Phase I, Single-Dose Study to Assess the Pharmacokinetics and Safety of Suramin in Healthy Chinese Volunteers.

Purpose: Suramin is a multifunctional molecule with a wide range of potential applications, including parasitic and viral diseases, as well as cancer. Methods: A double-blinded, randomized, placebo-controlled single ascending dose study was conducted to investigate the safety, tolerability, and pharmacokinetics of suramin in healthy Chinese volunteers. A total of 36 healthy subjects were enrolled. All doses of suramin sodium and placebo were administered as a 30-minute infusion. Blood and urine samples were collected at the designated time points for pharmacokinetic analysis. Safety was assessed by clinical examinations and adverse events. Results: After a single dose, suramin maximum plasma concentration (Cmax) and area under the plasma concentration-time curve from time zero to the time of the last measurable concentration (AUClast) increased in a dose-proportional manner. The plasma half-life (t1/2) was dose-independent, average 48 days (range 28-105 days). The cumulative percentages of the dose excreted in urine over 7 days were less than 4%. Suramin can be detected in urine samples for longer periods (more than 140 days following infusion). Suramin was generally well tolerated. Treatment-emergent adverse events (TEAEs) were generally mild in severity. Conclusion: The PK and safety profiles of suramin in Chinese subjects indicated that 10 mg/kg or 15 mg/kg could be an appropriate dose in a future multiple-dose study.

Repurposing suramin for the treatment of breast cancer lung metastasis with glycol chitosan-based nanoparticles.

Suramin (SM), a drug for African sleeping sickness and river blindness therapy, has been investigated in various clinical trials for cancer therapy. However, SM was eventually withdrawn from the market because of its narrow therapeutic window and the side effects associated with multiple targets. In this work, we developed a simple but effective system based on a nontoxic dose of SM combined with a chemotherapeutic agent for the treatment of metastatic triple-negative breast cancer (TNBC). SM and glycol chitosan (GCS) formed nanogels because of the electrostatic effect, whereas doxorubicin (DOX) was incorporated into the system through the hydrophilic and hydrophobic interactions between DOX and GCS as well as the ionic interactions between DOX and SM to yield GCS-SM/DOX nanoparticles (NPs). GCS-SM/DOX NPs have a size of approximately 186 nm and a spherical morphology. In vitro experiments showed that GCS-SM NPs could effectively inhibit cancer cell migration and invasion, as well as angiogenesis. Furthermore, in a TNBC lung metastasis animal model, GCS-SM/DOX NPs significantly reduced tumor burden and extended the lifespan of animals, while not inducing cardio and renal toxicities associated with the DOX and SM, respectively. As all the components used in this system are biocompatible and easy for large-scale fabrication, the GCS-SM/DOX system is highly translatable for the metastatic breast cancer treatment. STATEMENT OF SIGNIFICANCE: The doxorubicin-loaded glycol chitosan-suramin nanoparticle (GCS-SM/DOX) is novel in the following aspects: SM acts as not only a gelator for the first time in the preparation of the nanoparticle but also an active pharmaceutical agent in the dosage form. GCS-SM/DOX NP significantly reduced tumor burden and extended the lifespan of animals with triple-negative breast cancer lung metastasis. GCS-SM/DOX NPs attenuate cardio and renal toxicities associated with the DOX and SM. The GCS-SM/DOX system is highly translatable because of its simple, one-pot, and easy-to-scale-up preparation protocol.

Noncytotoxic suramin as a chemosensitizer in patients with advanced non-small-cell lung cancer: a phase II study.

BACKGROUND: The purpose of this study was to evaluate the potential of noncytotoxic doses of suramin to reverse chemotherapy resistance in advanced chemonaive and chemoresistant non-small-cell lung cancer patients. PATIENTS AND METHODS: Patients received paclitaxel (Taxol) (200 mg/m(2)) and carboplatin (area under the concentration-time curve 6 mg/ml/min) every 3 weeks. The total suramin per cycle dose was calculated using a nomogram derived from the preceding phase I trial to obtain the desirable plasma concentration range of 10-50 microM. RESULTS: Thirty-nine response-assessable chemonaive patients (arm A) received 213 cycles. Thirty-eight cycles were administered to 15 patients with demonstrated resistance to paclitaxel and carboplatin (arm B). The pattern/frequency of toxic effects was similar to those expected for paclitaxel/carboplatin, and pharmacokinetic analyses (199 cycles) showed suramin plasma concentrations maintained between 10 and 50 microM in 94% of cycles. In arm A, response evaluation criteria in solid tumors (RECIST) response rate was 36% (95% confidence interval 22% to 54%; two complete, 12 partial); 15 patients (38%) had disease stabilization for > or =4 months; median progression-free survival (intention to treat) was 6.4 months; median overall survival (OS) 10.4 months and 1-year survival rate 38%. In arm B, no RECIST responses occurred; four patients had disease stabilization for > or =4 months; median OS was 132 days and 1-year survival rate 7%. Plasma basic fibroblast growth factor levels were higher in chemopretreated/refractory patients compared with chemonaive patients (P = 0.05). Sequence analysis of the EGFR tyrosine kinase domain in a long-term disease-free survivor revealed an ATP-binding pocket mutation (T790M). CONCLUSIONS: Noncytotoxic suramin did not increase paclitaxel/carboplatin's toxicity and the suramin dose was predicted from clinical parameters. No clinically significant reversal of primary resistance was documented, but a modulatory effect in chemotherapy-naive patients cannot be excluded. Controlled randomization is planned for further evaluation of this treatment strategy.

Phase I/II trial of 5-fluorouracil and a noncytotoxic dose level of suramin in patients with metastatic renal cell carcinoma.

BACKGROUND: Renal cell carcinoma (RCC) is recognized as a neoplasm resistant to chemotherapy. In vitro experiments demonstrated that suramin, at noncytotoxic doses, enhanced the activity of chemotherapy including 5-fluorouracil (5-FU) in xenograft models. PATIENTS AND METHODS: A phase I/II trial of noncytotoxic suramin in combination with weekly 5-FU in patients with metastatic RCC was conducted. The treatment consisted of intravenous (i.v.) suramin followed by a 500 mg/m2 i.v. bolus of 5-FU given 4.5 hours after starting suramin. In the phase I portion, a cohort of 6 patients received a suramin dose calculated to achieve a plasma level of 10-50 micromol/L. Therapy was administered once weekly for 6 doses, followed by 2 weeks off. This was followed by a phase II portion in which the primary goal was to determine the objective response rate. RESULTS: Twenty-three patients were enrolled in the study: 6 in the phase I portion and 17 in phase II. Seventy-eight percent of patients were men, the mean age was 58.8 years, 96% had previous nephrectomy, and 70% had received previous systemic therapy. Histologic subtype was clear cell in 91%. Dose-limiting toxicity was observed in 1 of 6 patients (grade 3 hypersensitivity related to suramin infusion). The suramin dosing nomogram used in phase I and II portions of the trial yielded the desired plasma level of 10-50 micromol/L from 4.5 hours to 48 hours after infusion in 94 of 115 treatments. No objective responses were noted, and the median time to treatment failure was 2.5 months. The major toxicities (all grades) were fatigue (83%), nausea/vomiting (78%), diarrhea (61%), and chills (61%). CONCLUSION: Suramin levels expected to reverse fibroblast growth factor-induced resistance can be achieved with the dosing regimen used in this study. The toxicity observed with suramin and 5-FU was acceptable. The combination does not have clinical activity in patients with metastatic RCC.

Self-assembled nanocomplex of PEGylated protamine and heparin-suramin conjugate for accumulation at the tumor site.

Heparin-like sulfated polysaccharides are potential drug candidates owing to their ability to interact with angiogenic factors and inhibit angiogenesis, tumor growth, and metastasis. This study aimed to improve the delivery of heparin-like anticancer polysaccharides for accumulation at the tumor site. We designed a nanocarrier system using protamine attached to polyethylene glycol (PEG) and evaluated the stability, tumor targeting, and tumor growth inhibition of the nanocarrier loaded with heparin derivatives. When mixed with various polyanionic heparin derivatives, the polycationic PEG-protamine formed stable self-assembled nanocomplexes via ionic interactions, with flexible PEG chains located on the outside. Among the complexes, a nanocomplex loaded with a low-molecular-weight heparin-suramin conjugate (LHsura) had the most suitable average size (101.9nm) for the enhanced permeability and retention effect and allowed accumulation of LHsura at the tumor site for up to 48h. In a tumor-bearing mouse model, the PEG-protamine and LHsura nanocomplex (10mg/kg/3days, intravenously), which could be extravasated through the tumor vasculature, significantly inhibited tumor growth, more than LHsura alone did. Overall, the self-assembled nanocomplexation of PEG-protamine and LHsura helped control the release and extravasation of LHsura, which resulted in an antitumor effect on the target tumor cells.

Suramin, an active drug for prostate cancer: interim observations in a phase I trial.

BACKGROUND: Previous studies indicate that suramin may be an active agent for treatment of solid tumors. The clinical use of suramin is complicated by a broad spectrum of toxic effects and complex pharmacology. Studies have suggested that the dose-limiting neurotoxicity of this agent is closely related to sustained plasma drug concentrations of 350 micrograms/mL or more. PURPOSE: This phase I clinical trial in patients with solid tumors was designed to determine whether plasma concentrations resulting in both antitumor activity and manageable toxicity could be achieved with short, intermittent infusions of suramin. METHODS: Thirty-seven patients, including 33 with metastatic, hormone-refractory prostate cancer, collectively received 43 courses of suramin designed to maintain a plasma concentration range of 200-300, 175-275, or 150-250 micrograms/mL. Patients received a test dose of 200 mg and an initial loading dose of 1000 mg/m2 on day 1 of therapy. Subsequent suramin doses and schedules were individually determined using a strategy of adaptive control with feedback, which used a maximum a posteriori Bayesian algorithm to estimate individual pharmacokinetic parameters. Patients were treated until dose-limiting toxicity or progressive disease developed. RESULTS: Thirty-five of the 37 study patients and 31 of the 33 with prostate cancer were assessable for toxicity and response. Treatment was discontinued in 28 patients because of dose-limiting toxicity consisting of a syndrome of malaise, fatigue, and lethargy; recurrent reduction in creatinine clearance of 50% or more; or axonal neuropathy. Evidence of major antitumor activity was observed in patients with prostate cancer treated at all three plasma drug concentrations. Measurable responses (one complete response and five partial responses) were noted in six of 12 patients with measurable disease. Twenty-four (77%) of 31 patients had a reduction in prostate-specific antigen of 50% or more, and 17 (55%) of 31 had a reduction of 75% or more. Twenty (83%) of 24 patients reported reduction in pain. CONCLUSIONS: Suramin can be safely administered as an intermittent bolus injection by use of adaptive control with feedback to control plasma drug concentrations; toxicity is significant but manageable and reversible. Suramin is active against hormone-refractory prostate cancer. IMPLICATIONS: Future trials should address the role and necessary extent of therapeutic drug monitoring; the optimal plasma drug concentration range and duration of therapy; and the activity of suramin in combination with other agents, in earlier stages of prostate cancer, and in other tumor types.

Phase I evaluation of low-dose suramin as chemosensitizer of doxorubicin in dogs with naturally occurring cancers.

BACKGROUND: Low and nontoxic concentrations (10-50 microM) of suramin, which is a nonspecific inhibitor of multiple growth factors, including fibroblast growth factors, enhances the activities of cytotoxic chemotherapeutic agents, such as doxorubicin and paclitaxel, both in vitro and in vivo. Suramin has not been evaluated as a chemosensitizing agent in dogs with cancer. HYPOTHESIS: Nontoxic suramin can be used safely as a chemosensitizer in dogs. ANIMALS: Sixteen dogs of various breeds with measurable tumors were treated; 1 dog that had undergone amputation for osteosarcoma received adjuvant therapy. METHODS: The dogs received 53 courses of treatment with suramin in combination with doxorubicin. The suramin dosage was 6.75 mg/kg IV 3 h before standard doxorubicin administration every 2 weeks. The pharmacokinetics and clinical efficacy were determined. RESULTS: The pharmacokinetics of low-dose suramin followed a 2-compartment model with half-lives of 2 h and 6 days. The distribution volume was a 0.34 +/- 0.12 L/kg, and clearance was 1.86 +/- 0.76 mL/kg/h. During the time interval that doxorubicin was present at therapeutically active concentrations (ie, from the start of infusion to 24 hours), the plasma concentrations were maintained within 20% of the target range (8-60 microM) in 72% of the treatments. The toxicity of the suramin/doxorubicin combination was mild and comparable to the toxicity expected for doxorubicin monotherapy. Objective partial responses were observed in 2 out of 16 evaluable dogs (13%). All 5 dogs that previously received doxorubicin showed improved responses to the suramin/doxorubicin combination. CONCLUSIONS AND CLINICAL IMPORTANCE: A fixed, low-dose suramin regimen yields the desired target plasma concentrations in most dogs, and appears to enhance the activity of doxorubicin without enhancing toxicity.

Use of adaptive control with feedback to individualize suramin dosing.

Suramin is the first putative growth factor inhibitor in clinical trial that has demonstrated antitumor activity. Administration of suramin is complicated by a narrow therapeutic index and significant interpatient variability of measured pharmacokinetic parameters. Because both antitumor response and dose-limiting toxicities are related to plasma suramin concentration profiles, individualized dose schedules are required for optimal administration of the compound. In this report, the use of optimal sampling theory to derive sparse data monitoring and control strategies for use with suramin is described. A fixed rate continuous infusion schedule was used in seven patients, and the time to peak concentration (280-300 micrograms/ml) ranged from 7.7-21 days (mean, 13.2 days) with a decline to 150 micrograms/ml in 3-22 days (mean, 11 days). An initial population pharmacokinetic model was fit using a maximum likelihood algorithm. The mean volume of the central compartment was 4.5 +/- 6.7 liters/m2, volume of the peripheral compartment 10.6 +/- 1.4 liters/m2, distributional half-life 25 +/- 5.4 h, and elimination half-life 29.7 +/- 6.9 h. The terminal half-life was shorter than previously reported. These parameters were used as the initial population model for an iterative 2-stage analysis. The resulting distributional half-life of 22.3 +/- 2.7 h and elimination half-life of 28.2 +/- 5.0 h were similar, reflecting the intensive sampling. The iterative 2-stage analysis model was then used to determine the optimal sampling times and to simulate 20 data sets for a protocol designed to maintain plasma concentrations in a defined concentration range. This strategy is currently under investigation in phase I clinical trials.

Development and characterization of suramin-resistant Chinese hamster fibrosarcoma cells: drug-dependent formation of multicellular spheroids and a greatly enhanced metastatic potential.

Suramin-resistant DC-3F/SU 1,000 Chinese hamster fibrosarcoma cells were obtained by continuous exposure of parental DC-3F cells to increasing concentrations of suramin (1 mg/ml final concentration). These cells are 10-fold more resistant to suramin compared to the parental cell line as determined by colony formation in the continuous presence of drug; the 50% effective dose for DC-3F is 35 micrograms/ml whereas the 50% effective dose for DC-3F/SU 1,000 is 380 micrograms/ml. The resistance is not due to reduced drug accumulation and is stable for at least 10 months in the absence of drug. Sensitive and resistant cells show comparable growth rate, cell size, and DNA content. In the presence of suramin, DC-3F/SU 1,000 cells form big multicellular spheroids which regrow as monolayer cultures when the drug is removed. Similar morphological changes are not observed for sensitive DC-3F cells exposed to isotoxic doses of suramin but appeared early on during the development of resistance. Inoculation of DC-3F or DC-3F/SU 1,000 cells s.c. into nude mice results in 100% tumor take within 1 week for both groups. Although the tumor size increases at the same rate, only animals given injections of DC-3F/SU 1,000 cells show extensive and persistent s.c. hemorrhages around the tumor. By 3 weeks, 30% of DC-3F-injected mice (9 of 30) show approximately 5 metastases/lung compared to -262 metastases/lung in 100% of DC-3F/SU 1,000-inoculated mice (30 of 30). These findings have several important implications: (a) given the fact that suramin is currently used clinically, special precaution may be warranted in patients undergoing suramin treatment; (b) the drug may possess an unusual potential to interfere with processes essential to invasion and metastasis which, when properly used, may result in the development of antimetastatic therapies; and (c) suramin may serve as a model compound for other molecules of the antiangiogenic and/or antimetastatic type.

Phase II trial of suramin in patients with advanced renal cell carcinoma: treatment results, pharmacokinetics, and tumor growth factor expression.

Twenty-six patients with advanced renal cell carcinoma were treated with suramin administered by continuous infusion, with dosing determined by a nomogram. One patient achieved a partial response and five patients achieved a minor response or had stable disease for > 3 months. Toxicities included an immune-mediated thrombocytopenia in one patient and Staphylococcus sepsis that was not associated with neutropenia in five patients. Pharmacokinetic parameters were determined by the ADAPT II MAP-Bayesian parameter estimation program. Patient data were fit using a two-compartment open model and first-order rate elimination. This showed a wide interpatient variation in time to target level (median, 13.8 days), volume of distribution (median, 15.2 liters/m2), and t1/2-beta (median, 20.6 days). The patients who achieved a partial response, minor response, or stable disease had a slower elimination rate of suramin, compared to patients with progressive disease. Tumor specimens were obtained prior to therapy and were analyzed for the production of five different growth factor-specific RNA transcripts. These included transforming growth factor alpha, acidic fibroblast growth factor, basic fibroblast growth factor, and platelet-derived growth factor types A and B. No difference in the pattern of growth factor expression was seen in tumors of responding and nonresponding patients. Suramin does not have significant antitumor activity in renal cell carcinoma. The wide variability in pharmacokinetics suggests that individual dosing should be used in future trials of suramin for treatment for other malignancies. Pertinent corollary studies of tumor biology and clinical pharmacology should be included whenever possible in clinical trials in patients with renal cell carcinoma.

Phase I and clinical evaluation of a pharmacologically guided regimen of suramin in patients with hormone-refractory prostate cancer.

PURPOSE: This phase I study was designed with the following objectives: (1) to describe the overall and dose-limiting toxicity (DLT) of suramin administered by intermittent short intravenous infusions until DLT or disease progression; (2) to determine the ability of an adaptive control with feedback (ACF) dosing strategy to maintain suramin plasma concentrations within a preselected range; (3) to develop a population model of suramin pharmacokinetics; and (4) to identify preliminary evidence of antitumor activity. PATIENTS AND METHODS: Seventy-three patients with advanced, incurable, solid tumors (including 69 with hormone-refractory prostate cancer) received an initial 5- to 7-day daily loading treatment followed by intermittent infusions individually determined by ACF using a Bayesian algorithm and relying on population models of suramin pharmacokinetics. Treatment was given to three cohorts of patients based on target plasma suramin concentration ranges (peak, 30 minutes postsuramin, and trough on morning of the treatment day), as follows: cohort 1, 175 to 300 micrograms/mL (27 patients); cohort 2, 150 to 250 micrograms/mL (23 patients); and cohort 3, 100 to 200 micrograms/mL (23 patients). All patients were to receive suramin until DLT or disease progression. RESULTS: The DLT was most commonly seen in cohort 1 and included a syndrome of malaise and fatigue, associated with weight loss, anorexia, and changes in taste. Other reversible toxicities were neurologic, renal, cutaneous, edema, lymphopenia and anemia, ophthalmologic, and alopecia. Forty of 67 assessable patients (60%) had a 50% reduction and 25 of 67 (37%) a 75% reduction in prostate-specific antigen (PSA) levels that lasted more than 4 weeks, seven of 18 (40%) had measurable responses, and 18 of 37 (49%) demonstrated major pain improvement. The overall times to disease progression and survival were 170 and 492 days, respectively. CONCLUSION: We have characterized all toxicities with suramin in a pharmacologically guided phase I study designed to maintain plasma suramin concentrations of 100 to 300 micrograms/mL (cohorts 1 to 3). The incidence of grade 3 to 4 neurologic abnormalities was relatively low, particularly in cohorts 2 and 3 (100 to 250 micrograms/mL). Evidence of significant and durable antitumor activity was seen in all three cohorts.

Development and validation of a pharmacokinetically based fixed dosing scheme for suramin.

PURPOSE: We used population pharmacokinetic-parameter estimates and designed a fixed dosing schedule to maintain plasma suramin concentrations between 100 and 300 micrograms/mL and then evaluated its performance. MATERIALS AND METHODS: On day 1, patients received a 200-mg test dose and 1,000-mg/m2 loading dose. On days 2, 3, 4, and 5, patients received 1-hour infusions of 400, 300, 250, and 200 mg/m2, respectively. Subsequent 1-hour infusions of 275 mg/m2 were given on days 8, 11, 15, 19, 22, 29, 36, 43, 50, 57, 67, and 78. Therapy was discontinued for dose-limiting toxicity (DLT) or progressive disease (PD). Patients were to be removed from the fixed dosing schedule if, after day 5, three consecutive peak plasma suramin concentrations were greater than 300 micrograms/mL. RESULTS: Forty-two patients, including 40 with hormone-refractory prostate cancer (HRPC), received 700 infusions. Forty patients were assessable for toxicity; 38 were assessable for response. Two patients with preexisting pulmonary disease died early of respiratory insufficiency. Treatment was discontinued in five patients due to DLT and in seven due to PD. No patient had treatment discontinued due to repeated peak plasma suramin concentrations > or = 300 micrograms/mL. The fixed dosing schedule was precise, unbiased, and well tolerated. DLT consisted of grade 4 nephrotoxicity (n = 2), neurotoxicity (n = 2), and corticosteroid-induced psychosis (n = 1). Three patients, who received all 18 doses of suramin per protocol, developed severe, but not dose-limiting, malaise, fatigue, and lethargy. Twenty-four of 36 assessable patients with elevated serum prostate-specific antigen (PSA) levels had a > or = 50% reduction, lasting more than 4 weeks, and 18 had a > or = 75% reduction, lasting more than 4 weeks. Twelve of 23 (52%) symptomatic HRPC patients noted a subjective improvement in pain. There were no measurable responses in four patients with measurable disease. The estimated median survival time in 38 assessable patients with HRPC was 18.8 months. The estimated median time to progression in 35 patients, for whom data were available, was 10.1 months. CONCLUSION: This easily implemented schedule allowed suramin to be administered safely as an intermittent bolus injection. Toxicity was manageable and reversible.

Suramin and hydrocortisone: determining drug efficacy in androgen-independent prostate cancer.

PURPOSE: The combination of suramin and hydrocortisone has shown clinical benefit in patients with androgen-independent prostate cancer. Widespread use was limited by the complex dose schedules and the need for pharmacologic monitoring. This study reports three sequential pharmacokinetically derived treatment regimens that simplified the administration of suramin and hydrocortisone with reduced toxicity. PATIENTS AND METHODS: Three cohorts of patients with advanced prostate cancer that progressed despite castrate levels of testosterone received oral hydrocortisone plus suramin administered in the following manners: (1) a loading dose of suramin followed by a continuous infusion using an adaptive control program (cohort A); (2) an intermittent schedule using a simplified adaptive control schedule (cohort B); and (3) an empiric dosing regimen (cohort C). Drug concentrations were monitored along with the toxicities associated with each regimen. Efficacy was assessed using measurable-disease criteria, radionuclide scans, and posttherapy changes in prostate-specific antigen (PSA) levels. RESULTS: Fifty-six patients were treated and plasma suramin concentrations were similar for each regimen. A partial response was observed in 4% (one of 28; 95% confidence interval, 0% to 18.4%) of patients with measurable disease, while 12% (six of 50; 95% confidence interval, 4.5% to 24.3%) had a greater than 80% decline in the baseline PSA level. The median duration of response was 12 months. No responses on radionuclide scans were seen. Anemia and lymphocytopenia were the most common toxicities, while 7% of patients developed a sensory or motor neurotoxicity. In the sequential regimens, the frequency of renal insufficiency (P = .04) and coagulopathy (P < .0001) decreased, while transaminase elevations (P = .05) were more common using intermittent infusions (cohorts B and C) versus continuous infusion schedules (cohort A). CONCLUSION: The administration of suramin was simplified and the drug concentrations were maintained. In this cohort of patients with advanced prostate cancer, the clinical activity of suramin using these dosing schedules was limited. Pharmacodynamic issues, patients selection, and criteria to assess efficacy could have effected the clinical outcome.

Pharmacologic variables associated with the development of neurologic toxicity in patients treated with suramin.

PURPOSE: To describe pharmacologic variables correlated with the development of neurologic toxicity in patients treated with suramin. METHODS: Eighty-one patients were treated with suramin in a phase I study. The rate of drug infusion was continuously adjusted to maintain a preassigned plasma suramin concentration (175, 215, or 275 micrograms/mL) for a fixed duration (2 to 8 weeks). RESULTS: Eight patients developed grade III/IV neurologic motor impairment (predominantly motor axonal polyneuropathy). All were treated at the 275-micrograms/mL concentration. One patient treated at the 215-micrograms/mL concentration developed grade II motor dysfunction. In addition, seven of nine patients had sensory symptoms. Pharmacologic variables associated with the development of polyneuropathy included total cumulative suramin dose, duration of exposure to plasma concentrations greater than 200 micrograms/mL, and area under the curve (AUC) greater than 200 micrograms/mL. CONCLUSION: Significant neurologic toxicity can result from therapy with suramin, even when dosing is designed to avoid exposure to plasma concentrations greater than 350 micrograms/mL. Future clinical trials of suramin should be designed in such a way as to limit the total cumulative dose to < or = 157 mg/kg given over a period of > or = 8 weeks, limit the period of exposure to plasma suramin concentrations greater than 200 micrograms/mL to < or = 25 days, and limit the AUC greater than 200 micrograms/mL to < or = 48,000 mg.h/AL.

Suramin: development of a population pharmacokinetic model and its use with intermittent short infusions to control plasma drug concentration in patients with prostate cancer.

PURPOSE: This study aimed to (1) develop a population pharmacokinetic model for suramin; (2) use Bayesian methods to assess suramin pharmacokinetics in individual patients; (3) use individual patients' pharmacokinetic parameter estimates to individualize suramin dose and schedule and maintain plasma suramin concentrations within predetermined target ranges; and (4) assess the feasibility of outpatient administration of suramin by intermittent, short infusions. METHODS: Plasma suramin concentrations were measured by high-performance liquid chromatography (HPLC), and compartmental pharmacokinetic models were fit using a Bayesian algorithm. Population pharmacokinetic models were developed using an iterative two-stage approach. Estimates of each patient's central-compartment volume were used to calculate suramin dosage. Simulation of that patient's suramin clearance was used to predict the time of his next dose. Using this approach, plasma suramin concentration was maintained at between 200 and 300, 175 and 275, 150 and 250, or 100 and 200 microgram/mL in four sequential patient cohorts. The ability of two- and three-compartment, open, linear models to fit the pharmacokinetic data was compared. Population pharmacokinetic parameters were estimated, using both two- and three-compartment structural models in 69 hormone-refractory prostate cancer patients. RESULTS: Target plasma suramin concentrations in individual patients were rapidly achieved. Concentrations were maintained within desired ranges for > or = 85% of treatment duration in all cohorts. A three-compartment, open, linear model described suramin pharmacokinetics better than did a two-compartment, open, linear model. Population pharmacokinetic estimates generated for two- and three-compartment pharmacokinetic models demonstrated modest interpatient pharmacokinetic variability and the long terminal half-life of suramin. CONCLUSION: Suramin can be administered by intermittent short infusion. Adaptive-control-with-feedback dosing facilitated precise control of plasma suramin concentrations and allowed a number of different concentration ranges to be studied. This approach is expensive and labor-intensive. Although we have demonstrated the ability to control drug exposure, simpler dosing schedules require critical evaluation. Population pharmacokinetic parameters generated in men with hormone-refractory prostate cancer will facilitate rational design of such schedules.

Prospective evaluation of hydrocortisone and suramin in patients with androgen-independent prostate cancer.

PURPOSE: To assess efficacy of intermittent infusion of suramin in patients with androgen-independent prostate cancer who have had disease progression on hydrocortisone. PATIENTS AND METHODS: Chemotherapy-naive patients with progressive androgen-independent prostate cancer were given hydrocortisone 40 mg/d and monitored for treatment effect. At the time of disease progression, suramin was administered on a pharmacokinetically derived, 2-week dosing schedule. RESULTS: Thirty patients with a median Karnofsky performance status (KPS) of 90% were treated with hydrocortisone. No responses were seen in 12 patients with measurable disease or 29 patients with abnormal bone scans. Thirty patients had an increasing prostate-specific antigen (PSA) level before treatment and six (20%) had a more than 50% decline in PSA from the baseline value for a median of 16 weeks (range, 12 to 52+). Twenty-eight patients had disease progression after a median of 7 weeks (range, 3 to 23), and two patients have continued to receive hydrocortisone for 44 and 52 weeks. Twenty-eight patients received hydrocortisone and suramin, with median suramin concentrations of 97 to 170 micrograms/mL for 4 weeks. No responses in measurable disease and no improvements in bone scans were seen. Five patients (18%) showed a more than 50% decline in PSA levels from baseline, of whom three had previously responded to hydrocortisone. Only two of 24 patients who did not show a posttherapy decline in PSA levels after hydrocortisone had a reduction in PSA levels with the addition of suramin. Toxicity profiles were acceptable with each agent, although a higher proportion of subjects showed hematologic, cardiac, and neurologic events when suramin was added. CONCLUSION: Suramin has limited efficacy in patients with androgen-independent prostate cancer who have had disease progression after hydrocortisone.

Suramin in hormone-refractory metastatic prostate cancer: a drug with limited efficacy.

PURPOSE: To confirm the previously reported high response rates and prolonged survival in hormone-refractory prostate cancer treated with suramin. PATIENTS AND METHODS: Thirty-six eligible patients with hormone-refractory prostate cancer with either measurable disease or bone disease only and a prostate-specific antigen (PSA) level greater than 50 ng/mL were enrolled. Treatment consisted of two 8-week courses of outpatient-based therapy with an interposed rest period. A bayesian adaptive control strategy and a three-compartment pharmacokinetic model that accommodates clearance changes was used to guide individual dosing. A rapid infusion of 1,000 mg/m2 suramin was followed by five daily infusions that targeted 285 micrograms/mL peak plasma levels during the first week. All patients received concomitant hydrocortisone. For the next 7 weeks, patients received one to two doses per week that targeted levels in the 150 to 285 micrograms/mL range and integrated weekly averages of 200 ug/mL. RESULTS: Nine patients (28%) had a partial response to suramin based on a > or = 50% decrease in PSA levels coupled with either relief of bone pain or by a 50% decrease in measurable disease. The median overall survival time for all patients is 31 weeks (95% confidence interval [CI], 23 to 51). Treatment was generally well tolerated, with fatigue being the most common significant toxicity, but fatal idiosyncratic myelosuppression (grade V) was observed in one patient. CONCLUSION: Using this dosing schedule, suramin has limited activity against hormone-refractory metastatic prostate cancer. Recent data suggest that hydrocortisone administered with suramin may be partly responsible for the benefit attributed to the drug. Although a small cohort of patients appeared to benefit, we were unable to confirm the previously reported high rate of activity and durability of remission using this agent.

Phase I study of suramin given by intermittent infusion without adaptive control in patients with advanced cancer.

PURPOSE: Suramin is a promising agent for the treatment of hormone-refractory metastatic prostate cancer. However, questions about the relationship of severe neurotoxicity to sustained peak plasma concentrations greater than 300 micrograms/mL raised concerns that this drug could not be safely administered without adaptive control. To test the adaptive-control hypothesis, we designed a phase I study that relied on clinical end points, using a fixed dosing scheme that did not rely on adaptive control. PATIENTS AND METHODS: In a phase I dose-escalation study using fixed dosing without adaptive control, gradually decreasing doses of suramin were administered to 63 patients on days 1 (loading dose), 2, 8, and 9 of a 28-day cycle. Fifty-four patients with hormone-refractory metastatic prostate cancer and nine patients with other solid tumors have been treated. RESULTS: Doses of 400 mg/m2 to 2,080 mg/m2 on the first day have been administered. The mean peak plasma concentration following the loading dose at a dose level of 1,730 mg/m2 was 933 micrograms/mL (26% coefficient of variation), and the mean trough concentration was 139 micrograms/mL (40% CV) on day 1 of cycle 2 [corrected]. At 1,730 mg/m2, five of 13 patients experienced dose-limiting toxicity (DLT), including malaise, neurotoxicity, pericardial effusion, and coagulopathy. At 2,080 mg/m2, three of five patients experienced DLT. Two patients treated at this dose level died while on study. One of these patients died of a subdural hematoma sustained after a fall and had a prolonged prothrombin time at the time of his death. One patient developed classic suramin neurotoxicity, which led to respiratory failure, for which the patient refused intubation. No significant associations were noted between peak or trough concentrations during either cycles 1 or 2 and the occurrence of neurotoxicity. CONCLUSION: (1) Suramin can be safely administered without adaptive control, (2) suramin on this schedule may exhibit significant activity against hormone-refractory metastatic prostate cancer, and (3) based strictly on toxicity considerations, we recommended that a day-1 dose of 1,440 mg/m2 be used in subsequent clinical trials, with a maximum of three cycles. Further studies to establish the optimal empiric dosing regimen are needed.

Cell surface binding and cellular internalization properties of suramin, a novel antineoplastic agent.

Although suramin has shown promise in preliminary clinical trials as an antineoplastic agent, it is unclear if its mode of action is predominately extracellular or intracellular. We have attempted to address this problem by studying the cellular pharmacology of tritiated suramin ([3H]suramin) in the DU145 and LNCaP prostate cancer cell lines, as well as in HL60 cells, an acute promyelocytic leukemia cell line. In the cell lines studied, significant, multisite, trypsin-insensitive, low-affinity cell surface binding by [3H]suramin was observed (Bmax > 10(6), Kd > 1 microM). The binding of [3H]suramin to the cell surface was competitive with respect to a phosphorothioate oligodeoxynucleotide homopolymer of cytidine, 28 bases in length, but was not affected by ATP. Use of this competitor allowed us to determine that [3H]suramin bound to the surface of HL60 cells was internalized via the process of adsorptive endocytosis and was maximal at approximately 6 h. In contrast, binding of suramin to the surface of the prostate cells, but not to that of HL60 cells, was completely abrogated by the presence of albumin (DU145 and LNCaP cells), or by warming to 37 degreesC (DU145 cells only). The dynamics of internalization and compartmentalization of suramin in DU145 revealed that within a narrow concentration range, internalization was dependent on time of exposure and drug concentration. Analysis of the exocytosis of suramin from DU145 cells revealed that approximately 64% of the drug was effluxed from a shallow compartment (t1/2 = 3.15 min) and 31% from a deep compartment (t1/2 = 433 min); both compartments probably represent endosomes. The results suggest that, because of the complexities of suramin's cellular pharmacology, its mechanism of action may vary signficantly according to cell type.

Phase I study of low-dose suramin as a chemosensitizer in patients with advanced non-small cell lung cancer.

PURPOSE: Our preclinical studies have shown that acidic and basic fibroblastic growth factors confer broad spectrum chemoresistance and that low concentrations (10-50 microM) of suramin, a nonspecific fibroblastic growth factor inhibitor, enhance the antitumor activity of paclitaxel in vivo. The present Phase I study evaluated low-dose suramin in combination with paclitaxel/carboplatin in advanced non-small cell lung cancer patients. EXPERIMENTAL DESIGN: Patients received suramin followed by paclitaxel (175-200 mg/m(2)) and carboplatin area under the concentration-time curve of 6 mg/ml/min, every 3 weeks. The initial suramin dose for the first cycle was 240 mg/m(2), and the doses for subsequent cycles were calculated based on the 72-h pretreatment plasma concentrations. The recommended suramin dose would yield plasma concentrations of 10-20 microM at 48 h in >or=5 of 6 patients. RESULTS: Fifteen patients (11 stage IV, 4 stage IIIB, 9 chemonaive, and 6 previously treated) received 85 courses. The most common toxicities were neutropenia, nausea/vomiting, malaise/fatigue, and peripheral neuropathy. No treatment-related hospitalizations, adrenal dysfunction, or episodes of sepsis occurred. The initial suramin dose resulted in the targeted concentrations of 10-20 microM at 48 h in 5 of the first 6 patients treated but also resulted in peak concentrations > 50 microM in all patients. Dividing the suramin dose to be administered in two doses, 24 h apart, yielded the target concentrations and avoided undesirable peak concentrations. Discernable antitumor activity occurred in 7 of 10 patients with measurable disease, including 2 with prior chemotherapy. The median time to tumor progression is 8.5 months (range, 3-27+ months) for 12 evaluable patients. CONCLUSIONS: Low-dose suramin does not increase the toxicity of paclitaxel/carboplatin combination. The suramin dose can be calculated based on clinical parameters. Because of the preliminary antitumor activity observed, efficacy studies in chemonaive and chemorefractory patients are under way.