Splenic lymphocytes of mice, immunized with membrane-enriched fractions ofmetastatic human mammary carcinoma tissues, were fused with the NS-1 non-immunoglobulinsecreting murine myeloma cell line. This resulted in the generation of hybridoma cultures secreting immunoglobulins reactive in solid-phase radioimmunoassays with extracts of metastatic mammary carcinoma cells from involved livers, but not with extracts ofapparently normal human liver. As a result offurther screening of immunoglobulin reactivities and double cloning of cultures, 11 monoclonal antibodies were chosen that demonstrated reactivities with human mammary tumor cells and not with apparently normal human tissues. These monoclonal antibodies could be placed into at least five major groups on the basis of their differential binding to the surface of various live human mammary tumor cells in culture, to extracts of mammary tumor tissues, or to tissue sections of mammary tumor cells studied by the immunoperoxidase technique. Whereas a spectrum of reactivities to mammary tumors was observed with the 11 monoclonal antibodies, no reactivity was observed to apparently normal cells of the following human tissues: breast, lymph node, lung, skin, testis, kidney, thymus, bone marrow, spleen, uterus, thyroid, intestine, liver, bladder, tonsils, stomach, prostate, and salivary gland. Several of the antibodies also demonstrated a "pancarcinoma" reactivity, showing binding to selected non-breast carcinomas. None of the monoclonal antibodies showed binding to purified ferritin or carcinoembryonic antigen. Monoclonal antibodies of all five major groups, however, demonstrated binding to human metastatic mammary carcinoma cells both in axillary lymph nodes and at distal sites.Numerous investigators have reported the existence ofantigens associated with human mammary tumors (1-9). These studies, all conducted with conventional hyperimmune polyclonal sera, however, were unfortunately hampered with regard to the heterogeneity of the antibody populations employed and the amount of specific immunoglobulin that could be generated. Since the advent ofhybridoma technology (10), monoclonal antibodies of predefined specificity and virtually unlimited quantity may now be generated against a variety of antigenic determinants present on normal or neoplastic cells. The rationale of the studies reported here was to utilize extracts ofhuman metastatic mammary tumor cells as immunogens in an attempt to generate and characterize monoclonal antibodies reactive with determinants that would be maintained on metastatic, as well as primary, human mammary carcinoma cells. Multiple assays using tumor cell extracts, tissue sections, and live cells in culture have been employed to reveal the diversity of the monoclonal antibodies generated.MATERIALS AND METHODS Immunizations. Membrane-enriched cell extracts were prepared from breast tumor metastases to the liver from two patients as well as from apparently normal liver as described (11) Hybridoma Methodology. Somatic cell hybrids wer...
Women with human epidermal growth factor receptor 2 (HER2)-positive breast cancer are candidates for treatment with the anti-HER2 antibody trastuzumab. Assessment of HER2 status in recurrent disease is usually made by core needle biopsy of a single lesion which may not be representative of the larger tumor mass or other sites of disease. Our long-range goal is to develop positron emission tomography (PET) of radiolabeled trastuzumab for systemically assessing tumor HER2 expression and identifying appropriate use of anti-HER2 therapies. The purpose of this study was to evaluate PET-CT of 64Cu-DOTA-trastuzumab for detecting and measuring tumor uptake of trastuzumab in patients with HER2-positive metastatic breast cancer. Methods Eight women with biopsy-confirmed HER2-positive metastatic breast cancer and no anti-HER2 therapy for ≥ 4 mo underwent complete staging, including 18F-fluorodeoxyglucose (FDG)/PET-CT. For 6 of the 8 patients, 64Cu-DOTA-trastuzumab injection (364-512 MBq, 5 mg trastuzumab) was preceded by trastuzumab infusion (45 mg). PET-CT (PET scan duration 1 h) was performed 21-25 (“Day 1”) and 47-49 (“Day 2”) h after 64Cu-DOTA-trastuzumab injection. Scan fields of view were chosen based on 18F-FDG/PET-CT. Lesions visualized relative to adjacent tissue on PET were considered PET-positive; analysis was limited to lesions identifiable on CT. Radiolabel uptake in prominent lesions was measured as maximum single-voxel standardized uptake value (SUVmax). Results Liver uptake of 64Cu was reduced approximately 75% with the 45 mg trastuzumab pre-dose, without significant effect on tumor uptake. The study included 89 CT-positive lesions; detection sensitivity was 77, 89 and 93% for Day 1, Day 2 and 18F-FDG, respectively. On average, tumor uptake was similar for 64Cu-DOTA-trastuzumab and 18F-FDG [SUVmax (mean, range): Day 1 (8.1, 3.0-22.5, n=48); Day 2 (8.9, 0.9-28.9, n=38); 18F-FDG (9.7, 3.3-25.4, n=56)], but the extent of same-lesion uptake was not correlated between the 2 radiotracers. No toxicities were observed, and estimated radiation dose from 64Cu-DOTA-trastuzumab was similar to 18F-FDG. Conclusion 64Cu-DOTA-trastuzumab visualizes HER2-positive metastatic breast cancer with high sensitivity, and is effective in surveying disseminated disease. A 45 mg trastuzumab pre-dose provides a 64Cu-DOTA-trastuzumab biodistribution favorable for tumor imaging. 64Cu-DOTA-trastuzumab/PET-CT warrants further evaluation for assessing tumor HER2 expression and measuring delivery of trastuzumab-based therapy.
Chimeric antigen receptor (CAR) T cell therapy is a promising clinical approach for reducing tumor progression and prolonging patient survival. However, improvements in both the safety and the potency of CAR T cell therapy demand quantitative imaging techniques to determine the distribution of cells after adoptive transfer. The purpose of this study was to optimize Zr-oxine labeling of CAR T cells and evaluate PET as a platform for imaging adoptively transferred CAR T cells. CAR T cells were labeled with 0-1.4 MBq of Zr-oxine per 10 cells and assessed for radioactivity retention, viability, and functionality. In vivo trafficking of Zr-oxine-labeled CAR T cells was evaluated in 2 murine xenograft tumor models: glioblastoma brain tumors with intracranially delivered IL13Rα2-targeted CAR T cells, and subcutaneous prostate tumors with intravenously delivered prostate stem cell antigen (PSCA)-targeted CAR T cells. CAR T cells were efficiently labeled (75%) and retained more than 60% of the Zr over 6 d. In vitro cytokine production, migration, and tumor cytotoxicity, as well as in vivo antitumor activity, were not significantly reduced when labeled with 70 kBq/10 cells. IL13Rα2-CAR T cells delivered intraventricularly were detectable by PET for at least 6 d throughout the central nervous system and within intracranial tumors. When intravenously administered, PSCA-CAR T cells also showed tumor tropism, with a 9-fold greater tumor-to-muscle ratio than for CAR-negative T cells. Zr-oxine can be used for labeling and imaging CAR T cells while maintaining cell viability and function. On the basis of these studies, we conclude thatZr-oxine is a clinically translatable platform for real-time assessment of cell therapies.
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