High-dose methotrexate therapy of childhood acute lymphoblastic leukemia: lack of relation between serum methotrexate concentration and creatinine clearance.

BACKGROUND: The objectives of this study were: (1) to analyze the relation of serum methotrexate (MTX) concentration with creatinine clearance, (2) to compare the leucovorin rescue dose administered to the patients based on creatinine clearance, with the one calculated according to serum MTX levels, and (3) to determine MTX-related toxicity. PROCEDURE: Thirty children with high-risk non-B acute lymphoblastic leukemia (ALL) treated according to the national protocol (PINDA 92) based on ALL BFM 90, were randomized to receive consolidation with four doses of either 1 or 2 g/m(2) MTX as a 24-hr infusion, at 2-week intervals (group M1 and M2, respectively). Serum MTX concentrations were measured at 24, 42, and 48 hr after beginning the infusion and were analyzed retrospectively. The creatinine clearance was calculated after 12-hr intravenous hydration prior to each MTX dose. Leucovorin dosage was adjusted according to creatinine clearance. RESULTS: Serum MTX concentrations at 24, 42, and 48 hr after starting the infusion were not related to creatinine clearance in both treatment groups. Leucovorin rescue administered according to creatinine clearance was excessive in 43% in group M1 and in 51% in group M2, as compared to the dose calculated according to serum MTX levels. No serious clinical complications were observed. CONCLUSIONS: These results suggest that creatinine clearance is not a good parameter to calculate leucovorin rescue. MTX-related toxicity in this group of patients receiving a dose of 1 or 2 g/m(2) and rescued with leucovorin without monitoring serum MTX levels was acceptable.     

Methotrexate levels and outcome in osteosarcoma

BACKGROUND: Peak serum concentrations of methotrexate (MTX) have been reported to correlate with outcome in osteosarcoma (OS). Modification of the MTX dose to achieve peak levels between 700 and 1,000 micromol/L has been recommended. The goal of the study was to assess whether there is a correlation between histologic necrosis of the tumor and/or prognosis with peak MTX serum concentration. PROCEDURE: Treatment included multi-agent adjuvant chemotherapy, including high-dose MTX (12 g/m2). Peak MTX levels were drawn following a 4-hr infusion. Histologic evaluation for percent necrosis was done at the time of definitive resection. RESULTS: The median peak MTX level (n = 52 patients) was 1,060 micromol/L (range: 410-4,700 micromol/L), with significant intra-patient and inter-patient variability. Fifty-eight percent of the levels were 1,000 micromol/L or higher. Response to pre-operative chemotherapy was: 18% Grade I necrosis, 35% Grade II, 31% Grade III, and 16% Grade IV. No significant association was found between the mean peak MTX levels and necrosis (P = 0.44). Event-free survival (EFS) for the 48 patients with non-metastatic disease at diagnosis was 76% at 4 years of follow-up, with no association between the mean peak MTX level and EFS (P = 0.24). CONCLUSIONS: The absence of a demonstrable correlation between peak MTX levels and histologic necrosis or EFS may suggest that most patients achieve therapeutic levels when MTX is given at a dose of 12 g/m(2). The significant degree of intra-patient variability in peak levels poses a dilemma for pharmacokinetic adjustment. Continued use of HD-MTX in all patients, rather than dose adapted therapy, may be justified.     

Daily profiles of plasma phenylalanine and tyrosine in patients with osteogenic sarcoma during treatment with high-dose methotrexate-citrovorum rescue

Three adolescents and one child with osteosarcoma were studied during multiple courses of high-dose methotrexate, citrovorum factor rescue (HDMTX-CFR), with one adolescent treated intermittently over a period of 6 years. Plasma phenylalanine (Phe) and tyrosine (Tyr) were measured immediately before the infusion of MTX and then daily until serum MTX fell below 10(-7) M. At 24 hours, all showed marked increases in Phe and in the Phe/Tyr ratio. This suggests inhibition of dihydropteridine reductase (DHPR) which, in association with hepatic Phe hydroxylase, controls plasma concentrations of Phe. Inhibition of this enzyme system is not relieved by CFR. In the adolescent patients, although MTX levels in plasma declined steadily, Phe concentrations, which fell between 24 and 48 hours, rose to a new peak at 4-7 days. Possible reasons for this secondary increase are discussed. The patient with the longest exposure to HDMTX showed an increase in pretreatment Phe/Tyr ratios with time, suggesting damage to liver parenchymal cells not indicated by standard tests of liver function. Evaluation of plasma Phe during the course of HDMTX-CFR may permit assessment of intracellular concentrations of MTX or its metabolites in the liver without interference by CFR.     

Monitoring high dose methotrexate therapy (HD MTX) in children with osteosarcoma and computer simulation using a pharmacokinetic model

The pharmacokinetics of methotrexate (MTX) was studied in 15 children with osteosarcoma, treated (54 courses) with high-dose methotrexate (8, 10 i 12 g/m2; 4 h i.v. infusion). Pharmacokinetic analysis was performed by standard non-compartmental methods and using two-compartment nonlinear model with coexistence of additional, parallel linear route of elimination from central compartment. The model was used for computer simulation and prognosis of the serum-level curve course depending on the simulated dosage, enhanced diuresis and simulated kidney or liver insufficiency during the dose individualization. The usage of the pharmacokinetic model for computer simulations may improve understanding of the MTX kinetics and can optimise dosage regimens for the next cycles of chemotherapy.     

Successful Carboxypeptidase G2 Rescue in Delayed Methotrexate Elimination Due to Renal Failure

We report on an 18.5-year-old woman with osteosarcoma and delayed methotrexate (MTX) elimination due to renal failure after high-dose MTX, in whom rescue with high doses of folinic acid caused intolerable side effects. In this life-threatening clinical situation, the patient was rescued by the administration of recombinant carboxypeptidase G₂, a bacterial enzyme that rapidly hydrolyzes MTX into inactive metabolites. This is the first report on the successful clinical use of this alternative catabolic route for the elimination of MTX.     

Leucovorin and maximum tolerated dose toxicity of methotrexate in rats

High-dose methotrexate (HD-MTX) is widely used in combination chemotherapy and can be handled without life-threatening toxicity in combination with leucovorin (LV) rescue. However, in an experimental animal modelfortesting of short-term HD-MTX effects in anesthetized rats, the authors previously demonstrated intolerable toxicity and death within a few hours in some animals. Serum levels were below levels routinely found in patients on HD-MTX treatment. This study was aimed at disclosure of possible mechanisms for acute toxicity of MTX in rats. The previously determined maximum tolerated dose of 5 g/kg MTX was used as the test dose. The animals that died showed sudden reduction in heart rate and blood pressure. LV, 1 g/kg infused immediately prior to MTX, changed MTX elimination kinetics, but did not change the acute toxicity. The data of this study together with additional evidence obtained in the experimental model, suggest that MTX acute toxicity may not be related to its antiproliferative effect, but rather to perturbation of endothelial cell and platelet function.     

Safety of delayed leucovorin “rescue” following high-dose methotrexate in children

High-dose methotrexate (HDMTX) with leucovorin (CF) “rescue” is being investigated for treatment of many malignant tumors. CF is usually begun 2 hours after ending the HDMTX infusion. However, since CF and methotrexate compete for the same cellular transport system, at high extracellular methotrexate concentrations it may be impossible to “rescue” cells with CF. A regimen of HDMTX with delayed leucovorin “rescue” was therefore designed. In this program, a 6-hour infusion of methotrexate (7.5 gm/m²) was followed 24 hours later by leucovorin “rescue.” Nine patients with osteogenic sarcoma received 115 courses of this treatment. Toxicity was minimal. Plasma methotrexate values were identical to those following early CF “rescue” regimens. HDMTX with delayed “rescue” is well tolerated. Although theoretically sound, further studies are needed to determine its efficacy in comparison to standard early “rescue” regimens.     

Safety of delayed leucovorin "rescue" following high-dose methotrexate in children.

High-dose methotrexate (HDMTX) with leucovorin (CF) "rescue" is being investigated for treatment of many malignant tumors. CF is usually begun 2 hours after ending the HDMTX infusion. However, since CF and methotrexate compete for the same cellular transport system, at high extracellular methotrexate concentrations it may be impossible to "rescue" cells with CF. A regimen of HDMTX with delayed leucovorin "rescue" was therefore designed. In this program, a 6-hour infusion of methotrexate (7.5 gm/m2) was followed 24 hours later by leucovorin "rescue." Nine patients with osteogenic sarcoma received 115 courses of this treatment. Toxicity was minimal. Plasma methotrexate values were identical to those following early CF 'rescue" regimens. HDMTX with delayed "rescue" is well tolerated. Although theoretically sound, further studies are needed to determine its efficacy in comparison to standard early "rescue" regimens.     

LEUCOVORIN AND MAXIMUM TOLERATED DOSE TOXICITY OF METHOTREXATE IN RATS

High-dose methotrexate (HD-MTX) is widely used in combination chemotherapy and can be handled without life-threatening toxicity in combination with leucovorin (LV) rescue. However, in an experimental animal modelfortesting of short-term HD-MTX effects in anesthetized rats, the authors previously demonstrated intolerable toxicity and death within a few hours in some animals. Serum levels were below levels routinely found in patients on HD-MTX treatment. This study was aimed at disclosure of possible mechanisms for acute toxicity of MTX in rats. The previously determined maximum tolerated dose of 5 g/kg MTX was used as the test dose. The animals that died showed sudden reduction in heart rate and blood pressure. LV, 1 g/kg infused immediately prior to MTX, changed MTX elimination kinetics, but did not change the acute toxicity. The data of this study together with additional evidence obtained in the experimental model, suggest that MTX acute toxicity may not be related to its antiproliferative effect, but rather to perturbation of endothelial cell and platelet function.     

Safety and Efficacy of I-Leucovorin Rescue Following High-Dose Methotrexate for Osteosarcoma

High-dose methotrexate with leucovorin rescue (HDMTX-LCV) is an important component of regimens used in the treatment of osteosarcoma. As of this writing the commercially available form of leucovorin is a racemic mixture of d- and l-diastereoisomers; the l-isomer is the active component. This study describes the efficacy and safety of l-leucovorin in HDMTX-LCV regimens. Fifteen patients with osteosarcoma who were enrolled into or treated according to Pediatric Oncology Group protocols 8759 and 8651 received l-leucovorin (7.5 mg every 6 hours) in place of d,l-leucovorin following high-dose methotrexate. Safety data were collected for 1 week after each course or until any toxicities resolved. The mean number of l-leucovorin doses per course was 16.2 and the mean total dose per course was 126 mg. Adverse experiences were generally mild or moderate and occurred in 54 (60%) of 90 courses of l-leucovorin therapy. One l-leucovorin patient, who had inadequate methotrexate rescue, developed severe typhlitis. There were no instances of severe, acute methotrexate toxicity. Myelosuppression was seen but, in general, was not severe. These results support the conclusion that l-leucovorin effectively rescues patients from the toxicity of high-dose methotrexate. © 1995 Wi1ey-Liss, Inc.     

Methotrexate. II. Use in pediatric chemotherapy

The comprehensive use of methotrexate is possible because there is an easy way of reducing the toxic effects of this drug. Effective in the antidotic action are alkalinization of the urine, increasing hydration of the patient, and "rescue" of purine and pyrimidine metabolism in the tissues by use of reduced folates. Only intravenous administration, by means of infusion given over a long period (24 hours or more), results in reliable and reproducible concentrations in the plasma. Oral administration should be abandoned because of the variable resorption and the different concentrations reached in plasma by different individuals. Local administration, such as by intrathecal injection, is useful only when the interval between two succeeding injections is 14 days or more. On the basis of known pharmacokinetic constants, the dose of methotrexate and of citrovorum factor (leucovorin) which will result in the desired concentration in plasma, and possibly also in tissues, can easily be calculated. Use of the principle of concentration X time in dosage calculations will result in the avoidance of giving unnecessarily high doses of methotrexate.     

Degradation and clearance of methotrexate in children with osteosarcoma receiving high-dose infusion.

Plasma methotrexate (MTX) concentrations were quantitated in 34 patients after 127 high-dose (35--350 mg/kg) infusions with citrovorum factor rescue. Significant linear correlations have been obtained between methotrexate dosage and concentrations in plasma at 6 and 24 hours after the initiation of the therapy. However, similar trends have not been observed when 48- and 72-hour samples were analyzed. Clinical toxicity was not serious when the methotrexate level in plasma was less than 4.5 X 10(-6) M at 48 hours after the start of a six-hour infusion in children. A minimal four-hour steady-state methotrexate plasma level can be maintained during a six-hour infusion. Children excrete methotrexate at a faster rate than adults; the half-life of MTX during the first phase of plasma clearance curve is one hour shorter in children. Urinary analyses have indicated that substantial methotrexate is metabolized. The chemical nature of these components has not been identified. Further, the urinary metabolic profiles varied among patients.     

Degradation and clearance of methotrexate in children with osteosarcoma receiving high-dose infusion

Plasma methotrexate (MTX) concentrations were quantitated in 34 patients after 127 high-dose (35–350 mg/kg) infusions with citrovorum factor rescue. Significant linear correlations have been obtained between methotrexate dosage and concentrations in plasma at 6 and 24 hours after the initiation of the therapy. However, similar trends have not been observed when 48- and 72-hour samples were analyzed. Clinical toxicity was not serious when the methotrexate level in plasma was < 4.5 × 10^?6 M at 48 hours after the start of a six-hour infusion in children. A minimal four-hour steady-state methotrexate plasma level can be maintained during a six-hour infusion. Children excrete methotrexate at a faster rate than adults; the half-life of MTX during the first phase of plasma clearance curve is one hour shorter in children. Urinary analyses have indicated that substantial methotrexate is metabolized. The chemical nature of these components has not been identified. Further, the urinary metabolic profiles varied among patients.     

How long can folinic acid rescue be delayed after high‐dose methotrexate without toxicity?

To determine the optimal time of folinic acid rescue after methotrexate (MTX) treatment in patients with ALL, we selected and evaluated relevant studies that included doses, rescue delay, and side effects. Rescue at 42–48 hours resulted in considerable toxicity, except when low doses of MTX were used (1 g/m²) or serum MTX levels remained consistently low at 24, 30, and 36 hours. Rescue started at 30–36 hours was safe. In the absence of evidence that later rescue improves prognosis, we suggest that folinic acid rescue (105 mg/m²) be started no later than 36 hours from the start of MTX (5–6 g/m²). Pediatr Blood Cancer 2014;61:7–10. © 2013 Wiley Periodicals, Inc.     

A randomized study comparing high-dose methotrexate with moderate-dose methotrexate as components of adjuvant chemotherapy in childhood nonmetastatic osteosarcoma: a report from the Childrens Cancer Study Group

Methotrexate (MTX) has demonstrated significant activity against relapsed and metastatic osteosarcoma. However, there is little published data to indicate the appropriate dose for MTX when given as a component of a multidrug regimen for the treatment of osteosarcoma. Therefore, the investigators at the Childrens Cancer Study Group undertook a randomized clinical trial that compared Adriamycin and vincristine given with either high-dose methotrexate or moderate-dose methotrexate as postoperation chemotherapy in the treatment of childhood osteosarcoma. We report here the results for 166 patients with completely resected nonmetastatic disease of an extremity. The two therapies demonstrated equivalent disease-free survival (DFS). Further, no therapy prejudices survival after relapse. Approximately 38% of patients remain disease free 4 years after diagnosis. Two relapses occurred in patients free of disease at least 36 months after initiation of treatment. Some factors found by other investigators to be prognostic of poorer DFS, namely, male sex, primary tumor in the humerus or femur, and larger primary tumors, demonstrated similar though not statistically significant trends. The presence of spontaneous necrosis in the tumor sample from the definitive surgery was associated with poor prognosis for DFS. We postulate that this feature represents rapidly growing tumors with increased potential for metastases.     

Variability in dose intensity of high-dose methotrexate for nonmetastatic osteosarcoma

The authors evaluated their ability to maintain planned dosing schedules for high-dose methotrexate (HD-MTX) in patients with nonmetastatic osteosarcoma. Twenty-seven patients who received therapy according to 2 POG protocols (8651 and 9351), both of which included HD-MTX (12 g/m(2)/week for 2 consecutive weeks), between 1988 and 1998 were studied. Significantly fewer HD-MTX infusions were given on the second week to patients treated on POG 9351 (33 vs. 93%; p < .0001). The hydration guidelines were identical and there was no difference in peak serum MTX levels either within or between protocols. Differences in the administration of combination chemotherapy in 9351 compared to 8651 may have contributed to the increased toxicity associated with HD-MTX on 9351, although this is speculative. The use of HD-MTX should be carefully planned so that it does not decrease its dose intensity or that of other effective agents.     

Delayed methotrexate clearance in a patient with sickle cell anemia and osteosarcoma

A 15-year-old girl with homozygous sickle cell anemia (HbSS) and osteosarcoma is described. Delayed clearance of methotrexate (MTX) after the second course of high-dose MTX (HDMTX) led to the development of renal and hepatic toxicities. Rescue was accomplished with high-dose leucovorin, intravenous carboxypeptidase G2, and thymidine. Although the renal and hepatic abnormalities resolved, focal tonic-clonic seizures developed, accompanied by abnormal brain imaging. Four weeks after this episode, all clinical and biochemical abnormalities resolved. Preexistent end-organ damage associated with HbSS may compromise the ability to deliver high-dose chemotherapy with curative intent in patients with malignant disease.     

Methotrexate‐associated alterations of the folate and methyl‐transfer pathway in the CSF of ALL patients with and without symptoms of neurotoxicity

Background

Severe neurotoxicity has been observed after systemic high‐dose and intrathecal methotrexate (MTX) treatment. The role of biochemical MTX‐induced alterations of the folate and methyl‐transfer pathway in the development of neurotoxic symptoms is not yet fully elucidated.

Procedure

MTX, 5‐methyltetrahydrofolate, calcium folinate, S‐adenosylmethionine, and S‐adenosylhomocysteine were measured in the cerebrospinal fluid (CSF) of 29 patients with acute lymphoblastic leukemia (ALL) who were treated with high‐dose MTX (5 g/m²) followed by calcium folinate rescue (3 × 15 mg/m²) and/or intrathecal (8–12 mg) MTX. Two patients developed subacute MTX‐associated neurotoxicity. CSF was obtained by lumbal puncture 1–3 weeks after administration of MTX and shortly after the occurrence of neurotoxicity. The analytes were measured using HPLC assays with UV and/or fluorescence detection.

Results

In non‐toxic patients, CSF concentrations of 5‐methyltetrahydrofolate and S‐adenosylmethionine were in the normal range 2 weeks after administration of high‐dose and intrathecal MTX followed by rescue. In contrast, when these patients received intrathecal MTX without rescue, 5‐methyltetrahydrofolate concentrations were significantly decreased 12 days after the first MTX administration. S‐adenosylmethionine concentrations were significantly decreased up to 45 days. The two patients suffering from neurotoxicity had decreased levels of 5‐methyltetrahydrofolate and S‐adenosylmethionine during or following toxicity. S‐adenosylhomocysteine was determined in all samples of neurotoxic patients but was below the limit of quantification in most samples of non‐toxic patients. Calcium folinate was not detected; MTX was present only in samples obtained during its infusion.

Conclusion

Intrathecal MTX without folinate rescue as well as MTX‐associated neurotoxicity are likely to be associated with specific alterations of the folate and methyl‐transfer pathway. Pediatr Blood Cancer 2009;52:26–32. © 2008 Wiley‐Liss, Inc.     

Pharmacokinetics of HD-MTX in infants,children, and adolescents with non-B acute lymphoblastic leukemia

A retrospective pharmacokinetic analysis was done of methotrexate serum levels after high-dose treatment (HD-MTX, four cycles at two-week intervals of 5 g/sq.¹m. over 24 h i.v.) in children with non-B acute lymphoblastic leukemia (ALL) with the specific aim of seeking differences in patients of different ages, including infants under one year. A total of 122 children (seven infants aged 3 months-1 year, 26 children aged 1–3 years, 68 children aged 3–10 years and 21 adolescents aged 10–15 years) with normal liver and renal function, receiving consolidation therapy at the Pediatric Clinic of Monza between May 1988 and April 1992, were enrolled in this study. MTX was given as an intravenous infusion in 24 h and serum concentrations were measured up to at least 72 h after the start of infusion by an enzyme immunoassay (TDX Abbot, Dallas, TX) in order to modulate folinic acid rescue. Pharmacokinetic analysis of MTX levels according to a two-compartment open model indicated that, compared to all children up to 10 years old, in adolescents older than 10 years the drug reached higher concentrations in serum and was cleared at a lower rate. Steady-state levels and AUC were from 60% higher to more than double and the total clearance of the compound, expressed either per square meter surface area or per kg body weight, in each cycle was significantly lower in adolescents >10 years of age, sometimes being only one-third of the clearance in infants (0.2 vs. 0.6 1/h/kg and 6.6 vs. 10.7 1/h/sq.m). The relationship between each age and systemic clearance was highly significant as measured by regression analysis. Methotrexate systemic clearance progressively decreased as a function of age. Subsequent treatments did not induce changes in MTX pharmacokinetics. These data suggest that the better tolerance of HD-MTX in children may have a pharmacokinetic basis. The faster elimination of MTX in infants, who usually show the worst prognosis, suggests that full doses could be safely used in order to maximize the antileukemic effect without a high risk of toxicity. © 1995 Wiley-Liss, Inc.     

Action of Intermediate Doses of Methotrexate on Dihydrofolate Reductase in Malignant Diseases

This report describes the effect of intermediate methotrexate (MTX) doses on dihydrofolate reductase (DHFR) activity in vivo in the leukocytes of 16 children with malignant diseases. The authors used a cytochemical technique, and the enzyme was studied in intact cells. The treatment protocols included MTX 500 mg—2 g/m² weekly with leucovorin rescue. The above doses of MTX partially inhibit DHFR. The reduction of enzyme activity was observed in leukocytes within 24 h after MTX infusion, and it was more obvious in the polymorphonucleas and the monocytes. Complete inhibition of enzyme activity was not observed. These results do not agree with those of previous reports using biochemical techniques, which showed that small amounts of MTX inhibit DHFR activity. Even the large doses of MTX used in this study do not completely inhibit enzyme activity. It would be worthwhile to test the effect of even larger doses of MTX to find out if DHFR activity is inhibited.