Hepatic arterial iodine-131-labeled metuximab injection combined with chemoembolization for unresectable hepatocellular carcinoma: interim safety and survival data from 110 patients

Few options are available to treat patients with hepatocellular carcinoma (HCC). It was tested whether the combination of iodine-131(131I)-metuximab with chemoembolization could improve outcomes in patients with intermediate HCC. Between April 2008 and April 2009, 110 patients with unresectable HCC were treated with 113 intra-arterial 131I-metuximab injections combined with chemoembolization (mean, 1.03 per patient; median, 1; range, 1-2), followed by 264 sessions of transcatheter arterial chemoembolization (mean, 2.4 per patient; median, 3; range, 1-6). The survival rates at 6, 12, and 18 months were 88.2%, 79.1%, and 57.4%, respectively, by the Kaplan-Meier method. Of these patients, 12% exhibited grade 3/4 bilirubin toxicity, 5% exhibited grade 3/4 white blood count toxicity, and 7% exhibited grade 3/4 platelet toxicity. Response rates based on World Health Organization and European Association for the Study of the Liver criteria were 42.73% and 61.82%, respectively. The combination of 131I-metuximab and chemoembolization appeared to extend survival in patients with unresectable HCC compared with historical controls, as well as being well tolerated by patients with Child-Pugh A and B. This combination may represent a promising treatment modality for patients with intermediate HCC.     

Intra-arterial injection of iodine-131-labeled lipiodol for treatment of hepatocellular carcinoma.

BACKGROUND/AIM: The therapeutic effect of intra-arterial injection of 131-iodine-labeled lipiodol for treatment of hepatocellular carcinoma in palliative or adjuvant settings has been promising. We report, the results of an open study of this therapy in cirrhotic patients with small hepatocellular carcinoma. PATIENTS AND METHOD: Forty patients with hepatocellular carcinoma were given intra-arterial injections of 131-iodine-labeled lipiodol. These injections were repeated if necessary every 3 months. Tumor response (WHO criteria) was determined on CT scans performed after each treatment and every 3 months during the follow-up. Side effects and the cause of death were recorded. Therapeutic response and survival were analyzed. RESULTS: The median number of treatment was 2 (1-4). There was one complete response, 18 partial responses (47.5% response rate); 19 had stable disease and 2 progressions. Overall survival rates (+/-CI 95%) at 1, 2 and 3 years were: 90+/-4.7%, 60.3+/-8%, and 39+/-8.3%, respectively. Median survival was 27 months; 25 patients have died (4-56 months), 8 of tumor progression with a multifocal spread in the liver. Tolerance was good except for 2 patients who develop a fatal drug-related pulmonary insufficiency. CONCLUSION: These data suggest that intra-arterial therapeutic injection of 131-iodine-labeled lipiodol for treatment of hepatocellular carcinoma can provide high rate response and long survival for individuals not eligible for surgery or local treatment.     

Pivotal study of iodine-131-labeled chimeric tumor necrosis treatment radioimmunotherapy in patients with advanced lung cancer.

PURPOSE: Tumor necrosis treatment (TNT) uses degenerating tumor cells and necrotic regions of tumors as targets for radioimmunotherapy. Previous studies in animal tumor models and clinical trials have demonstrated that when linked to the therapeutic radionuclide iodine-131, recombinant chimeric TNT antibody ((131)I-chTNT) can deliver therapeutic doses to tumors regardless of the location or type of malignancy. Therapeutic efficacy and toxicity of (131)I-chTNT in advanced lung cancer patients were studied in this pivotal registration trial. PATIENTS AND METHODS: Patients with advanced lung cancer were treated with systemic or intratumoral injection of (131)I-chTNT in eight oncology centers in China. The objective response rate (ORR) was assessed as the primary end point. RESULTS: All 107 patients who were entered onto the study and completed therapy had experienced treatment failure after prior radiotherapy or chemotherapy a mean of three times. The results showed an ORR of 34.6% (complete response, 3.7%; partial response, 30.8%; no change, 55.1%; and progressive disease, 10.3%) in all patients and 33% in 97 non-small-cell lung cancer patients. A biodistribution study demonstrated excellent localization of the radioactivity in tumors in both systemically and intratumorally injected patients. The most obvious adverse side effect was mild and reversible bone marrow suppression. CONCLUSION: Radioimmunotherapy with (131)I-chTNT was well tolerated and can be used systemically or locally to treat refractory tumors of the lung.     

Treatment of refractory Hodgkin's lymphoma patients with an iodine-131-labeled murine anti-CD30 monoclonal antibody.

PURPOSE: Hodgkin's lymphoma (HL) has been demonstrated to be a good target for immunotherapy since lymphocyte activation markers such as CD30 are expressed in high numbers on the malignant cells. Thus, we developed a new radioimmunoconjugate consisting of the murine anti-CD30 monoclonal antibody (MAb) Ki-4 labeled with iodine-131 ((131)I). PATIENTS AND METHODS: The biodistribution of (131)I-Ki-4 was assessed via dosimetry after preinfusion of 5 mg native Ki-4 followed by 250 to 300 MBq (131)I-labeled Ki-4. Whole-body scintigraphy was performed 1 hour, 24 hours, 48 hours, 72 hours, and 6 days after the infusion. Dosimetry was calculated using the programs NucliDose ICON-IDL (version 5.0.2; Siemens, Erlanger, Germany) and MIRDOSE (version 3.1; Oak Ridge National Laboratories; Oak Ridge, TN). The therapeutic dose was given on day 8 after preinfusion of unlabeled Ki-4. RESULTS: We treated 22 patients with relapsed or refractory CD30-positive HL. Preinfusion of 5 mg native Ki-4 was sufficient to bind the soluble CD30. Imaging demonstrated localization of involved areas measuring 5 cm in diameter or more in four patients and 2.5 cm in one patient. Patients received total body doses of 0.035 Gy to 0.99 Gy. Acute toxicity was mild with grade 1 fatigue in 19 of 22 assessable patients. Seven patients experienced grade 4 degrees hematotoxicity 4 to 8 weeks after treatment. Response included one complete remission, five partial remissions, and three minor responses. CONCLUSION: Treatment with (131)I-Ki-4 is effective but can be associated with severe hematotoxicity.     

Targeting radioimmunotherapy of hepatocellular carcinoma with iodine (131I) metuximab injection: clinical phase I/II trials

PURPOSE: HAb18G/CD147 is a hepatocellular carcinoma (HCC)-associated antigen. We developed iodine (131I) metuximab injection (Licartin), a novel 131I-labeled HAb18G/CD147-specific monoclonal antibody Fab'2 fragment, and evaluated its safety, pharmacokinetics, and clinical efficacy on HCC in Phase I/II trials. METHODS AND MATERIALS: In a Phase I trial, 28 patients were randomly assigned to receive the injection in 9.25-, 18.5-, 27.75-, or 37-MBq/kg doses by hepatic artery infusion. In a multicenter Phase II trial, 106 patients received the injection (27.75 MBq/kg) on Day 1 of a 28-day cycle. Response rate and survival rate were the endpoints. RESULTS: No life-threatening toxic effects were found. The safe dosage was 27.75 MBq/kg. The blood clearance fitted a biphasic model, and its half-life was 90.56-63.93 h. In the Phase II trial, the injection was found to be targeted and concentrated to tumor tissues. Of the 73 patients completing two cycles, 6 (8.22%) had a partial response, 14 (19.18%) minor response, and 43 (58.90%) stable disease. The 21-month survival rate was 44.54%. The survival rate of progression-free patients was significantly higher than that of patients with progressive disease after either one or two cycles (p < 0.0001 or p = 0.0019). CONCLUSION: Iodine (131I) metuximab injection is safe and active for HCC patients.     

Nodular hepatocellular carcinoma. Treatment with subsegmental intraarterial injection of iodine 131-labeled iodized oil.

Internal radiation therapy with subsegmental arterial injection of iodine 131(131I)-labeled iodized oil (Lipiodol; Laboratorie, Guerbet, France) was evaluated in 24 patients with nodular hepatocellular carcinoma (HCC) ranging from 2.5 to 8.0 cm in size. 131I Lipiodol (555 to 2220 MBq in 3 to 8 ml) was injected depending on the tumor size. Tumor reduction was seen in 88.9% of tumors smaller than 4.0 cm in diameter, 65.5% of tumors between 4.1 to 6.0 cm, and 25.0% of tumors larger than 5.1 cm. The tumor size reduction corresponded to the gradual drop of serum alpha-fetoprotein (AFP) levels and devascularization on follow-up angiography. Adverse reactions from treatment included fever, mild abdominal pain, nausea, and elevation of transaminases. These were mild and well tolerated by patients. This method provided long-term local control without complications related to the thyroid, lung, gastrointestinal tract, and bone marrow.     

Hepatic resection with or without adjuvant iodine-131-lipiodol for hepatocellular carcinoma: a comparative analysis

Background  

Resection of hepatocellular carcinoma (HCC) is potentially curative; however, recurrence is common. To date, few or no effective adjuvant therapies have been adequately investigated. This study evaluates the efficacy of adjuvant iodine-131-lipiodol after hepatic resection through the experience of a single-center hepatobiliary service of managing this disease.     

Targeting, dosimetry, and radioimmunotherapy of B-cell lymphomas with iodine-131-labeled LL2 monoclonal antibody

Sixteen patients with non-Hodgkin's lymphoma were infused with 6.2 to 58.2 mCi (0.2 to 3.9 mg) doses of radioactive iodine (131I)-labeled LL2 immunoglobulin G (IgG) or F(ab')2, in order to study antibody distribution, pharmacokinetics, dosimetry, toxicity, tumor targeting, and therapy. LL2 is a murine IgG2a monoclonal antibody (MAb) reactive with B cells and non-Hodgkin's B-cell lymphoma. In a series of five assessable therapy patients, doses as small as 30 mCi 131I-LL2 IgG or F(ab')2 resulted in tumor responses (two partial remissions, two mixed and minor responses, and one no response), while one patient receiving diagnostic doses as low as 6.2 mCi showed a partial remission for 1 year and a complete remission after a second low radiation dose. No acute toxicities were noted, and only myelotoxicity accompanied therapeutic doses, with grade IV marrow toxicity seen in three of seven patients receiving total doses of about 50 mCi. Dosimetry calculations showed spleen and tumor dose rules of about 4.6 cGy/mCi, which was three to four times the dose to other organs. Despite the administration of relatively low doses of LL2 (0.2 to 3.9 mg), 82% of 60 known extrasplenic lymphoma sites were imaged. Serum clearance showed an average distribution half-life (T1/2) of 2.1 hours and an elimination T1/2 of 32.0 hours. The average total-body clearance T1/2 was 43 to 45 hours. LL2's antigenic target does not appear to be shed in high amounts into the circulation. Three of eight patients having at least two injections showed a human antimouse antibody response. These patients may have been presensitized to animal protein. An interesting observation in this study was the marked drop in circulating B lymphocytes after the administration of radioiodinated LL2 or anticarcinoembryonic antigen MAbs, suggesting that this is a nonspecific radiation effect and not necessarily related to the binding of MAb to normal B cells.     

Dosimetry and dose-response relationships in newly diagnosed patients with malignant gliomas treated with iodine-131-labeled anti-tenascin monoclonal antibody 81C6 therapy

PURPOSE: The objective of this study was to perform the dosimetry and evaluate the dose-response relationships in newly diagnosed patients with malignant brain tumors treated by direct injections of (131)I-labeled 81C6 monoclonal antibody (MAb) into surgically created resection cavities (SCRCs). METHODS AND MATERIALS: Absorbed doses to the 2-cm-thick shell as measured from the margins of the resection cavity interface were estimated for 42 patients with primary brain tumors. MR images were used to assess the enhanced-rim volume as a function of time after radiolabeled MAb therapy. Biopsy samples were obtained from 15 patients and 1 autopsy. RESULTS: The average absorbed dose [range] to the 2-cm shell region was 32 [3-59] Gy. For the endpoint of minimal time to MR contrast enhancement, the optimal absorbed dose and initial dose-rate were 43 +/- 16 Gy and 0. 41 +/- 0.10 Gy/h, respectively. There was a correlation between the absorbed dose and dose rate to the shell region and biopsy outcome (tumor recurrence, radionecrosis, and tumor recurrence and/or radionecrosis). In this Phase I study, the maximum tolerated dose (MTD) was 120 mCi. At this MTD, the estimated average absorbed dose and initial dose rate to the 2-cm shell were 41 [9-89] Gy and 0.51 [0.24-1.13] Gy/h, respectively. These values are in agreement with the optimal values based on the time to MR lesion rim enhancement. CONCLUSIONS: The average absorbed dose to the 2-cm shell region varied considerably and mainly depended on cavity volume. In future clinical trials, the administered activity of (131)I-labeled 81C6 MAb may be adjusted based on cavity volume in order to deliver the optimal absorbed dose of 43 Gy rather than giving a fixed administered activity.     

In vitro and in vivo targeting properties of iodine-123- or iodine-131-labeled monoclonal antibody 14C5 in a non-small cell lung cancer and colon carcinoma model.

PURPOSE: The monoclonal antibody (mAb) 14C5 is a murine IgG1 directed against a yet undefined molecule involved in cell substrate adhesion found on the surface of malignant breast cancer tissue. mAb 14C5 is able to inhibit cell substrate adhesion and invasion of breast cancer cells in vitro. In normal tissues as well as in the stroma surrounding in situ carcinomas of the breast, no expression of the antigen 14C5 occurs. The aim of this study was to investigate the in vitro and in vivo targeting properties of 123I- and 131I-labeled mAb 14C5 as a novel agent for radioimmunodetection and radioimmunotherapy. EXPERIMENTAL DESIGN: Internalization of mAb 14C5 was investigated with 125I-labeled mAb 14C5 and by confocal laser scanning microscopy. Biodistribution studies of 131I-labeled mAb 14C5 and planar gamma imaging were done in nude mice bearing an A549 (non-small cell lung carcinoma) or a LoVo (colon carcinoma) tumor. RESULTS: Internalization studies with both A549 and LoVo cells showed that 125I-labeled mAb 14C5 is slowly internalized with approximately 30% of the initially bound mAb 14C5 internalized after 2 hours at 37 degrees C. Internalization of mAb 14C5 could be visualized with confocal laser scanning microscopy. In vivo, radioisotope uptake peaked at 24 hours for both tumor models (n = 5) with no significant difference in percentage of injected dose/g tissue (A549 10.4 +/- 0.8 and LoVo 9.3 +/- 0.8). Via planar gamma camera imaging, A549 lung tumors as well as LoVo colon tumors could be clearly visualized. CONCLUSIONS: The in vitro and in vivo targeting properties of 123I- and 131I-labeled mAb 14C5 are promising and could provide a new antibody-based agent for radioimmunodetection and radioimmunotherapy of patients bearing antigen 14C5-expressing tumors.     

Phase I trial results of iodine-131-labeled antitenascin monoclonal antibody 81C6 treatment of patients with newly diagnosed malignant gliomas.

PURPOSE: To determine the maximum-tolerated dose (MTD) of iodine-131 ((131)I)-labeled 81C6 antitenascin monoclonal antibody (mAb) administered clinically into surgically created resection cavities (SCRCs) in malignant glioma patients and to identify any objective responses with this treatment. PATIENTS AND METHODS: In this phase I trial, newly diagnosed patients with malignant gliomas with no prior external-beam therapy or chemotherapy were treated with a single injection of (131)I-labeled 81C6 through a Rickham reservoir into the resection cavity. The initial dose was 20 mCi and escalation was in 20-mCi increments. Patients were observed for toxicity and response until death or for a minimum of 1 year after treatment. RESULTS: We treated 42 patients with (131)I-labeled 81C6 mAb in administered doses up to 180 mCi. Dose-limiting toxicity was observed at doses greater than 120 mCi and consisted of delayed neurotoxicity. None of the patients developed major hematologic toxicity. Median survival for patients with glioblastoma multiforme and for all patients was 69 and 79 weeks, respectively. CONCLUSION: The MTD for administration of (131)I-labeled 81C6 into the SCRC of newly diagnosed patients with no prior radiation therapy or chemotherapy was 120 mCi. Dose-limiting toxicity was delayed neurologic toxicity. We are encouraged by the survival and toxicity and by the low 2.5% prevalence of debulking surgery for symptomatic radiation necrosis.     

Repeat treatment with iodine-131-rituximab is safe and effective in patients with relapsed indolent B-cell non-Hodgkin's lymphoma who had previously responded to iodine-131-rituximab

BackgroundSmall series suggest retreatment of indolent lymphomas with murine anti-CD20 radioimmunotherapy is effective. The longer half-life of iodine-131 (¹³¹I)-rituximab may result in increased bone marrow exposure, with greater toxicity on repeat administration. We examined the effects of a second ¹³¹I-rituximab in patients with indolent lymphoma following relapse.Patients and methodsWe analyzed two institutional databases from January 2000 to July 2007 for retreatment with ¹³¹I-rituximab. The severity of cytopenia, development of myelodysplasia (MDS), acute myeloid leukemia (AML) and hypothyroidism was noted. We compared response duration and toxicity of the treatments.ResultsFourteen of 16 patients responded with nine complete responses (CRs), with a median duration of 10.5 months in responders. Six of 13 reresponders had the same or a longer response and six more remain in complete response. The median event-free survival was not significantly different for the two treatments. There was no significant difference in the severity of myelosuppression. Four patients developed hypothyroidism with three requiring thyroxine. One patient developed AML, with no other cases of MDS. The actuarial progression-free survival rate at 12 months was 36%.ConclusionsRepeat ¹³¹I-rituximab induces high response rates, some of which result in durable remissions in patients who had previously responded.     

Effects of hyperthermia and iodine-131-labeled anticarcinoembryonic antigen monoclonal antibody on human tumor xenografts in nude mice.

BACKGROUND. Many studies have demonstrated synergistic interaction between hyperthermia and radiation. This study was undertaken to determine whether hyperthermia could enhance the effect of radioimmunotherapy (RIT) in the treatment of human colon adenocarcinoma xenografts in nude mice. METHODS. The experiments were conducted in two parts. During the first part of the study, preliminary information was obtained regarding the effect of various temperatures (41 degrees C, 42 degrees C, and 43 degrees C for 45 minutes) and iodine-131-labeled anticarcinoembryonic antigen (CEA) monoclonal antibodies (RMoAb) with administered activity ranging from 130 +/- 19 microCi to 546 +/- 19 microCi on tumor regrowth delay (TRD) and volume doubling time. This information was used in Part 2 of the study, which included four groups of mice: (1) a control group, (2) a group treated with hyperthermia, (3) a group treated with RMoAb, and (4) a group treated with a combination of RMoAb and hyperthermia. RESULTS. Maximum and significantly increased TRD was observed in the group treated with RMoAb and hyperthermia (slope, 0.057) compared with the control group (slope, 0.322), the hyperthermia-treated group (slope, 0.302), and the group treated with RMoAb alone (slope, 0.098). The ratio of the slopes between the groups treated with RMoAb and those treated with RMoAb and hyperthermia was 1.72. No correlation was detected between the percent of antibody uptake in the tumor and tumor regression in the groups treated with heat and RMoAb and those treated with RMoAb alone. CONCLUSIONS. The results of these experiments show that hyperthermia increased the effectiveness of iodine-131-labeled anti-CEA monoclonal antibodies against human colon carcinoma xenografts in nude mice. This study offers a rationale for combining hyperthermia and low-dose radiation produced from RIT in clinical practice.     

Necrosis targeted radiotherapy with iodine-131-labeled hypericin to improve anticancer efficacy of vascular disrupting treatment in rabbit VX2 tumor models

A viable rim of tumor cells surrounding central necrosis always exists and leads to tumor recurrence after vascular disrupting treatment (VDT). A novel necrosis targeted radiotherapy (NTRT) using iodine-131-labeled hypericin (¹³¹I-Hyp) was specifically designed to treat viable tumor rim and improve tumor control after VDT in rabbit models of multifocal VX2 tumors. NTRT was administered 24 hours after VDT. Tumor growth was significantly slowed down by NTRT with a smaller tumor volume and a prolonged tumor doubling time (14.4 vs. 5.7 days), as followed by in vivo magnetic resonance imaging over 12 days. The viable tumor rims were well inhibited in NTRT group compared with single VDT control group, as showed on tumor cross sections at day 12 (1 vs. 3.7 in area). High targetability of ¹³¹I-Hyp to tumor necrosis was demonstrated by in vivo SPECT as high uptake in tumor regions lasting over 9 days with 4.26 to 98 times higher radioactivity for necrosis versus the viable tumor and other organs by gamma counting, and with ratios of 7.7–11.7 and 10.5–13.7 for necrosis over peri-tumor tissue by autoradiography and fluorescence microscopy, respectively. In conclusion, NTRT improved the anticancer efficacy of VDT in rabbits with VX2 tumors.     

Radioimmunotherapy of human hepatocellular carcinoma xenografts with 131I-labelled antiferritin antibody

The effects of 131-labelled antiferritin polyclonal antibody for the treatment of established hepatocellular carcinoma (HC-04) in athymic nude mice were evaluated. 131I-labelled antiferritin antibody localised specifically to a subcutaneous tumour with a mean of 8.1% of the infused dose per gram of tumour at 24 h after infusion when the experiment was started 15 days after inoculation and with a mean of about 6.5% of the infused dose per gram of tumour when the experiment was started 30 days after tumour transplantation. The concentrations of 131I-antiferritin antibody in tumour delivered a mean of 1994 cGy to tumour following infusion of 500 microCi of radiolabelled antiferritin antibody in the early group and a mean of 1600 cGy in the late group. Treatment with 500 microCi led to regression of the tumour in 55% of animals in the early group and 44% in the late group. In contrast, unlabelled antiferritin and 131I-labelled IgG failed to exert any significant effect on tumour growth. The transplanted tumours in the early groups of animals had relatively higher concentration of ferritin than those in the late group. There was accelerated inhibition of tumour growth and prolonged survival in animals in the early group compared with those in the late group.     

Phase I clinical trial of targeted therapy using 131I-Hepama-1 mAb in patients with hepatocellular carcinoma

OBJECTIVES: The aim of this study was to evaluate the response- and treatment-related toxicity for patients with unresectable hepatocellular carcinoma (HCC) treated with 131I-Hepama-1 mAb (DGDK-1). MATERIALS AND METHODS: Seeking approval for the use of 131I-hepama-1 mAb, 32 patients with unresectable HCC were divided into 5 groups to take part in the Phase I clinical trial study. Systemic reactions and acute toxicity were evaluated weekly for at least 45 days following treatment with an intravenous injection of 10 mg of antibody radiolabeled with 740-3700 MBq (20-100 mCi), divided into 5 groups. RESULTS: No patients demonstrated any evidence of fever, severe side effects, or impairments of important organs, such as the lung, liver, and heart. During, and for 45 days after, the treatment, most of their routine examinations of blood, functions of liver and kidneys, and the thyroid hormone were all normal. Hypothyroidism was not observed during the course of monitoring. None of the 32 patients developed human antimurine antibodies (HAMA) within 15 days of therapy; however, 82% of patients were HAMA-positive by 45 days of therapy. According to the pilot study of prognosis, survival from the start of radioimmunotherapy (RIT) was a median of 4 months, and the 1-year survival rate was 31%. The median survival time of 15 patients without metastases was 10 months, and the 1-year survival rate was 60%. Of alpha-fetoprotein (AFP)-positive patients, 75% of AFP levels decreased by at least 50% or became normal. Of all patients, 84% showed an improved Eastern Cooperative Oncology Group (ECOG) performance status. CONCLUSION: This phase I clinical trial demonstrated that it was safe to use 131I-hepama- 1 mAb by peripheral intravenous administration. The recommended dose of DGDK-1 for clinical use is 1480-2960 MBq/10 mg.     

Comparison of L-thyroxine and a saturated solution of potassium iodide in preventing damage to the thyroid following iodine-131-labeled antibody injection

Following injection of radioiodinated antibodies in diagnostic amounts, there is variable uptake of radioiodine by the thyroid. Unless preventive steps are taken, radiation damage to the gland may occur. We have evaluated the role of L-thyroxine and a saturated solution of potassium iodide (SSKI) in preventing radiation damage to the thyroid glands of Sprague-Dawley adult male rats by measuring DNA strand breakage by the nucleoid sedimentation gradient method. Pretreatment with SSKI reduced DNA damage and also reduced 131I accumulation in the thyroid. Pretreatment with L-thyroxine also reduced DNA damage without significantly reducing 131I accumulation in the thyroid. The possible mechanisms of action of L-thyroxine and SSKI in preventing radiation damage to the thyroid are addressed.     

Biodistribution of indium-111-labeled OC 125 monoclonal antibody after intraperitoneal injection in nude mice intraperitoneally grafted with ovarian carcinoma

The purpose of this work was to study the biodistribution of 111In-labeled OC 125 monoclonal antibody (MAb) with known affinity for ovarian carcinomas in a nude mouse model grafted i.p. with a human ovarian cancer (NIH:OVCAR-3). Tumor uptake 24 h after i.p. injection was higher with intact 111In-labeled OC 125 MAb (28 +/- 7.44%ID/g) than with 111In-nonspecific immunoglobulin (6.86 +/- 1.35%ID/g). The kinetics of tumor uptake also differed, showing a plateau followed by a drop at Day 7 with 111In-OC 125 MAb and a decrease beginning at 24 h with 111In-nonspecific immunoglobulin. Tumor-to-normal tissue ratios ranged between 29.91 +/- 11.85 and 0.68 +/- 0.15 with 111In-OC 125 MAb and between 4.50 +/- 1.06 and 0.53 +/- 0.04 with 111In-nonspecific immunoglobulin according to the normal tissues and the time points considered. Tumor uptake 2 h after injection was the same for F(ab')2 fragments as for intact MAb, whereas maximum uptake at 24 h (18.76 +/- 4.62%ID/g) was lower and was followed by a decrease at Day 4. Tumor-to-normal tissue ratios were in the same range, except for the tumor to blood ratio which was higher and the tumor to kidney ratio which was lower at 24 and 96 h. Maximum tumor uptake was higher after i.p. (30.77 +/- 4.76%ID/g) than i.v. (14.59 +/- 2.70%ID/g) injection. Instead of attaining the plateau noted after i.p. injection, tumor uptake after i.v. injection remained low at 2 h (2.11 +/- 1.66%ID/g), reaching its peak only after 96 h. 131I-OC 125 injected i.p., which reached maximum tumor uptake at 2 h (13.53 +/- 4.25%ID/g), showed tumor-to-tissue ratios ranging between 15.98 +/- 2.63 and 0.96 +/- 0.86, i.e., not very different from those with 111In. After i.p. injection of a radiolabeled colloid solution, maximum tumor uptake was reached at 96 h (20.22 +/- 5.35%ID/g), but with very high nonspecific uptake in liver (31.06 +/- 6.22%ID/g) and spleen (55.23 +/- 14.11%ID/g). These results indicate high, selective tumor uptake of 111In-OC 125 after i.p. injection and demonstrate the feasibility of i.p. radioimmunotherapy of ovarian carcinomas.     

Use of iodine-131-labeled anti-immune response-associated monoclonal antibody as preparative regimen prior to bone marrow transplantation: initial dosimetry

Despite the use of near maximal doses of external beam total-body irradiation, many patients who received transplants for relapsed hematologic cancers will fail because of tumor recurrence following therapy. With the use of radioisotope-labeled monoclonal antibodies, a more directed delivery of systemic radiotherapy may be achieved; tumor cell kill is increased without increased toxicity. On the basis of this hypothesis, we have begun dosimetry studies in normal dogs using an anti-immune response-associated antibody (7.2) labeled with 131I. Compared with an irrelevant isotype-matched antibody, the blood concentration of 131I-labeled 7.2 fell rapidly over the first 3 hours and then cleared more slowly. During this time, there was specific localization of 131I-7.2 in lymph nodes, spleen, and marrow. On the basis of the concentration curves generated over 48 hours, administration of enough 131I-7.2 to deliver 10 Grays to the blood would result in radiation doses of 9.8, 16.3, and 32.3 Grays to liver, marrow, and spleen, respectively. The liver uptake of labeled 7.2 appeared to be the result of its direct antigen-specific binding to hepatic Kupffer cells rather than to the clearance by the liver of either antigen-antibody complexes or antibody-coated cells. Gastric or intestinal radiation toxicity may be a problem due to gastric excretion of free I following binding of 131I-7.2 and subsequent deiodination.     

Phase-I/II radio-immunotherapy study with iodine-131-labeled anti-CEA monoclonal antibody F6 F(ab′)2 in patients with non-resectable liver metastases from colorectal cancer

Experimental studies in nude mice with human colon-carcinoma grafts demonstrated the therapeutic efficiency of F(ab′)₂ fragments to carcinoembryonic antigen (CEA) labeled with a high dose of ¹³¹Iodine. A phase I/II study was designed to determine the maximum tolerated dose of ¹³¹I-labeled F(ab′)₂ fragments (¹³¹I-F(ab′)₂) from anti-CEA monoclonal antibody F6, its limiting organ toxicity and tumor uptake. Ten patients with non-resectable liver metastases from colorectal cancer (9 detected by CT scan and 1 by laparotomy) were treated with ¹³¹I-F(ab′)₂, doses ranging from 87 mCi to 300 mCi for the first 5 patients, with a constant 300-mCi dose for the last 5 patients. For all the patients, autologous bone marrow was harvested and stored before treatment. Circulating CEA ranged from 2 to 126 ng/ml. No severe adverse events were observed during or immediately following infusion of therapeutic doses. The 9 patients with radiologic evidence of liver metastases showed uptake of ¹³¹I-F(ab′)₂ in the metastases, as observed by single-photon-emission tomography. The only toxicity was hematologic, and no severe aplasia was observed when up to 250 mCi was infused. At the 300-mCi dose, 5 out of 6 patients presented grade-3 or -4 hematologic toxicity, with a nadir for neutrophiles and thrombocytes ranging from 25 to 35 days after infusion. In these 5 cases, bone marrow was re-infused. No clinical complications were observed during aplasia. The tumor response could be evaluated in 9 out of 10 patients. One patient showed a partial response of one small liver metastasis (2 cm in diameter) and a stable evolution of the other metastases, 2 patients had stable disease, and 6 showed tumor progression at the time of evaluation (2 or 3 months after injection) by CT scan. This phase-I/II study demonstrated that a dose of 300 mCi of ¹³¹I-F(ab′)₂ from the anti-CEA Mab F6 is well tolerated with bone-marrow rescue, whereas a dose of 200 mCi can be infused without severe bone-marrow toxicity. Int. J. Cancer 75:615–619, 1998. © 1998 Wiley-Liss, Inc.