Chromatographic method for dacarbazine quantification in skin permeation experiments.

Dacarbazine (DTIC) is a chemotherapeutic drug currently used for the systemic treatment of melanomas. Considering the easy access to these tumors, a topical route of drug administration could provide a more comfortable and less toxic treatment. However, DTIC quantification aiming at the design of topical formulations is challenging, pondering all the interferents present in the drug samples recovered from the skin. Hence, this work intended to validate a selective chromatographic method for DTIC determination in skin permeation studies. A reversed-phase C18 column was used as a stationary phase, and gradient elution of a mobile phase consisting of methanol and pH 6.5 sodium phosphate monohydrate buffer (0.01 mol/L) at a flow rate of 1.0 mL/min was implemented. DTIC was detected at 364 nm. The method was selective against skin interferents, linear (r = 0.9995) in a concentration range of 1.0-15.0 µg/mL, precise with an overall variation coefficient lower than 3.8%, accurate achieving recovery from the skin layers within 91-112%, and sensitive for the proposed application (detection limit = 0.10 µg/ mL, quantification limit = 0.30 µg/mL). Furthermore, the analytical method was successfully tested in in vitro skin permeation studies. In conclusion, the developed method is appropriate for DTIC analysis from the skin sample matrix.

Developing a clinically relevant radiosensitizer for temozolomide-resistant gliomas.

The prognosis for patients with glioblastoma (GB) remains grim. Concurrent temozolomide (TMZ) radiation-the cornerstone of glioma control-extends the overall median survival of GB patients by only a few months over radiotherapy alone. While these survival gains could be partly attributed to radiosensitization, this benefit is greatly minimized in tumors expressing O6-methylguanine DNA methyltransferase (MGMT), which specifically reverses O6-methylguanine lesions. Theoretically, non-O6-methylguanine lesions (i.e., the N-methylpurine adducts), which represent up to 90% of TMZ-generated DNA adducts, could also contribute to radiosensitization. Unfortunately, at concentrations attainable in clinical practice, the alkylation capacity of TMZ cannot overwhelm the repair of N-methylpurine adducts to efficiently exploit these lesions. The current therapeutic application of TMZ therefore faces two main obstacles: (i) the stochastic presence of MGMT and (ii) a blunted radiosensitization potential at physiologic concentrations. To circumvent these limitations, we are developing a novel molecule called NEO212-a derivatization of TMZ generated by coupling TMZ to perillyl alcohol. Based on gas chromatography/mass spectrometry and high-performance liquid chromatography analyses, we determined that NEO212 had greater tumor cell uptake than TMZ. In mouse models, NEO212 was more efficient than TMZ at crossing the blood-brain barrier, preferentially accumulating in tumoral over normal brain tissue. Moreover, in vitro analyses with GB cell lines, including TMZ-resistant isogenic variants, revealed more potent cytotoxic and radiosensitizing activities for NEO212 at physiologic concentrations. Mechanistically, these advantages of NEO212 over TMZ could be attributed to its enhanced tumor uptake presumably leading to more extensive DNA alkylation at equivalent dosages which, ultimately, allows for N-methylpurine lesions to be better exploited for radiosensitization. This effect cannot be achieved with TMZ at clinically relevant concentrations and is independent of MGMT. Our findings establish NEO212 as a superior radiosensitizer and a potentially better alternative to TMZ for newly diagnosed GB patients, irrespective of their MGMT status.

Development of surface imprinted nanospheres using the inverse suspension polymerization method for electrochemical ultra sensing of dacarbazine.

A new ultra sensing molecularly imprinted polymer beads modified pencil graphite electrode was fabricated, with the help of the inverse suspension polymerization technique, for ascertaining the adequate supplementation of dacarbazine in the cancer treatment. The inverse suspension polymerization technique was beneficial in obtaining surface imprinted polymer-based electrocatalytic nanospheres with narrow size distribution. These nanospheres were found to be superior to the corresponding microspheres and planar films, in terms of electrode kinetics and sensitivity, with the differential pulse anodic stripping voltammetric transduction. Herein, multiwalled carbon nanotubes functionalized ester links were invoked in between the imprinted nanospheres and the pencil graphite electrode surface to secure a stable coating and better electrodics. The proposed electrochemical sensor showed the imprinting factor and the analyte adsorption coefficient as high as 24.3 and 1.06 × 109 L mol-1, respectively. Furthermore, 16-fold and 4-fold faster electron transfer kinetics were observed with the imprinted nanospheres than the corresponding imprinted planar film and the microspheres based electrodes, respectively. The limits of detection [0.02 (aqueous), 0.02 (plasma), 0.01 (urine), and 0.03 ng mL-1 (pharmaceutics), (3σ, RSD ≤ 0.23%)] of dacarbazine, realized with the imprinted polymer nanospheres, were free from any cross-reactivity and false-positive complications in aqueous, blood plasma, urine, and pharmaceutical samples.

Molecular imaging coupled to pattern recognition distinguishes response to temozolomide in preclinical glioblastoma.

Non-invasive monitoring of response to treatment of glioblastoma (GB) is nowadays carried out using MRI. MRS and MR spectroscopic imaging (MRSI) constitute promising tools for this undertaking. A temozolomide (TMZ) protocol was optimized for GL261 GB. Sixty-three mice were studied by MRI/MRS/MRSI. The spectroscopic information was used for the classification of control brain and untreated and responding GB, and validated against post-mortem immunostainings in selected animals. A classification system was developed, based on the MRSI-sampled metabolome of normal brain parenchyma, untreated and responding GB, with a 93% accuracy. Classification of an independent test set yielded a balanced error rate of 6% or less. Classifications correlated well both with tumor volume changes detected by MRI after two TMZ cycles and with the histopathological data: a significant decrease (p < 0.05) in the proliferation and mitotic rates and a 4.6-fold increase in the apoptotic rate. A surrogate response biomarker based on the linear combination of 12 spectral features has been found in the MRS/MRSI pattern of treated tumors, allowing the non-invasive classification of growing and responding GL261 GB. The methodology described can be applied to preclinical treatment efficacy studies to test new antitumoral drugs, and begets translational potential for early response detection in clinical studies.

Development of a new UPLC-MSMS method for the determination of temozolomide in mice: application to plasma pharmacokinetics and brain distribution study.

A sensitive and accurate liquid chromatography method with mass spectrometry detection was developed and validated for the quantification of temozolomide in mouse plasma and brain. Theophyllin was used as the internal standard. A single-step protein precipitation was used for plasma and brain sample preparation. The method was validated with respect to selectivity, extraction recovery, linearity, intra- and inter-day precision and accuracy, limit of quantification and stability. The method has a limit of quantification of 50 ng/mL for temozolomide in plasma and 125 ng/g in brain. This method was used successfully to perform brain and plasma pharmacokinetic studies of temozolomide in mice after intraperitoneal administration.

Determination of temozolomide in serum and brain tumor with micellar electrokinetic capillary chromatography.

Micellar electrokinetic capillary chromatographic (MEKC) with photodiode-array detection was applied to determine temozolomide (TMZ) in human serum and brain tumor. The limit of quantitation (LOQ) was 0.096 µg/mL using 325 nm as detection wavelength. The method made possible that the TMZ could be detected in in vivo serum samples without sample pretreatment. In order to detect TMZ at lower concentration, an extraction with ethyl acetate was applied to preconcentrate the analyte. Small amount of brain tumor tissues (less than 1g) were lyophilized and pretreated using extraction as a clean up and concentrating step. After removing the organic solvent a final sample volume of only 10 µL was analyzed. The obtained peak concentrations (8.2-10.1 µg/mL) and T(max) (44-65 min) of TMZ in serum were similar to the data reported by others, the in vivo TMZ concentrations found in brain tumor ranged between 0.061 and 0.117 µg/g.

Analysis and stability study of temozolomide using capillary electrophoresis.

The applicability of micellar electrokinetic capillary chromatography (MEKC) for the analysis of temozolomide (TMZ) and its degradants, 3-methyl-(triazen-1-yl)imidazole-4-carboxamide (MTIC) and 5-amino-imidazole-4-carboxamide (AIC) has been studied. Using short-end injection, the analysis of TMZ and its degradants could be performed within 1.2 min. The obtained precision of migration times was better than 1.6 RSD%, and the limit of quantitation (LOQ) was 0.31-0.93 microg/mL. The therapeutic concentration of TMZ in blood samples can be determined after direct sample injection and conventional on-capillary UV detection. The proposed MEKC method was applied to study the stability of TMZ in water and serum at different pH values. It was established that the half-life of the TMZ in vitro serum at room temperature was 33 min, close to the half-life (28 min) obtained in water at pH 7.9.

Noninvasive detection of temozolomide in brain tumor xenografts by magnetic resonance spectroscopy.

Poor drug delivery to brain tumors caused by aberrant tumor vasculature and a partly intact blood-brain barrier (BBB) and blood-brain tumor barrier (BTB) can significantly impair the efficacy of chemotherapy. Determining drug delivery to brain tumors is a challenging problem, and the noninvasive detection of drug directly in the tumor can be critically important for accessing, predicting, and eventually improving effectiveness of therapy. In this study, in vivo magnetic resonance spectroscopy (MRS) was used to detect an anticancer agent, temozolomide (TMZ), in vivo in murine xenotransplants of U87MG human brain cancer. Dynamic magnetic resonance imaging (MRI) with the low-molecular-weight contrast agent, gadolinium diethylenetriaminepentaacetic acid (GdDTPA), was used to evaluate tumor vascular parameters. Carbon-13-labeled TMZ ([(13)C]TMZ, 99%) was intraperitoneally administered at a dose of approximately 140 mg/kg (450 mg/m(2), well within the maximal clinical dose of 1000 mg/m(2) used in humans) during the course of in vivo MRS experiments. Heteronuclear multiple-quantum coherence (HMQC) MRS of brain tumors was performed before and after i.p. administration of [(13)C]TMZ. Dynamic MRI experiments demonstrated slower recovery of MRI signal following an intravenous bolus injection of GdDTPA, higher vascular flow and volume obtained by T*(2)-weighted MRI, as well as enhanced uptake of the contrast agent in the brain tumor compared with normal brain detected by T(1)-weighted MRI. These data demonstrate partial breakdown of the BBB/BTB and good vascularization in U87MG xenografts. A [(13)C]TMZ peak was detected at 3.9 ppm by HMQC from a selected volume of about 0.15 cm(3) within the brain tumor with HMQC pulse sequences. This study clearly demonstrates the noninvasive detection of [(13)C]TMZ in xenografted U87MG brain tumors with MRS. Noninvasive tracking of antineoplastic agents using MRS can have a significant impact on brain tumor chemotherapy.

Validated high-performance liquid chromatographic assay for simultaneous determination of dacarbazine and the plasma metabolites 5-(3-hydroxymethyl-3-methyl-1-triazeno)imidazole-4-carboxamide and 5-(3-methyl-1-triazeno)imidazole-4-carboxamide.

Dacarbazine (DTIC) is a prodrug that is clinically effective in the treatment of Hodgkin's disease, melanoma and soft tissue sarcoma. To better characterize the clinical pharmacology of parent drug and reactive metabolites, a reversed-phase HPLC method with UV detection was developed for simultaneous determination of dacarbazine and the metabolites 5-(3-hydroxymethyl-3-methyl-1-triazeno)imidazole-4-carboxamide (HMMTIC) and 5-(3-methyl-1-triazeno)imidazole-4-carboxamide (MTIC). Chromatographic separation was achieved with a Zorbax SB-CN column and with a mobile phase of 80% 50 mM ammonium phosphate, pH 6.5, 20% methanol and 0.1% triethylamine. HMMTIC, MTIC and DTIC were extracted from plasma with methanol precipitation of the proteins. Recovery of DTIC and the metabolites from whole blood was greater than 92%. Rapid processing of whole blood, methanol extraction and storage at -70 degrees C substantially increased the stability of HMMTIC and MTIC from less than 15 min to 3 days. Precision for HMMTIC, MTIC and DTIC ranged from 3.7 to 16.3% relative standard deviation. The accuracy ranged from 101 to 114% for all three analytes. The validated assay was used to determine the pharmacokinetic data for dacarbazine and its active metabolites for human patients with recurrent glioma receiving DTIC intravenously.

Degradation of dacarbazine in aqueous solution.

The effects of initial concentration (0.05-5.0 mg ml-1, 2.5 x 10(-4)-0.025 M) (pH 1-13), buffer concentration (0.01-0.075 M), light, antioxidants and co-solvents on the degradation of dacarbazine in aqueous solution were investigated at 37 degrees C. Liquid chromatography was used to monitor the degradation of dacarbazine as well as the appearance of degradation products. The kinetics of hydrolysis of dacarbazine in the dark were pseudo first-order and independent of the initial concentration of the drug. The degradation of dacarbazine was accelerated by light and at low concentration proceeded by pseudo zero-order kinetics. The pH-rate profiles showed that both the photolytic and the hydrolytic reactions were dependent on the ionization state of the molecule. The main degradation product of both hydrolysis and photolysis was detected by liquid chromatography and confirmed by mass spectrometry to be 2-azahypoxanthine.

Clinical pharmacokinetics of high-dose DTIC.

The pharmacokinetics of 5-(3,3-dimethyl-1-triazeno)imidazole-4-carboxamide (DTIC, dacarbazine) given at a dose of 850-1,980 mg/m2 as a 10- to 30-min infusion was studied in cancer patients, and the plasma concentration-time curves were adjusted to a two-compartment model, with a mean t1/2 alpha value of 0.17 h (range, 0.1-0.26 h) and a mean t1/2 beta value of 2 h (range, 1.5-2.7 h) being found. The mean volume of the central compartment of (Vc) and the apparent volume of distribution (VB) were 0.42 1 kg-1 (range, 0.24-0.54 1 kg-1) and 1.49 1 kg-1 (range, 0.88-1.74 1 kg-1), respectively. The mean total body clearance of DTIC was 0.58 1 kg-1 h-1 (range, 0.26-0.82 1 kg-1 h-1), and the mean renal clearance was 0.28 1 kg-1 h-1 (range, 0.17-0.49 1 kg-1 h-1). Unchanged DTIC recovered from urine within 24 h varied from 11% to 63% of the delivered dose, with an inverse correlation being found between the DTIC dose and the amount excreted. The metabolite aminoimidazole carboxamide (AICA) was detectable in plasma from the start of DTIC infusion, and its concentration-time curve showed a monophasic decay, exhibiting a mean t1/2 value of 3.25 h (range, 1.77-5.82 h). Mean AICA renal clearance was 0.15 1 kg-1 h-1 (range, 0.05-0.32 1 kg-1 h-1). The amount of AICA excreted in urine increased with increasing DTIC dose and varied from 1.2% to 13.6% of the delivered DTIC dose. Both DTIC distribution and disposition and AICA production and renal excretion seemed to be limited after high DTIC doses as compared with the pharmacokinetics of low-dose DTIC. Nonlinear pharmacokinetics for high-dose DTIC could not be clearly excluded.

Simultaneous determination of dacarbazine, its photolytic degradation product, 2-azahypoxanthine, and the metabolite 5-aminoimidazole-4-carboxamide in plasma and urine by high-pressure liquid chromatography.

A high-pressure liquid chromatographic method has been developed that allows for the simultaneous analysis of dacarbazine (DTIC), 5-aminoimidazole-4-carboxamide (AIC), and 2-azahypoxanthine (2-AZA) in plasma or urine. Plasma samples were prepared by ultrafiltration, whereas urine samples were filtered and diluted for analysis. Chromatography was done with a C18 mu Bondapak column along with gradient elution of the drugs. The mobile phase consisted of 100% 0.5 M sodium acetate (pH 7.0) and 25% acetonitrile in 0.05 M sodium acetate (pH 5.5) with detection at 280 nm. Linearity was observed up to 500 micrograms/ml for DTIC and up to 53 micrograms/ml for AIC and 2-AZA. The assay methodology was reproducible, with a lower limit of detection of 5.0, 0.5, and 0.5 micrograms/ml for DTIC, AIC, and 2-AZA, respectively. Interday and intraday coefficients of variation ranged between 4 to 14% and 2 to 16%, respectively. The analytical method was applied to the analysis of plasma and urine samples resulting from the isolation perfusion chemotherapy of an extremity with 57 mg of DTIC per kg in a patient with melanoma.

5-(3-Hydroxymethyl-3-methyl-1-triazeno imidazole-4-carboxamide is a metabolite of 5-(3,3-dimethyl-1-triazeno)imidazole-4-carboxamide (DIC, DTIC NSC-45388).

The cancer chemotherapeutic drug, 5-(3,3-dimethyl-1-triazeno) imidazole-4-carboxamide (DIC, DTIC, NSC-45388), is metabolised in rats to a structurally related product which was detected by thin-layer chromatography. The novel metabolite has a lower mobility and a colour reaction that is indistinguishable from the parent compound. The metabolite is not retained on an anionic exchanger which is inconsistent with the expected covalent binding of the drug to endogenic anionic substrates (e.g. glucuronic acid). Since both DIC and the metabolite yielded 5-[(4-ethylamino-1-napthyl)-azo]imidazole-4-carboxamide through release of 5-diazoimidazole-4-carboxamide, followed by coupling with N-ethyl-1-napthylamine, no biotransformation (hydroxylation) of the imidazole moiety of the injected DIC had occurred. By corollary, the lowered chromatographic mobility of the metabolite was explicable by the introduction of a polar but non-acidic function into the terminal dimethylamino group of the triazene side-chain. The metabolite was identified as 5-(3-hydroxymethyl-3-methyl-1-triazeno)imidazole-4-carboxamide by co-chromatography with an authentic sample of HMIC and by its methylating capacity for nucleophilic substrates.