Pretargeted radioimmunotherapy of human colorectal xenografts with bispecific antibody and 131I-labeled bivalent hapten.

We have developed a pretargeting strategy, called the affinity enhancement system (AES), which uses bispecific antibodies to target radiolabeled bivalent haptens to tumor cells. The aim of this study was to evaluate the potential of the AES for the radioimmunotherapy (RIT) of LS174T colorectal xenografts in comparison with RIT with directly labeled F(ab')2 fragment. METHODS: A total of 6 groups of tumor-bearing mice were treated using anticarcinoembryonic antigen (CEA) x anti-diethylenetriamine pentaacetic acid (DTPA)-In bispecific antibody (BsF(ab')2) and 131I-labeled di-DTPA-In bivalent hapten. Three groups of mice were injected with various activities of 131I-labeled bivalent hapten (75, 96, and 112 MBq) 20 h after administration of BsF(ab)'2. Three other groups were injected with an almost constant activity of labeled hapten (102 MBq) at 3 time periods (15, 30, and 48 h) after BsF(ab')2 administration. For conventional RIT, mice were treated with 96 MBq 131-labeled anti-CEA F(ab')2. Control groups were left untreated. Toxicity and tumor growth were monitored at weekly intervals. RESULTS: Doses used for conventional RIT induced severe toxicity and resulted in death of several treated animals. Nevertheless, all surviving animals treated with 131I-labeled anti-CEA F(ab')2 relapsed shortly after treatment (tumor growth delay = 48+/-13 d). For animals treated with the AES reagents, toxicity varied with the pretargeting time interval and the administered activity. For 20-h pretargeting time, the maximum tolerated dose was 96 MBq. For all AES RIT except 1 (with 48-h pretargeting time interval and growth delay of 82+/-26 d), no tumor growth was observed over a period of 8 mo. Furthermore, based on clinical and histologic criteria, 33% of the treated mice were considered cured. CONCLUSION: High cure rates of LS174T colon carcinoma were achieved with the AES, and the flexibility of the pretargeting approach allowed the control of hematologic toxicity, which is the main limitation to dose escalation with conventional RIT.     

Pretargeted radioimmunotherapy of mesothelin-expressing cancer using a tetravalent single-chain Fv-streptavidin fusion protein.

Mesothelin is a glycoprotein that is overexpressed in several human tumors, including mesotheliomas and ovarian cancers, and has been identified as a potential target for therapy. We evaluated the biodistribution and tumor-targeting ability of an antimesothelin tetravalent single-chain Fv-streptavidin fusion protein (SS1scFvSA) in mice. METHODS: SS1scFvSA was labeled with 125I or 111In for evaluation of internalization in vitro and for optimization of its biodistribution. The A431-K5 mesothelin transfected cell line was used as the target. We used a 3-step pretargeting approach consisting of injections of (i) SS1scFvSA, followed 20 h later by (ii) a synthetic clearing agent, and (iii) 4 h later, radiolabeled (111In, 88Y/90Y, or 177Lu) 1,4,7,10-tetraazacyclododecane-N,N',N',N'-tetraacetic acid (DOTA)-biotin. To optimize the tumor uptake, the effect of the specific activity of 111In-DOTA-biotin was evaluated. RESULTS: Approximately 60% of SS1sc FvSA internalized within 6 h. The optimal dose of SS1scFvSA for pretargeting was 600 microg. Decreasing the specific activity of DOTA-biotin by administering 0.1-5 microg of DOTA-biotin resulted in tumor uptake decreasing from 31.8 to 5.5 %ID/g (percentage injected dose per gram) at 2 h. Pretargeted therapy of A431-K5 tumor with 90Y doses of 11.1-32.4 MBq resulted in a dose-dependent tumor response. With 32.4 MBq, 86% of mice survived tumor free for 110 d. All nontreated mice died, with a median survival of 16 d. CONCLUSION: SS1scFvSA localized in the mesothelin-expressing tumor, resulting in a high accumulation of radiolabeled DOTA-biotin. The specific activity of DOTA-biotin had a significant effect on its tumor uptake. Therapeutic tumor doses were obtained without dose-limiting toxicity.     

Patient-specific dosimetry of pretargeted radioimmunotherapy using CC49 fusion protein in patients with gastrointestinal malignancies.

Pretargeted radioimmunotherapy (RIT) using CC49 fusion protein, comprised of CC49-(scFv)4 and streptavidin, in conjunction with 90Y/111In-DOTA-biotin (DOTA = dodecanetetraacetic acid) provides a new opportunity to improve efficacy by increasing the tumor-to-normal tissue dose ratio. To our knowledge, the patient-specific dosimetry of pretargeted 90Y/111In-DOTA-biotin after CC49 fusion protein in patients has not been reported previously. METHODS: Nine patients received 3-step pretargeted RIT: (a) 160 mg/m2 of CC49 fusion protein, (b) synthetic clearing agent (sCA) at 48 or 72 h later, and (c) 90Y/111In-DOTA-biotin 24 h after the sCA administration. Sequential whole-body 111In images were acquired immediately and at 2-144 h after injection of 90Y/111In-DOTA-biotin. Geometric-mean quantification with background and attenuation correction was used for liver and lung dosimetry. Effective point source quantification was used for spleen, kidneys, and tumors. Organ and tumor 90Y doses were calculated based on 111In imaging data and the MIRD formalism using patient-specific organ masses determined from CT images. Patient-specific marrow doses were determined based on radioactivity concentration in the blood. RESULTS: The 90Y/111In-DOTA-biotin had a rapid plasma clearance, which was biphasic with <10% residual at 8 h. Organ masses ranged from 1,263 to 3,855 g for liver, 95 to 1,009 g for spleen, and 309 to 578 g for kidneys. The patient-specific mean 90Y dose (cGy/37 MBq, or rad/mCi) was 0.53 (0.32-0.78) to whole body, 3.75 (0.63-6.89) to liver, 2.32 (0.58-4.46) to spleen, 7.02 (3.36-11.2) to kidneys, 0.30 (0.09-0.44) to lungs, 0.22 (0.12-0.34) to marrow, and 28.9 (4.18-121.6) to tumors. CONCLUSION: Radiation dose to normal organs from circulating radionuclide is substantially reduced using pretargeted RIT. Tumor-to-normal organ dose ratios were increased about 8- to 11-fold compared with reported patient-specific mean dose to liver, spleen, marrow, and tumors from 90Y-CC49.     

Bifunctional phage-based pretargeted imaging of human prostate carcinoma

IntroductionTwo-step and three-step pretargeting systems utilizing biotinylated prostate tumor-homing bacteriophage (phage) and ¹¹¹In-radiolabeled streptavidin or biotin were developed for use in cancer radioimaging. The in vivo selected prostate carcinoma-specific phage (G1) displaying up to five copies of the peptide IAGLATPGWSHWLAL was the focus of the present study.MethodsThe ability of G1 phage to extravasate and target prostate tumor cells was investigated using immunohistochemistry. G1 phages were biotinylated, streptavidin was conjugated to diethylenetriaminepentaacetic acid (DTPA) and biotin was conjugated to 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid (DOTA). Biodistribution studies and single-photon emission computed tomography (SPECT)/CT imaging of xenografted PC-3 tumors via two-step pretargeted ¹¹¹In-labeled streptavidin and three-step pretargeted ¹¹¹In-labeled biotin were performed in SCID mice to determine the optimal pretargeting method.ResultsThe ability of G1 phage to extravasate the vasculature and bind directly to human PC-3 prostate carcinoma tumor cells in vivo was demonstrated via immunocytochemical analysis. Comparative biodistribution studies of the two-step and three-step pretargeting strategies indicated increased PC-3 human prostate carcinoma tumor uptake in SCID mice of 4.34±0.26 %ID g^?1 at 0.5 h postinjection of ¹¹¹In-radiolabeled biotin (utilized in a three-step protocol) compared to 0.67±0.06 %ID g^?1 at 24 h postinjection of ¹¹¹In radiolabeled streptavidin (employed in a two-step protocol). In vivo SPECT/CT imaging of xenografted PC-3 tumors in SCID mice with the three-step pretargeting method was superior to that of the two-step pretargeting method, and, importantly, blocking studies demonstrated specificity of tumor uptake of ¹¹¹In-labeled biotin in the three-step pretargeting scheme.ConclusionThis study demonstrates the use of multivalent bifunctional phage in a three-step pretargeting system for prostate cancer radioimaging.     

Bispecific antibody pretargeting PET (immunoPET) with an 124I-labeled hapten-peptide.

We previously described a highly flexible bispecific antibody (bs-mAb) pretargeting procedure using a multivalent, recombinant anti-CEA (carcinoembryonic antigen) x anti-HSG (histamine-succinyl-glycine) fusion protein with peptides radiolabeled with 111In, 90Y, 177Lu, and 99mTc. The objective of this study was to develop a radioiodination procedure primarily to assess PET imaging with 124I. METHODS: A new peptide, DOTA-D-Tyr-D-Lys(HSG)-D-Glu-D-Lys(HSG)-NH2 (DOTA is 1,4,7,10-tetraazacyclododecane-N,N',N',N'-tetraacetic acid), was synthesized and conditions were established for radioiodination with yields of approximately 70% for 131I and 60% for 124I. Pretargeting with the 131I- and 124I-labeled peptide was tested in nude mice bearing LS174T human colonic tumors that were first given the anti-CEA x anti-HSG bs-mAb. Imaging (including small-animal PET) and necropsy data were collected at several intervals over 24 h. Comparisons were made between animals given 124I-anti-CEA Fab', 18F-FDG, the same peptide radiolabeled with 111In and pretargeted with the bs-mAb, and the radioiodinated peptide alone. RESULTS: The radioiodinated peptide alone cleared quickly from the blood with no evidence of tumor targeting, but when pretargeted with the bs-mAb, tumor uptake increased 70-fold, with efficient and rapid clearance from normal tissues, allowing clear visualization of tumor within 1-2 h. Tumor uptake measured at necropsy was 3- to 15-fold higher and tumor-to-blood ratios were 10- to 20-fold higher than those for 124I-Fab' at 1 and 24 h, respectively. Thyroid and stomach uptake was observed with the radioiodinated peptide several hours after injection (animals were not premedicated to reduce uptake in these tissues), but gastric uptake was much more pronounced with 124I-Fab'. Tumor visualization with 18F-FDG at approximately 1.5 h was also good but showed substantially more uptake in several normal tissues, making image interpretation in the pretargeted animals less ambiguous than with 18F-FDG. CONCLUSION: Bispecific antibody pretargeting has a significant advantage for tumor imaging over directly radiolabeled antibodies and could provide additional enhancements for oncologic imaging, particularly for improving targeting specificity as compared with 18F-FDG.     

Radiation dosimetry for 90Y-2IT-BAD-Lym-1 extrapolated from pharmacokinetics using 111In-2IT-BAD-Lym-1 in patients with non-Hodgkin's lymphoma.

Several monoclonal antibodies, including Lym-1, have proven effective for treatment of hematologic malignancies. Lym-1, which preferentially targets malignant lymphocytes, has induced therapeutic responses and prolonged survival in patients with non-Hodgkin's lymphoma (NHL) when labeled with 131. Because radiometal-labeled monoclonal antibodies provide higher tumor radiation doses than corresponding 131I-labeled monoclonal antibodies, the radiation dosimetry of 90Y-2-iminothiolane-2-[p-(bromoacetamido)benzyl]-1,4,7,10-tetraazacyc lododecane-N,N',N",N"'-tetraacetic acid-Lym-1 (90Y-21T-BAD-Lym-1) is of importance because of its potential for radioimmunotherapy. Although 90Y has attractive properties for therapy, its secondary bremsstrahlung is less suitable for imaging and pharmacokinetic studies in patients. Thus, the pharmacokinetic data obtained for 111In-21T-BAD-Lym-1 in patients with NHL were used to calculate dosimetry for 90SY-21T-BAD-Lym-1. METHODS: Thirteen patients with advanced-stage NHLwere given a preload dose of unmodified Lym-1 followed by an imaging dose of 111In-21T-BAD-Lym-1. Sequential imaging and blood and urine samples obtained for up to 10 d after infusion were used to assess pharmacokinetics. Using 111In pharmacokinetic data and 90Y physical constants, radiation dosimetry for 90Y-21T-BAD-Lym-1 was determined. RESULTS: The uptake of 111In-21T-BAD-Lym-1 in tumors was greater than uptakes in the lung and kidney but similar to uptakes in the liver and spleen. The biologic half-time in tumors was greater than in lungs. The mean radiation dose to tumors was 6.57 +/- 3.18 Gy/GBq. The mean tumor-to-marrow (from blood) radiation ratio was 66:1, tumor-to-total body was 13:1, and tumor-to-liver was 1:1. Images of 111In were of excellent quality; tumors and normal organs were readily identified. Mild and transient Lym-1 toxicity occurred in 3 patients. CONCLUSION: Because of the long residence time of 111In-2IT-BAD-Lym-1 in tumors, high 90Y therapeutic ratios (tumor-to-tissue radiation dose) were achieved for some tissues, but the liver also showed high uptake and retention of the radiometal.     

Single-chain Fv-streptavidin substantially improved therapeutic index in multistep targeting directed at disialoganglioside GD2.

Multistep targeting can improve the therapeutic index of antibody-based targeting, particularly relevant to pediatric tumors where acute toxicity and late effects of treatment are major concerns. Neuroblastoma is uniquely suited for such investigations because of its abundance of surface ganglioside GD2. METHODS: 5F11scFv (scFv = single-chain variable fragment) was constructed from the variable regions of the heavy (V(H)) and kappa-light (V(L)) chain complementary DNA (cDNA) of anti-GD2 IgM hybridoma 5F11 and ligated to full-length streptavidin cDNA for expression in Escherichia coli. Purified 5F11-scFv-streptavidin (5F11-scFv-SA) was a homotetramer and showed comparable avidity to 5F11 IgM and a 30-fold improvement over monomeric scFv. Biodistribution of 5F11-scFv-SA was studied in nude mice xenografted with neuroblastoma LAN-1. Twenty-four hours after intravenous injection of 300-900 microg 5F11-scFv-SA, 150-450 microg of a thiogalactoside-containing clearing agent, (Gal-NAc)(16)-alpha-S-C(5)H(10)-NH-LC-N-Me-biotin (molecular weight, 8652), were administered intravenously, followed by approximately 2.5 microg (1.85-3.7 MBq) (111)In-1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid-biotin ((111)In-DOTA-biotin) intravenously 4 h later and clocked as time 0. RESULTS: Tumor uptake (percentage of injected dose per gram [%ID/g]) at 2 h was 7 %ID/g and decayed with a half-life of 72 h, whereas blood %ID/g rapidly decreased to <1/500 of that of tumor after the first 24 h. The tumor-to-nontumor (T/NT) ratio at 72 h was high (median, 106; range, 3.4 [kidney] to 1660 [blood]). When the area under the radioactivity curve was computed, the T/NT organ ratio was favorable (4.8 for kidney and 162 for blood). When human and murine tumors were surveyed, the T/NT ratio of (111)In-DOTA-biotin uptake correlated with their levels of GD2 expression as assayed by flow cytometry. Biotinylated polypeptides (bovine serum albumin and vasointestinal peptides) achieved selective tumor targeting when the multistep strategy was applied. CONCLUSION: Improvement in the T/NT ratio using pretargeting strategy may increase the efficacy and safety of scFv-based approaches in cancer therapy. Additionally, since biotinylated polypeptides can be rendered tumor selective, a large repertoire of agents can potentially be explored.     

Pharmacokinetics and biodistribution of 111In- and 177Lu-labeled J591 antibody specific for prostate-specific membrane antigen: prediction of 90Y-J591 radiation dosimetry based on 111In or 177Lu?

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: 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.     

Pretargeting with bispecific anti-renal cell carcinoma x anti-DTPA(In) antibody in 3 RCC models.

We have developed an efficient pretargeting strategy for renal cell carcinoma (RCC) based on a biologically produced bispecific monoclonal antibody (bs-mAb). Tumor targeting with this 2-step pretargeting strategy in the NU-12 mouse RCC model was very efficient compared with other pretargeting strategies, possibly due to unique characteristics of the NU-12 tumor used in our studies. Here we describe the bs-mAb G250xDTIn-1 pretargeting strategy in 3 different RCC nude mouse models. METHODS: Three different human RCC xenografts in nude mice (NU-12, SK-RC-1, and SK-RC-52 tumors) were pretargeted with 100 pmol bs-mAb G250xDTIn-1. Three days after administration of the bs-mAb, mice were injected intravenously with 4 pmol 111In-labeled bivalent peptide, diDTPA-FKYK (DTPA is diethylenetriaminepentaacetic acid). At 1, 4, 24, 48, and 72 h after injection of the radiolabeled peptide, the biodistribution of the radiolabel was determined. The 3 RCC tumors were characterized in vivo and in vitro for G250 antigen expression, vessel density, vascular volume, and vascular permeability and by targeting with 111In-/125I-labeled cG250 mAb. RESULTS: Using the pretargeting strategy, relatively high uptake of the radiolabel was observed in all 3 tumor models (maximum uptake: SK-RC-1 [278 +/- 130 %ID/g (percentage injected dose per gram), 1 h after injection] > NU-12 [93 +/- 41 %ID/g, 72 h after injection] > SK-RC-52 [54 +/- 9 %ID/g, 4 h after injection]). Remarkably, uptake of the radiolabel in the tumor did not correlate with G250 antigen expression. The kinetics of the radiolabel in the tumor varied largely in the 3 RCC tumors: SK-RC-1 and SK-RC-52 tumors showed a washout of the 111In label from the tumor with time: only 30% of the radiolabel was retained in the tumor 3 d after injection, whereas the 111In label was fully retained in NU-12 tumors. Physiologic characteristics (vessel density, vascular volume, and vascular permeability) of the tumors may explain these differences. CONCLUSION: G250 antigen-expressing tumors can be pretargeted very efficiently with the bs-mAb G250xDTIn-1. There was no correlation between G250 antigen expression and uptake of the radiolabel in the tumor using the pretargeting strategy or with directly labeled mAbs. Therefore, these studies show that physiologic characteristics of the tumor, such as vascular permeability, play a significant role in pretargeting.     

Metabolite production in patients with lymphoma after radiometal-labeled antibody administration.

Radiometal-labeled monoclonal antibodies are retained longer in tumors than iodinated antibodies, leading to their increased use for radioimmunotherapy. Dissociation of radioiodine from the antibody during metabolism has been documented. We now report metabolites in the plasma of lymphoma patients given 111In- and 90Y-2-iminothiolane-2-[p-(bromoacetamido)benzyl]-1,4,7,10-tetraazacyclododecane-N,N',N",N"'-tetraacetic acid-Lym-1 (111In/90Y-2IT-BAD-Lym-1). METHODS: Nineteen patients with non-Hodgkin's lymphoma (NHL) received 111In- and 90Y-2IT-BAD-Lym-1; 111In was used as a surrogate tracer for 90Y, which emits no gamma-photon. Plasma was obtained up to 7 d and analyzed by high-performance liquid chromatography to determine the fraction of radiolabel associated with monomeric antibody, metabolites, and complexed antibody. Planar images of conjugate views were acquired up to 7 d and used to quantitate 111In in organs and tumors. RESULTS: Metabolites and complexes were observed in the plasma of every patient who received 111In-2IT-BAD-Lym-1. At 3 d, the mean percentages of 111In in the patients' plasma in monomeric, metabolite, and complexed forms were 54%, 36%, and 10%, respectively. Metabolites of 90Y-2IT-BAD-Lym-1 were formed to a similar extent. In comparison, in groups of breast and prostate cancer patients who received the radioimmunoconjugate 111In-2IT-BAD-m170, 91% and 94% of 111In in the patients' plasma were in monomeric form, respectively. Metabolites and complexes of 111In-2IT-BAD-Lym-1 contributed a mean 10% of the total area under the time-activity curve (AUC) for blood. Little formation of metabolites and complexes occurred in vitro in NHL patient or volunteer plasma or in Raji cell culture. The clinical and in vitro data supported the processing of 111In/90Y-2IT-BAD-Lym-1 in the hepatocytes as the dominant mechanism for the production of metabolites. CONCLUSION: Metabolites of 111In/90Y-2IT-BAD-Lym-1 accounted for 10% of blood AUC in patients. The therapeutic index was adversely affected by metabolism of 111In/90Y-2IT-BAD-Lym-1 to the extent that the tumor specificity of the radioactive metabolites was lost.     

Three-step radioimmunotherapy with yttrium-90 biotin: dosimetry and pharmacokinetics in cancer patients

. A three-step avidin-biotin approach has been applied as a pretargeting system in radioimmunotherapy (RIT) as an alternative to conventional RIT with directly labelled monoclonal antibodies (MoAbs). Although dosimetric and toxicity studies following conventional RIT have been reported, these aspects have not previously been evaluated in a three-step RIT protocol. This report presents the results of pharmacokinetic and dosimetric studies performed in 24 patients with different tumours. Special consideration was given to the dose delivered to the red marrow and to the haematological toxicity. The possible additive dose to red marrow due to the release of unbound yttrium-90 was investigated. The protocol consisted in the injection of biotinylated MoAbs (first step) followed 1 day later by the combined administration of avidin and streptavidin (second step). After 24 h, biotin radiolabelled with 1.85–2.97 GBq/m² of ⁹⁰Y was injected (third step). Two different chelating agents, DTPA and DOTA, coupled to biotin, were used in these studies. Indium-111 biotin was used as a tracer of ⁹⁰Y to follow the biodistribution during therapy. Serial blood samples and complete urine collection were obtained over 3 days. Whole-body and single-photon emission tomography images were acquired at 1, 16, 24 and 40 h after injection. The sequence of images was used to extrapolate ⁹⁰Y-biotin time-activity curves. Numerical fitting and compartmental modelling were used to calculate the residence time values (τ) for critical organs and tumour, and results were compared; the absorbed doses were estimated using the MIRDOSE3.1 software. The residence times obtained by the numerical and compartmental models showed no relevant differences (<10%); the compartmental model seemed to be more appropriate, giving a more accurate representation of the exchange between organs. The mean value for the τ in blood was 2.0±1.1 h; the mean urinary excretion in the first 24 h was 82.5%±10.8%. Without considering any contribution of free ⁹⁰Y, kidneys, liver, bladder and red marrow mean absorbed doses were 1.62±1.14, 0.27±0.23, 3.61±0.70 and 0.11±0.05 mGy/MBq, respectively; the effective dose was 0.32±0.06 mSv/MBq, while the dose to the tumour ranged from 0.62 to 15.05 mGy/MBq. The amount of free ⁹⁰Y released after the injection proved to be negligible in the case of ⁹⁰Y-DOTA-biotin, but noteworthy in the case of ⁹⁰Y-DTPA-biotin (mean value: 5.6%±2.5% of injected dose), giving an additive dose to red marrow of 0.18±0.08 mGy per MBq of injected ⁹⁰Y-DTPA-biotin. Small fractions of free ⁹⁰Y originating from incomplete radiolabelling can contribute significantly to the red marrow dose (3.26 mGy per MBq of free ⁹⁰Y) and may explain some of the high levels of haematological toxicity observed. These results indicate that pretargeted three-step RIT allows the administraton of high ⁹⁰Y activities capable of delivering a high dose to the tumour and sparing red marrow and other normal organs. Although ⁹⁰Y-biotin clears rapidly from circulation, the use of DOTA-biotin conjugate for a stable chelation of ⁹⁰Y is strongly recommended, considering that small amounts of free ⁹⁰Y contribute significantly in increasing the red marrow dose. Received 6 June and in revised form 19 September 1998     

Therapeutic advantages of Auger electron- over beta-emitting radiometals or radioiodine when conjugated to internalizing antibodies

Recent studies suggest a higher anti-tumour efficacy of internalizing monoclonal antibodies (MAbs) when labelled with Auger electron emitters, as compared with beta-emitters. The aim of this study was to compare the anti-tumour efficacy and toxicity of the internalizing MAb, CO17-1A, labelled with Auger electron emitters (125I, (111)In) versus conventional beta(-)-emitters (131I, 90Y) in a colon cancer model, and to assess whether the residualizing radiometals may have therapeutic advantages over the conventionally iodinated conjugates. Biodistribution studies of 125I-, (111)In- or 88Y-labelled CO17-1A were performed in nude mice bearing subcutaneous human colon cancer xenografts. For therapy, the mice were injected with either unlabelled or 125I-, 131I-, (111)In- or 90Y-labelled CO17-1A IgG2a, whereas control groups were left untreated or were given a radiolabelled isotype-matched irrelevant antibody. The influence of internalization was assessed by comparing the results with those obtained with an anti-carcinoembryonic antigen (CEA) antibody which does not internalize to a relevant extent. The maximum tolerated activities (MTA) and doses (MTD) of each agent were determined. Myelotoxicity and potential second-organ toxicities, as well as tumour growth, were monitored. Bone marrow transplantation (BMT) was performed in order to enable dose intensification. Radiometals showed significantly better tumour-to-blood ratios than the respective iodinated conjugates. The MTAs of 131I- and 125I-CO17-1A without artificial support were 11.1 MBq (300 microCi) and 111 MBq (3 mCi), respectively; the MTA of the metals was reached at 4 MBq (100 microCi) for 90Y-, and at 85 MBq (2.3 mCi) for (111)In-CO17-1A. Myelotoxicity was dose limiting in all cases. BMT enabled an increase in the MTA to 15 MBq (400 microCi) of 131I-labelled CO17-1A, to 4.4 MBq (120 microCi) of 90Y-labelled CO17-1A, and to 118 MBq (3.2 mCi) of (111)In-labelled CO17-1A, while the MTA of 125I-CO17-1A had not been reached at 185 MBq (5 mCi) with BMT. Whereas no significant therapeutic effects were seen with unlabelled CO17-1A, tumour growth was retarded significantly with its radiolabelled forms. The therapeutic results were significantly (P<0.01) better with both Auger electron emitters (125I and (111)In) than with the beta-emitters, and, in accordance with the biodistribution data, a trend towards better therapeutic results was found with radiometals (more complete remissions) as compared with radioiodine. In contrast, at equitoxic doses, no significant difference was observed in the therapeutic efficacy of 131I- versus 125I-labelled non-internalizing anti-CEA antibody, F023C5. These data suggest that, at equitoxic doses, the therapeutic efficacy of internalizing MAbs labelled with Auger electron emitters, such as 125I or (111)In, is superior to that of internalizing MAbs labelled with conventional beta-emitters. The lower toxicity of Auger electron emitters may be due to the short path length of their low-energy electrons, which can reach the nuclear DNA only if the antibody is internalized (as is the case in antigen-expressing tumour tissue, but not in the stem cells of the red marrow).     

Therapeutic advantages of Auger electron- over β-emitting radiometals or radioiodine when conjugated to internalizing antibodies

Recent studies suggest a higher anti-tumour efficacy of internalizing monoclonal antibodies (MAbs) when labelled with Auger electron emitters, as compared with β-emitters. The aim of this study was to compare the anti-tumour efficacy and toxicity of the internalizing MAb, CO17-1A, labelled with Auger electron emitters (¹²⁵I, ¹¹¹In) versus conventional β^–-emitters (¹³¹I, ⁹⁰Y) in a colon cancer model, and to assess whether the residualizing radiometals may have therapeutic advantages over the conventionally iodinated conjugates. Biodistribution studies of ¹²⁵I-, ¹¹¹In- or ⁸⁸Y-labelled CO17-1A were performed in nude mice bearing subcutaneous human colon cancer xenografts. For therapy, the mice were injected with either unlabelled or ¹²⁵I-, ¹³¹I-, ¹¹¹In- or ⁹⁰Y-labelled CO17-1A IgG_2a, whereas control groups were left untreated or were given a radiolabelled isotype-matched irrelevant antibody. The influence of internalization was assessed by comparing the results with those obtained with an anti-carcinoembryonic antigen (CEA) antibody which does not internalize to a relevant extent. The maximum tolerated activities (MTA) and doses (MTD) of each agent were determined. Myelotoxicity and potential second-organ toxicities, as well as tumour growth, were monitored. Bone marrow transplantation (BMT) was performed in order to enable dose intensification. Radiometals showed significantly better tumour-to-blood ratios than the respective iodinated conjugates. The MTAs of ¹³¹I- and ¹²⁵I-CO17-1A without artificial support were 11.1 MBq (300 μCi) and 111 MBq (3 mCi), respectively; the MTA of the metals was reached at 4 MBq (100 μCi) for ⁹⁰Y-, and at 85 MBq (2.3 mCi) for ¹¹¹In-CO17-1A. Myelotoxicity was dose limiting in all cases. BMT enabled an increase in the MTA to 15 MBq (400 μCi) of ¹³¹I-labelled CO17-1A, to 4.4 MBq (120 μCi) of ⁹⁰Y-labelled CO17-1A, and to 118 MBq (3.2 mCi) of ¹¹¹In-labelled CO17-1A, while the MTA of ¹²⁵I-CO17-1A had not been reached at 185 MBq (5 mCi) with BMT. Whereas no significant therapeutic effects were seen with unlabelled CO17-1A, tumour growth was retarded significantly with its radiolabelled forms. The therapeutic results were significantly (P<0.01) better with both Auger electron emitters (¹²⁵I and ¹¹¹In) than with the β-emitters, and, in accordance with the biodistribution data, a trend towards better therapeutic results was found with radiometals (more complete remissions) as compared with radioiodine. In contrast, at equitoxic doses, no significant difference was observed in the therapeutic efficacy of ¹³¹I- versus ¹²⁵I-labelled non-internalizing anti-CEA antibody, F023C5. These data suggest that, at equitoxic doses, the therapeutic efficacy of internalizing MAbs labelled with Auger electron emitters, such as ¹²⁵I or ¹¹¹In, is superior to that of internalizing MAbs labelled with conventional β-emitters. The lower toxicity of Auger electron emitters may be due to the short path length of their low-energy electrons, which can reach the nuclear DNA only if the antibody is internalized (as is the case in antigen-expressing tumour tissue, but not in the stem cells of the red marrow). Received 1 October 1999 and in revised form 15 March 2000     

CaNa2EDTA for improvement of radioimmunodetection and radioimmunotherapy with 111In and 90Y-DTPA-anti-CEA MAbs in nude mice bearing human colorectal cancer.

111In and 90Y, dissociated from 111In-labeled-monoclonal antibody (MAb) and 90Y-labeled MAb, may cause deterioration of the image quality in radioimmunodetection (RID) and undesirable irradiation of nontargeted tissue in radioimmunotherapy (RIT), respectively. The aim of this study was to investigate any improvement in RID and RIT with 111In-MAb and 90Y-MAb by pre- and postadministration of calcium disodium ethylenetriaminetetraacetic acid (CaNa2EDTA). METHODS: Murine MAb F33-104 against carcinoembryonic antigen (CEA) was labeled with 111In or 90Y by the diethylenetriamine pentaacetic (DTPA)-anhydride method. The influence of CaNa2EDTA on loss of radioactivity from 111In-MAb or 90Y-MAb in serum was investigated in vitro. The effects of CaNa2EDTA, administered before and after 111In-MAb or 90Y-MAb, on the biodistribution of radioactive isotopes in nude mice bearing human colon adenocarcinoma LS 180 tumor expressing CEA, or human pulmonary carcinoma PC 9 tumor expressing no CEA, were then examined. As a control, 0.9% NaCl was used in both the in vitro and in vivo studies. RESULTS: CaNa2EDTA did not cause any decrease in levels of radioactivity of radiolabeled MAbs. Pre- and post-treatment with CaNa2EDTA reduced radioctivity in both specific and nonspecific tumors at 72 h after 111In-MAb injection resulting in an increase of the specific tumor-to-nonspecific tumor radioactivity ratio. The levels of hepatic and renal radioactivity were also subsequently decreased by CaNa2EDTA. On the other hand, CaNa2EDTA pre- and post-treatment reduced levels of bony, hepatic, and renal radioactivity at 24, 72, and 72 h, respectively, after 90Y-MAb injection, although it had no effect on tumor radioactivity. CONCLUSION: Pre- and post-treatment with CaNa2EDTA would be of great use in humans who undergo RID or RIT with 111In-MAb and 90Y-MAb accompanied by disassociation of the labeled radionuclides.     

Pretargeted radioimmunotherapy of cancer: progress step by step.

To enhance the therapeutic efficacy of radioimmunotherapy of cancer, several pretargeting strategies have been developed. In pretargeted radioimmunotherapy, the tumor is pretargeted with an antibody construct that has affinity for the tumor-associated antigen on the one hand and for a radiolabeled hapten on the other. The radiolabeled hapten is administered in a later phase, preferably after the antibody construct has cleared from the circulation. In pretargeted radioimmunotherapy, 2 main approaches can be distinguished: pretargeting strategies based on the avid interaction between streptavidin (SA) or avidin and biotin, and pretargeting strategies based on the use of bispecific antibodies. In pretargeting strategies based on biotin and SA or avidin, the use of a clearing agent that could remove the pretargeting construct from the circulation markedly improved the targeting of the radiolabeled biotin to the tumor. Thus, multistep injection schemes in which 3-5 different agents are subsequently injected were developed. In bispecific antibody-based pretargeting strategies, the use of bivalent haptens improved the efficacy of the tumor targeting, and a 2-step pretargeted radioimmunotherapy strategy is now being tested in cancer patients. Preclinical studies as well as studies on cancer patients have shown that these pretargeting strategies can result in higher radiation doses to the tumor than can directly radiolabeled antitumor antibodies. Here, the development and state of the art of the most effective approaches for pretargeted radioimmunotherapy are reviewed.     

Pretargeted immuno-PET and radioimmunotherapy of prostate cancer with an anti-TROP-2 x anti-HSG bispecific antibody

Purpose

TF12 is a trivalent bispecific antibody that consists of two anti-TROP-2 Fab fragments and one anti-histamine-succinyl-glycine (HSG) Fab fragment. The TROP-2 antigen is found in many epithelial cancers, including prostate cancer (PC), and therefore this bispecific antibody could be suitable for pretargeting in this cancer. In this study, the characteristics and the potential for pretargeted radioimmunoimaging and radioimmunotherapy with TF12 and the radiolabeled di-HSG peptide IMP288 in mice with human PC were investigated.

Methods

The optimal TF12 protein dose, IMP288 peptide dose, and dose interval for PC targeting were assessed in nude mice with s.c. PC3 xenografts. Immuno-positron emission tomography (PET)/CT was performed using TF12/⁶⁸Ga-IMP288 at optimized conditions. The potential of pretargeted radioimmunotherapy (PRIT) using the TF12 pretargeted ¹⁷⁷Lu-IMP288 was determined.

Results

TF12 and ¹¹¹In-IMP288 showed high and fast accumulation in the tumor [20.4?±?0.6 %ID/g at 1 h post-injection (p.i.)] at optimized conditions, despite the internalizing properties of TF12. The potential for PRIT was shown by retention of 50 % of the ¹¹¹In-IMP288 in the tumor at 48 h p.i. One cycle of treatment with TF12 and ¹⁷⁷Lu-IMP288 showed significant improvement of survival compared to treatment with ¹⁷⁷Lu-IMP288 alone (90 vs. 67 days, p?<?0.0001) with no renal or hematological toxicity.

Conclusion

TROP-2-expressing PC can be pretargeted efficiently with TF12, with very rapid uptake of the radiolabeled hapten-peptide, IMP288, sensitive immuno-PET, and effective therapy.     

In vivo evaluation of pretargeted 64Cu for tumor imaging and therapy.

Pretargeting involves administration of a tumor-targeting monoclonal antibody (mAb) covalently linked to a molecule having a high-affinity binding site for a rapidly distributed radiolabeled effector molecule. The aim of this study was to compare pretargeting to a conventionally labeled antibody for tumor targeting of the intermediate-lived radionuclide (64)Cu, which has shown promise for PET imaging and radioimmunotherapy of cancer. METHODS: DOTA-biotin (where DOTA is 1,4,7,10-tetraazacyclododecane-N,N',N",N"'-tetraacetic acid) and the intact immunoconjugate DOTA-NR-LU-10 were labeled to high specific activities with (64)Cu, and the serum stabilities and target binding capabilities of each agent were assayed in vitro. Nude mice bearing SW1222 human colorectal carcinoma xenografts were administered (64)Cu-DOTA-biotin, with and without pretreatment with the mAb-streptavidin conjugate NR-LU-10/SA and the synthetic clearing agent Biotin-GalNAc(16), or injected with (64)Cu-DOTA-NR-LU-10. Biodistributions of both agents were obtained from 5 min to 48 h after injection. RESULTS: Both (64)Cu-DOTA-biotin and (64)Cu-DOTA-NR-LU-10 were 100% stable in serum in vitro. (64)Cu-DOTA-biotin exhibited >98% specific binding to immobilized streptavidin, whereas the immunoreactivity of (64)Cu-DOTA-NR-LU-10 averaged nearly 80%. Biodistributions in SW1222-bearing mice showed that NR-LU-10/SA-pretargeted (64)Cu-DOTA-biotin attained a peak tumor uptake of 18.9 percentage injected dose per gram (%ID/g) at 1 h, with concomitant rapid disappearance from blood and renal excretion. In the absence of pretargeting, (64)Cu-DOTA-biotin had very similar biodistribution and clearance properties, except with extremely low nonspecific tumor uptake. In contrast, (64)Cu-DOTA-NR-LU-10 reached 80.3 %ID/g in tumor tissue, after 48 h, whereas blood clearance was considerably slower than pretargeted (64)Cu-DOTA-biotin. Comparison of the time-activity curves for tumor uptake and blood clearance of pretargeted (64)Cu and the (64)Cu-labeled antibody revealed that the maximum tumor accumulations of radioactivity were similar for each agent, 17.9 percentage injected activity per gram (%IA/g) and 20.7 %IA/g, respectively. However, the tumor-to-blood ratio of areas under the curves was 14 times higher for pretargeted (64)Cu-DOTA-biotin because of the substantial increase in blood clearance of the small effector molecule. CONCLUSION: The extremely rapid tumor uptake and blood clearance of pretargeted (64)Cu-DOTA-biotin should afford markedly superior PET imaging contrast and therapeutic efficacy, compared with conventionally labeled (64)Cu-DOTA-NR-LU-10. Further comparison of the therapeutic efficacy, toxicity, and dosimetry of these 2 agents is warranted.     

Melanoma imaging using 111In-, 86Y- and 68Ga-labeled CHX-A″-Re(Arg11)CCMSH

IntroductionA novel alpha-melanocyte-stimulating hormone peptide analog CHX-A″-Re(Arg¹¹)CCMSH, which targeted the melanocortin-1 receptor (MC1-R) overexpressed on melanoma cells, was investigated for its biodistribution and tumor imaging properties.MethodsThe metal bifunctional chelator CHX-A″ was conjugated to the melanoma targeting peptide (Arg¹¹)CCMSH and cyclized by Re incorporation to yield CHX-A″-Re(Arg¹¹)CCMSH. CHX-A″-Re(Arg¹¹)CCMSH was labeled with ¹¹¹In, ⁸⁶Y and ⁶⁸Ga, and the radiolabeled peptides were examined in B16/F1 melanoma-bearing mice for their pharmacokinetic as well as their tumor targeting properties using small animal SPECT and PET.ResultsThe radiolabeling efficiencies of the ¹¹¹In-, ⁸⁶Y- and ⁶⁸Ga-labeled CHX-A″-Re(Arg¹¹)CCMSH peptides were >95%, resulting in specific activities of 4.44, 3.7 and 1.85 MBq/μg, respectively. Tumor uptake of the ¹¹¹In-, ⁸⁶Y- and ⁶⁸Ga-labeled peptides was rapid with 4.17±0.94, 4.68±1.02 and 2.68±0.69 %ID/g present in the tumors 2 h postinjection, respectively. Disappearance of radioactivity from the normal organs and tissues was rapid with the exception of the kidneys. Melanoma tumors were imaged with all three radiolabeled peptides 2 h postinjection. MC1-R-specific uptake was confirmed by competitive receptor blocking studies.ConclusionsMelanoma tumor uptake and imaging was exhibited by the ¹¹¹In-, ⁸⁶Y- and ⁶⁸Ga-labeled Re(Arg¹¹)CCMSH peptides, although the tumor uptake was moderated by low specific activity. The facile radiolabeling properties of CHX-A″-Re(Arg¹¹)CCMSH allow it to be employed as a melanoma imaging agent with little or no purification after ¹¹¹In, ⁸⁶Y and ⁶⁸Ga labeling.     

Residualizing iodine markedly improved tumor targeting using bispecific antibody-based pretargeting.

Previous studies have shown that pretargeting allows rapid visualization of renal cell carcinomas (RCC) with an (111)In-labeled bivalent peptide. For radioimmunotherapy, a beta-emitting radionuclide labeled to a bivalent peptide is required. Therapeutic efficacy of these radionuclides depends on the E(max), physical half-life, and residence time of the radiolabel in the tumor. The (131)I radiolabel generally clears rapidly from the tumor after internalization and subsequent degradation of the bivalent l-amino acid peptide (l-a.a. peptide) in the tumor cells. To improve the residence time of the iodine label in the tumor, a new bivalent peptide was synthesized that is peptidase resistant and consists of 4 d-amino acids (d-a.a. peptide). Here we investigated the characteristics of the residualizing iodine label in SK-RC-52 RCC tumors. METHODS: The d-a.a. peptide was manually synthesized according to standard solid-phase Fmoc/HBTU (2-[1H-benzotriazole-1-yl]-1,1,3,3-tetramethyluronium hexafluorophosphate) chemistry. The uptake and retention in the tumor of (111)In-/(125)I-labeled bivalent peptides (l-a.a. peptide and d-a.a. peptide) were studied in female BALB/c athymic mice with subcutaneous SK-RC-52 RCC tumors. Tumors were pretargeted with the bispecific monoclonal antibody (bs-mAb) G250xDTIn-1 and, 72 h later, mice were injected intravenously with one of both radiolabeled peptides. The effect of bs-mAb-diDTPA-bs-mAb (DTPA is diethylenetriaminepentaacetic acid) bridging at the tumor cell surface on the internalization of the bs-mAb-diDTPA complex was investigated in SK-RC-52 tumor-bearing mice. RESULTS: The maximum uptake and retention of (125)I-labeled l-a.a. peptide in the tumor were significantly lower compared with that of the (111)In-labeled l-a.a. peptide. In contrast, the tumor uptake and retention of the (125)I-labeled d-a.a. peptide) were similar to that of the (111)In-labeled l-a.a. peptide but were superior at later time points. The biodistribution of the radioiodinated d-a.a. peptide was highly similar to that of the (111)In-labeled d-a.a. peptide, and both radiolabeled peptides were retained significantly better in the tumor than the (111)In-labeled l-a.a. peptide. bs-mAb-diDTPA-bs-mAb bridge formation did not affect internalization of the bs-mAb-diDTPA complex. CONCLUSION: Uptake and retention in the tumor of the iodinated peptide after pretargeting with a bs-mAb can be significantly improved using d-a.a. peptides. Accordingly, the radiation dose to the tumor, correlating with the therapeutic efficacy of pretargeted RCC, can be enhanced substantially.     

Clinical optimization of pretargeted radioimmunotherapy with antibody-streptavidin conjugate and 90Y-DOTA-biotin.

Pretargeted radioimmunotherapy (PRIT) was evaluated using an antibody-streptavidin conjugate, followed by a biotin-galactose-human serum albumin clearing agent and 90Y-dodecane tetraacetic acid (DOTA)-biotin as the final step for therapy. The objective was to develop a clinical protocol that could show an improved tumor-to-red marrow therapeutic ratio compared with conventional radioimmunotherapy (RIT) and at the same time preserve the efficiency of tumor targeting. METHOD: Forty-three patients with adenocarcinomas reactive to NR-LU-10 murine monoclonal antibody received the 3 components. Doses and timing parameters were varied to develop an optimized schema. In some patients, the conjugate was radiolabeled with 186Re as an imaging tracer to assess biodistribution of the conjugate and effectiveness of the clearing agent. 111In-DOTA-biotin was coinjected with 90Y-DOTA-biotin for quantitative imaging. Safety, biodistribution, pharmacokinetics, dosimetry, and antiglobulin formation were evaluated. RESULTS: The optimal schema was defined as a conjugate dose of 125 microg/mL plasma volume followed at 48 h by a clearing agent in a 10:1 molar ratio of clearing agent to serum conjugate. The therapeutic third step was 0.5 mg radiobiotin administered 24 h later. No significant adverse events were observed after administration of any of the components. The mean tumor-to-marrow absorbed dose ratio when using the optimized PRIT schema was 63:1, compared with a 6:1 ratio reported previously for conventional RIT. Antiglobulin to murine antibody and to streptavidin developed in most patients. CONCLUSION: This initial study confirmed that the PRIT approach is safe and feasible and achieved a higher therapeutic ratio than that achieved with conventional RIT using the same antibody.