Sarah Yu

Pulsed High-Intensity Focused Ultrasound Enhances Uptake of Radiolabeled Monoclonal Antibody to Human Epidermoid Tumor in Nude Mice

The aim of this study was to determine if pulsed high-intensity focused ultrasound (HIFU) exposures could enhance tumor uptake of 111In-MX-B3, a murine IgG1κ monoclonal antibody directed against the Ley antigen. Methods: MX-B3 was labeled with 111In, purified, and confirmed for its binding to the antigen-positive A431 cell line. Groups of nude mice were inoculated subcutaneously with A431 tumor cells on both hind flanks. A tumor on one flank was treated with pulsed-HIFU; the other tumor was used as an untreated control. Within 10 min after the HIFU exposure, the mice received intravenous 111In-MX-B3 for imaging and biodistribution studies. Mice were euthanized at 1, 24, 48, and 120 h after injection for biodistribution studies. Results: The HIFU exposure shortened the peak tumor uptake time (24 vs. 48 h for the control) and increased the peak tumor uptake value (38 vs. 25 %ID/g [percentage injected dose per gram] for the control). The HIFU effect on enhancing tumor uptake was greater at earlier times up to 24 h, but the effect was gradually diminished thereafter. The HIFU effect on enhancing tumor uptake was substantiated by nuclear imaging studies. HIFU also increased the uptake of the antibody in surrounding tissues, but the net increase was marginal compared with the increase in tumor uptake. Conclusion: This study demonstrates that pulsed-HIFU significantly enhances the delivery of 111In-MX-B3 in human epidermoid tumors xenografted in nude mice. The results of this pilot study warrant further evaluation of other treatment regimens, such as repeated HIFU exposures for greater delivery enhancement of antibodies labeled with cytotoxic radioisotopes or pulsed-HIFU exposure in addition to a combined therapy of 90Y-B3 and taxol to enhance the synergistic effect.

The use of chelated radionuclide (samarium-153-ethylenediaminetetramethylenephosphonate) to modulate phenotype of tumor cells and enhance T cell-mediated killing.

Purpose: Exposing human tumor cells to sublethal doses of external beam radiation up-regulates expression of tumor antigen and accessory molecules, rendering tumor cells more susceptible to killing by antigen-specific CTLs. This study explored the possibility that exposure to palliative doses of a radiopharmaceutical agent could alter the phenotype of tumor cells to render them more susceptible to T cell–mediated killing. Experimental Design: Here, 10 human tumor cell lines (4 prostate, 2 breast, and 4 lung) were exposed to increasing doses of the radiopharmaceutical samarium-153-ethylenediaminetetramethylenephosphonate (153Sm-EDTMP) used in cancer patients to treat pain due to bone metastasis. Fluorescence-activated cell sorting analysis and quantitative real-time PCR analysis for expression of five surface molecules and several tumor-associated antigens involved in prostate cancer were done. LNCaP human prostate cancer cells were exposed to 153Sm-EDTMP and incubated with tumor-associated antigen-specific CTL in a CTL killing assay to determine whether exposure to 153Sm-EDTMP rendered LNCaP cells more susceptible to T cell–mediated killing. Results: Tumor cells up-regulated the surface molecules Fas (100% of cell lines up-regulated Fas), carcinoembryonic antigen (90%), mucin-1 (60%), MHC class I (50%), and intercellular adhesion molecule-1 (40%) in response to 153Sm-EDTMP. Quantitative real-time PCR analysis revealed additional up-regulated tumor antigens. Exposure to 153Sm-EDTMP rendered LNCaP cells more susceptible to killing by CTLs specific for prostate-specific antigen, carcinoembryonic antigen, and mucin-1. Conclusions: Doses of 153Sm-EDTMP equivalent to palliative doses delivered to bone alter the phenotype of tumor cells, suggesting that 153Sm-EDTMP may work synergistically with immunotherapy to increase the susceptibility of tumor cells to CTL killing.

Use of radiolabeled monoclonal antibody to enhance vaccine-mediated antitumor effects

Radiolabeled monoclonal antibodies (mAb) have demonstrated measurable antitumor effects in hematologic malignancies. This outcome has been more difficult to achieve for solid tumors due, for the most part, to difficulties in delivering sufficient quantities of mAb to the tumor mass. Previous studies have shown that nonlytic levels of external beam radiation can render tumor cells more susceptible to T cell-mediated killing. The goal of these studies was to determine if the selective delivery of a radiolabeled mAb to tumors would modulate tumor cell phenotype so as to enhance vaccine-mediated T-cell killing. Here, mice transgenic for human carcinoembryonic antigen (CEA) were transplanted with a CEA expressing murine carcinoma cell line. Radioimmunotherapy consisted of yttrium-90 (Y-90)-labeled anti-CEA mAb, used either alone or in combination with vaccine therapy. A single dose of Y-90-labeled anti-CEA mAb, in combination with vaccine therapy, resulted in a statistically significant increase in survival in tumor-bearing mice over vaccine or mAb alone; this was shown to be mediated by engagement of the Fas/Fas ligand pathway. Mice receiving the combination therapy also showed a significant increase in the percentage of viable tumor-infiltrating CEA-specific CD8+ T cells compared to vaccine alone. Mice cured of tumors demonstrated an antigen cascade resulting in CD4+ and CD8+ T-cell responses not only for CEA, but for p53 and gp70. These results show that systemic radiotherapy in the form of radiolabeled mAb, in combination with vaccine, promotes effective antitumor response, which may have implications in the design of future clinical trials.

The Anti-CD25 Monoclonal Antibody 7G7/B6, Armed with the α-Emitter 211At, Provides Effective Radioimmunotherapy for a Murine Model of Leukemia

Radioimmunotherapy of cancer with radiolabeled antibodies has shown promise. alpha-Particles are very attractive for cancer therapy, especially for isolated malignant cells, as is observed in leukemia, because of their high linear energy transfer and short effective path length. We evaluated an anti-CD25 [interleukin-2 receptor alpha (IL-2R alpha)] monoclonal antibody, 7G7/B6, armed with (211)At as a potential radioimmunotherapeutic agent for CD25-expressing leukemias and lymphomas. Therapeutic studies were done in severe combined immunodeficient/nonobese diabetic mice bearing the karpas299 leukemia and in nude mice bearing the SUDHL-1 lymphoma. The results from a pharmacokinetic study showed that the clearance of (211)At-7G7/B6 from the circulation was virtually identical to (125)I-7G7/B6. The biodistributions of (211)At-7G7/B6 and (125)I-7G7/B6 were also similar with the exception of a higher stomach uptake of radioactivity with (211)At-7G7/B6. Therapy using 15 microCi of (211)At-7G7/B6 prolonged survival of the karpas299 leukemia-bearing mice significantly when compared with untreated mice and mice treated with (211)At-11F11, a radiolabeled nonspecific control antibody (P < 0.01). All of the mice in the control and (211)At-11F11 groups died by day 46 whereas >70% of the mice in the (211)At-7G7/B6 group still survived at that time. In summary, (211)At-7G7/B6 could serve as an effective therapeutic agent for patients with CD25-expressing leukemias.

Preclinical Evaluation of an Anti-CD25 Monoclonal Antibody, 7G7/B6, Armed with the β-Emitter, Yttrium-90, as a Radioimmunotherapeutic Agent for Treating Lymphoma

OBJECTIVE Radioimmunotherapy of cancer with radiolabeled antibodies has shown promise. We evaluated an anti-CD25 monoclonal Antibody, 7G7/B6, armed with (90)Y as a potential radioimmunotherapeutic agent for CD25-expressing lymphomas. MATERIALS AND METHODS The lymphoma model was established by subcutaneous injection of 1 x 10(7) SUDHL-1 cells into nude mice. The biodistribution of (111)In-7G7/B6 and therapeutic studies with (90)Y-7G7/B6 were performed in the tumor-bearing mice. RESULTS Therapy using (90)Y-7G7/B6 prolonged survival of the SUDHL-1 lymphoma-bearing mice significantly, as compared with either untreated mice or the mice treated with (90)Y-11F11, a radiolabeled isotype-matched control antibody (p < 0.001). All of the mice in the control and the (90)Y-11F11 treatment groups died by days 18 and 24, respectively. In contrast, 30% of the mice in the low-dose group (75 microCi of (90)Y-7G7/B6/mouse) and 75% in the high-dose group (150 microCi of (90)Y-7G7/B6/mouse) became tumor free and remained healthy for greater than 6 months. CONCLUSIONS Our findings suggested that (90)Y-7G7/B6 is a potentially useful radioimmunotherapeutic agent for the treatment of patients with CD25-expressing lymphomas.