Originally published as JCO Early Release 10.1200/JCO.2004.11.035 on October 13 2004

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Phase I Clinical Trial of the Immunocytokine EMD 273063 in Melanoma Patients

From the University of Wisconsin, Madison, WI; Departments of Medicine, Human Oncology, Surgery, Pathology, Biostatistics, Pediatrics, and Genetics, Ohio State University, Columbus, OH; The Scripps Research Institute, La Jolla CA; and EMD-Lexigen Research Center, Billerica, MA

Address reprint requests to Mark R. Albertini MD, 600 Highland Avenue, K4/414 CSC, Madison, WI 53792; e-mail: mralbert{at}facstaff.wisc.edu

	ABSTRACT

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PURPOSE: To evaluate the safety, toxicity, in vivo immunologic activation, and maximum-tolerated dose (MTD) of EMD 273063 (hu14.18-IL-2) in patients with metastatic melanoma.

PATIENTS AND METHODS: Thirty-three patients were treated with EMD 273063, a humanized anti-GD2 monoclonal antibody (mAb) linked to interleukin-2 (IL-2). EMD 273063 was given as a 4-hour intravenous infusion on days 1, 2, and 3 of week 1. Patients with stabilization or regression of disease could receive a second course of treatment at week 5. Dose levels evaluated were 0.8, 1.6, 3.2, 4.8, 6.0, and 7.5 mg/m²/d.

RESULTS: Nineteen of 33 patients completed course 1 with stable disease and went on to receive course 2. Eight patients had stable disease on completion of course 2. Grade 3 adverse events included hypophosphatemia (11 patients), hyperglycemia (three patients), hypotension (two patients), thrombocytopenia (one patient), hypoxia (three patients), elevated hepatic transaminases (two patients), and hyperbilirubinemia (one patient). Opioids were required for treatment-associated arthralgias and/or myalgias during 17 of 52 treatment courses. No grade 4 adverse events were observed. Dose-limiting toxicities at the MTD included hypoxia, hypotension, and elevations in AST/ALT. Grade 3 toxicities were anticipated based on prior studies of IL-2 or anti-GD2 mAbs, and all resolved. Immune activation was induced, as measured by lymphocytosis, increased peripheral-blood natural killer activity, and cell numbers, and increased serum levels of the soluble alpha chain of the IL-2 receptor complex.

CONCLUSION: Treatment with the immunocytokine EMD 273063 induced immune activation and was associated with reversible clinical toxicities at the MTD of 7.5 mg/m²/d in melanoma patients.

	INTRODUCTION

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Interleukin-2 (IL-2) has been used alone and in combination with other therapies in the treatment of patients with metastatic melanoma and has well-documented antitumor effects in a minority of patients.¹ Murine models suggest two distinct mechanisms by which IL-2 treatment can mediate antitumor effects.² IL-2 treatment augments the activation of preexisting antigen-specific T cells to enhance their recognition and destruction of neoplastic tissue and activates a separate population of lymphocytes known as natural killer (NK) cells. NK cells lack T-cell markers and antigen-specific receptors and have demonstrated the ability to destroy tumor targets in vitro and in vivo.^3,4 Novel approaches that selectively induce immune attack at sites of tumor while minimizing the known side effects of IL-2 are needed. A more selective induction of tumor-specific T cells, or localization of activated NK cells to sites of tumor, may provide better tumor specificity and more effective tumor destruction.

One way to potentially improve the antitumor efficacy of activated NK cells is to direct their lytic activity more selectively toward tumor cells.^5,6 This can be demonstrated in vitro with the addition of tumor-reactive monoclonal antibody (mAb) to facilitate antibody-dependent cell-mediated cytotoxicity (ADCC). Fc receptor–bearing effector cells, including NK cells, primarily mediate ADCC. In vitro studies have demonstrated that ADCC of tumor cells is increased when effector cells are initially activated with IL-2. This IL-2 activation can be performed in vitro or in vivo. Mice receiving IL-2 plus tumor-specific mAb demonstrate improved antitumor effects compared with animals treated with either agent alone.^7-9 Only intact mAb, not fragment antigen-binding regions, were able to induce ADCC in vitro or provide the antitumor effects in vivo.⁸ These results suggest that direct effector cell–tumor cell contact is involved in the antitumor mechanism and that it may be possible, with in vivo activation of effector cells by IL-2, to improve clinical antitumor effects of mAb treatment.

Preclinical studies in selected murine models bearing syngeneic tumors have tested the antitumor activity and immunologic effects of tumor-reactive mAbs genetically linked to IL-2, designated immunocytokines (IC). These studies document that IC can induce potent antitumor effects in vivo that exceed the antitumor activity of comparable amounts of mAb and IL-2 given in combination as separate molecules. Furthermore, depending on the model system evaluated, the antitumor activity is mediated primarily by T cells¹⁰ or by NK cells.¹¹ It appears that the IC molecule localizes to the tumor cell surface because of the recognition by the mAb component of the IC molecule. This would allow NK cells to be activated by the IL-2 component of the IC molecule and then mediate ADCC using the Fc component of the IC molecule.

The EMD 273063 molecule evaluated in this clinical trial consists of the humanized 14.18 antibody genetically linked to a molecule of human IL-2 at the carboxy terminus of each immunoglobulin heavy chain. The hu14.18 mAb recognizes the GD2 disialoganglioside, expressed on tumors of neuroectodermal origin including melanoma, neuroblastoma, and certain sarcomas.^12,13 The primary objectives of this study were to assess the safety, toxicity, and in vivo immunologic effects and to determine the maximum-tolerated dose (MTD) of EMD 273063 when administered as three daily 4-hour intravenous (IV) infusions in patients with melanoma. Furthermore, the pharmacokinetics of EMD 273063 at different dose levels was investigated.

	PATIENTS AND METHODS

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Patients
Potentially eligible patients required histologically confirmed melanoma (or other GD2⁺ malignancy confirmed by immunohistochemistry) that was considered surgically and medically incurable. These patients could have either measurable or nonmeasurable but evaluable metastatic disease, or they could have no evidence of disease after surgical resection of either distant metastases or regionally recurrent disease. Patients with multiple (two or more) local or regional recurrences were included only if they had prior evidence of lymph node involvement and if each recurrence was separated in time by at least 2 months. All patients needed to have adequate bone marrow function (defined by total WBC > 3,500/µL or total granulocytes > 2,000/µL, platelets > 100,000/µL, and hemoglobin > 10.0 g/dL), adequate liver function (defined by an AST less than three times the normal level and a total bilirubin less than 2.0 mg/dL), and adequate renal function (defined by a serum creatinine < 2.0 mg/dL or a creatinine clearance of > 60 mL/min). All patients had an Eastern Cooperative Oncology Group performance status of 0 or 1 and a life expectancy of at least 12 weeks. Patients who had previously received chemotherapy, radiation therapy, or other immunosuppressive therapy within 4 weeks before study were excluded. Patients could have prior CNS metastases if treated and stable for at least 4 weeks before starting the study. Written informed consent that was approved by the University of Wisconsin Health Sciences institutional review board was obtained from all patients.

Hu14.18-IL-2 Immunocytokine
The hu14.18-IL-2 IC (EMD 273063) was provided by EMD Pharmaceuticals Inc. (Durham, NC). Preclinical evaluation has shown that 1 mg of the fusion protein contains approximately 3 x 10⁶ U of IL-2 (based on a proliferative assay with IL-2 responsive Tf-1ß cells) and approximately 0.8 mg of the hu14.18 mAb¹⁴ (J.A. Hank, unpublished data; Tf-1ß cells are described in the cell lines subsection of Immunologic Monitoring).

Study Design
This phase I trial was designed as an open-label, nonrandomized dose-escalation study. Patient accrual followed a two-stage design as described by Storer.¹⁵ In the first stage, escalation to the next dose level was permitted after a single patient had been evaluated at the current dose level without the occurrence of any toxicity (other than fever) one grade or worse above baseline. Once that level of toxicity was observed, three to six patients were to be entered into that dose level as well as into subsequent treatment cohorts. The MTD was defined as that dose that was estimated to cause dose-limiting toxicity (DLT) during course 1 in 33% of patients. EMD 273063 was administered on an inpatient basis as a 4-hour IV infusion over 3 consecutive days during the first week of each course. Patients were discharged from the hospital, if stable, approximately 24 hours after the completion of the third infusion. Adverse events and toxicities were graded as per the National Cancer Institute Common Toxicity Criteria (version 2.0) and the University of Wisconsin Comprehensive Cancer Center Toxicity Grading Scale for IL-2 (performance status, weight gain, and temperature).¹⁶ DLT was defined as the occurrence of grade 3 or 4 toxicity other than grade 3 lymphopenia, hyperbilirubinemia, or hypophosphatemia. A protocol amendment excluded patients with a known history of diabetes, as this therapy may alter blood glucose levels. Patients with grade 3 treatment-related toxicities were required to recover to at least grade 1 before they could resume treatment at a 50% dose reduction for course 2. Disease assessment was performed between 20 to 26 days after initiation of each treatment course. Patients with 25% disease progression were removed from the study. Patients with stable disease were eligible for course 2, starting on day 29. Patients were required to have an objective partial or complete clinical response to be eligible for any additional courses of therapy past course 2.

Clinical Laboratory Monitoring
Clinical hematology, chemistry, and C-reactive protein (CRP) evaluations were performed by standard methodology at the University of Wisconsin Hospital Clinical Laboratory. Blood samples, unless otherwise indicated, were taken in the morning on the indicated protocol day, before administration of EMD 273063. Thus day 1 samples from course 1 reflect blood samples obtained before any EMD 273063 treatment.

Immunologic Monitoring
Cell lines. The Daudi, K562, LA-N-5 (GD-2–positive neuroblastoma) and M21 (GD-2–positive melanoma) cell lines were maintained as previously described.^14,17 The IL-2 responsive Tf-1ß cell line was created by transfecting the gene for the IL-2 receptor beta chain into the myeloid leukemia Tf-1 cell line, already expressing the IL-2 receptor gamma chain.¹⁸

Flow cytometry. Fluorescent cell-bound antibody was detected by standard indirect immunofluorescence methods (Becton Dickinson, San Diego, CA). To detect intact hu14.18-IL-2 IC binding to GD2 positive cells lines, phycoerythrin-conjugated monoclonal rat antihuman IL-2 (PharMingen, San Diego, CA) was used.¹⁰

ADCC and NK assays. These ⁵¹Cr release assays were performed in RPMI-HS, as previously described.¹⁰ For ADCC assays, IC, serum, or antibody as indicated was added to the effectors. Target cells at 5 x 10³ were added to the effector cells. Fresh peripheral-blood mononuclear cells (PBMCs) from the patients were used as effector cells, and PBMCs from a healthy control donor were tested in parallel, to insure the validity of the assays.

In vitro proliferative response to IL-2. The IL-2 responsive Tf-1ß cell line was cultured at a concentration of 1 x 10⁵ cells/well. Patient serum was added to each microwell to determine the IL-2–inducing capacity of the IC present in the serum obtained after an infusion of IC. Cultures were incubated at 37°C for 48 hours, pulsed with 1 µCi of [³H]thymidine for 18 hours, collected with a Filtermate 196 (Packard-Canberra, Meriden, CT) harvester, and [³H]thymidine incorporation was quantified with a Matrix 9600 direct beta counter with a 5-minute counting period (Packard-Canberra).

Enzyme-linked immunosorbent assay (ELISA) methods. Soluble IL-2 receptor alpha (sIL-2R) was measured by a commercial (Immunotech, Marseilles, France) double-mAb ELISA kit, according to the manufacturer's specifications. Measurement of EMD 273063 levels in patients' sera by ELISA were performed as previously described.^19,20 Plates coated with 1A7, a mouse anti-idiotype antibody to 14.18, were used. Diluted serum specimens (in duplicates) were incubated overnight at 4°C. They were then serially washed and incubated with biotinylated goat antihuman IL-2 antibody (R&D Systems, Minneapolis, MN) followed by ExtrAvidin-AP (Sigma, St Louis, MO). A standard curve was based on dilutions of lot no. 31,916 of hu 14.18-IL-2 and ranged from 0 to 20 ng/mL. The detection limit for this assay was determined as 0.16 ng/mL. The intra-assay and inter-assay precision was estimated as 4.9% and 3.2%, respectively.

Statistical Methods
Pharmacokinetic parameters and immunologic end points are described using descriptive statistics. The area under the curve from time zero to 24 (AUC_0-24) hours was calculated with the Lagrange method. Blood samples for determining pharmacokinetic parameters were collected on day 1, course 1, at 0, 0.5, 4, 4.5, 5, 6, 8, 16, and 24 hours from the start of the 4-hour infusion. The terminal half-life (T_1/2) was determined from the terminal slope on a log-linear plot of concentration versus time (after 4 hours).

Jonckheere-Terpstra trend test was performed to determine the significance of the association between increasing dose level and each of the pharmacokinetic parameters AUC_0-24 and peak concentration. A Spearman rank correlation analysis was also performed to determine the relationship between actual dose administered and the pharmacokinetic parameters.

Linear regression methods for repeated measures were used to evaluate the relationships between dose and immunologic end points.²¹ Wilcoxon signed-rank test was used to determine changes from baseline in CRP levels. All statistical analyses were performed with SAS software (version 8.2, SAS Institute Inc, Cary, NC). All P values are two-sided and were not adjusted for the number of parameters evaluated. As such, they should only be interpreted as exploratory.

	RESULTS

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Patient Characteristics
Pretreatment characteristics are outlined in Table 1. The median age of the 33 patients was 49 years (range, 27 to 69 years), and all had Eastern Cooperative Oncology Group performance status 0 or 1. Prior therapies included surgery (29 patients), biologic therapy (20 patients), radiotherapy (10 patients), and chemotherapy (nine patients). Sites of metastatic disease included lung (19 patients), distant nodal, skin, or subcutaneous disease (26 patients), other visceral sites (13 patients), and bone (three patients). Two patients had previously treated brain metastases. Five patients (15%) had no evidence of disease at the time of treatment.

Significant laboratory changes observed for each dose level for two courses of treatment are listed in Table 5. Four patients (12%) had grade 2 thrombocytopenia and one patient, at dose level 4, had grade 3 thrombocytopenia. One patient at dose level 4 experienced a grade 3 elevation of bilirubin on day 2 of course 1. Treatment was held on day 3 with resolution of the hyperbilirubinemia. The patient did not receive course 2 secondary to progression of disease. Eight patients (24%) had a grade 2 elevation of AST and one patient at dose level 6 had a grade 3 elevation of AST and ALT.

Although this phase I study was not designed to determine overall tumor response rate to treatment, all patients were followed for antitumor activity. None showed improvement of measurable disease to qualify as a complete or partial response. Eight patients (24% of all patients) had stable disease after the second course of treatment. Four of these eight patients continue with no evidence of progressive disease (one with stable disease treated at 4.8 mg/m²/d and three with no evidence of disease treated at 0.8, 3.2, and 6.0 mg/m²/d) for 26 to 60 months since completing protocol therapy. Five of the 33 patients entered the study with no measurable disease after surgical resection of recurrences or metastases. Two of these five patients have experienced disease progression, whereas the remaining three patients continue with no evidence of disease. One additional patient had an objective decrease in a lung nodule after two courses of therapy, but the overall disease response was scored as disease progression because of growth in a distant node. The node was resected after hu14.18-IL-2 therapy, and the patient remained free from disease progression for 3 years, after which disease progression was noted and alternate therapy begun.

Immunologic Monitoring
A peripheral-blood lymphopenia occurred on days 2 to 4 (P < .0001), and this was followed by a rebound lymphocytosis on days 5 to 22 (P < .0001) in course 1 (Fig 1A). Both of these changes were dose-dependent (P < .01 and P < .05, respectively). Lymphocyte counts for the 12 patients who received course 2 of EMD 273063 without a dose reduction are shown in Figure 1B. The baseline lymphocyte count for course 2 (day 29 of course 1) was increased over the baseline lymphocyte count for course 1, indicating that effects of the first course of treatment are still present on day 29 (Fig 1B). In addition, the lymphocyte counts during course 2 on days 5, 8. and 15 are greater than the corresponding values for days 5, 8, and 15 during course 1 for these 12 patients.

View larger version (27K): [in this window] [in a new window]   Fig 1. Mean peripheral-blood lymphocyte count (cell number per mcL ± SE) for (A) the 31 patients completing course 1 and (B) the 12 patients completing both courses at the same dose level. In A, values after d1 are different from pretreatment (P < .0001). Significant differences in B are shown (course 2 v course 1). (*), P < .05; (**), P < .01.

View larger version (25K): [in this window] [in a new window]   Fig 2. Mean (+ SE) percentage of peripheral-blood mononuclear cell–expressing marker before treatment (day 1) and on day 8 for (A) patients completing course 1 and (B) patients completing courses 1 and 2 at the same dose level. Significant differences are shown for (A) day 1 versus day 8 and (B) for course 2 versus course 1. (*), P < .05; (**), P < .01.

View larger version (30K): [in this window] [in a new window]   Fig 3. Mean soluble interleukin-2 receptor levels in serum by dose level pre-infusion and 4 hours after starting infusion (days 1 and 3) and on days 2, 4, 5, and 8 for (A) patients completing course 1 and (B) for patients completing course 2.

View larger version (14K): [in this window] [in a new window]   Fig 4. Antibody-dependent cell-mediated cytotoxicity using the LA-N-5 target with peripheral-blood mononuclear cells obtained from patients on day 1 (before treatment) and day 8. Mean lytic units (+ SE) for cultures containing medium alone, interleukin-2 (IL-2; 100 U/mL), or EMD 273063 (0.25 µg/mL). Significant differences are shown for day 8 versus day 1. (**), P < .01; (***), P < .001.

Serum samples from selected patients were also evaluated to determine functional IL-2 activity of circulating IC and anti-GD2 binding ability of the antibody component of IC. As shown in Figure 5A, the IL-2 responsive Tf-1ß cell line demonstrated IL-2–induced proliferation with patient serum obtained after infusion of EMD 273063. An increase in proliferation was seen during the first 4 hours after the start of the 4-hour infusion. Values returned to baseline by 16 hours after this infusion. Serum samples collected at these time points were also examined by flow cytometry for the presence of intact EMD 273063 IC that retains its IL-2 component and its anti-GD2 antibody activity. As shown in Figure 5B, patient serum samples obtained after the EMD 273063 infusion contained EMD 273063 capable of binding to the M21 (GD2-positive) cell line as detected by flow cytometry using a PE-labeled anti–IL-2 detection antibody. The amount of IC able to bind to M21 increased during the first 4 hours after the start of the 4-hour infusion. Values returned to baseline by 8 to 16 hours after this infusion.

View larger version (26K): [in this window] [in a new window]   Fig 5. Serum samples were obtained at the indicated times from patients (PT) 1 and 2 (0.8 mg/m2/d) for assays (see Immunologic Monitoring section of Patients and Methods). (A) Proliferation of interleukin-2 responsive Tf-1ß cells (cpm); (B) binding of EMD 273063 to M21 (mean fluorescence intensity units). IL-2, interleukin-2.

View larger version (17K): [in this window] [in a new window]   Fig 6. Antibody-dependent cell-mediated cytotoxicity using the LA-N-5 target (% cytotoxicity; effector: target ratio of 50:1) with and without effectors (day 8 of course 2) in medium containing autologous serum obtained pretreatment (pre) or after the initial 4-hour infusion, for six consecutive assays on patients at 4.8 to 6.0 mg/m2/d. The killing by effectors in 4 hours' serum was six-fold greater than with effectors in preserum when calculated using lytic units (not shown).

	DISCUSSION

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This phase I dose escalation study enrolled 33 adults with melanoma. The MTD¹⁵ was determined to be 7.5 mg/m²/d, as two of six patients showed reversible DLT at that dose level during course 1, using the specific DLT criteria defined for this study. The 90% CI for this value is 1.2 to 13.8 mg/m²/d, reflecting the low statistical power of a study with three to six patients per dose level. In a previous clinical trial in which we combined the chimeric form of this mAb (not the IC) with separate constant infusions of IL-2, the MTD of the ch14.18 mAb was found to be 7.5 mg/m²/d.¹⁶ DLTs in that study were pain requiring morphine, allergic reactions, weakness, and decreased performance status. As the hu14.18-IL-2 is composed of 16.7% IL-2 and 83.3% hu14.18, the amount of hu14.18 mAb in 7.5 mg of hu14.18-IL-2 is 6.25 mg. Thus the 7.5 mg/m²/d MTD of the chimeric mAb when combined with IL-2 is similar to the amount of hu14.18 mAb (6.25 mg/m²/d) present in the MTD of the hu14.18-IL-2 molecule determined here. Dose-limiting side effects of EMD 273063 at the MTD were IL-2–related and included transient, reversible hypoxia and hypotension. Most of the clinical toxicities seen in this study were anticipated and were similar to those previously reported for IL-2 and anti-GD2 mAb treatments.^16,27,28 Most patients in the three highest dose levels had pelvic, abdominal, chest, or extremity pain requiring IV morphine. This pain was similar to what we previously reported for patients treated with ch14.18.^16,29 Although this pain could be moderate to severe and require use of intermittent or constant IV infusion of morphine, it could be adequately controlled to the satisfaction of most patients and was not dose-limiting. There was no evidence of motor neuropathy associated with this treatment. The remaining toxicities were similar to those frequently seen with IL-2 given alone. These toxicities were reversible and resolved after therapy.

Two common toxicities with this therapy, as noted by laboratory values, were hypophosphatemia and hyperglycemia. A majority of patients had grade 2 or 3 hypophosphatemia that was noted during routine laboratory monitoring. This hypophosphatemia was not associated with any clinical symptoms and resolved spontaneously in all patients without supplementation. This laboratory finding is thought to represent the effects of IL-2–related intracellular phosphate migration rather than renal wasting of phosphate.^30,31 The lack of renal wasting was demonstrated here in patients with grade 3 hypophosphatemia. Treatment-associated hyperglycemia was also present in most patients. The majority of this hyperglycemia was grade 1 (18 patients), but five patients had grade 2 and three patients had grade 3 hyperglycemia. Two patients with known diabetes previously requiring an oral agent required temporary use of insulin for management of this treatment-associated hyperglycemia. Although the etiology of this hyperglycemia is not known, treatment with IL-2 has previously been associated with exacerbation of diabetes mellitus.³² It is important to note that, in all cases, the hyperglycemia was managed without difficulty and without additional clinical sequelae, and this toxicity resolved after therapy was completed.

There were immunologic changes associated with this EMD 273063 therapy, including an increase in lymphocyte count, an increase in the percentage of CD16+ and CD56+ PBMCs, an increase in NK lysis, and an increase in ADCC. Additional evidence for immune activation included an increase in serum levels of CRP and of sIL-2R. All of these changes can be seen in patients receiving treatment with IL-2; thus these responses provide evidence that the EMD 273063 molecule has an IL-2 component that functions in vivo and induces similar systemic immune activation as is seen with IL-2. Laboratory analyses of sera and PBMCs showed that the EMD 273063 molecule circulating in patient sera after IV administration retained its ability to activate IL-2–responsive cells through the IL-2 receptor and retained its ability to bind to GD-2–positive tumor cells and deliver IL-2 to their surface, as detected by flow cytometry. All patients achieved conditions necessary for immune activation. Our previous trial combining the ch14.18 mAb with IL-2 infusion in patients with melanoma reported the development of anti-idiotypic antibody against the ch14.18 mAb in treated patients.¹⁶ Our preliminary analysis of sera from these 33 patients reported here shows that 16 developed an anti-idiotypic antibody after treatment with hu14.18-IL-2 using a similar assay to that used in our prior report (Hank et al, manuscript in preparation).

In conclusion, a treatment dose and schedule for the IC EMD 273063 that can induce immune activation with acceptable toxicity was identified in patients with melanoma. The finding of four high-risk patients who continue without evidence of disease progression for 26 to 60 months after only two cycles (six doses) of treatment suggests possible clinical benefit from this immunotherapeutic intervention. The MTD of 7.5 mg/m²/d is suggested for phase II testing but will require clear guidelines for cessation of treatment and dose adjustment for DLT. Phase II testing is now planned to determine antitumor activity of hu14.18-IL-2 in patients with metastatic melanoma.

	Authors' Disclosures of Potential Conflicts of Interest

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The following authors or their immediate family members have indicated a financial interest. No conflict exists for drugs or devices used in a study if they are not being evaluated as part of the investigation. Acted as a consultant within the last 2 years: Ralph Reisfeld, EMD. Served as an officer or member of the Board of a company: Stephen D. Gillies, EMD. Received more than $2,000 per year from a company for either of the last 2 years: Stephen D. Gillies, EMD.

	Acknowledgment

 
We thank our colleagues, Drs Alexander Rakhmilevich, Zane Neal, and Ilia Buhtoiarov of University of Wisconsin–Madison for helpful discussions; Drs Tom Dahl and Mike Super of EMD–Lexigen in Billerica, MA; and Drs Oscar Kashala, Lothar Finke, Knut Sturmhoefel, Raj Malik, Denise Wayne, and Tom Wong of EMD Pharmaceuticals–Durham, NC, for provision of hu14.18-IL-2 and involvement in the conduct of this study; and Kathy Neish for assistance with manuscript preparation.

	NOTES

 
Supported by grant Nos. CA32685, CA14520, CA87025, CA81403, and RR03186 from the National Institutes of Health and a grant from the Midwest Athletes for Childhood Cancer Fund. Partial personnel support was provided by EMD for data management required by EMD for this study, which was beyond the clinical research and data monitoring required for this National Cancer Institute–supported study.

Work previously presented in part at the 35th Annual Meeting of the American Society of Clinical Oncology, Atlanta, GA, May 15-18, 1999; the 36th Annual Meeting of the American Society of Clinical Oncology, New Orleans, LA, May 20-23, 2000; the 38th Annual Meeting of the American Society of Clinical Oncology, Orlando, FL, May 18-21, 2002; American Association for Cancer Research Annual Meeting, Washington DC, July 11-15, 2003; and Society for Biologic Therapy Annual Meetings, Bethesda, MD, November 8-10, 2001, and San Diego, CA, November 7-9, 2002.

Authors' disclosures of potential conflicts of interest are found at the end of this article.

	REFERENCES

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Submitted November 7, 2003; accepted May 27, 2004.

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