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Increased Bioavailability of Intravenous Versus Oral CI-1033, a Pan erbB Tyrosine Kinase Inhibitor: Results of a Phase I Pharmacokinetic Study

Authors' Affiliations: ¹ H. Lee Moffitt Cancer Center, Tampa, Florida and ² Pfizer Global Research and Development, Ann Arbor, Michigan

Requests for reprints: George R. Simon, H. Lee Moffitt Cancer Center and Research Institute, Division of Thoracic Oncology, 12902 Magnolia Drive, MRC-4W, Tampa, FL 33612. Phone: 813-972-8372; Fax: 813-979-3027; E-mail: simongr{at}moffitt.usf.edu.

	Abstract

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Purpose: In phase I studies with oral CI-1033, dose-limiting toxicities were primarily gastrointestinal, supporting the exploration of i.v. dosing to achieve optimal drug exposures by increasing bioavailability.

Experimental Design: Fifty-three patients with advanced nonhematologic malignancies received i.v. CI-1033 via 30-minute infusions (10-500 mg) on a thrice-weekly schedule. Pharmacokinetic samples were collected on days 1 and 8 and evaluated using noncompartmental analysis.

Results: Dose levels evaluated were 10, 20, 30, 45, 67.5, 100, 150, 225, 337.5, and 500 mg. The maximum administered dose was 500 mg, whereas the maximum tolerated dose was 225 mg. The most common treatment-related grade 1 to 2 adverse events were rashes (38% of patients), nausea (17%), vomiting (17%), stomatitis (14%), and diarrhea (13%). Most common grade 3 adverse events were hypersensitivity reactions (7.5%), rashes (3.8%), and diarrhea (3.8%). No grade 4 toxicities were observed. Ten of the 53 (19%) patients had disease stabilization at their first efficacy evaluation visit (including two with minor responses). A 5- to 10-fold increase in i.v. C_max was noted with a 3-fold increase in AUC compared with oral CI-1033 at equivalent doses. Treatment-related gastrointestinal adverse events were notably less frequent with this i.v. regimen.

Conclusions: CI-1033 was safely given i.v. up to 225 mg/dose on a thrice-weekly schedule, with evidence of antitumor activity. At equivalent doses, the bioavailability of i.v. CI-1033 is thrice that of the oral formulation. Treatment with i.v. CI-1033 is feasible and may be warranted when increased drug exposures are desired.

CI-1033 (canertinib dihydrochloride; Pfizer Global Research and Development, Ann Arbor, MI; Fig. 1 ) is an orally bioavailable 3-chloro,4-fluoro,4-anilinoquinazoline. It irreversibly inhibits the tyrosine kinase (TK) domain of all erbB members (7) by alkylation of the cysteine in the TK domain of the erbB receptors.

View larger version (6K): [in this window] [in a new window] [Download PPT slide]   Fig. 1. CI-1033 (canertinib dihydrochloride; Pfizer Global Research and Development) is an orally bioavailable 3-chloro,4-fluoro,4-anilinoquinazoline. It irreversibly inhibits the TK domain of all erbB members by alkylation of the cysteine in the TK domain of the erbB receptors.

In phase I studies with oral CI-1033, dose-limiting toxicities (DLT) were primarily gastrointestinal (7). Based on the mechanism of action, it was hypothesized that the gastrointestinal toxicity may be a function of local drug effects as well as systemic drug action, and that an i.v. formulation might ameliorate the gastrointestinal toxicities thus allowing for further dose escalation. Here, we report the results of a phase I trial with i.v. CI-1033 designed to increase the bioavailability of the drug beyond those achieved by using the drug orally at the maximum tolerated dose (MTD).

	Materials and Methods

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Study design
This was an open-label, noncomparative, single center, dose escalation trial of i.v. CI-1033 in patients with advanced solid tumors to establish the MTD and DLT of the i.v. dosing schedule and to compare the bioavailability of the i.v. preparation at its MTD with the oral formulation of CI-1033 at its MTD.

Patient selection
Patients with histologically documented, advanced-stage nonhematologic malignancies that were refractory to standard therapy, or for whom no effective therapy existed, were candidates for this study. Eligibility criteria were: (a) age 18 years; (b) Karnofsky performance status 60%; (c) life expectancy of at least 12 weeks; (d) no chemotherapy within 4 weeks before the first dose of CI-1033 and no hormonal therapy, immunotherapy, or radiotherapy within 2 weeks; (e) adequate hematopoietic (absolute neutrophil count 1,500/µL, platelet count 100,000/µL), hepatic (total bilirubin 1.5 times the institutional upper normal limit, aspartate amino transaminase, and alanine amino transaminase 3 times the institutional upper normal limit); and renal function (calculated creatinine clearance 45 mL/min; ref. 19); and (f) no concurrent serious infection or coexisting medical problem of sufficient severity to potentially limit full compliance with the protocol. All patients gave written informed consent before entry into the study in accordance with federal and institutional guidelines.

Dosage and drug administration
At the beginning of the study, CI-1033 was administered as a single i.v. dose over 30 minutes thrice a week with at least 1 day between doses (e.g., Monday, Wednesday, and Friday) for 4 consecutive weeks followed by 2 weeks without treatment. Before escalation to the next higher dose level, patients who did not receive all protocol-specified study medication doses during the first 4 weeks of therapy for reasons other than a DLT were replaced in order to achieve a full cohort of at least three patients per cohort.

Dose escalation started at the 10 mg dose (schedule A), with subsequent dose escalations at 20, 30, 45, 67.5, and 100 mg (see Table 1 for dose escalation schema). At the 100 mg dose, after obtaining regulatory approval, the dosing schedule was modified to a continuous regimen (schedule B), thrice a week (without the 2-week interruption). Dose escalation then continued in schedule B, with the 150, 225, 337.5, and 500 mg dose levels being explored.

CI-1033 was supplied by Pfizer Global Research and Development (Ann Arbor, MI) as a solution of 2.5 mg/mL in two different vial sizes: a 75 mg vial containing 30 mL of CI-1033 in solution, and a 250 mg vial containing 100 mL of CI-1033 in solution (2.5 mg/mL x 100 mL = 250 mg). An absolute dose was administered irrespective of the body surface area and weight of the patient based on the results of previous pharmacokinetic studies that did not show a relationship between clearance with either body weight or body surface area.

Pharmacokinetic evaluations
Pharmacokinetic sampling. Plasma samples were collected on days 1 and 8 before the infusion, 10, 20, and 30 minutes after the start of the infusion and at the following times after the end of the infusion: 5, 10, 20, and 40 minutes and 1, 2, 4, and 8 hours for pharmacokinetic profiling. Plasma samples were stored and shipped at –20°C or less until the time of assay. CI-1033 stability under these conditions exceeds the retention time for all samples collected in this study.

Assay. CI-1033 was isolated from potassium EDTA/ascorbic acid–treated human plasma using a protein precipitation reaction. Internal standard [³H]-CI-1033 was added to the protein precipitation reagent (acetonitrile). Analysis was conducted by liquid chromatography-tandem mass spectrometry using multiple reaction monitoring. Regression variables were estimated using a linear model with reciprocal squared response weighting and used to back-calculate QC and patient sample concentrations. The range of quantitation for CI-1033 as determined by suitable (<10% absolute error) accuracy and precision was 1.00 to 500 ng/mL in potassium EDTA/ascorbic acid–treated human plasma, based on a sample volume of 0.2 mL. QC overall precision (%CV) was 9.9%, whereas QC overall accuracy (%RE) ranged from –7.7% to –1.6% (20). Matrix effects were not observed.

CI-1033 was assayed in urine without extraction. A 50 µL aliquot of urine was diluted with 30 ng/mL of internal standard in acetonitrile and assayed directly by liquid chromatography-tandem mass spectrometry using multiple reaction monitoring. The range of quantitation for CI-1033, as determined by suitable accuracy and precision, was 10 to 500 ng/mL, based on a sample volume of 50 mL. QC overall precision (%CV) was 13.0%, whereas QC overall accuracy (%RE) ranged from –5.08% to 6.56%.

Data analysis. Plasma CI-1033 pharmacokinetic variable values were calculated for each subject for each treatment using noncompartmental analysis of concentration-time data. Samples below the limit of quantitation were reported as zero. Nominal sample collection times were used for pharmacokinetic analysis and the generation of mean profiles. Pharmacokinetic variable values were calculated using WinNonlin version 4.0.1. Plasma and urine CI-1033 concentration-time profiles were inspected visually for similarities to and difference from a typical profile following oral dosing.

	Results

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Fifty-three patients with advanced nonhematologic malignancies received i.v. CI-1033 via 30-minute infusions (10-500 mg) on a thrice weekly schedule (please see dose escalation schema in Table 1). Patients were initially given treatment 4 out of 6 weeks, and subsequently, the protocol was modified to allow continuous dosing without interruption. Pharmacokinetic samples were collected on days 1 and 8 and evaluated using noncompartmental analysis.

Thirty-one men and 22 women were treated (please see Table 2 ). The median Karnofsky performance status was 90 with the range being 70 to 100. The median age was 64 (range, 23-78). Patients with NSCLC (n = 14), colorectal cancer (10), mesothelioma (10), melanoma (5), breast cancer (2), sarcoma (2), head and neck cancer (2), carcinoma of unknown primary (2), and one each with cancers of the endometrium, thyroid, anus, kidney, round cell tumor, and bladder were enrolled. Patients were enrolled in the 10, 20, 30, 45, 67.5, 100, 150, 225, 337.5, and 500 mg dose levels. The maximum administered dose was 500 mg. Two DLTs occurred in the three patients enrolled at this dose level, a grade 3 myalgia and syncope secondary to prolonged corrected QT interval in the EKG. Three additional patients were then enrolled at the 337.5 mg dose level. Out of the seven patients enrolled in this dose level, two DLTs were encountered which were grade 3 hypersensitivity reaction and grade 3 diarrhea. Hence, the next lower dose level, i.e., 225 mg dose level, at which seven patients were previously treated, was determined to be the MTD.

The stomatitis encountered in this study was mild and palliated easily with routine measures. Interestingly the occurrence of stomatitis seemed to coincide with the presence of rashes.

Hypersensitivity reactions were seen in this trial and were the DLT at both the maximum administered doses of 500 and 337.5 mg. These reactions almost always occurred in the first cycle (although not necessarily with the first dose). Two grade 3 hypersensitivity reactions occurred with the first cycle and these patients were not rechallenged. In all other instances, patients were rechallenged after prophylaxis with steroids and/or benadryl, and/or just by doubling the time of infusion. Subsequently, in some instances, we were able to continue treatment without steroid and/or benadryl prophylaxis and were able to continue infusion at the regular rate. In some instances, patients continued to require the additional premedications and/or a slower rate of infusion but were able to continue with treatment.

Dyspnea was reported by 19% of the patients. In all instances they were grade 1 or 2. All patients were evaluated as the clinical situation mandated. On workup, two patients were found to have atrial fibrillation and one patient was found to have a deep venous thrombosis with a suspected pulmonary embolism. Other patients required treatment for possible infectious bronchitis or for their chronic obstructive pulmonary disease. Generalized myalgia was reported by 19% of the patients. In all instances, they were grade 1 or 2 and were well palliated with acetaminophen.

Thrombocytopenia was seen only in schedule B and was spread across all dose levels and did not seem to be dose-related. In all instances, it was grade 1 or 2 and treatment was continued without a further drop in platelets. There were no clinical manifestations associated with these episodes of thrombocytopenia. The thrombocytopenia seemed to be idiosyncratic rather than dose related.

In the majority of patients, treatment was discontinued secondary to progressive disease. Only at the maximum administered doses was treatment discontinued secondary to toxicity. At the MTD, i.v. CI-1033 was well tolerated.

Pharmacokinetics. Pharmacokinetic profiles were obtained in all patients. Four patients discontinued treatment prior to characterization of the day 8 profile. Data for these patients are included in the day 1 analysis and in both graphical and tabular study summaries. Urinary excretion of the parent drug represented a small percentage of the administered dose and will not be further evaluated.

Systemic exposure was dose-proportional and without accumulation under this thrice weekly dosing regimen (Table 4 ). Elimination was strongly multiphasic with an initial distribution phase apparent over the first 2 to 3 hours following infusion. Concentrations dropped to 30% of their respective peak values within 20 minutes of stopping the infusion (see Fig. 2 for a representative pharmacokinetic graph at the 100 mg dose level). Within 2 to 4 hours of stopping the infusion, concentrations were 10% of respective peak values and approximated those observed following oral administration of a bioequivalent dose (Fig. 3 ). Subsequent elimination approximated that observed following oral dosing and was characterized by an elimination half-life of 3 to 4 hours. Total body clearance and the respective volume of distribution (CL/K_el) averaged 73 L/h and 371 L, respectively.

View larger version (12K): [in this window] [in a new window] [Download PPT slide]   Fig. 2. CI-1033 plasma concentration-time curve after treatment with 100 mg of CI-1033 i.v. on days 1 and 8. Elimination was strongly multiphasic with an initial distribution phase apparent over the first 2 to 3 hours following infusion. Concentrations dropped to 30% of their respective peak values within 20 minutes of stopping the infusion. Day 1 and day 8 concentration-time curves were essentially identical.

View larger version (11K): [in this window] [in a new window] [Download PPT slide]   Fig. 3. Relative systemic exposure following i.v. dosing at the MTD (225 mg) as well as oral dosing at the MTD (500 mg) and at a dose (725 mg) bioequivalent to the i.v. MTD. Within 2 to 4 hours of stopping the infusion, concentrations were 10% of respective peak values and approximated those observed following oral administration. Subsequent elimination approximated that observed following oral dosing and was characterized by an elimination half-life of 3 to 4 hours.

	Discussion

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Despite an 20-fold increase in C_max and 3-fold increases in AUC following i.v. administration compared with oral administration at equivalent doses, treatment-related gastrointestinal adverse events were notably less frequent with this regimen (Table 5 ). Although plasma CI-1033 concentrations during and shortly after a 30-minute infusion greatly exceed those achieved during oral dosing, these exposures were transient and converged with those more typical of oral regimens within a few hours (Fig. 3). The brief nature of this relatively high exposure, together with avoidance of direct exposure of the gastrointestinal tract to the drug may have facilitated achieving an MTD that, whereas lower (225 versus 500 mg), provided an almost 10-fold increase in C_max and 50% increase in AUC.

Erlotinib, on the other hand, is used at its MTD and has shown statistically significant improvement in survival of unselected patients with previously treated NSCLC. Erlotinib is currently being evaluated in several malignancies other than NSCLC.

Hence, oral EGFR-TKIs have only found a limited role in the clinic, despite the demonstrable overexpression of EGFRs in a wide variety of epithelial tumors. Currently, its use is confined to previously treated advanced-stage NSCLC. The gefitinib/erlotinib experience suggests the wider clinical applicability of EGFR-TKIs if used at its MTD. We therefore speculate that increasing the bioavailability of EGFR-TKIs by its i.v. use may further extend their clinical application(s). Here we show that i.v. CI-1033 increases drug exposures, with very little variability between doses, versus the oral preparation.

Patients with NSCLC that harbor EGFR mutations activate the phosphatidylinositol-3 kinase (PI3K)/Akt survival pathway. This pathway is also a major effector of mutant K-ras signaling. Therefore, in tumors bearing EGFR mutations, treatment with EGFR-TKIs leads to tumor regression owing to brisk tumor apoptosis. In contrast, the wild-type EGFR is a weak activator of PI3K/Akt. In these tumors, the PI3K/Akt pathway may be predominantly activated by other signaling inputs (i.e., K-ras, etc.). Hence, in tumors with wild-type EGFR, treatment with EGFR-TKIs may not have a major inhibitory effect on PI3K/Akt, potentially explaining the lack of antitumor activity in NSCLC with K-ras mutations (27). This would argue against obtaining improved benefit by increasing drug exposures.

However, other markers associated with sensitivity to EGFR inhibitors have been described (28). Increased EGFR gene copy numbers based on fluorescence in situ hybridization analysis may be a good predictive marker for response, stable disease, time to progression, and survival. The optimal paradigm for selection of patients for treatment with EGFR-TKIs is yet to be determined and validated in prospective clinical trials (29–31). Designing clinical trials with i.v. EGFR-TKIs in a selected population of patients who do not have the activation mutations but who overexpress EGFR by fluorescence in situ hybridization may be a prudent strategy.

Based on this phase I experience, we conclude that the i.v. formulations of EGFR-TKIs CI-1033 allows for increased drug exposures that may be of clinical relevance in select group of patients. The oral bioavailability of CI-1033 is about one-third of that observed following i.v. dosing. Additionally, with respect to CI-1033, variability in drug exposure is reduced through i.v. administration. Day 1 and day 8 profiles in this study showed remarkable similarity within individual patients (Fig. 2). Hence, disease-specific phase II trials, in a well-selected population of patients, may be warranted with i.v. formulation of CI-1033. It is likely that this paradigm could be extended to other EGFR-TKIs as well.

Nevertheless, the inconvenience of continuous i.v. use of CI-1033 is a significant deterrent to widespread clinical use and may not be justified secondary to the rapid lowering of peak concentrations to approximate those observed following oral administration at a bioequivalent dose a few hours after the conclusion of the infusion. Therefore, a loading dose followed by an oral maintenance may be an alternative strategy that is both practical and backed by pharmacokinetic observations. Studies exploring weekly or 3-weekly cycles may therefore be justified with the EGFR-TKI being given i.v. initially followed by daily oral doses for the rest of the cycle. At the very least, the clearly shown decrease in gastrointestinal toxicity by the i.v. preparation may allow for the continued use of CI-1033 in patients who are unable to tolerate the drug owing to gastrointestinal toxicities.

	Footnotes

 
Grant support: Pfizer Global Research and Development.

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Received 11/ 1/05; revised 3/14/06; accepted 4/26/06.

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