Pharmacokinetics of methotrexate in the cerebrospinal fluid after intracerebroventricular administration in patients with meningeal carcinomatosis and altered cerebrospinal fluid flow dynamics

Transverse myelopathy occurring with intrathecal administration of methotrexate and cytarabine chemotherapy: A case report

Paraplegia following spinal injury is a rare complication subsequent to the administration of intrathecal chemotherapy; however, it is also one of the rare clinical features of central nervous system leukemia (CNSL). Distinguishing between the two is extremely important. The present study reports the case of a 46-year-old man who was diagnosed with acute lymphoblastic leukemia and subsequently achieved remission in the blood and bone marrow following the initial course of chemotherapy. However, the patient developed a sudden onset of paraplegia and urinary retention due to spinal cord infiltration of leukemia cells following the administration of intrathecal methotrexate and cytarabine. The paraplegia was initially reversible. However, a few weeks later, the patient developed irreversible paraplegia due to a complication of the intrathecal administration of chemotherapy (methotrexate and cytarabine arabinoside). The patient gave up further treatment in May 2013 and succumbed to the disease in June 2013.

Methotrexate-induced myelopathy mimicking subacute combined degeneration of the spinal cord

Methotrexate (MTX), a folate antagonist, is widely used to treat hematological malignancies. Although it is known to cause myelopathy, little is known about the pathophysiology and natural history of this myelopathy. We describe a 42-year-old woman with acute lymphoblastic leukemia who was treated with chemotherapy consisting of intrathecal MTX who developed a progressive myelopathy. The myelopathy mimicked, radiologically, subacute combined degeneration (SACD) of the spinal cord. This myelopathy mimicking SACD could be explained by the folate antagonism of MTX. The progressive clinical signs and serial MRI in this patient further our understanding of the natural progression of this myelopathy.

Pharmacokinetics Following Intraventricular Administration of Chemotherapy in Patients with Neoplastic Meningitis

Intraventricular administration of chemotherapy is one approach to overcoming the limited distribution of anticancer drugs and their active metabolites into the CNS. This form of regional chemotherapy has led to effective treatment of occult and overt meningeal leukaemia in humans. In contrast, the efficacy of this therapy is extremely limited in the treatment of leptomeningeal dissemination of various solid tumours. Pharmacokinetic studies of the commonly intraventricularly applied anticancer agents in humans have demonstrated that, using low drug doses, very high drug concentrations can be achieved in the cerebrospinal fluid (CSF) and relatively high concentrations in the leptomeninges but not in the brain tissue and the plasma. Therefore, this approach is not an effective treatment for bulky disease of brain tissue, and results in minimal systemic toxicity. In comparison with intralumbar administration, lower interpatient variability of CSF drug concentrations and improved clinical efficacy were observed. 'Concentration x time' schedules, i.e. frequent small drug doses over a short period, enable long-term CSF exposure to cytotoxic drug concentrations while avoiding excessively high and potentially neurotoxic drug concentrations. The technique of ventriculolumbar cerebrospinal perfusion delivers continuously high drug concentrations throughout the CSF for several hours, but its widespread use is limited by the technical complexities of this approach. In this article, the dosages, schedules and pharmacokinetic data of routinely used intraventricular agents in humans, e.g. methotrexate, cytarabine, glucocorticoids and thiotepa, are outlined in detail. In addition, pharmacokinetic data of investigational agents for intraventricular administration (diaziquone, DTC 101, mercaptopurine, mafosfamide, etoposide, topotecan, nimustine [ACNU] and bleomycin) are presented. Better understanding of the CSF pharmacology of these drugs is an essential prerequisite for safe, effective administration of these drugs. Investigational efforts are underway to verify the feasibility and efficacy of different dosages, schedules and combination therapies of these new intra-CSF agents. Current and future clinical research should also focus on methods allowing the delivery of tumoricidal drug concentrations for extended periods into the CSF and the brain tissue while minimising neurotoxicity and systemic toxicity (e.g. liposomal drug preparations, monoclonal antibodies, immunotoxins and gene therapy).

Strategies for increasing drug delivery to the brain: focus on brain lymphoma

The blood-brain barrier (BBB) is a gate that controls the influx and efflux of a wide variety of substances and consequently restricts the delivery of drugs into the central nervous system (CNS). Brain tumours may disrupt the function of this barrier locally and nonhomogeneously. Therefore, the delivery of drugs to brain tumours has long been a controversial subject. The current concept is that inadequate drug delivery is a major factor that explains the unsatisfactory response of chemosensitive brain tumours. Various strategies have been devised to circumvent the BBB in order to increase drug delivery to the CNS. The various approaches can be categorised as those that attempt to increase delivery of intravascularly administered drugs, and those that attempt to increase delivery by local drug administration. Strategies that increase delivery of intravascularly injected drugs can manipulate either the drugs or the capillary permeability of the various barriers (BBB or blood-tumour barrier), or may attempt to increase plasma concentration or the fraction of the drug reaching the tumour (high-dose chemotherapy, intra-arterial injection). Neurotoxicity is a major concern with increased penetration of drugs into the CNS or when local delivery is practised. Systemic toxicity remains the limiting factor for most methods that use intravascular delivery. This review evaluates the strategies used to increase drug delivery in view of current knowledge of drug pharmacokinetics and its relevance to clinical studies of chemosensitive brain tumours. The main focus is on primary CNS lymphoma, as it is a chemosensitive brain tumour and its management routinely utilises specialised strategies to enhance drug delivery to the affected CNS compartments.

Dose-related increases in cerebrospinal fluid concentrations of methotrexate in a postoperative patient with glioblastoma

OBJECTIVE

To investigate the postoperative pharmacokinetics of methotrexate in the plasma and cerebrospinal fluid (CSF) in the space created by tumor removal of a patient with glioblastoma during hyperosmotic disruption of the blood-brain barrier (BBB) and intraarterial chemotherapy with a stepwise increase in the methotrexate dosage.

CASE SUMMARY

A 30-year-old Japanese woman with glioblastoma received four courses of hyperosmotic disruption of the BBB and intraarterial chemotherapy with a combination of peplomycin, vindesine, nimustine, pirarubicin, and methotrexate. The patient was initially administered mannitol; anticancer drugs were then infused into the left internal carotid artery. Following the first, second, third, and fourth courses of treatment, methotrexate 350, 700, 1000, and 1500 mg, respectively, were administered for 30 minutes. Samples of blood and CSF from the space created by tumor removal were obtained. Methotrexate concentrations were measured by fluorescence polarization immunoassay and the pharmacokinetic parameters of methotrexate in plasma and CSF were estimated.

RESULTS

The plasma concentration of methotrexate peaked at the end of drug infusion, then decreased in a biexponential decay manner during the remainder of the treatment period. The CSF concentration of methotrexate in the space created by tumor removal peaked two hours after drug administration, then monoexponentially decreased. Although the maximal CSF concentration of methotrexate in the space created by tumor removal was lower than that in the plasma, the CSF concentration of methotrexate in the space created by tumor removal exceeded that in the plasma six hours after drug infusion. The half-life of methotrexate in the CSF exceeded that in the plasma. The AUC for the plasma and CSF methotrexate concentration increased parallel with the methotrexate dosage. The mean CSF AUC of methotrexate was 59.4% of that found in plasma.

CONCLUSIONS

The CSF AUC of methotrexate in the space created by tumor removal increased parallel with the methotrexate dosage during hyperosmotic disruption of the BBB and intraarterial chemotherapy.

Pharmacokinetics of methotrexate in plasma and cerebrospinal fluid

OBJECTIVE

To investigate the pharmacokinetics of methotrexate (MTX) in plasma and cerebrospinal fluid (CSF) during osmotic disruption of the blood-brain barrier and the intraarterial administration of combination chemotherapy postoperatively in a patient with glioblastoma.

CASE SUMMARY

A 60-year-old Japanese woman with a glioblastoma received two courses of combination intraarterial chemotherapy. In the first course of treatment, 20 mL of mannitol 20%, peplomycin 10 mg, vindesine 2 mg, and MTX 500 mg were administered via the right internal carotid artery, and then via the right vertebral artery. In the second course of treatment, 20 mL of mannitol 20%, peplomycin 15 mg, vindesine 2.5 mg, and MTX 1000 mg were similarly administered. Blood samples and CSF samples from the ventricle and the space left by tumor removal were obtained; the MTX concentrations were measured from these sites by fluorescence polarization immunoassay. The pharmacokinetic parameters of MTX in plasma and CSF were estimated.

DISCUSSION

The plasma concentration of MTX decreased in a biexponential decay pattern during each course of treatment. CSF concentrations of MTX in the ventricle and in the space left by tumor removal peaked at 2 and 6 hours, respectively, after drug administration and decreased monoexponentially. When the dose of MTX was doubled, the AUC for the plasma MTX concentration increased 2.4-fold and the AUCs for MTX in the ventricle and the space left by tumor removal increased 3.4- and 9.1-fold, respectively. The half-life of MTX in the CSF in the space left by tumor removal exceeded the half-lives of MTX in the plasma and in the ventricular CSF.

CONCLUSIONS

The CSF AUCs of MTX in the ventricle and the space left by tumor removal increased markedly and in parallel with the MTX dosage increase during osmotic disruption of the blood-brain barrier and intraarterial combination chemotherapy. Such treatment improves the delivery of chemotherapy agents to the brain.

Carcinomatous meningitis in solid tumours

Carcinomatous meningitis (CM) is an uncommon but devastating complication of malignancy. The management is controversial and clear recommendations cannot be made because: 1) Most series include patients with CM that has arisen from different primary malignancies which are associated with different median survival intervals. 2) There have been no prospective randomised investigations of treatment modalities in patients with CM from a particular tumour type. 3) The definition of response varies from one report to another so that some response rates refer to cytological changes in the CSF while others take clinical, cytological and biochemical parameters into account. 4) Reports include patients with and without parenchymal metastases and the natural history of carcinomatous meningitis in the two situations may differ. The median survival of solid tumour carcinomatous meningitis (excluding leukaemia and lymphoma) is approximately 2-3 months and patients with breast cancer have the longest survival (median 3 months). Currently patients are treated with radiotherapy to part or all of the neuraxis with either intrathecal or intravenous chemotherapy but the relative contribution of these modalities to survival or quality of life remains unknown. Approximately 50% of patients with carcinomatous meningitis die from other causes, including systemic disease. The two most important endpoints for the patient, neurological improvement and overall survival, are seldom used in isolation in the literature. Many reports have focused on surrogate markers of response, namely biochemical and cytological data points but the correlation between clinical status and these parameters is poor because of differences between lumbar and ventricular CSF and disturbances of CSF flow in CM. The current literature does not provide clear guidelines for the treatment of this condition. Multicentre, prospective, randomised trials should be conducted that address questions of most relevance to the patient, namely neurological status and overall survival.

Distribution of intrathecally administered ACNU in mongrel dogs: pharmacokinetics and quantitative autoradiographic study

The pharmacokinetics of 1-(4-amino-2-methyl-5-pyrimidinyl) methyl-3-(2-chloroethyl)-3-nitrosourea (ACNU) in the cerebrospinal fluid (CSF), were determined in dogs after ventriculolumbar perfusion (VLP, n = 6), and bolus injection into the ventricle (VB, n = 2), cisterna magna (MB, n = 5), and lumbar cistern (LB, n = 3), by high-performance liquid chromatography. The VLP method introduced effective amounts of ACNU into the lumbar cistern for cell kill in vitro. That is, the areas under the time concentration curve (AUC) of ACNU in the lumbar CSF for those receiving a 1.5 mg perfusion of ACNU were 481, 791, and 520 micrograms.min/ml and those receiving a 5 mg perfusion were 1,081, 2,048, and 1,215 micrograms.min/ml, respectively. These values were superior to 3-log cell kill condition of 9L gliosarcoma and 1.5-log cell kill of HU-126 human glioma cell line. Among the groups to which 5 mg of ACNU was administered, the VLP method attained significantly higher AUC values in the lumbar CSF than MB method. Quantitative autoradiography using an imaging plate system was performed in the VLP group (n = 2), VB group (n = 1), MB group (n = 2), and LB group (n = 2) using a 10 microCi/kg [ethylene-14C] ACNU dose which is thought to be related to the alkylating activity of ACNU. The VLP method attained a stable and abundant distribution of ACNU in the neural axis from the ventricular cavity to the lumbar cistern, but the cerebral convexity surface was devoid of a significant level of ACNU. When the MB method was used, the pharmacokinetic data varied in the cisterna magna and lumbar region, and again no significant level of ACNU was detected in the ventricular cavity. With the LB method, although a rich distribution was detected in the spinal cord, the concentration decreased abruptly at the upper cervical level. The VB method was unsatisfactory for obtaining an effective amount of ACNU in the lumbar region. The research and testing to date indicate that the VLP method is the procedure of choice in the treatment of meningeal dissemination.

Do anticancer agents reach the tumor target in the human brain?

The development of effective chemotherapy for tumors of the central nervous system (CNS) is complicated in that the blood-brain barrier (BBB) hampers the penetration of most drugs into the brain and cerebrospinal fluid (CSF). This review summarizes the main reports on the distribution to CNS tumors and peritumoral normal brain of antitumor agents such as epipodophyllotoxins, cis-diamminedichloroplatinum(II), some nitrosoureas, bleomycin, vinblastine, and other clinically used antitumor agents as well as that of some experimental compounds with specific physicochemical properties. Drug levels were measured at surgical resection or in autopsy samples taken from patients who presented with different primary brain tumors or with brain metastases from extracerebral tumors. The observations made in each study were summarized in some detail, and the main points were then evaluated comparatively so as to highlight common aspects in the pharmacokinetic patterns of antitumor agents in human CNS tumors. Independently of their physicochemical properties, most antitumor agents appear to accumulate to a greater extent and to persist longer in intracerebral tumors than in the normal peritumoral brain. From in vitro cytotoxicity assays, it appears that epipodophyllotoxins, platinum compounds, bleomycin, and nitrosoureas reach potentially active therapeutic concentrations at the tumor target. However, all drugs have difficulty in reaching brain tissue adjacent to the tumor, as the intact BBB hampers their penetration. Plasma and CSF drug concentrations usually give little useful indication of the absolute quantity of drugs in brain tumors. To obtain a clear understanding of the CNS distribution of antitumor agents, one must determine whether the compound being measured is actually responsible for the observed activity and must consider the role of metabolites in the effect of the parent drug.