Targeting and therapy of human glioma xenografts in vivo using radiolabeled antibodies.

Radiolabeled antibodies provide a potential basis for selective radiotherapy of human gliomas. Monoclonal P96.5, a mouse IgG2a immunoglobulin, defines an epitope of a human melanoma cell surface protein and specifically binds the U-251 human glioma as measured by immunoperoxidase histochemistry. 111In-radiolabeled P96.5 specifically targets the U-251 human glioma xenograft and yields 87.0 microCuries (uCi) of tumor activity per gram per 100 uCi injected activity compared to 4.5 uCi following administration of radiolabeled irrelevant monoclonal antibody. Calculations of targeting ratios demonstrate deposited dose to be 11.6 times greater with radiolabeled P96.5 administration compared to irrelevant monoclonal antibody. Tumor dose found in normal organs is less than 20% of the tumor dose, further supporting specific targeting of the human glioma xenograft by this antibody. Monoclonal antibodies QCI054 and ZME018, which define a tumor-associated and a second melanoma-associated antigen, respectively, demonstrate positive immunoperoxidase staining of the tumor, but comparatively decreased targeting. To test the therapeutic potential of 90Y-radiolabeled P96.5, QCI054, and ZME018, tumors and normal sites were implanted with miniature thermoluminescent dosimeters (TLD). Average absorbed doses of 3770 +/- 445 (mean +/- SEM), 2043 +/- 134, and 645 +/- 48 cGy in tumor, 353 +/- 41, 243 +/- 22, and 222 +/- 13 cGy in a contralateral control intramuscular site, 980 +/- 127, 815 +/- 41, and 651 +/- 63 cGy in liver, and 275 +/- 14, 263 +/- 11, and 256 +/- 18 cGy in total body were observed 7 days following administration of 100 uCi 90Y-radiolabeled P96.5, QCI054, and ZME018, respectively. To test the therapeutic potential, tumor-bearing nude mice were given intracardiac injections of either buffer or 90Y-radiolabeled P96.5, QCI054, or ZME018. Striking tumor regression and prolonged survival were measured following administration of 90Y-labeled P96.5. Average maximal decreases in tumor volume were 42.7 +/- 11.9 and 94.2 +/- 3.3 percent 28 and 58 days following 100 and 200 uCi 90Y-radiolabeled P96.5 administration, respectively. The time required to achieve four times the initial tumor volume was 6.1 +/- 0.9 days for buffer; 43 +/- 12 and 63 +/- 10 days for 50 and 100 uCi 90Y-radiolabeled P96.5; 7 +/- 2, 20 +/- 1, and 53 +/- 4 for 50, 100, and 200 uCi 90Y-radiolabeled QCI054; and 9 +/- 1, 13 +/- 1, and 29 +/- 3 days for 50, 100, and 200 uCi 90Y-radiolabeled ZME018, respectively. Average tumor regrowth failed to occur 180 days following administration of 200 uCi 90Y-labeled P96.5.(ABSTRACT TRUNCATED AT 400 WORDS)

Targeting of human glioma xenografts in vivo utilizing radiolabeled antibodies.

Radiolabeled antibodies provide a potential basis for selective radiotherapy of human gliomas. We have measured tumor targeting by radiolabeled monoclonal and polyclonal antibodies directed against neuroectodermal and tumor-associated antigens in nude mice bearing human glioma xenografts. Monoclonal P96.5, a mouse IgG2a immunoglobulin, defines an epitope of a human melanoma cell surface protein, and specifically binds the U-251 human glioma as measured by immunoperoxidase histochemistry. 111In-radiolabeled P96.5 specifically targets the U-251 human glioma xenograft and yields 87.0 microCuries (microCi) of tumor activity per gram per 100 microCi injected activity compared to 4.5 microCi following administration of radiolabeled irrelevant monoclonal antibody. Calculations of targeting ratios demonstrate deposited dose to be 11.6 times greater with radiolabeled P96.5 administration compared to irrelevant monoclonal antibody. The proportion of tumor dose found in normal organs is less than 10%, further supporting specific targeting of the human glioma xenograft by this antibody. Monoclonal antibody ZME018, which defines a second melanoma-associated antigen, and polyclonal rabbit antiferritin, which defines a tumor-associated antigen, demonstrate positive immunoperoxidase staining of the tumor, but comparatively decreased targeting. When compared to the 111In-radiolabeled antibody, 90Y-radiolabeled P96.5 demonstrates comparable tumor targeting and percentages of tumor dose found in normal organs. To test the therapeutic potential of 90Y-radiolabeled P96.5, tumors and normal sites were implanted with miniature thermoluminescent dosimeters (TLD). Seven days following administration of 100 microCi 90Y-radiolabeled P96.5, average absorbed doses of 3770, 980, 353, and 274 cGy were observed in tumor, liver, contralateral control site, and total body, respectively. Shared cell surface antigens among neuroectodermally derived neoplasms provide a basis for exploration of human glioma radioimmunotherapy.

The use of rare-earth radionuclides and other bone-seekers in the evaluation of bone lesions in patients with multiple myeloma or solitary plasmacytoma.

Twenty-four patients with multiple myeloma and 4 with solitary plasmacytoma had total-body scans after intravenous injection of 67Ga-citrate alone (17 patients) or combined with other agents (11 patients). The latter included 99mTc-diphosphonate (99mTc-DP), 99mTc-polyphosphate (99mTc-PP), or 99mTc-sulfur colloid (99mTc-SC) given alone or combined with 171Er, 157Dy, or 167Tm as citrate. In some patients more than one agent was compared to 67Ga and radiographic bone surveys. In general, localization of the rare-earth "bone-seekers" was poor except for 157Dy, which compared well with 99mTc-PP and 99mTc-DP; 157Dy was also helpful in studies of the abdomen and pelvis because of its failure to concentrate in the gastrointestinal tract. No toxic or nonspecific effects were noted.

Elution of benzo[alpha]pyrene from carbon particles in the respiratory tract of mice.

The effect of carrier particle size on the rate of dissociation of benzo[alpha]pyrene (BaP) from carrier particles deposited in the respiratory tract of mice was studied. BaP-coated carbon particles (in two size ranges, 0.5-1.0 and 15-30 mum) plus 103Ru-tagged carbon tracer particles were intratracheally instilled in mice. The clearance of carbon particles and the simultaneous rate of elimination of BaP from the respiratory tract was measured. BaP adsorbed to 15- to 30-muM carbon particles was eliminated from the lung at essentially the same rate as the carbon particles were cleared. In contrast, BaP adsorbed to 0.5- to 1.0-muM carbon particles was eliminated from the lung approximately 4 times faster than the carbon particles were cleared. The persistence of carcinogens and their rates of elution from carrier particles are discussed in relation to the pathogenesis of lung cancer in animals treated with carcinogen-carrier particle preparations.