Pretargeting of Carcinoembryonic Antigen–Expressing Cancers with a Trivalent Bispecific Fusion Protein Produced in Myeloma Cells

PURPOSE

To characterize a novel trivalent bispecific fusion protein and evaluate its potential utility for pretargeted delivery of radionuclides to tumors.

EXPERIMENTAL DESIGN

hBS14, a recombinant fusion protein that binds bispecifically to carcinoembryonic antigen (CEA) and the hapten, histamine-succinyl-glycine (HSG), was produced by transgenic myeloma cells and purified to near homogeneity in a single step using a novel HSG-based affinity chromatography system. Biochemical characterization included size-exclusion high-performance liquid chromatography (SE-HPLC), SDS-PAGE, and isoelectric focusing. Functional characterization was provided by BIAcore and SE-HPLC. The efficacy of hBS14 for tumor pretargeting was evaluated in CEA-expressing GW-39 human colon tumor-bearing nude mice using a bivalent HSG hapten (IMP-241) labeled with (111)In.

RESULTS

Biochemical analysis showed that single-step affinity chromatography provided highly purified material. SE-HPLC shows a single protein peak consistent with the predicted molecular size of hBS14. SDS-PAGE analysis shows only two polypeptide bands, which are consistent with the calculated molecular weights of the hBS14 polypeptides. BIAcore showed the bispecific binding properties and suggested that hBS14 possesses two functional CEA-binding sites. This was supported by SE-HPLC immunoreactivity experiments. All of the data suggest that the structure of hBS14 is an 80 kDa heterodimer with one HSG and two CEA binding sites. Pretargeting experiments in the mouse model showed high uptake of radiopeptide in the tumor, with favorable tumor-to-nontumor ratios as early as 3 hours postinjection.

CONCLUSIONS

The results indicate that hBS14 is an attractive candidate for use in a variety of pretargeting applications, particularly tumor therapy with radionuclides and drugs.

Improved therapy of non-Hodgkin's lymphoma xenografts using radionuclides pretargeted with a new anti-CD20 bispecific antibody

A comparison of the therapeutic efficacy of a new bispecific monoclonal antibody (bsMAb)-pretargeting system vs the conventional direct targeting modality was undertaken. A bsMAb was made by coupling the Fab' of a humanized anti-CD20 antibody to the Fab' of a murine antibody directed against the peptide histamine-succinyl-glycine (HSG). The tumor targeting of the bsMAb was separated from the subsequent delivery of the radionuclide-bearing HSG peptide conjugated with (111)In or (90)Y. Nude mice bearing s.c. Ramos human B-cell lymphomas were injected with the bsMAb and then, 48 h later, (111)In/(90)Y-HSG peptide was given. At 3 h postinjection, tumor/blood ratios for pretargeted (111)In-HSG-peptide were similar to that observed with the directly conjugated (111)In-anti-CD20 IgG at its highest level on day 7, but by day 1, tumor/blood ratios were about 10-fold higher than the IgG. Tumors progressed rapidly in animals given 800 microCi of (90)Y-HSG peptide alone, whereas 5/10 animals in the group pretargeted by the anti-CD20 bsMAb were tumor-free 18 weeks later. The antitumor response in animals administered the pretargeted (90)Y-HSG peptide was also significantly superior to treatment with the directly radiolabeled (90)Y-anti-CD20 IgG, whether given as a single injection (P<0.007) or as a divided dose (P=0.016). This bsMAb-pretargeting procedure significantly improves the therapeutic response of targeted radionuclides in non-Hodgkin's lymphoma, warranting further development of this method of radioimmunotherapy.

A phase I trial combining high-dose 90Y-labeled humanized anti-CEA monoclonal antibody with doxorubicin and peripheral blood stem cell rescue in advanced medullary thyroid cancer

This trial determined the pharmacokinetics, dosimetry, and dose-limiting toxicity of 90Y-hMN-14 IgG (humanized anticarcinoembryonic antigen [CEA, or CEACAM5] monoclonal antibody; labetuzumab), combined with doxorubicin and peripheral blood stem cell (PBSC) support in advanced medullary thyroid cancer (MTC) patients.

METHODS

Fifteen patients received an infusion of 111In-hMN-14 IgG. One to 2 wk later, 14 patients received 90Y-hMN-14 IgG, starting at 740 MBq/m2, followed 24 h later with a fixed intravenous bolus dose of doxorubicin (60 mg/m2). Preharvested PBSCs were reinfused when the 90Y activity in the body was < or =111 MBq/m2.

RESULTS

The mean red marrow dose estimated for the 90Y-hMN-14 IgG was 1.65 +/- 0.59 mGy/MBq (n = 11), with normal organs ranging from approximately 2.3 to 4.4 mGy/MBq. Eighty percent of all known lesions (125/156), including 78 of 79 bone and 16 putatively occult lesions, were targeted. The average radiation dose to the tumor was 15.1 +/- 10.8 mGy/MBq (55.8 +/- 39.8 cGy/mCi) 90Y-hMN-4 IgG (n = 29 tumors in 8 patients), with a majority of the lesions receiving >2,000 cGy at an administered dose of < or =1,480 MBq/m2. The average tumor-to-red marrow, tumor-to-liver, tumor-to-lungs, and tumor-to-kidneys ratios were 15.0 +/- 11.0, 5.1 +/- 3.6, 6.9 +/- 6.1, and 9.0 +/- 8.7, respectively. Cardiopulmonary toxicity was dose limiting at 1,850 MBq/m2. Minor responses were noted in 2 patients and 1 patient had a partial response (68% reduction in local and hepatic metastatic disease).

CONCLUSION

This treatment combination was well tolerated with complete recovery of blood counts and reversible nonhematologic toxicities at the maximum tolerated dose of 1,480 MBq/m2. Evidence of antitumor response in these patients with advanced cancer was modest, but encouraging; this type of treatment may be more successful if applied to more limited, earlier-stage disease.

Perspectives on cancer therapy with radiolabeled monoclonal antibodies

With the approval of 2 radiolabeled antibody products for the treatment of non-Hodgkin's lymphoma (NHL), radioimmunotherapy (RIT) has finally come of age as a new therapeutic modality, exemplifying the collaboration of multiple disciplines, including immunology, radiochemistry, radiation medicine, medical oncology, and nuclear medicine. Despite the many challenges that this new therapy discipline has encountered, there is growing evidence that RIT can have a significant impact on the treatment of cancer. Although follicular NHL is currently the only indication in which RIT has been proven to be effective, clinical trials are showing usefulness in other forms of NHL as well as in other hematologic neoplasms. However, the treatment of solid tumors remains a formidable challenge, because the doses shown to be effective in hematologic tumors are insufficient in the more common epithelial cancers. Nevertheless, there has been progress in locoregional applications and in the treatment of minimal residual disease. There is also optimism that pretargeting procedures, including new molecular constructs and targets, will improve the delivery of radioactivity to tumors, do so with less hematologic toxicity, and become the next generation of RIT.

Clinical-scale radiolabeling of a humanized anticarcinoembryonic antigen monoclonal antibody, hMN-14, with residualizing 131I for use in radioimmunotherapy

Radiolabeling of monoclonal antibodies (mAbs) with an intracellularly trapped form of (131)I (residualizing (131)I) involves radioiodinating a small molecular entity, conjugating it to the mAb, and purification. Column purifications are impractical during procedures involving multi-gigabecquerel levels of radioactivity. The goal of this study was to develop a simple, remote, "1-pot" method of radiolabeling and purification for the scaled-up radioiodination of a humanized anti-carcinoembryonic antigen (CEA) mAb, humanized MN-14 (hMN-14; labetuzumab), with an optimized residualizing (131)I moiety, (131)I-IMP-R4. IMP-R4 is MCC-Lys(MCC)-Lys(X)-d-Tyr-d-Lys(X)-OH, where MCC is 4-(N-maleimidomethyl)-cyclohexane-1-carbonyl and X is 1-((4-thiocarbonylamino)benzyl)-diethylenetriaminepentaacetic acid.

METHODS

An IODO-GEN-based remote labeling system was used. IMP-R4 was radioiodinated (0.13 mumol per 3.7 GBq of (131)I) at a pH of 7.0-7.4 and conjugated to disulfide-reduced hMN-14 after quenching of unused reactive (131)I. The product was purified by stirring for 5 min with a 20% (w/v) suspension of an anion-exchange resin and sterilely filtered into a sealed vial. Human serum albumin was added at a final concentration of 1%-2.5%. Immunoreactivity was determined by mixing with CEA and determining the complexation level by size-exclusion high-pressure liquid chromatography. Two control radiolabelings, either with unreduced hMN-14 or with IMP-R4 omitted, also were performed.

RESULTS

In 18 radiolabelings with (131)I in the range of 2.04-4.81 GBq (55-130 mCi), yields of 59.9% +/- 7.9% (mean +/- SD) at specific activities of 200 +/- 26 MBq/mg (5.4 +/- 0.7 mCi/mg) were obtained, with > or =95% of the radioactivity being associated with hMN-14 and with < or =4% aggregation. Similar yields were obtained in a subset of radiolabelings (n = 7) with >3.7 GBq of (131)I. The immunoreactivities of the preparations were typically >95%. Nonspecific incorporation in the absence of IMP-R4 was 0.5%, whereas that obtained with unreduced IgG was approximately 8%, possibly because of conjugation of IMP-R4 at lysine sites. The process also removed >99% of the quenching reagent used. Radiolabelings performed with freshly prepared solutions or lyophilized preparations produced similar yields, a result that suggested the option for a single-use kit design.

CONCLUSION

Efficient removal of (131)I-IMP-R4 and quenched (131)I by 5 min of stirring with anion-exchange resin renders a multi-gigabecquerel-level preparation of (131)I-IMP-R4-hMN-14 safe, convenient, and practical.

Improved targeting of pancreatic cancer: experimental studies of a new bispecific antibody, pretargeting enhancement system for immunoscintigraphy

PURPOSE

The early detection and diagnosis of pancreatic cancer remains a major clinical challenge in which imaging procedures have a central role. The purpose of this study was to evaluate a pretargeting method with a bispecific PAM4 (bsPAM4; anti-MUC1) antibody for radioimmunoscintigraphy of experimental human pancreatic cancer.

EXPERIMENTAL DESIGN

A bispecific F(ab')(2) antibody was generated from chimeric PAM4 Fab' and murine 734 (anti-indium-diethylenetriaminepentaacetic acid) Fab' fragments and then used in conjunction with 2 peptide haptens ((111)In-IMP-156 and (99m)Tc-IMP-192). Biodistribution studies and radioimmunoscintigraphic imaging properties of the radiolabeled bsPAM4, and pretargeted, radiolabeled peptides were examined in the CaPan1 human pancreatic tumor grown as s.c. xenografts in athymic nude mice. Tumor uptake and tumor:nontumor ratios were compared with a nontargeting irrelevant anti-CD20, bispecific rituximab, radiolabeled peptides alone, and with directly labeled PAM4.

RESULTS

Biodistribution results indicated significantly greater tumor uptake of radiolabeled peptides at 3 h after injection when pretargeting was performed with bsPAM4 as compared with the bispecific rituximab [20.2 +/- 5.5 percentage of injected dose per gram of tissue (%ID/g) versus 0.9 +/- 0.1%ID/g, respectively, for (111)In-IMP-156, and 16.8 +/- 4.8%ID/g versus 1.1 +/- 0.2%ID/g, respectively, for (99m)Tc-IMP-192]. Similar results were obtained at the 24-h time point. Tumor:nontumor ratios were >30 for all of the tissues except the kidneys, where a ratio of 7.8 +/- 2.8 was observed. By immunoscintigraphy, tumors could be visualized as early as 30 min after injection of the radiolabeled peptide.

CONCLUSIONS

These studies demonstrate the feasibility of using the pretargeted, bispecific antibody technology for nuclear imaging of pancreatic cancer. The advantage of pretargeted bsPAM4 antibody as an imaging platform is the high specificity for pancreatic cancer as compared with the physicochemical parameters identified by current imaging technologies.

Reagents and methods for PET using bispecific antibody pretargeting and 68Ga-radiolabeled bivalent hapten-peptide-chelate conjugates

The aim of this work was to develop reagents and methods potentially useful in PET, using (68)Ga in a 2-step pretargeting protocol.

METHODS

We prepared bispecific antibodies (bsAbs) for disease-specific targeting of carcinoembryonic antigen-positive cells and recognition of later-administered bivalent hapten-peptide conjugates. The secondary antibody arm (antibody 679) recognizes a histaminyl-succinyl-glycine (HSG) structural subunit. The bsAbs were prepared as Fab' x Fab' conjugates using chemical cross-linking methods and as bispecific diabodies using recombinant DNA technologies. A HSG-bivalent hapten conjugate bearing the macrocyclic ring chelating agent 1,4,7,10-tetraazacyclododecane-N,N',N",N"'-tetraacetic acid (DOTA) was designed to be readily radiolabeled with (68)Ga taken directly from a (68)Ge/(68)Ga generator system. Reagents were tested in vitro and, then, for their targeting properties in a preclinical animal model of human cancer.

RESULTS

A chemically cross-linked hMN-14 x 679 F(ab')(2) and a fully humanized bispecific diabody construct (BS1.5H), expressed in Escherichia coli, were prepared for this work. We synthesized the bivalent peptide termed IMP 241 [DOTA-Phe-Lys(HSG)-D-Tyr-Lys(HSG)-NH(2)] and labeled it with (68)Ga and (67)Ga at temperatures from 45 degrees C to 100 degrees C, over times of 15 min to 1 h, establishing 15 min at 95 degrees C as a useful condition for (68)Ga labeling. When we formulated the IMP 241 bivalent hapten-peptide with ammonium acetate buffer at pH 4-5 and eluted the (68)Ga from the generator directly into the peptide solution, we achieved an almost quantitative incorporation of the (68)Ga into IMP 241, as analyzed by size-exclusion high-performance liquid chromatography, after mixing the complex with the 679 antibody. For in vivo studies we used (67)Ga-IMP 241 as a surrogate for (68)Ga-IMP 241, in view of the short, 68-min half-life of the (68)Ga nuclide. The (67)Ga-IMP 241 was successfully pretargeted to human colon tumor xenografts in athymic mice with both the chemical and the diabody bispecific proteins. High tumor-to-normal tissue ratios for (67)Ga uptake were found for all tissues at 1 to 6 h after injection of (67)Ga-IMP 241. When using the BS1.5H diabody for pretargeting, tumor-to-blood, tumor-to-liver, and tumor-to-lung ratios of (67)Ga-IMP 241 at 1 and 3 h after injection were 41:1 and 137:1, 51:1 and 106:1, and 16:1 and 46:1, respectively.

CONCLUSION

The general approach described, along with the new compositions and the labeling methods we have developed, may eventually allow for use of (68)Ga-labeled specific targeting agents in a routine clinical PET application.

Radioimmunotherapy of non-Hodgkin's lymphoma with 90Y-DOTA humanized anti-CD22 IgG (90Y-Epratuzumab): do tumor targeting and dosimetry predict therapeutic response?

A DOTA (1,4,7,10-tetraazacyclododecane-N,N',N",N"'-tetraacetic acid)-conjugated, (111)In- and (90)Y-labeled humanized antibody to CD22, epratuzumab, was studied in patients with non-Hodgkin's lymphoma (NHL) to assess biodistribution and tumor targeting, pharmacokinetics, dosimetry, and anti-antibody response. Of particular interest was to evaluate whether pretherapy targeting and tumor dosimetry could predict therapeutic responses.

METHODS

Patients received a pretherapy imaging study with (111)In-DOTA-epratuzumab IgG (0.75 mg/kg), followed about 1 wk later with (90)Y-DOTA-epratuzumab starting at a dose level of 0.185 GBq/m(2) (5 mCi/m(2)) in patients who had prior high-dose chemotherapy (group 2), and at 0.370 GBq/m(2) in patients who did not have a prior transplant (group 1), with escalation in 0.185-GBq/m(2) increments.

RESULTS

The effective blood half-life for (111)In-DOTA epratuzumab was 36.1 +/- 7.9 h (n = 25) compared with 35.2 +/- 7.0 h for (90)Y-DOTA-epratuzumab (n = 22). The whole-body half-life for (90)Y-DOTA-epratuzumab estimated from (111)In-DOTA-epratuzumab scintigraphy was 58.3 +/- 4.7 h (n = 20), with urine collection confirming the loss of between 2.2% and 15.9% of the injected activity over 3 d (n = 3). One-hundred sixteen of 165 CT-confirmed lesions were visualized with (111)In-DOTA-epratuzumab. Radiation-absorbed doses to liver, lungs, and kidneys averaged 0.55 +/- 0.13 (n = 17), 0.28 +/- 0.06 (n = 17), and 0.38 +/- 0.07 mGy/MBq (n = 10), respectively, with 0.14 +/- 0.02 and 0.23 +/- 0.04 mGy/MBq delivered to the whole-body and red marrow, respectively. Tumor doses (n = 14 lesions in 10 patients) ranged from 1.0 to as much as 83 mGy/MBq for a 0.5-g lesion (median, 7.15 mGy/MBq). Group 2 patients were more likely to experience significant hematologic toxicities, but doses of up to 0.370 GBq/m(2) of (90)Y-DOTA-epratuzumab were tolerated with standard support measures, whereas patients in group 1 tolerated doses of up to 0.740 GBq/m(2) with the potential for further escalation. Anti-tumor effects were seen in both indolent and aggressive NHL. The data also suggest that anti-tumor responses of potentially equal magnitude can occur irrespective of tumor targeting and tumor size. Hence, tumor response did not correlate with the radiation dose delivered or with the tumor being visualized by external imaging. An anti-antibody response to epratuzumab was detected by an enzyme-linked immunosorbent assay in only 2 of 16 patients.

CONCLUSION

These results suggest that (90)Y-DOTA-epratuzmab is a promising agent for the treatment of NHL and warrants further study. There was evidence suggesting that in this system, factors other than tumor radiation dose and targeting may be involved in the success of radioimmunotherapy.

Meeting report on the Ninth Conference on Cancer Therapy with Antibodies and Immunoconjugates

This conference, held biennially for the past 12 years, provides a forum where investigators from throughout the world can gather and discuss how monoclonal antibodies can be used to improve the treatment of cancer. As in the past, this meeting focused primarily on the use of radiolabeled antibodies in cancer treatment, but this year there were many additional contributions on the use of unconjugated "naked" antibodies for the treatment of cancer, reflecting a growing understanding that antibodies not only can be used to direct isotopes and drugs to tumors but can also be effective agents in themselves. Preclinical studies using immunoconjugates prepared with toxins, drugs, or other agents were also reported to be highly effective therapeutic agents. Some of these are now showing efficacy in clinical trials. In addition, presentations focused on a variety of approaches, including pretargeting, regional delivery, and combinations with other standard treatment regimens designed to optimize antibody-targeted treatment strategies. Although the most efficacious treatments were reported in a variety of hematological malignancies, there were a number of presentations, primarily in early preclinical development, that provided evidence for potential future improvements in the treatment of solid tumors.

Pharmacokinetics and dosimetry studies for optimization of anti-carcinoembryonic antigen x anti-hapten bispecific antibody-mediated pretargeting of Iodine-131-labeled hapten in a phase I radioimmunotherapy trial

PURPOSE

Pharmacokinetics and dosimetry of hMN-14 x m734 bispecific monoclonal antibody (BsMAb) and (131)I-labeled di-diethylenetriaminepentaacetic acid-indium ((131)I-hapten) were studied to optimize pretargeted radioimmunotherapy.

EXPERIMENTAL DESIGN

Thirty-five patients with carcinoembryonic antigen-expressing tumors were included. In a first group of 12 patients, (131)I-trace-labeled BsMAb doses were escalated from 10 to 100 mg/m(2), and 3.7 GBq of (131)I-hapten were administered 7 days later. In a second group, 12 patients received 75 mg/m(2) BsMAb and 2.6-4.2 GBq of (131)I-hapten 5 days later. The BsMAb dose was then reduced to 40 mg/m(2), and 10 patients received 1.9-5.5 GBq of (131)I-hapten. Blood samples were collected. Biodistribution was monitored by quantitative scintigraphy.

RESULTS

Directly labeled BsMAb pharmacokinetics was described by two exponentials: half-lives were 8.1 h (2.0-18.1 h) and 48.2 h (22.8-79.4 h); blood clearance was 123 ml/h (64-195 ml/h). With a 7-day interval, 10 or 30 mg/m(2) BsMAb resulted in fast elimination and very low tumor uptake of hapten, whereas 50 or 100 mg/m(2) resulted in favorable tumor accretion. With 75 mg/m(2) BsMAb and a 5-day interval, hapten clearance was 152 ml/h (81-298 ml/h). Calculated radiation dose to tumor was 3.9 Gy/GBq (0.4-22.4 Gy/GBq) for the hapten, compared with 2.0 Gy/GBq (0.3-3.8 Gy/GBq) for the BsMAb, but hematological toxicity prevented dose escalation. Reduction of the BsMAb dose to 40 mg/m(2) accelerated hapten clearance to 492 ml/h (113-2544 ml/h) and reduced hematological toxicity without compromising tumor uptake [5.2 Gy/GBq (0.5-12.6 Gy/GBq)].

CONCLUSIONS

Optimized BsMAb doses and time interval will allow for the administration of higher, tumoricidal, activity doses.

Development of new multivalent-bispecific agents for pretargeting tumor localization and therapy

PURPOSE

Two bispecific diabodies (BS1.5 and BS1.5H) and two bispecific trivalent proteins (BS6 and BS8) were produced and tested as potential agents for pretargeted delivery of radiolabeled bivalent haptens to tumors expressing carcinoembryonic antigen.

EXPERIMENTAL DESIGN

Each of the four proteins was expressed in Escherichia coli and purified from the soluble fraction. BS1.5 and BS1.5H (a humanized version of BS1.5) were evaluated in the GW-39 human colonic tumor-nude mouse model using a di-HSG-1,4,7,10-tetra-azacyclododecane-N,N',N" N"'-tetraacetic acid peptide (IMP-241) radiolabeled with (111)In. The biodistribution and T/NT ratios were compared with those of hMN-14 x m679 (Fab' x Fab') prepared chemically.

RESULTS

In animals, both BS1.5 and BS1.5H cleared more rapidly than hMN-14 x m679 and showed tumor to nontumor ratios far superior to those of hMN-14 x m679. For example, with BS1.5 injected 8 h before (111)In-IMP-241, the tumor uptake of (111)In was 10.3 +/- 2.7 and 6.3 +/- 2.2% ID/g at 3 and 24 h, respectively, with the tumor to blood ratios being 167 +/- 35 at 3 h and 631 +/- 231 at 24 h. In comparison, the tumor to blood ratios of (111)In observed for hMN-14 x m679 given 24 h earlier were 8 +/- 2 at 3 h and 16 +/- 3 at 24 h.

CONCLUSIONS

These results indicate that BS1.5 and BS1.5H are promising candidates for use in a variety of pretargeting applications, including tumor therapy with radionuclides and drugs. BS6 and BS8 may be even more attractive because of their potential to achieve higher levels of tumor uptake because of divalent carcinoembryonic antigen binding.

Optimizing bispecific antibody pretargeting for use in radioimmunotherapy

PURPOSE

With increasing interest in pretargeting procedures for improving the delivery of radionuclides for cancer imaging and therapy, this investigation was undertaken to examine how to optimize a bispecific monoclonal antibody (bsMAb) pretargeting procedure for therapeutic applications.

EXPERIMENTAL DESIGN

The model system examined was a bsMAb composed of two Fab' fragments, one from a humanized anti-carcinoembryonic antigen antibody (hMN-14), and the other a murine antibody (679) against histamine-succinyl-glycine. These Fab' fragments were chemically conjugated to form a F(ab')(2) that is joined by a stable thioether bond. The peptide used for these studies (IMP-241) contained two histamine-succinyl-glycine moieties for binding to the 679 portion of the bsMAb and a single 1,4,7,10-tetra-azacyclododecane N,N',N",N"'-tetraacetic acid chelate for radiolabeling with (111)In.

RESULTS

The bsMAb cleared rapidly in nude mice bearing the GW-39 human colonic cancer xenograft. Administration of a radiolabeled peptide 1 day after the bsMAb, using a bsMAb/peptide mole injection ratio of 10:1, allowed for higher tumor accretion than if delayed by 2 days. Tumor uptake measured 3 h after the peptide injection given 1 day after the bsMAb was 11.3 +/- 2.2% percentage of injected dose/gram (%ID/g), with just 2.9 +/- 0.4% ID/g of the bsMAb in the tumor at this time. Tumor/blood ratios were 8.1 +/- 2.1. Peptide uptake was highest in the kidneys, but even so, the tumor/kidney ratio was 2.5 +/- 1.9 just 3 h after the peptide injection. Although low bsMAb/peptide mole injection ratios allow for greater concentrations of the peptide in the tumor, kidney uptake is increased at a proportionally higher amount than in the tumor. Therefore, a bsMAb/peptide injection ratio of 10:1 with a 24-h interval was preferred for pretargeting. Increasing the bsMAb dose, and thereby increasing the bsMAb/peptide injection ratio, further enhanced the delivery of the radiolabeled peptide to the tumor, but the interval spacing between the bsMAb and peptide had to be increased. Despite having a lower %ID/g of the bsMAb in the tumor, with a bsMAb/peptide injection ratio of 50:1 and a 48-h interval, tumor uptake of the (111)In-peptide was nearly 30% ID/g, a 1.6-fold improvement over that seen with the 10:1/24-h interval pretargeting group, and tumor/blood was 35:1, and tumor/kidney ratio was 8:1. Two fractionation strategies were also examined. Giving two equal fractions of peptide after a single injection of bsMAb loaded more moles of peptide into the tumor but would not permit higher radioactivity delivery than what could be achieved with a single injection. However, area under the curve analysis indicated that giving repeated cycles of the bsMAb followed by the peptide would enable improvements in the amount of radioactivity delivered to the tumor without increasing the amount delivered to normal tissues, but the timing of the bsMAb/peptide cycles was important to optimize this process. Finally, it was noted that larger tumors (e.g. those > 0.3 g) were more likely to have higher peptide uptake in a pretargeting procedure than smaller tumors (e.g., those of approximately 0.1 g), perhaps due to the greater mass of the bsMAb localized in the larger tumors, but also possibly because of better blood supply in these tumors.

CONCLUSIONS

These studies reveal principles that might be applied generally to other pretargeting procedures and demonstrate how a bsMAb pretargeting method could potentially exceed a directly radiolabeled antibody in its ability to deliver radionuclides for cancer therapy.

Use of ibritumomab tiuxetan anti-CD20 radioimmunotherapy in a non-Hodgkin's lymphoma patient previously treated with a yttrium-90-labeled anti-CD22 monoclonal antibody

Ibritumomab tiuxetan is a novel radioimmunotherapeutic agent that has a high response rate in relapsed or chemotherapy-refractory CD20+ B-cell non-Hodgkin's lymphoma. Whereas chemotherapy agents can successfully be used multiple times in a given patient, there are few data on the repeated use of radioimmunotherapy in terms of efficacy or morbidity, and no reports as yet involving radioconjugates that target different antigens We report on a patient who was treated successfully with yttrium-90-labeled humanized anti-CD22 monoclonal antibody (90Y-epratuzumab). Upon relapse 3 years later, the patient was treated again with radioimmunotherapy consisting of 90Y-ibritumomab tiuxetan anti-CD20 monoclonal antibody, with a good response and acceptable bone marrow suppression. This case report demonstrates the potential for repeated treatments with radioimmunotherapy agents in patients with chemotherapy-refractory non-Hodgkin's lymphoma.

A universal pretargeting system for cancer detection and therapy using bispecific antibody

Multistep targeting systems represent highly selective alternatives to targeting systems using directly radiolabeled antibodies for diagnostic and therapeutic applications. A flexible bispecific antibody (bsMAb) multistep, pretargeting system that potentially can be developed for use with a variety of different imaging or therapeutic agents is described herein. The flexibility of this system is based on use of an antibody directed against histamine-succinyl-glycine (HSG) and the development of peptides containing the HSG residue. HSG-containing peptides were synthesized with either 1,4,7,10-tetraazacyclododecane-N,N',N",N"'-tetraacetic acid for the chelation of 111In, 90Y, or 177Lu, or a technetium/rhenium chelate. The peptides can be radiolabeled to a high specific activity in a facile manner that avoids the need for purification. In vivo studies in nude mice bearing human colon tumor xenografts showed that the radiolabeled peptides cleared rapidly from the body with minimal retention in tumor or normal tissues. For pretargeting, these peptides were used in combination with a bsMAb composed of the anti-HSG Fab' that was covalently coupled with the Fab' of either an anticarcinoembryonic antigen or an anticolon-specific antigen-p antibody to provide tumor targeting capability. When the radiolabeled peptides were administered 1-2 days after a pretargeting dose of the bsMAbs, tumor uptake of the radiolabeled peptides increased as much as 28-175-fold over that seen with the peptides alone with tumor:nontumor ratios exceeding 2:1 to 8:1 within just 3 h of the peptide injection, which was a marked improvement over the tumor:nontumor ratios seen with a directly radiolabeled 99mTc-anti-anticarcinoembryonic antigen Fab' at this same time. The anticolon-specific antigen-p x anti-HSG F(ab')2 bsMAb had the highest and longest retention in the tumor, and when used in combination with the 111In-labeled peptide, radiation dose estimates for therapeutic radionuclides, such as 90Y and 177Lu, suggested that antitumor effects would be expected with tolerable radiation exposure to the normal tissues. These results suggest that this multistep, pretargeting system has diagnostic imaging and therapeutic potential.

Red marrow radiation dose adjustment using plasma FLT3-L cytokine levels: improved correlations between hematologic toxicity and bone marrow dose for radioimmunotherapy patients

Calculated red marrow absorbed dose in patients receiving radioimmunotherapy (RAIT) has not been highly predictive of the dose-limiting hematologic toxicity observed in many patient populations studied. Because patients receiving the same red marrow dose often experience different grades of toxicity, other factors might help predict the different grades of toxicity observed. One such factor may be the plasma FLT3-L (FMS-related tyrosine kinase 3 ligand, hematopoiesis stimulatory cytokine) level, which has been shown to be a better indicator of recovery of progenitor cells and, thus, red marrow radiosensitivity (because during the recovery period the progenitor cells are hyperproliferative and potentially more radiosensitive) for patients treated with previous chemotherapy than peripheral blood counts.

METHODS

Red marrow radiation doses were determined for 30 patients (20 male, 10 female; all without bone marrow or bone involvement; 19 had prior chemotherapy) after receiving (131)I RAIT (activity range, 2.1-8.9 GBq) for treatment of solid cancers known to produce carcinoembryonic antigen. Radiation dose estimates were calculated using 2 different methods of red marrow cumulated activity and red marrow-to-blood activity concentration ratio determinations for 2 dosimetric models: using both male and female and male-only masses and S values. Highest platelet toxicity grade at nadir (PTG), percentage platelet decrease (PPD) in counts, and platelet nadir (PN) counts were measured. FLT3-L levels (pg/mL) were determined by immunoassay before treatment; a normal FLT3-L level was assumed to be 80 pg/mL. The red marrow radiation doses (cGy) were adjusted for the patient's FLT3-L level when the patient's cytokine level exceeded the normal value. Marrow doses and FLT3-L-adjusted marrow doses were correlated with PTG, PPD, PN, and 1/PN. Administered activity, administered activity per unit body weight, and total body radiation dose were also correlated with these hematologic toxicity measures.

RESULTS

All red marrow dose calculation schemes resulted in essentially the same correlations for a given hematologic toxicity measure. Poor correlations were observed between administered activity, administered activity per unit body weight, total body radiation dose, or red marrow radiation dose and PTG, PPD, PN, and 1/PN. All correlations improved greatly when the various predictors of toxicity were adjusted for the patient's FLT3-L level. The highest correlation observed was between red marrow dose or total body dose and 1/PN (r = 0.86). Using an unadjusted red marrow dose to predict toxicity >/= grade 3, there were 8 true-positive, but 13 false-positive cases with 9 true-negatives. However, using a FLT3-L-adjusted red marrow dose, there were 8 true-positives, but only 2 false-positives and 20 true-negatives.

CONCLUSION

FLT3-L-adjusted red marrow radiation doses provide improved correlation with hematologic toxicity. Thus, elevated FLT3-L plasma levels before RAIT may indicate increased radiosensitivity of the bone marrow, and use of this measurement to adjust calculated red marrow or total body radiation doses may provide significantly better prediction of toxicity than radiation dose alone, leading to a patient-specific administered activity prescription that will deliver radiation doses to diseased tissues sufficient to produce an effective treatment outcome at acceptable toxicity levels.

90Y-DOTA-hLL2: an agent for radioimmunotherapy of non-Hodgkin's lymphoma

The goal of this work was to determine an optimal radioimmunotherapy agent for further development against non-Hodgkin's lymphoma. We sought to establish the stability profile of (90)Y-labeled humanized LL2 (hLL2) monoclonal antibody (mAb) when prepared with different chelating agents and, from these data, to estimate the dosimetric improvement to be expected from use of the most stable (90)Y-chelate-hLL2 complex.

METHODS

The complementarity-determining region-grafted (humanized) anti-CD22 mAb, hLL2 (epratuzumab), was conjugated to 3 different chelating agents, 2 of which were derivatives of diethylenetriaminepentaacetic acid (DTPA) and 1 of which was the macrocyclic chelate 1,4,7,10-tetraazacyclododecane-N,N',N",N"'-tetraacetic acid (DOTA). The 3 hLL2 conjugates were radiolabeled with (90)Y and tested for stability in vitro against a 10,000-fold molar excess of free DTPA over 9 d. They were also tested against normal human serum at 37 degrees C over 12 d. Each conjugate was radiolabeled with the gamma-emitting radionuclide, (88)Y, and compared for biodistribution in normal and lymphoma xenograft-bearing athymic mice. In vivo data were analyzed for statistical differences in the uptake of yttrium in bone and washed bone when either the DOTA or the Mx-DTPA chelates were used, and dosimetry calculations were made for each complex.

RESULTS

(90)Y-DOTA complex of the hLL2 mAb was completely stable to either DTPA or serum challenge for the duration of either experiment (equivalent to 3.3-4.5 half-lives of (90)Y radionuclide or >90% of possible (90)Y decays from any initial starting activity). Complexes of hLL2 that had been prepared using the DTPA-type chelates lost 3%-4% of initially bound (90)Y over the first few days and about 10%-15% over the duration of the challenges. In vivo, these stability differences manifested as significantly lower yttrium uptake in bone and cortical bone over a 10-d period when DOTA was used as the yttrium chelating agent. Absorbed doses per 37 MBq (1 mCi) of (90)Y-mAb were 3,555 and 5,405 cGy for bone and 2,664 and 4,524 cGy for washed bone for (90)Y-DOTA-hLL2 and (90)Y-MxDTPA-hLL2, respectively, amounting to 52.0% and 69.8% increases in absorbed radiation doses for bone and washed bone, respectively, when a DOTA chelate was switched to a Mx-DTPA chelate.

CONCLUSION

(90)Y-hLL2 prepared with the DOTA chelate represents an improved agent for radioimmunotherapy of non-Hodgkin's lymphoma, with an in vivo model demonstrating a large reduction in bone-deposited yttrium, compared with (90)Y-hLL2 agents prepared with open-chain DTPA-type chelating agents. Dosimetry suggests that this benefit will result in a substantial toxicologic advantage for a DOTA-based hLL2 conjugate.

Pretargeting for cancer radioimmunotherapy with bispecific antibodies: role of the bispecific antibody's valency for the tumor target antigen

The use of a divalent effector molecule improves bispecific antibody (bsMAb) pretargeting by enabling the cross-linking of monovalently bound bsMAb on the cell surface, thereby increasing the functional affinity of a bsMAb. In this work, it was determined if a bsMAb with divalency for the primary target antigen would improve bsMAb pretargeting of a divalent hapten. The pretargeting of a (99m)Tc-labeled divalent DTPA-peptide, IMP-192, using a bsMAb prepared by chemically coupling two Fab' fragments, one with monovalent specificity to the primary target antigen, carcinoembryonic antigen (CEA), and to indium-loaded DTPA [DTPA(In)], was compared to two other bsMAbs, both with divalency to CEA. One conjugate used the whole anti-CEA IgG, while the other used the anti-CEA F(ab')(2) fragment to make bsMAbs that had divalency to CEA, but with different molecular weights to affect their pharmacokinetic behavior. The rate of bsMAb blood clearance was a function of molecular weight (IgG x Fab' < F(ab')(2) x Fab' < Fab' x Fab' conjugate). The IgG x Fab' bsMAb conjugate had the highest uptake and longest retention in the tumor. However, when used for pretargeting, the F(ab')(2) x Fab' conjugate allowed for superior tumor accretion of the (99m)Tc-IMP-192 peptide, because its more rapid clearance from the blood enabled early intervention with the radiolabeled peptide when tumor uptake of the bsMAb was at its peak. Excellent peptide targeting was also seen with the Fab' x Fab' conjugate, albeit tumor uptake was lower than with the F(ab')(2) x Fab' conjugate. Because the IgG x Fab' bsMAb cleared from the blood so slowly, when the peptide was given at the time of its maximum tumor accretion, the peptide was captured predominantly by the bsMAb in the blood. Several strategies were explored to reduce the IgG x Fab' bsMAb remaining in the blood to take advantage of its 3-4-fold higher tumor accretion than the other bsMAb conjugates. A number of agents were tested, including those that could clear the bsMAb from the blood (e.g., galactosylated or nongalactosylated anti-id antibody) and those that could block the anti-DTPA(In) binding arm [e.g., DTPA(In), divalent-DTPA(In) peptide, and DTPA coupled to bovine serum albumin (BSA) or IgG]. When clearing agents were given 65 h after the IgG x Fab' conjugate (time of maximum tumor accretion for this bsMAb), (99m)Tc-IMP-192 levels in the blood were significantly reduced, but a majority of the peptide localized in the liver. Increasing the interval between the clearing agent and the time the peptide was given to allow for further processing of the bsMAb-clearing agent complex did not improve targeting. At the dose and level of substitution tested, galacosylated BSA-DTPA(In) was cleared too quickly to be an effective blocking agent, but BSA- and IgG-DTPA(In) conjugates were able to reduce the uptake of the (99m)Tc-IMP-192 in the blood and liver. Tumor/nontumor ratios compared favorably for the radiolabeled peptide using the IgG x Fab'/blocking agent combination and the F(ab')(2) x Fab' (no clearing/blocking agent), and peptide uptake 3 h after the blocking agent even exceeded that of the F(ab')(2) x Fab'. However, this higher level of peptide in the tumor was not sustained over 24 h, and actually decreased to levels lower than that seen with the F(ab')(2) x Fab' by this time. These results demonstrate that divalency of a bsMAb to its primary target antigen can lead to higher tumor accretion by a pretargeted divalent peptide, but that the pharmacokinetic behavior of the bsMAb also needs to be optimized to allow for its clearance from the blood. Otherwise, blocking agents will need to be developed to reduce unwanted peptide uptake in normal tissues.

Phase I radioimmunotherapy trial with iodine-131--labeled humanized MN-14 anti-carcinoembryonic antigen monoclonal antibody in patients with metastatic gastrointestinal and colorectal cancer

This trial was conducted to determine the pharmacokinetics, dosimetry, dose-limiting toxicity, and the maximum tolerated dose of iodine-131 humanized MN-14 immunoglobulin G (131I-hMN-14 IgG), a humanized complementary-determining region-grafted anti-carcinoembryonic antigen monoclonal antibody, in metastatic gastrointestinal and colorectal cancer patients. Patients were divided into 2 groups: group A consisted of patients who had prior external beam radiation therapy (n = 8), and group B included patients who had received standard chemotherapy (n = 13). All patients received a diagnostic infusion of 131I-hMN-14 IgG (approximately 8.0 mCi, 15 mg/m2) to study the pharmacokinetics, biodistribution, and dosimetry. One week later, 17 of 21 patients received infusional therapy of escalating radioactive doses of 131I-hMN-14 IgG. Blood pharmacokinetics and quantitative imaging were performed again after the therapeutic dose. Radiation-absorbed doses to normal organs and tumors were determined by MIRDOSE-3 algorithms. The primary dose-limiting toxicity was hematologic toxicity at 40 mCi/m2. The blood half-life (n = 20) was identical for the diagnostic and therapy infusions. The mean red marrow dose was 2.2 +/- 2.4 cGy/mCi. The mean tumor radiation dose (n = 8) was 24.2 +/- 22.6 cGy/mCi. Tumor targeting was seen in most large metastatic lesions. No objective responses were seen in these heavily pretreated and mostly advanced patients. In conclusion, 131I-hMN-14 IgG has good targeting, good tumor to normal organs radiation absorbed ratios, and an acceptable toxicity profile in advanced metastatic gastrointestinal and colorectal cancer patients.

Molecular advances in pretargeting radioimunotherapy with bispecific antibodies

The use of antibodies against tumor-associated cell surface antigens for the targeted delivery of radionuclides was introduced >20 years ago. Although encouraging results have been achieved with radiolabeled antibodies in the management of hematopoietic malignancies, there remains a need for successfully treating solid tumors with this modality. One promising approach involving pretargeted delivery of radionuclides has been shown to be capable of significantly increasing the radioactive uptake in tumor relative to normal organs, thereby potentially improving the efficacy of both detection and therapy of cancer. Uncoupling of the radionuclide from the tumor-targeting antibody allows the relatively slow process of antibody localization and clearance to occur before a very rapid and highly specific delivery of the radioactive payload carried on a small molecule, such as a peptide. This minireview discusses the various strategies and advancements made since the concept of pretargeting was proposed in the mid-1980s, with emphasis on those comprising bispecific antibodies for cancer therapy. Critical aspects of these pretargeting systems for achieving higher tumor:nontumor ratios are considered. In addition, both preclinical and clinical results obtained from a pretargeting method known as the Affinity Enhancement System are presented. Future directions of pretargeting technology are also suggested.

Localization of pancreatic cancer with radiolabeled monoclonal antibody PAM4

Experimental animal studies were performed with (111)In-labeled PAM4 anti-MUC1 antibody along with (111)In-labeled control antibody. Tumor uptake of radiolabeled PAM4 was significantly higher than for the control antibody at all time points. When normalized to a blood dose of 1500 cGy as an estimate of myelotoxicity, (90)Y-labeled PAM4 would provide 5344 cGy to the tumor, whereas an equitoxic dose of (90)Y-labeled control antibody would provide only 862 cGy to the tumor. In addition to the animal studies, five patients with proven pancreatic cancer were administered either (131)I-PAM4 IgG (n=2) or 99mTc-PAM4 Fab' (n=3). Tumor targeting was observed in four out of five patients. By immunohistochemistry, PAM4 was non-reactive with tumor from the one patient not targeted. Dosimetry from the patients given (131)I-PAM4 predicted that tumors would receive 10-20 cGy/mCi with tumor/red marrow dose ratios ranging from 3 to 10. Based upon these results, we have established a phase-I (111)In-labeled PAM4 imaging and (90)Y-labeled PAM4 therapy trial.

Cure of metastatic human colonic cancer in mice with radiolabeled monoclonal antibody fragments

There is currently no method to cure patients with disseminated colorectal cancer, which is the third leading cancer killer in the Western World. This report shows that the GW-39 intrapulmonary micrometastatic human colonic cancer model in nude mice can be cured with radiolabeled antibodies against carcinoembryonic antigen, and that this approach of radioimmunotherapy is superior to conventional chemotherapy with 5-fluorouracil and leucovorin (5-FU/LV). Monovalent Fab fragments labeled with 131I are superior to intact IgG when survival was evaluated 3, 7, and 14 days after implantation, leading to cures in up to 90% of the mice. Histological results provide support for the differences in therapeutic efficacy observed. Microautoradiography was used to evaluate the intratumoral distribution of each form of antibody. The enhanced tumor control by Fab compared with IgG could be explained in part by the homogeneity of radioantibody distribution of Fab. Biodistribution analysis and initial dose rate calculations for all three forms of antibody also help explain the ability of 131I-labeled Fab to provide better tumor growth control than seen with 131I-labeled IgG. Thus, radioimmunotherapy may be a new modality to treat metastatic disease, particularly when using small antibody fragments.