 days). At pH 7.4 and 22 degrees C, the covalent soman-albumin adduct, measured by MALDI-TOF mass spectrometry, was more stable ( t1/2 = 20 days). Though the concentration of albumin in plasma is very high (about 0.6 mM), its reactivity with soman (phosphonylation and phosphotriesterase activity) is too slow to play a major role in detoxification of the highly toxic organophosphorus compound soman. Increasing the bimolecular rate constant of albumin for organophosphates is a protein engineering challenge that could lead to a new class of bioscavengers to be used against poisoning by nerve agents. Soman-albumin adducts detected by mass spectrometry could be useful for the diagnosis of soman exposure.     

Formation of soman (1,2,2-trimethylpropyl methylphosphonofluoridate) via fluoride-induced reactivation of soman-inhibited aliesterase in rat plasma

After incubation (37°) of rat blood or plasma with the nerve agent soman, (CH₃)₃C(CH₃)C(H)O(CH₃)P(O)F (7.7 μM), for 10 min, only a small amount of this organophosphate (7 or 1%, respectively) is left, as determined enzymatically (acetylcholinesterase) and gas chromatographically. Comparison of the results obtained with both analyses shows that this residual soman consists only of its P(?)-isomers. Incubation (25°) at pH 4.8–6.1 of such soman-treated rat blood or plasma with sodium fluoride (2.5 mM) for 0.5 min leads to (i) a substantial increase of the P(?)-soman concentration, and (ii) a (partial) reactivation of the soman-inhibited aliesterase, proportional to the amount of generated P(?)-soman. These results indicate strongly that added fluoride ions regenerate soman by a reversal of the inhibition reaction. From the relationship between percentage of reactivation and increase of soman concentration the aliesterase concentration in rat plasma is calculated as 2.6 μM.Sodium fluoride has a similar effect in blood taken from rats to which soman was administered intravenously.The increase of the P(?)-soman concentration is higher with higher sodium fluoride concentrations and at lower pH values.In accordance with the absence of aliesterase, addition of sodium fluoride does not induce an increase of the P(?)-soman concentration in soman-treated human plasma.     

Structural and stereochemical specificity of mouse monoclonal antibodies to the organophosphorous cholinesterase inhibitor soman

To test the usefulness of immunotherapy in organophosphate poisoning, two mouse monoclonal antibodies were prepared to the chemical warfare agent soman. The antibodies bound reversibly to soman and afforded considerable protection to acetylcholinesterase in vitro. However, they were only marginally effective in preventing the consequences of soman poisoning in mice (these data have been published elsewhere). Since potential for immunotherapeutic usefulness resides in antibody affinity and specificity, we conducted experiments to define these parameters to enable us to maximize them in the production of later antibodies. Interaction of the antibodies (CC1 and BE2) in affinity-purified form with a series of soman analogs in a competitive inhibition enzyme immunoassay was used to assess the contribution to binding affinity of each functional group on the soman molecule. Neither antibody interacted with the -P = S analog of soman or methylphosphonic acid. A decrease in the number of methyl groups on the pinacolyl side chain reduced or eliminated binding with both antibodies while increasing the size of this group had a mixed result. The major metabolite of soman, its basic hydrolysis product, interacted weakly with BE2 and failed to interact with CC1. Alkyl ester group substitution at the fluorine position increased antibody binding up to the symmetrical dipinacolyl analog. Stereochemical specificity was determined by measuring the apparent decrease in the rate of inhibition of cholinesterases (acetylcholine acetylhydrolase, EC 3.1.1.7, or acylcholine acylhydrolase, EC 3.1.1.8) by pure soman stereoisomers in the presence of increasing concentrations of each antibody. CC1 demonstrated specificity that varied as C(+)P(+) less than C(-)P(+) less than C(-)P(-) less than C(+)P(-). Although affinities were much lower, BE2 also showed a preference for the more toxic P(-) isomers.     

Reactivation of nerve agent inhibited human acetylcholinesterases by HI-6 and obidoxime

Acetylcholinesterase was purified from human caudate nucleus and skeletal muscle. The enzyme preparations were used to study aging and reactivation by HI-6 and obidoxime after inhibition by soman and its isomers. HI-6 was found to be the most potent reactivator. For both enzyme preparations a higher reactivatability and a higher rate of aging were observed after inhibition by C+-soman than after inhibition by C(-)-soman. Aging was retarded by propidium diiodide. Reactivation by the two oximes was also studied after inhibition by tabun, sarin and VX. Tissue homogenates were used for this part of the work. Our conclusion is that HI-6 is superior to obidoxime for human acetylcholinesterases inhibited by soman and sarin, while obidoxime is better towards tabun-inhibited enzyme.     

尼莫地平对兔血中梭曼的消除及[^3H]梭曼在小鼠组织分布的影响

目的:考察尼莫地平对兔血中梭曼的消除及结合[~3H]梭曼在小鼠组织分布的影响,以探索尼莫地平对梭曼代谢解毒的作用.方法:以二异丙基氟磷酸酯(DFP)为内标,用大进样量手性毛细管柱气相色谱法测定兔梭曼静脉染毒后血中游离C(±)P(-)梭曼浓度.同位素示踪法测定结合[~3H]梭曼在小鼠组织中的分布.结果:尼莫地平(10 mg/kg,ip,预给药1小时)使兔梭曼染毒(43.2 μg/kg,iv)15 s后,血中游离C(±)P(-)梭曼浓度从(54±13)μg/L下降到(19±12)μg/L,使血中C(±)P(-)梭曼的清除率从(20.8±1.5)mL·kg~(-1)·s~(-1)增加到(31±11)mL·kg~(-1)·s~(-1),从而使AUC从(2.08±0.15)mg·s·L~(-1)降低到(1.6±0.4)mg·s·L~(-1).尼莫地平(10 mg/kg,ip,预给药1小时)能显著降低在[~3H]梭曼皮下染毒(0.544 GBq·119 μg/kg)0-120 min后小鼠血浆、脑、肺及肝脏中结合[~3H]梭曼的分布,而小肠中结合[~3H]梭曼的分布却显著升高.结论:尼莫地平可能通过改变梭曼的分布,降低了血中梭曼的初始浓度而起到促进梭曼代谢解毒的作用.     

A physiologically based pharmacokinetic (PB/PK) model for multiple exposure routes of soman in multiple species

A physiologically based pharmacokinetic (PB/PK) model has been developed in advanced computer simulation language (ACSL) to describe blood and tissue concentration–time profiles of the C(±)P(−) stereoisomers of soman after inhalation, subcutaneous and intravenous exposures at low (0.8–1.0 × LD₅₀), medium (2–3 × LD₅₀) and high (6 × LD₅₀) levels of soman challenge in three species (rat, guinea pig, marmoset). Allometric formulae were used to compute the compartment volumes, blood flow rates, tidal volume and respiratory rate based upon total animal weight. Blood/tissue partition coefficients for soman, initial carboxylesterase and acetylcholinesterase levels and the rate constants for interactions between soman and these enzymes were species-dependent and were obtained from in vitro measurements reported in the literature. The model incorporated arterial and venous blood, lung, kidney, liver, richly perfused, poorly perfused and fat tissue compartments as well as subcutaneous and nasal exposure site compartments. First-order absorption from linearly filled soman deposits into metabolizing exposure site compartments was employed to model subcutaneous and inhalation exposures. The model was validated by comparing the predicted and observed values for C(±)P(−)-soman in arterial blood at various times following exposure and by regression analysis. Sensitivity analysis was used to determine the effects of perturbations in the model parameters on the time-course of arterial C(−)P(−)-soman concentrations for different exposure routes. In our evaluation of 28 datasets, predicted values were generally within 95% confidence limits of the observed values, and regression coefficients comparing predicted and observed data were greater than 0.85 for 95% of the intravenous and subcutaneous datasets and 25% of the inhalation datasets. We conclude that the model predicts the soman toxicokinetics for doses ≥1 × LD₅₀ for intravenous and subcutaneous exposures and inhalation exposures of 8 min or less sufficiently well to allow its use in the modeling of bioscavenger protection.