Renal and hepatic toxicity after high-dose 7-hydroxymethotrexate in the rat

To examine directly the hepatic and renal toxicity of 7-hydroxymethotrexate (7-OH-MTX) without interference of the parent compound methotrexate (MTX), we purified and gave 100 mg/kg 7-OH-MTX to rats, a dose resulting in serum levels of 7-OH-MTX comparable with those achieved in the clinic after the administration of high-dose MTX (HD-MTX). After only 5 h, the 7-OH-MTX-treated rats demonstrated 2.6-fold increases in serum creatinine values and 2-fold elevations in serum aspartate aminotransferase (ASAT) levels as compared with the controls. Morphologic evidence of toxicity, however, was apparent only in the kidneys. Intraluminal cellular debris containing membranous material and deteriorated organelles was seen, but no precipitate of the delivered drug. The peak serum concentration of 7-OH was up to 939 M, and concentrations of 7-OH-MTX declined triphasically, showing at1/2 value of 2.45 min, at1/2 value of 30.5 min, and a terminal half-life (t1/2) of 240 min. The total clearance value was 14.5 ml min^–1 kg, and the postdistributional volume of distribution (V) was 5070 ml/kg. Our results may indicate a direct toxic effect of 7-OH-MTX on kidney and liver cells.This study was supported financially by the Norwegian Cancer Society     

Conversion of methotrexate to 7-hydroxymethotrexate and 7-hydroxymethotrexate polyglutamates in cultured rat hepatic cells

The formation of 7-hydroxymethotrexate and its diglutamate has been established in rat hepatic parenchymal cells in culture. The formation of 7-hydroxymethotrexate increases with the extracellular methotrexate concentration (1-50 microM) and with time over a 24-h period. The majority of the 7-hydroxy derivative is found in the medium after 6- and 24-h incubations at all concentrations examined. At high methotrexate concentration (50 microM) 7% of the total extracellular methotrexate was the 7-hydroxy derivative. 7-Hydroxymethotrexate diglutamate is accumulated within the cell, although longer chain length derivatives are not observed. The inability to form longer chain length polyglutamate derivatives is consistent with a limited capacity of hepatocytes to convert radiolabeled 7-hydroxymethotrexate to the tri- and tetraglutamates although the diglutamate is readily formed. A hepatoma cell line has an extremely limited capacity to form 7-hydroxy derivatives from methotrexate but form measurable amounts of mono-, di-, and triglutamates of 7-hydroxymethotrexate. 7-Hydroxymethotrexate was a good substrate for glutamylation in the hepatoma cells with large amounts of tri- through pentaglutamate derivatives. These studies confirm that 7-hydroxymethotrexate and the diglutamate must be considered when evaluating methotrexate pharmacology and demonstrate that this will be necessary with regard to methotrexate hepatotoxicity.     

Protection of cells from methotrexate toxicity by 7-hydroxymethotrexate.

Cell growth survival studies have revealed that 7-OH methotrexate is two orders of magnitude less cytotoxic to human melanoma and human acute lymphoblastic leukaemia (ALL) cells in vitro than methotrexate. The influence of 7-OH methotrexate on methotrexate toxicity was investigated by studying cell growth in the presence of methotrexate and its 7-OH metabolite and by studying [3H]-methotrexate movement across the plasma membrane of isolated human cells. Transport was followed for net entry of the drug into drug-free cells, net exit of drug into drug-free medium and for unidirectional exit fluxes with drug and/or metabolite in the extracellular medium (exchange exit). Results indicate that 7-OH methotrexate (10(-6) M) interacts with melanoma cells to reduce the initial cellular uptake rate of [3H]-methotrexate but that no such interaction occurs with ALL cells. Efflux measurements revealed that a stimulatory effect of extracellular methotrexate on [3H]-methotrexate exit was apparent and that extracellular 7-OH methotrexate had a less stimulatory effect. Overall, loss of intracellular drug was greater from melanoma cells than from ALL cells. The results suggest that the drug resistance encountered following high dose therapy may be due to reduced cellular uptake and/or increased efflux of methotrexate from cells, both events being enhanced by 7-OH methotrexate. In addition, there is an apparently endogenous resistance of the melanomas to methotrexate as regards time of exposure to this agent which could also contribute to the lack of clinical response when compared to ALL.     

Dose-dependent pharmacokinetics of methotrexate and 7-hydroxymethotrexate in the rat in vivo

The pharmacokinetics of methotrexate (MTX) and 7-hydroxymethotrexate (7-OH-MTX) in bile, urine, and serum was studied in rats in vivo after short-time infusions of 10, 50, 250, and 1000 mg/kg MTX. All animals were anesthetized and drained of bile during experiments. The biliary secretion rate of MTX approached saturation when serum MTX levels surpassed 700-800 microM, causing a significant reduction in biliary recovery as the parent compound (49 to 32%) at MTX doses exceeding 50 mg/kg. The hepatic metabolism of MTX to the 7-hydroxy metabolite was not saturated at the doses used. Serum MTX pharmacokinetics demonstrated dose dependency, inasmuch as doses exceeding 10 mg/kg were accompanied by a reduced total body clearance (Clr) and biliary clearance (ClB). A significant finding in relation to acute hepatotoxicity reported after high-dose MTX in humans was the occurrence of cholestasis 30-90 min after drug infusion and the observation of macroscopic precipitations in the bile duct in five of six animals treated with 1000 mg/kg MTX. In these five animals, cessation of bile secretion occurred at similar bile 7-OH-MTX levels [9800 +/- 1100 (SD) microM], while the single rat that secreted bile throughout the experiment had a 5-fold lower peak 7-OH-MTX concentration in bile. Analysis of biliary precipitates formed in vivo and in vitro found 7-OH-MTX to constitute 97% and MTX 3% of the drug content of the precipitated material.     

Formation and elimination of 7-hydroxymethotrexate in the rat in vivo after methotrexate administration

Bile, urine, and serum concentrations of methotrexate (MTX) and 7-hydroxy-methotrexate (7-OH-MTX) were monitored in rats in vivo following a short-time infusion of 10 mg/kg [3H]MTX. The experiments were performed in one group of anesthetized, bile-drained rats and in two control groups, one anesthetized and one unanesthetized, that were not bile-drained. Peak biliary levels of MTX (3.8 x 10(-3) M) and 7-OH-MTX (1.8 x 10(-4) M) appeared within 15 min after cessation of infusions. For two log ranges of serum MTX concentrations, biliary levels remained 180-fold higher. High bile 7-OH-MTX levels appeared few min after start of MTX administration, and were 720 times higher than the peak serum concentrations, indicating that the liver is a major site of 7-OH-MTX formation in the rat. 7-OH-MTX concentrations in bile declined monophasically with a half-life of 29.4 min, while MTX showed a biphasic elimination with initial and second phase half-lives of 23.1 and 86.4 min, respectively. Bile was the major excretory route for MTX and 7-OH-MTX, with 50% of the dose recovered as the parent compound and 3.6% as the metabolite. There was no difference in urinary recovery of MTX in bile-drained and control animals, indicative of insignificant enterohepatic circulation of MTX. This was further corroborated by the finding of just 2.1% urinary recovery of MTX in rats who received previously collected MTX-containing bile through a duodenal catheter. Serum concentration curves were analyzed according to a three-compartment open model with an initial elimination half-life of 1.7-3.3 min, a second phase half-life of 15.4-21.0 min, and a terminal phase half-life of 119-240 min. Our finding of 7-OH-MTX formation and high biliary levels of the metabolite in the rat, can be used as basis for studies of interactions with in vivo MTX conversion to the 7-hydroxy metabolite.     

Interactions between 7-hydroxymethotrexate and folinic acid in RAJI cells, in vitro

HPLC analysis of plasma samples obtained from patients included in a high-dose methotrexate-folinic acid Rescue (HD-MTX-CF) protocol, allowed the simultaneous determination of MTX, CF and their respective plasma metabolites, 7-hydroxymethotrexate (7-OH-MTX) and 5-methyltetrahydrofolate (5-CH3-FH4). These 4 compounds interact at the cellular level to ensure the selective effectiveness of the HD-MTX-CF rescue protocol. An in vitro study has been investigated in RAJI cells to better describe the interference of CF on uptake, accumulation and metabolism of [3H]7-OH-MTX. Results about uptake and accumulation of CF were also obtained using [3H]CF, in the absence or the presence of unlabeled 7-OH-MTX. The rate of [3H]7-OH-MTX influx in RAJI cells (Km = 25.30 +/- 7.75 microM, n = 3) was competitively inhibited by the presence of 10 microM CF with a Ki value of 6.00 +/- 1.94 microM (n = 2). Intracellular 7-OH-MTX accumulation was decreased by approximately 30% when extracellular CF concentration was twice as high as that of 7-OH-MTX, and 70% when CF extracellular concentration was 5 times higher. The metabolism of 7-OH-MTX to its intracellular polyglutamyl derivatives was depressed by 90% when 10 microM CF were incubated for 2 h with equimolar [3H]7-OH-MTX, and it was completely abolished in the presence of 100 microM CF.     

Influence of piperacillin on the pharmacokinetics of methotrexate and 7-hydroxymethotrexate

The influence of concomitant administration of piperacillin (PIP) on the pharmacokinetic parameters of methotrexate (MTX) and 7-hydroxymethotrexate (7-OH-MTX) was studied in rabbits. Six rabbits received an initial i.v. bolus (0.21 mg kg⁻¹) followed by a constant-rate i.v. infusion of the drug (5 μg min⁻¹ kg⁻¹) for 240 min. The PIP dose (30 mg kg⁻¹) was repeated every 30 min until the end of the infusion period. The control group consisted of four rabbits treated the same way except for the addition of PIP. There were significant increases in the mean residence times found for MTX (MRT_inf) and 7-OH-MTX (MRT_m,inf) following PIP administration. Concomitant administration of PIP with MTX also produced significant 1.5- and 2.8-fold increases in the area under the curve of MTX and 7-OH-MTX, respectively. The total body clearance of MTX and the operative total body clearance of 7-OH-MTX significantly decreased, but in a less than proportional manner. The study demonstrates that the interaction between MTX and PIP is mainly due to the reduced clearance of both MTX and 7-OH-MTX combined with a slight increase in the formation clearance of the metabolite. Received: 9 March 1998 / Accepted: 14 May 1998     

Cephalosporins increase the renal clearance of methotrexate and 7-hydroxymethotrexate in rabbits

Summary Anaesthetized rabbits were infused with methotrexate (MTX; 30 μg × kg⁻¹ × min⁻¹ for 4h. Constant plasma concentrations of MTX and its main metabolite 7-hydroxymethotrexate (7-OH-MTX) were achieved 40–60 min after the start of the infusion. In all, 50% of the infused MTX was eliminated by the kidney; another 15%–30% was hydroxylated and excreted as 7-OH-MTX in the urine. A concomitant infusion of penicillin G (3.96 mg × kg⁻¹ × min⁻¹) decreased the renal clearance of MTX and 7-OH-MTX, probably by competitive antagonism at the common tubular secretion site. In contrast, the four cephalosporins ceftriaxone, ceftazidime, ceftizoxime and cefoperazone all increased the renal clearance of MTX and 7-OH-MTX. At similar plasma concentrations, ceftriaxone and ceftazidime were almost equipotent, ceftizoxime was less effective and cefoperazone seemed to have a biphasic effect, depressing the clearance of MTX and 7-OH-MTX at higher drug concentrations. The effects are best explained by an inhibition of the tubular reabsorption of the cytostatic and its metabolite. The results suggest that cephalosporins are a better choice than penicillin for antibiotic treatment during MTX therapy.     

Acute systemic toxicity of combined cis-diamminedichloroplatinum and hyperthermia in the rat

To investigate the previously observed increased morbidity and mortality of combined cis-diamminedichloroplatinum (cis-DDP) and hyperthermia, BD IX rats were given 4 mg/kg cis-DDP i.p., waterbath hind leg heating (44°C, 60 min) with resultant whole body hyperthermia, or combined treatment with or without systemic cooling. Cardiac blood and histopathologic sections of kidney, small intestine and liver were examined in rats sacrificed 2, 3 and 5 days after and femur bone marrow 5 days after treatment. In a separate experiment, the effect of systemic hyperthermia on renal function was tested.The most significant finding was a marked increased in cis-DDP induced renal damage by systemic hyperthermia, expressed as elevated creatine levels and quantitatively enhanced proximal tubular necrosis. As both system hyperthermia and cis-DDP can result in primarily altered renal haemodynamics, it is postulated that relative tubular epithelial hypoxia and increased tubular exposure time to cis-DDP due to reduced tubular filtrate flow rate are likely mechanisms for the increased toxicity.     

Maximum tolerated doses of methotrexate and 7-hydroxy-methotrexate in a model of acute toxicity in rats

Purpose: After more than 50 years of methotrexate (MTX) treatment of acute lymphoblastic leukaemia (ALL), it is currently believed that as long as dose escalations are followed by adequate leucovorin rescue guided by monitoring MTX serum concentrations, hydration and urinary alkalinization, high-dose MTX (HD-MTX) can be tolerated without life-threatening toxicity. However, our recent experimental animal studies of the major metabolite of MTX, 7-OH-MTX, indicate that this concept may have some limitations. Animals with levels of 7-OH-MTX of 1 mM, which is below the levels routinely found in patients on HD-MTX, demonstrate intolerable toxicity and some animals die within 8 h. Electron microscopy indicates that endothelial cell and platelet functions are perturbed. Since animal data are lacking, and interspecies differences not known, we wanted to investigate the maximum tolerated doses of MTX and 7-OH-MTX in a rat model of short-term effects. The maximum tolerated dose was chosen instead of LD₅₀ for reasons of animal welfare. Methods: We infused MTX and 7-OH-MTX into anaesthetized male Wistar rats and monitored the animals for 8 h. The drugs were given as a bolus plus continuous infusion. The dose-finding ranges were 1.8–11.3 g/kg MTX and 0.1–1.2 g/kg 7-OH-MTX. Results: The maximum tolerated dose was between 3 and 5 g/kg for MTX and lower than 0.1 g/kg for 7-OH-MTX. The mean serum concentrations of MTX and 7-OH-MTX in animals that did not survive the 8-h period were 21.9 and 1.6 mM, respectively. The animals that received the highest MTX or 7-OH-MTX doses and concentrations died after sudden reductions in heart rate and blood pressure. Conclusions: We demonstrated a lower maximum tolerated dose of 7-OH-MTX than of MTX in rats after 8 h. The 7-OH-MTX concentrations were in the therapeutic range after HD-MTX. If the rat/human interspecies differences are not large, our data may indicate that HD-MTX regimens should not be further dose intensified, due not so much to the effects of MTX as to those of 7-OH-MTX. Received: 28 July 1999 / Accepted: 25 January 2000     

Determination of 7-hydroxymethotrexate in human plasma by reversed phase high-performance liquid chromatography

A rapid and sensitive reversed phase HPLC method was developed for the detection of 7-hydroxymethotrexate (7-OHMTX) which is the main metabolite in human plasma after high-dose methotrexate (MTX) therapy. The simple clean-up procedure of plasma samples described allows the measurement of 7-OHMTX during clinical management of MTX infusions. Elimination kinetics of 7-OHMTX are given from 53 drug cycles of 6 patients.     

Modulation of tumor-induced lethality after pneumoperitoneum in a mouse model

BACKGROUND: To the authors' knowledge, a generally accepted approach to prevent increased intraabdominal tumor implantation after laparoscopic cancer surgery does not exist. METHODS: One week after establishing an ovarian carcinoma cell line in black mice intraabdominally (n = 156), a carbon dioxide pneumoperitoneum (Group 1: n = 78) was administered. The effect of this procedure on tumor-induced lethality and the therapeutic effect of mitoxantrone and taurolidin mixed with heparin and sodium chloride was investigated. The different drugs were added immediately after the release of the pneumoperitoneum and after 48 hours. The 78 control animals received the drugs at the same time without preexisting pneumoperitoneum. Survival time was registered. RESULTS: The survival time was reduced significantly in all pneumoperitoneum groups compared with the corresponding control group without pneumoperitoneum. The effect of mitoxantrone on survival time (mean, 62.08 days) was diminished significantly by the application of a pneumoperitoneum (mean, 34.27 days). Taurolidine/heparin appeared to have a positive effect on survival time only in the case of a previous pneumoperitoneum (mean of 21.12 days vs. mean of 16.04 days in the pneumoperitoneum control group; P < 0.001). CONCLUSIONS: The induction of a pneumoperitoneum appears to decrease survival time by increasing tumor cell growth and decreases the efficacy of intraperitoneal chemotherapy. The effects of pneumoperitoneum appear to be reduced by the use of heparin/taurolidine, which theoretically blocks extracellular matrix binding domains and inhibits the production of interleukin-1.     

Characteristics of the formation and membrane transport of 7-hydroxymethotrexate in freshly isolated rabbit hepatocytes

The cellular pharmacology of methotrexate was evaluated in freshly isolated rabbit hepatocytes in suspension with an analysis of drug metabolism by high-performance liquid chromatography. After exposure of hepatocytes at a cytocrit of 5% to 5 microM [3H]-methotrexate, intracellular 7-hydroxymethotrexate appears rapidly within the cell; within 15 sec, the level of 7-hydroxymethotrexate exceeds the level of intracellular methotrexate, although the latter has not achieved the dihydrofolate reductase binding capacity. Within 20 min, virtually all methotrexate is hydroxylated. There is minimal formation of methotrexate polyglutamyl derivatives even after exposure of cells to very high levels of methotrexate, and 7-hydroxymethotrexate polyglutamates do not accumulate in the cell at all after incubation with [3H]-7-hydroxymethotrexate. Because of the rapidity of the hydroxylation of methotrexate, transport of this agent could not be characterized. However, some aspects of the transport properties of 7-hydroxymethotrexate could be studied since the catabolite is neither bound nor metabolized in this system. Net 7-hydroxymethotrexate transport was reduced by the addition of 5-formyltetrahydrofolate. As observed for 4-aminoantifolate transport in other cell systems, net 7-hydroxymethotrexate transport was markedly stimulated by sodium azide, an inhibitor of energy metabolism. The data suggest that hydroxylation of methotrexate proceeds at a rate at least comparable to the rate of association of the drug with dihydrofolate reductase and that transport of methotrexate into rabbit hepatocytes is slow relative to the rate of catabolism to the 7-hydroxy derivative. Rabbit hepatocytes may be a useful model for exploring methotrexate catabolism at the cellular level and may provide insights into the interaction between methotrexate and/or other 4-aminoantifolates and the human liver.     

High-dose cyclophosphamide treatment of acute myelocytic leukemia. Studies in the BNML rat model

In view of its application in patients with acute leukemia prior to bone marrow transplantation, the toxicity and efficacy of high-dose cyclophosphamide treatment were evaluated in a rat model for human acute myelocytic leukemia (BNML). The ld₅₀ in leukemic rats proved to be lower than that in normal rats (100 vs 164 mg/kg respectively). With dosages above 120 mg/kg, bone marrow transplantation was required to overcome irreversible aplasia. Additional causes of death were lung-, bladder- and intestinal tract hemorrhages (160–200 mg/kg) or acute cardiopulmonary failure (250–300 mg/kg). In leukemic rats, excessive leukemic cell kill leading to tumor cell embolism was another contributing factor. In this respect, treatment of late-stage leukemia proved invariably fatal. In leukemic rats, the highest therapeutic index was achieved with 100 mg/kg. Depending on the stage of disease, a 5–8.5 log leukemic cell kill was achieved. An increased proliferation rate of residual leukemic cells after cyclophosphamide treatment appeared likely. Finally, the present data are extrapolated to the current treatment of human acute myelocytic leukemia in complete remission with high-dose cyclophosphamide in combination with supralethal total-body irradiation.     

Transgenic rescue from embryonic lethality and renal carcinogenesis in the Nihon rat model by introduction of a wild-type Bhd gene

We recently reported that a germline insertion of a single nucleotide in the rat homologue of the human Birt-Hogg-Dubé gene (BHD) gives rise to dominantly inherited cancer in the Nihon rat model. In this study, we constructed transgenic Nihon rats with introduction of a wild-type Bhd gene to ascertain whether suppression of the Nihon phenotype is possible. Rescue from embryonic lethality of mutant homozygotes (Nihon/Nihon) and suppression of renal carcinogenesis in heterozygotes (Nihon/+) were both observed, defining the germline Bhd mutation in the Nihon rat as an embryonal lethal and tumor predisposing mutation. This transgenic rescue system will be useful to analyse Bhd gene function, its relation to tumorigenesis in vivo, and genetic-environmental interactions in carcinogenesis.     

Late toxicity of total body irradiation with bone marrow transplantation in a rat model

In defined-flora, barrier-maintained rats, radiation nephritis is the principle late toxicity seen after high dose-rate total body irradiation (TBI), when hematologic toxicity is prevented by bone marrow transplantation (BMT). Pneumonitis develops only if rats are placed in a conventional microbiological environment during and after BMT. Low dose-rate TBI gives qualitatively similar late toxicity, but at radiation doses twice as large. Fractionation of the TBI has little effect on the bone marrow ablation doses, but results in increased gastrointestinal and renal tolerance. The addition of immunosuppressive or cytotoxic drugs (cyclosporine-A, methotrexate, cis-platinum) after TBI and BMT greatly decreases the dose of TBI that can be tolerated. The use of a cyclophosphamide plus cytosine arabinoside conditioning regimen prior to TBI and BMT increases the bone marrow ablation dose, but has no effect on acute gastrointestinal toxicity or on renal toxicity. These results indicate that substantial late toxicity may be associated with the TBI conditioning regimens used for BMT even in the absence of cytotoxic and antibiotic drugs, immunosuppressive agents, infection and graft-versus-host disease; and that radiation may be a contributing factor in the nephritis sometimes observed after TBI and BMT.     

Interactions between 7-hydroxymethotrexate and methotrexate at the cellular level in the Ehrlich ascites tumor in vitro

Studies were undertaken to characterize the cellular pharmacology of 7-hydroxymethotrexate (7-OH-MTX) in Ehrlich ascites tumor cells, compare it to that of methotrexate (MTX), and define the interactions between the parent compound and its catabolite. Transport of 7-OH-MTX is mediated by the MTX-tetrahydrofolate cofactor carrier, with a Km of 9 microM in comparison to the MTX Km of 5 microM. Both compounds mutually inhibit their influx and steady-state levels of free drug accumulated. While influx of 7-OH-MTX is slower than influx of MTX, 7-OH-MTX efflux is likewise slower, so that the steady-state level of 7-OH-MTX achieved is comparable to that of MTX. Influx of 7-OH-MTX is inhibited by extracellular 5-formyltetrahydrofolate and trans-stimulated in cells preloaded with this tetrahydrofolate cofactor. The energetics of 7-OH-MTX transport is similar to that of MTX in the influx and net transport are stimulated by sodium azide, while net transport is reduced by glucose. As observed for MTX, 7-OH-MTX transport is sensitive to the anionic composition of the extracellular compartment and was shown to be inhibited by organic and inorganic phosphates. 7-OH-MTX does not, alone, inhibit [3H]deoxyuridine incorporation into DNA at concentrations of up to 50 microM. However, the catabolite reduces MTX inhibition of deoxyuridine metabolism, presumably due to the reduction in the free level of intracellular MTX achieved. These findings support the possibility that when 7-OH-MTX accumulates to high levels relative to MTX in clinical regimens, it may modulate the pharmacological effects of MTX.     

Formation of 7-hydroxymethotrexate polyglutamyl derivatives and their cytotoxicity in human chronic myelogenous leukemia cells, in vitro

The rapid synthesis of poly-gamma-glutamyl derivatives of 7-hydroxymethotrexate (7-OH-MTX) and their selective intracellular retention are reported in human chronic myelogenous leukemia cells, K-562. After a 30-min exposure to 5 microM [3H]7-OH-MTX, three different polyglutamyl derivatives were detected by high-performance liquid chromatography. When extracellular 7-OH-MTX was removed, the 7-OH-MTX diglutamate level declined slowly in comparison to the monoglutamate, but the higher polyglutamyl derivative levels increased. Within 10 min after exposure of cells to 7-OH-MTX, the level of these polyglutamyl derivatives far exceeds the dihydrofolate reductase binding capacity. Gel filtration or charcoal binding analysis followed by high-performance liquid chromatography analysis of the bound component showed intracellular binding of virtually all 7-OH-MTX tetraglutamate at a level 4-fold higher than that of the dihydrofolate reductase binding capacity. No bound 7-OH-MTX diglutamate or triglutamate could be detected. Treatment of the 7-OH-MTX tetraglutamate: protein complex with 100 microM unlabeled methotrexate (MTX) for 15 min resulted in only a partial dissociation of this complex to an extent compatible with the dihydrofolate reductase level. The residual 7-OH-MTX tetraglutamate remained bound to a site with a molecular weight of approximately 25,000 to 35,000 as assessed by Bio-Gel P-60 analysis and could not be displaced by folic acid, 5-formyltetrahydrofolate, 7-OH-MTX, or the tetraglutamate of MTX. 7-OH-MTX and MTX cytotoxicities were compared by clonogenic assay in agar and by their effects on cell growth. After a 2-hr exposure, the 50% inhibitory concentrations for 7-OH-MTX and MTX in cells growing in agar were 10(-5) and 10(-6) M, respectively. A 10-fold difference in cytotoxicity was also observed in cells growing in suspension. Continuous exposure to glycine: adenosine: thymidine completely protects cells from a sustained exposure to 7-OH-MTX over the entire period of clonal growth. However, even a brief exposure to 7-OH-MTX also requires continuous exposure to glycine: adenosine: thymidine for protection. This suggests that, as observed for MTX, the 7-OH-MTX polyglutamyl derivatives that are retained within the cells have a sustained cytotoxic effect after the monoglutamate is removed.     

甲氧化三丁基锡的急性毒性和遗传毒性研究

目的:研究甲氧化三丁基锡(tributyltin methoxide,TBTMO)对小鼠的急性毒性和遗传毒性。方法:选取昆明种小鼠110只,随机分为11组(TBTMO 420、286、194、180、132、90、73、61、41.5、28 mg/kg及阴性对照组),一次性灌胃给药进行急性毒性测试;另取昆明种小鼠50只随机分成5组(TBTMO 80、40、20 mg/kg组,阴性对照组和阳性对照组),各剂量组和阴性对照组均连续给药2 d,阳性对照组连续给药5 d,均连续观察35d,处死小鼠取双侧附睾制片进行精子畸形试验;并取昆明种小鼠50只随机分成5组(TBTMO 80、40、20 mg/kg组,阴性对照组和阳性对照组),灌胃给药30 h后处死小鼠取胸骨骨髓进行微核试验;取GFP转基因小鼠50只随机分成5组(TBTMO 80、40、20 mg/kg组,阴性对照组和阳性对照组),收集每只小鼠的脾淋巴细胞进行hprt基因突变试验。然后用不同浓度TBTMO(69.4、48.6、34.0、23.8、16.6、0μg/ml)分别处理中国仓鼠肺成纤维细胞(Chinesehamster lung,CHL)进行染色体畸变试验;用不同浓度TBTMO(每皿5×10~5、5×10~4、5×10~3、5×10~2、50、5、0.5、0.05、5×10~-3、5×10~-4μg)分别处理TA97、TA98、TA100、TA102 4种菌株进行Ames试验。结果:TBTMO对小鼠的半数致死量(LD_(50))为98 mg/kg。与阴性对照组比较,TBTMO可致小鼠精子畸形(P0.05或P0.01),且有剂量依赖趋势,其余4项遗传毒性试验结果均为阴性。结论:在本实验条件下,TBTMO对小鼠的急性经口毒性属于中等毒性,可能具有一定的遗传毒性。     

Effect of high-dose pentoxifylline on acute radiation-induced lung toxicity in a rat lung perfusion model

PURPOSE: The purpose of this study was to study the effect of high-dose oral pentoxifylline on radiation-induced acute lung injury as assessed with a rat lung perfusion model. METHODS AND MATERIALS: Adult male Sprague-Dawley rats were used throughout this study. A preliminary experiment determined that treatment with 2 g/liter pentoxifylline in drinking water resulted in an average consumption of 1.38 g/m2/day, which is comparable to the maximum tolerated dosage in humans. Seventy-two rats were irradiated to the left hemithorax with single fraction doses ranging from 10 through 18 Gy. Half were treated with 2 g/liter pentoxifylline in drinking water from 1 week before radiation through 8 weeks after radiation. Lung vascular perfusion scanning was performed at 3, 4, 5, 6, and 8 weeks after radiation using 99mTc-macroaggregated albumin. The lung perfusion ratio was defined as the number of counts due to radioactivity within the irradiated left lung region of interest divided by the number of counts within the region of the nonirradiated right lung. This lung perfusion ratio has been shown to decrease with radiation-induced lung injury. RESULTS: Although radiation led to a decreased lung perfusion ratio in all groups, those receiving pentoxifylline maintained higher ratios than irradiated controls from 3-5 weeks, especially for those receiving 15 or 18 Gy. However, from 6 through 8 weeks the irradiated controls exhibited partial recovery of lung perfusion ratio, whereas the pentoxifylline groups did not. By 8 weeks after 15 and 18 Gy, lung perfusion ratios were significantly higher for the irradiated controls than for pentoxifylline-treated rats-a reversal of the pattern observed at 3-5 weeks. CONCLUSIONS: The protection by pentoxifylline against radiation-induced acute lung injury was transient and limited to the first 5 weeks after radiation. Subsequent recovery from lung injury was inhibited by this drug at later times within the acute phase.