Faculty Bibliography

Prostate cancer represents an ideal target for radioimmunotherapy based on the pattern of spread, including bone marrow and lymph nodes, sites that typically receive high levels of circulating antibody, and the small volume of disease, ideally suited for antibody delivery and antigen access. This review explores possible antibody targets in prostate cancer and focuses on the potential role for radioimmunotherapy by highlighting several clinical trials involving radiolabeled anti-prostate-specific membrane antigen monoclonal antibody J591. Prostate-specific membrane antigen, a highly prostate-restricted transmembrane glycoprotein with increased expression in high-grade, metastatic, and hormone-refractory disease, represents an ideal target for monoclonal antibody therapy in prostate cancer. Radiolabeled anti-prostate-specific membrane antigen monoclonal antibody J591 trials using the radiometals yttrium-90 and lutetium-177 have demonstrated manageable myelotoxicity, no significant nonhematologic toxicity, excellent targeting of soft-tissue and bone metastases, and preliminary efficacy including prostate-specific antigen and measurable disease responses. Additional studies are under way to better define the activity of radiolabeled antibody therapy as well as the role for fractionated therapy and combination approaches with taxane-based chemotherapy.

BACKGROUND:Iodine I-131 tositumomab is a well tolerated and effective therapy for recurrent low-grade and transformed low-grade non-Hodgkin lymphoma (NHL). Hematologic reserve after radioimmunotherapy (RIT) is an important consideration when subsequent therapy is required. METHODS:One hundred fifty-five patients who received treatment with I-131 tositumomab were assessed, and 68 patients had progressive disease after RIT. The median age (n=68 patients) was 59 years (range,18-82 yrs), and patients received a median of 2 pre-RIT regimens (range,1-8 regimens), including 66% who received anthracycline, 19% who received platinum, and 50% who received fludarabine. RESULTS:The median time to disease progression (among progressors) was 168 days (range, 19-771 days). At the time they developed recurrent disease, patients had median white blood cell count (WBC) of 4.9 K cells/microL (range, 1.1-21.4 K cells/microL), a median absolute neutrophil count (ANC) of 3.25 K cells/microL (range, 0.59-8.20 K cells/microL), a median platelet count of 130 K cells/microL (range, 9-440 K cells/microL), and there was no significant difference between pre-RIT and recurrence values except for the platelet count (P<0.05). No patient demonstrated a WBC<1.0 K cells/microL or an ANC<0.5 K cells/microL, although 1 patient had a platelet count<10 K cells/microL. Twenty-four patients subsequently received no further chemotherapy; and, in 21 patients (88%), hematologic parameters appeared to allow subsequent chemotherapy if necessary (blood counts: National Cancer Institute Grade 0-2). Among 44 patients (65%) who received further chemotherapy (median, 2 regimens; range, 1-4 regimens), 19 patients (43%) were treated with anthracyclines, 17 patients (39%) were treated with platinum, 10 patients (23%) were treated with fludarabine, and 13 patients (30%) underwent stem cell transplantation. Disease improvement occurred in most patients, although 18 patients died (40%) after further chemotherapy, predominantly from refractory lymphoma. CONCLUSIONS:Most patients with progressive disease after treatment with iodine I-131 tositumomab were able to receive subsequent therapy, including cytotoxic chemotherapy and stem cell transplantation.

PURPOSE/OBJECTIVE:Bone marrow is the dose-limiting organ in radioimmunotherapy. Fractionated dose regimens may decrease myelotoxicity and increase greater total administered dose. We have studied the effect of two or three treatments of 177Lu-J591 and 90Y-J591 monoclonal antibodies (mAb) on myelotoxicity. EXPERIMENTAL DESIGN/METHODS:J591 is a deimmunized anti-PSMA mAb. Seven groups of patients with prostate cancer (n = 35) received 10 to 75 mCi/m2 of 177Lu-J591 and five additional groups (n = 28) received 5 to 20 mCi/m2 of 90Y-J591. Fifteen patients received two to three treatments of 177Lu-J591 (30, 45, or 60 mCi/m2) and four patients received two or three doses of 90Y-J591 (17.5 or 20 mCi/m2). Re-treatment consisted of patients receiving the same 177Lu or 90Y dose as their initial cycle. Time between treatments was 2 to 4 months. RESULTS:The single dose maximum tolerated dose was 70 mCi/m2 with 177Lu-J591 and 17.5 mCi/m2 with 90Y-J591. With a single dose of 177Lu, no severe toxicity was observed below 60 mCi/m2. With 177Lu, two doses of 45 or 60 mCi/m2, totaling 90 to 120 mCi/m2, proved to be quite toxic. Three doses of 30 mCi/m2 (total 90 mCi/m2), however, were well tolerated. With 90Y, four patients tolerated two to three doses of 17.5 or 20 mCi/m2. Thrombocytopenia increased at higher doses and after repeat treatments. At higher doses, the nadir was lower and the time to reach nadir was longer. Time for recovery of platelets seems related to the total dose. CONCLUSIONS:Multiple (two or three) administrations of 177Lu-J591 (30-60 mCi/m2) or 90Y-J591 (17.5 mCi/m2) over a 4- to 6-month period were tolerated by the patients with manageable thrombocytopenia. Although a single large dose may deliver optimal radiation dose to kill a larger fraction of tumor cells, fractionated therapy offers the advantage of lower myelotoxicity and prolonged tumor response. With 177Lu-J591, dose fractionation in combination with taxanes should be considered as an alternative approach to achieve optimal therapeutic efficacy in patients with prostate cancer.

PURPOSE/OBJECTIVE:To evaluate the safety and efficacy of a sequential chemotherapy plus radioimmunotherapy (RIT) regimen in previously untreated follicular non-Hodgkin's lymphoma. PATIENTS AND METHODS/METHODS:Thirty-five patients received an abbreviated course (three cycles) of fludarabine followed 6 to 8 weeks later by tositumomab and iodine I 131 tositumomab. RESULTS:After fludarabine, 31 (89%) of 35 patients responded, with three (9%) of 31 patients achieving a complete response (CR). After the full regimen of fludarabine and iodine I 131 tositumomab, all 35 patients responded; 30 (86%) of 35 patients achieved CR, and five (14%) of 35 achieved partial response. After a median follow-up of 58 months, the median progression-free survival (PFS) had not been reached (95% CI, 27 months to not reached), but it will be at least 48 months. The 5-year estimated PFS rate is 60%. Baseline Follicular Lymphoma International Prognostic Index (FLIPI) was significantly associated (P = .003) with PFS. Five of six patients with more than 25% bone marrow involvement at baseline achieved adequate bone marrow cytoreduction to receive standard-dose iodine I 131 tositumomab. Ten (77%) of 13 patients with baseline bone marrow Bcl-2 positivity demonstrated molecular remissions at month 12. Toxicities were manageable and principally hematologic. Two (6%) of 35 patients developed human antimurine antibodies (HAMA) after RIT. CONCLUSION/CONCLUSIONS:Use of abbreviated fludarabine before iodine I 131 tositumomab can reduce bone marrow involvement, when needed, to allow the use of RIT and can suppress HAMA responses. This sequential treatment regimen is highly effective as front-line therapy for follicular lymphoma, particularly for low- or intermediate-risk FLIPI patients.

PURPOSE/OBJECTIVE:To determine the maximum tolerated dose (MTD), toxicity, human anti-J591 response, pharmacokinetics (PK), organ dosimetry, targeting, and biologic activity of (177)Lutetium-labeled anti-prostate-specific membrane antigen (PSMA) monoclonal antibody J591 ((177)Lu-J591) in patients with androgen-independent prostate cancer (PC). PATIENTS AND METHODS/METHODS:Thirty-five patients with progressing androgen-independent PC received (177)Lu-J591. All patients underwent (177)Lu-J591 imaging, PK, and biodistribution determinations. Patients were eligible for up to three retreatments. RESULTS:Thirty-five patients received (177)Lu-J591, of whom 16 received up to three doses. Myelosuppression was dose limiting at 75 mCi/m(2), and the 70-mCi/m(2) dose level was determined to be the single-dose MTD. Repeat dosing at 45 to 60 mCi/m(2) was associated with dose-limiting myelosuppression; however, up to three doses of 30 mCi/m(2) could be safely administered. Nonhematologic toxicity was not dose limiting. Targeting of all known sites of bone and soft tissue metastases was seen in all 30 patients with positive bone, computed tomography, or magnetic resonance images. No patient developed a human anti-J591 antibody response to deimmunized J591 regardless of number of doses. Biologic activity was seen with four patients experiencing >or= 50% declines in prostate-specific antigen (PSA) levels lasting from 3+ to 8 months. An additional 16 patients (46%) experienced PSA stabilization for a median of 60 days (range, 1 to 21+ months). CONCLUSION/CONCLUSIONS:The MTD of (177)Lu-J591 is 70 mCi/m(2). Multiple doses of 30 mCi/m(2) are well tolerated. Acceptable toxicity, excellent targeting of known sites of PC metastases, and biologic activity in patients with androgen-independent PC warrant further investigation.

UNLABELLED:In radioimmunotherapy, myelotoxicity due to bone marrow radiation-absorbed dose is the predominant factor and frequently is the dose-limiting factor that determines the maximum tolerated dose (MTD). With (90)Y- and (131)I-labeled monoclonal antibodies, it has been reported that myelotoxicity cannot be predicted on the basis of the amount of radioactive dose administered or the bone marrow radiation-absorbed dose (BMrad), estimated using blood radioactivity concentration. As part of a phase I dose-escalation study in patients with prostate cancer with (90)Y-DOTA-J591 (DOTA = 1,4,7,10-tetraazacyclododecane-N,N',N'',N'''-tetraacetic acid) ((90)Y-J591) and (177)Lu-DOTA-J591 ((177)Lu-J591), we evaluated the potential value of several factors in predicting myelotoxicity. METHODS:Seven groups of patients (n = 28) received 370-2,775 MBq/m(2) (10-75 mCi/m(2)) of (177)Lu-J591 and 5 groups of patients (n = 27) received 185-740 MBq (5-20 mCi/m(2)) of (90)Y-J591. Pharmacokinetics and imaging studies were performed for 1-2 wk after (177)Lu treatment, whereas patients receiving (90)Y had these studies performed with (111)In-DOTA-J591 ((111)In-J591) as a surrogate. The BMrad was estimated based on blood radioactivity concentration. Myelotoxicity consisting of thrombocytopenia or neutropenia was graded 1-4 based on criteria of the National Cancer Institute. RESULTS:Blood pharmacokinetics are similar for both tracers. The radiation dose (mGy/MBq) to the bone marrow was 3 times higher with (90)Y (0.91 +/- 0.43) compared with that with (177)Lu (0.32 +/- 0.10). The MTD was 647.5 MBq/m(2) with (90)Y-J591 and 2,590 MBq/m(2) with (177)Lu-J591. The percentage of patients with myelotoxicity (grade 3-4) increased with increasing doses of (90)Y (r = 0.91) or (177)Lu (r = 0.92). There was a better correlation between the radioactive dose administered and the BMrad with (177)Lu (r = 0.91) compared with that with (90)Y (r = 0.75). In addition, with (177)Lu, the fractional decrease in platelets (FDP) correlates well with both the radioactive dose administered (r = 0.88) and the BMrad (r = 0.86). In contrast, with (90)Y, there was poor correlation between the FDP and the radioactive dose administered (r = 0.20) or the BMrad (r = 0.26). Similar results were also observed with white blood cell toxicity. CONCLUSION/CONCLUSIONS:In patients with prostate cancer, myelotoxicity after treatment with (177)Lu-J591 can be predicted on the basis of the amount of radioactive dose administered or the BMrad. The lack of correlation between myelotoxicity and (90)Y-J591 BMrad may be due to several factors. (90)Y-J591 may be less stable in vivo and, as a result, higher amounts of free (90)Y may be localized in the bone. In addition, the cross-fire effect of high-energy beta(-)-particles within the bone and the marrow may deliver radiation dose nonuniformly within the marrow.

UNLABELLED:111In-Labeled antibodies and peptides have been routinely used as chemical and biologic surrogates for 90Y-labeled therapeutic agents. However, recent studies have shown that there are significant differences in biodistribution between 111In- and 90Y-labeled agents. Yttrium and lutetium metals favor the +3 oxidation state, similar to indium, but there are minor differences in the solution and coordination chemistries among these metals. These 3 metals, however, form strong complexes with the macrocyclic chelator, 1,4,7,10-tetraazacyclododecane-N,N',N'',N'''-tetraacetic acid (DOTA). We, therefore, compared the pharmacokinetics and biodistribution of 111In- and 177Lu-labeled J591 antibody. The radiation dosimetry of 90Y-J591 was estimated based on both 111In and 177Lu data to validate the usage of 111In as a chemical and biologic surrogate for 90Y. METHODS:J591 is a deimmunized monoclonal antibody with specificity for the extracellular domain of prostate-specific membrane antigen. In patients with prostate cancer, phase I dose-escalation studies were conducted with 90Y-J591 (n = 29) and 177Lu-J591 (n = 25). Each patient had pharmacokinetics and imaging studies with 111In-J591 (185 MBq/20 mg) over a period of 1 wk and before treatment with 90Y-J591 antibody. In the 177Lu trial, the pharmacokinetics and imaging studies were performed after treatment with the 177Lu-J591 dose (370-2,590 MBq/m2/10 mg/m2) over a 2-wk period after treatment. RESULTS:Blood and urinary pharmacokinetics were similar for both tracers. Based on biexponential decay, the terminal half-life was 44 +/- 15 h for both tracers. In addition, the total-body retention of radioactivity over a 7-d period was also similar between the 2 isotopes. The percentage uptake in liver was about 20% greater with 111In than with 177Lu. Radiation dosimetry estimates for 90Y-J591 calculated on the basis of 111In or 177Lu data were mostly similar and showed that liver is the critical organ, followed by spleen and kidney. Based on blood radioactivity, the radiation dose (mGy/MBq) to the bone marrow was 3 times higher with 90Y (0.91 +/- 0.43) compared with that with 177Lu (0.32 +/- 0.10). CONCLUSION/CONCLUSIONS:111In- and 177Lu-labeled J591 antibodies have similar plasma and whole-body clearance kinetics. The net retention of 111In activity by lung, liver, and spleen is slightly higher compared with that with 177Lu. These results justify using 111In as a chemical and biologic surrogate for 90Y. However, the radiation dose to the liver may be overestimated by about 25% based on 111In data. In addition, the data also suggest that 177Lu may be a potential alternative for estimating the pharmacokinetics and biodistribution of 90Y-labeled radiopharmaceuticals.

PURPOSE/OBJECTIVE:To determine the maximum-tolerated dose (MTD), toxicity, human antihuman antibody (HAHA) response, pharmacokinetics, organ dosimetry, targeting, and preliminary efficacy of yttrium-90-labeled anti-prostate-specific membrane antigen monoclonal antibody J591 ((90)Y-J591) in patients with androgen-independent prostate cancer (PC). PATIENTS AND METHODS/METHODS:Patients with androgen-independent PC and evidence of disease progression received indium-111-J591 for pharmacokinetic and biodistribution determinations followed 1 week later by (90)Y-J591 at five dose levels: 5, 10, 15, 17.5, and 20 mCi/m(2). Patients were eligible for up to three re-treatments if platelet and neutrophil recovery was satisfactory. RESULTS:Twenty-nine patients with androgen-independent PC received (90)Y-J591, four of whom were re-treated. Dose limiting toxicity (DLT) was seen at 20 mCi/m(2), with two patients experiencing thrombocytopenia with non-life-threatening bleeding episodes requiring platelet transfusions. The 17.5-mCi/m(2) dose level was determined to be the MTD. No re-treated patients experienced DLT. Nonhematologic toxicity was not dose limiting. Targeting of known sites of bone and soft tissue metastases was seen in the majority of patients. No HAHA response was seen. Antitumor activity was seen, with two patients experiencing 85% and 70% declines in prostate-specific antigen (PSA) levels lasting 8 and 8.6 months, respectively, before returning to baseline. Both patients had objective measurable disease responses. An additional six patients (21%) experienced PSA stabilization. CONCLUSION/CONCLUSIONS:The recommended dose for (90)Y-J591 is 17.5 mCi/m(2). Acceptable toxicity, excellent targeting of known sites of PC metastases, and biologic activity in patients with androgen-independent PC warrant further investigation of (90)Y-J591 in the treatment of patients with PC.

Positron emission tomography (PET) imaging using [F-18]fluorodeoxyglucose (FDG) has become a useful imaging modality in the staging and treatment evaluation algorithm for lymphoma, providing unique metabolic information. Increased FDG uptake in lymphoma tumor masses is a function of increased anaerobic metabolism and longer residence time of FDG in malignant cells relative to most normal tissues. The information provided by FDG-PET appears to result in greater sensitivity compared to anatomic imaging modalities, particularly computed tomography (CT). Over several decades CT has been the principal imaging modality for the staging and restaging of lymphoma, although it can have significant shortcomings stemming from its sized-based criteria, particularly in the post-therapy setting. Gallium-67 (Ga-67) scintigraphy has played an important role in monitoring response to therapy; however, the sensitivity of Ga-67 depends on histologic subtype of lymphoma, size, and location of disease. Published results suggest that FDG-PET is superior to Ga-67 imaging and equal or superior to CT for the detection of nodal and extranodal lymphoma at initial staging. Furthermore, persistent FDG uptake during and after chemotherapy has a high sensitivity and specificity for prediction of subsequent relapse. While in some cases FDG-PET imaging can yield findings that prompt a change in treatment strategy, prospective studies are necessary to better establish the ability of routine FDG-PET imaging to impact therapeutic outcomes for patients with lymphoma.