Suoping Zhai

Phase I Clinical and Pharmacokinetic Study of Flavopiridol Administered as a Daily 1-Hour Infusion in Patients With Advanced Neoplasms

PURPOSE To define the maximum-tolerated dose (MTD), dose-limiting toxicity, and pharmacokinetics of the cyclin-dependent kinase inhibitor flavopiridol administered as a daily 1-hour infusion every 3 weeks. PATIENTS AND METHODS Fifty-five patients with advanced neoplasms were treated with flavopiridol at doses of 12, 17, 24, 30, 37.5, and 52.5 mg/m(2)/d for 5 days; doses of 50 and 62.5 mg/m(2)/d for 3 days; and doses of 62.5 and 78 mg/m(2)/d for 1 day. Plasma sampling was performed to characterize the pharmacokinetics of flavopiridol with these schedules. RESULTS Dose-limiting neutropenia developed at doses >/= 52.5 mg/m(2)/d. Nonhematologic toxicities included nausea, vomiting, diarrhea, hypotension, and a proinflammatory syndrome characterized by anorexia, fatigue, fever, and tumor pain. The median peak concentrations of flavopiridol achieved at the MTDs on the 5-day, 3-day, and 1-day schedule were 1.7 micro mol/L (range, 1.3 to 4.2 micro mol/L), 3.2 micro mol/L (range, 1.7 to 4.8 micro mol/L), and 3.9 micro mol/L (1.8 to 5.1 micro mol/L), respectively. Twelve patients had stable disease for >/= 3 months, with a median duration of 6 months (range, 3 to 11 months). CONCLUSION The recommended phase II doses of flavopiridol as a 1-hour infusion are 37.5 mg/m(2)/d for 5 days, 50 mg/m(2)/d for 3 days, and 62.5 mg/m(2)/d for 1 day. Flavopiridol as a daily 1-hour infusion can be safely administered and can achieve concentrations in the micromolar range, sufficient to inhibit cyclin-dependent kinases in preclinical models. Further studies to determine the optimal schedule of flavopiridol as a single agent and in combination with chemotherapeutic agents are underway.

Flavopiridol, a Novel Cyclin-Dependent Kinase Inhibitor, in Clinical Development

OBJECTIVE: To review preclinical and clinical information on flavopiridol, an inhibitor of cyclin-dependent kinases (CDKs), tested as an antitumor agent. DATA SOURCES: Primary and review articles were identified by MEDLINE search (1990–June 2001). Abstracts from recent meetings were also used as source materials. DATA EXTRACTION: Flavopiridol was reviewed with regard to its mechanisms, preclinical and clinical results, pharmacokinetics, and metabolism. DATA SYNTHESIS: Flavopiridol is an inhibitor of several CDKs and displays unique anticancer properties. In addition to direct CDK inhibition, flavopiridol also exhibited other features such as inducing apoptosis in many cancer cell lines, decreasing cyclin D1 concentration, and inhibiting angiogenesis. Preclinical xenograft models showed significant antitumor activity for flavopiridol. The regimen using 72-hour continuous infusion every 2 weeks has been most extensively applied in clinical trials, with a 1-hour infusion currently being explored to achieve higher peak concentrations. Several Phase I and II trials have been reported, with some evidence of antitumor activity noted. Further Phase I and II trials using flavopiridol as a single agent and in combination with standard chemotherapeutic regimens and various tumor types are ongoing. CONCLUSIONS: Flavopiridol is the first CDK inhibitor to enter clinical trials. Several Phase I and Phase II clinical trials with different regimens (72-h or 1-h infusion) have been completed. Initial clinical trials have been intriguing, but many questions remain: What is the best regimen (≤72-h infusion)? Does optimal future development of this drug depend on the combination with other chemotherapy? What is the best combination of flavopiridol with other chemotherapy?

Phase II trial of carboxyamidotriazole in patients with relapsed epithelial ovarian cancer.

PURPOSE Carboxyamidotriazole (CAI) is a cytostatic inhibitor of nonvoltage-operated calcium channels and calcium channel-mediated signaling pathways. It inhibits angiogenesis, tumor growth, invasion, and metastasis. We hypothesized that CAI would promote disease stabilization lasting >/= 6 months in patients with relapsed ovarian cancer. PATIENTS AND METHODS Patients with epithelial ovarian cancer, good end-organ function, measurable disease, and three or fewer prior regimens were eligible. Oral CAI was given daily using a pharmacokinetic-dosing approach to maintain plasma concentrations between 2 and 4 microg/mL. Radiographic imaging to assess response was performed every 8 weeks. Positive outcome included stabilization or improvement of disease lasting >/= 6 months. Plasma vascular endothelial growth factor (VEGF), interleukin (IL)-8, and matrix metalloproteinase (MMP)-2 were measured. RESULTS Thirty-six patients were assessable for primary end point analysis, and 38 were assessable for toxicity. Forty-four percent of patients had three prior regimens, more than 50% had four or more disease sites, and 48% had liver metastases. Thirty-three patients reached the targeted concentration range during the first cycle. Eleven patients (31%) attained the >/= 6-month outcome end point, with one partial response (8 months) and three minor responses (8, 12+, and 13 months). Median time to progression was 3.6 months (range, 1.6 to 13.3 months). CAI was well tolerated, with mostly grade 1 to 2 toxicity. Grade 3 events included fatigue (5%), vomiting (2%), neutropenic fever (2%), and neutropenia (2%). There were no grade 4 adverse events. No associations between VEGF, IL-8, and MMP-2 with CAI concentration or clinical outcome were observed. CONCLUSION CAI is a potential agent for additional study in the stabilization of relapsed ovarian cancer. Given a limited toxicity profile, it may have utility as a maintenance therapeutic agent for this disease.

Concurrent Paclitaxel and Radiation in the Treatment of Locally Advanced Head and Neck Cancer

PURPOSE To determine the feasibility of an organ preservation regimen consisting of infusional paclitaxel administered concurrently with radiotherapy to patients with locally advanced head and neck squamous cell carcinoma (HNSCC). PATIENTS AND METHODS Thirty-three previously untreated patients with stage III or IV tumors were enrolled onto the study. Paclitaxel was administered as a 120-hour continuous infusion every 3 weeks during the course of radiation therapy. Sixteen patients received a paclitaxel dose of 105 mg/m(2), and 17 patients received 120 mg/m(2). Radiation was delivered in a standard format at 1.8 Gy/d to a total dose of 70.2 to 72 Gy. RESULTS Three months after therapy, a 76% complete response (CR) at the primary site and a 70% overall CR was achieved. At 36 months, locoregional control was 55.7%, overall survival was 57.8%, and disease-free survival was 51.1%. The median survival duration for all 33 patients was greater than 50 months at the time of this report. Local toxicities including mucositis, dysphagia, and skin reactions were severe but tolerable. All patients retained functional speech, and all but four patients were swallowing food 3 months after treatment. Steady-state plasma concentrations for paclitaxel were not achieved during a 120-hour infusion, suggesting a nonlinear process. Tumor volume quantified by pretreatment computerized tomography imaging was associated with likelihood of response and survival. CONCLUSION Paclitaxel administered as a 120-hour continuous infusion in combination with radiotherapy is a feasible and promising treatment for patients with advanced HNSCC.

A Phase I/II Study of Infusional Vinblastine with the P-Glycoprotein Antagonist Valspodar (PSC 833) in Renal Cell Carcinoma

Purpose: P-glycoprotein (Pgp) inhibitors have been under clinical evaluation for drug resistance reversal for over a decade. Valspodar (PSC 833) inhibits Pgp-mediated efflux but delays drug clearance, requiring reduction of anticancer drug dosage. We designed an infusional schedule for valspodar and vinblastine to mimic infusional vinblastine alone. The study was designed to determine the maximally tolerated dose of vinblastine, while attempting to understand the pharmacokinetic interactions between vinblastine and valspodar and to determine the response rate in patients with metastatic renal cell cancer. Patients and Methods: Thirty-nine patients received continuous infusion valspodar and vinblastine. Vinblastine was administered for 3 days to compensate for the expected delay in clearance and the required dose reduction. Valspodar was administered initially at a dose of 10 mg/kg/d; the dose of vinblastine varied. Results: The maximum-tolerated dose of vinblastine was 1.3 mg/m2/d. As suggested previously, serum valspodar concentrations exceeded those needed for Pgp inhibition. Consequently, the dose of valspodar was reduced to 5 mg/kg, allowing a vinblastine dose of 2.1 mg/m2/d to be administered. Pharmacodynamic studies demonstrated continued inhibition of Pgp at lower valspodar doses by functional assay in Pgp-expressing CD56+ cells and by 99mTc-sestamibi imaging. A 15-fold range in cytochrome P450 activity was observed, as measured by midazolam clearance. No major responses were observed. Conclusions: These results suggest that the pharmacokinetic impact of cytochrome P450 inhibition by valspodar can be reduced although not eliminated, while preserving Pgp inhibition, thus separating the pharmacokinetic and pharmacodynamic activities of valspodar.

Phase I trial of the cyclin-dependent kinase inhibitor flavopiridol in combination with Docetaxel in patients with metastatic breast cancer

Purpose: The purpose of this study was to determine the toxicities and characterize the pharmacokinetics of docetaxel and flavopiridol in patients with metastatic breast cancer. Experimental Design: Docetaxel was administered at an initial dose of 60 mg/m2 followed in 24 hours by a 72-hour infusion of flavopiridol at 50 mg/m2/d every 3 weeks. Because dose-limiting myelosuppression occurred, the schedule was amended to docetaxel, 50 mg/m2, followed by escalating doses of flavopiridol (starting dose, 26 mg/m2/d) as a 1-hour infusion daily for 3 days. Pharmacokinetic studies were performed. Ki67, p53, and phosphorylated retinoblastoma protein (phospho-Rb) in paired tumor and buccal mucosa biopsies (obtained pre- and posttreatment) were examined by immunohistochemistry. Results: Eleven patients were enrolled. Five patients received docetaxel and 72-hour flavopiridol. Dose-limiting toxicity was grade 4 neutropenia. Six patients received docetaxel and 1-hour flavopiridol, and the dose-limiting toxicity was grade 3 hypotension. Pharmacokinetics of flavopiridol and docetaxel were consistent with historical data. Nuclear staining with p53 increased and phospho-Rb decreased in 10 pairs of buccal mucosa biopsies posttreatment (P = 0.002 and P = 0.04, respectively). No significant changes in Ki67, p53, or phospho-Rb were detected in six paired tumors. Two patients sustained stable disease for >3 months (72-hour flavopiridol), and one partial response was observed (1-hour flavopiridol). Conclusions: Docetaxel combined with 72-hour flavopiridol was not feasible because of dose-limiting neutropenia. Dose escalation of a 1-hour infusion of flavopiridol with docetaxel was also not possible. The changes in p53 and phospho-Rb in buccal mucosa suggest that a biological effect with flavopiridol was achieved.

Laparoscopic continuous hyperthermic peritoneal perfusion.

Peritoneal carcinomatosis occurs as an advanced stage of certain malignancies and is often considered incurable. 1 No good standard treatment options exist, so new and innovative treatments must be sought and investigated to combat this stage of disease. These treatments may be used as an adjuvant after surgical resection or to palliate symptoms such as ascites in patients with bulky disease. Regional intraperitoneal chemotherapy provides prolonged high concentration of a cytotoxic agent directly to intraperitoneal tumor cells while limiting systemic exposure of the patient to the drug. It has been shown to improve results compared with systemic chemotherapy alone in patients with ovarian cancer. 2 Continuous hyperthermic peritoneal perfusion (CHPP) is a method by which heated cytotoxic chemotherapy is recirculated at high flow rates through the peritoneal cavity. 3 This technique is designed to improve distribution of the chemotherapy in the peritoneal cavity and take advantage of known synergy between chemotherapy and hyperthermia. Although this has been previously performed after open laparotomy and complete lysis of adhesions, we describe here a minimally invasive approach that may be more appropriate for many clinical settings.