SBIR-STTR Award

The funding of the application will yield safety and efficacy data on a new combination cancer therapy for leukemia and lymphomas. Monoclonal antibodies (mAbs) have emerged as a class of novel oncology therapeutics. We are developing a molecule that can improve the therapeutic effects of mAbs by: 1) increasing the sensitivity of cancers to treatment 2) unmasking resistant cancers so they again become sensitized and 3) potentially allowing treatment of cancers that have become refractory to therapy. This project will move a clinical candidate forward for future testing in humans. The public health implications of dose-sparing and cost reduction for mAb therapy, improved outcomes in cancer and making a new therapy available for previously resistant cancers are significant. The immediate goal of the research is to collect data to enable an Investigational New Drug (IND) filing on a combination therapy for lymphoma. Our consultant at the University of Washington has collected a significant body of information supporting the superiority of the combination of depleting CD46 on the cell surface with antibody therapy in blood cancers Our long-term goal is to translate the technology from research bench to clinical bedside leading to enhancement of monoclonal antibody (mAb) therapy.

Public Health Relevance:
Although monoclonal antibody therapy can be an effective way to treat cancer, further progress is needed to increase therapeutic success. We intend to enhance cancer therapy to improve treatment worldwide.

Thesaurus Terms:
Antibody Therapy;Biosynthetic Proteins;Bp35;Cd 46 Antigen;Cd20;Cd46;Cd46 Antigen;Cancer Treatment;Cancers;Cell Line;Cell Surface;Cellline;Cells;Clinic;Clinical;Clinical Treatment Moab;Clinical Trials;Combined Modality Therapy;Complement;Complement Proteins;Crab-Eating Macaque;Crab-Eating Monkey;Cynomolgus Monkey;Data;Dose;Enhancing Antibodies;Funding;Future;Germinoblastic Sarcoma;Germinoblastoma;Goals;Hematopoietic Cell Tumor;Hematopoietic Malignancies;Hematopoietic Neoplasms;Hematopoietic Neoplasms Including Lymphomas;Hematopoietic Tumor;Hematopoietic And Lymphoid Cell Neoplasm;Hematopoietic And Lymphoid Neoplasms;Human;Investigational Drugs;Investigational New Drugs;Lead;Leu-16;Licensing;Lymphoma;Lymphoma (Hodgkin's And Non-Hodgkin's);Mcp Antigen;Ms4a1;Ms4a1 Gene;Ms4a2;Macaca Fascicularis;Malignant Hematopoietic Neoplasm;Malignant Lymphoma;Malignant Neoplasm Therapy;Malignant Neoplasm Treatment;Malignant Neoplasms;Malignant Tumor;Man (Taxonomy);Modeling;Modern Man;Monoclonal Antibodies;Monoclonal Antibody Therapy;Multimodal Therapy;Multimodal Treatment;Multimodality Treatment;Oncology Cancer;Outcome;Pb Element;Preparation;Proteins;Public Health;Recombinant Proteins;Refractory;Regimen;Research;Resistance;Reticulolymphosarcoma;Safety;Strains Cell Lines;Tlx-B Antigen;Technology;Testing;Therapeutic;Therapeutic Effect;Transgenic Mice;Translating;Universities;Washington;Anticancer Therapy;Base;Blood Cancer;Cancer Therapy;Cell Killing;Clinical Investigation;Combination Cancer Therapy;Combination Therapy;Combined Modality Treatment;Combined Treatment;Cost;Cultured Cell Line;Experiment;Experimental Research;Experimental Study;Gene Product;Gp45-70 Protein;Heavy Metal Pb;Heavy Metal Lead;Improved;In Vivo;Leukemia/Lymphoma;Lymphoma/Leukemia;Malignancy;Membrane Cofactor Protein;Multimodality Therapy;Neoplasm/Cancer;Non-Human Primate;Nonhuman Primate;Novel;Oncology;Pre-Clinical;Preclinical;Preclinical Efficacy;Preclinical Safety;Public Health Medicine (Field);Research Study;Resistant;Success

Funding of this application will move a new combination cancer therapy for leukemia and lymphomas towards human clinical trials. Monoclonal antibodies, "mAbs" have emerged as a rapidly growing class of oncology therapeutics. Despite their success in certain clinical applications, the therapeutic efficacy of mAbs is limited, with only a minority of patients responding to these agents as therapies on their own. It is becoming clear that many tumors evade successful elimination by co-opting the body's own immune regulatory systems. These same mechanisms also reduce the anti-cancer effects of mAbs. We are developing a molecule that addresses one of these key mechanisms that improves the therapeutic effects of mAbs by: 1) increasing sensitivity of cancers to treatment; 2) unmasking resistant cancers so they again become sensitized; and 3) possibly allowing treatment of cancers that have become refractory to therapy. This could make mAb therapy more effective, and potentially reduce the amounts of mAbs required for treatment, thus reducing costs and potential side effects. The public health implications of improving rituximab treatment are significant. There are over 300,000 patients with non-Hodgkins lymphoma (NHL), and the majority receives treatment with rituximab either alone or combined with chemotherapy. Many patients develop recurrent diseases, and 5-year survival rates for NHL is 63%. In most cases of tumor recurrence, patients develop resistance to rituximab therapy. The immediate goal of the research is to collect data to enable an Investigational New Drug (IND) filing on a combination therapy for lymphoma. Our consultant at the University of Washington has collected a significant body of information supporting the superiority of the combination of depleting CD46 on the cell surface with antibody therapy in blood cancers Our long-term goal is to translate the technology from research bench to clinical bedside leading to enhancement of monoclonal antibody (mAb) therapy.

Public Health Relevance Statement:


Public Health Relevance:
Although monoclonal antibody therapy can be an effective way to treat cancer, further progress is needed to increase therapeutic success. We intend to enhance cancer therapy to improve treatment worldwide.

Project Terms:
Address; Advanced Development; Adverse effects; Antibody Therapy; Biological Assay; cancer therapy; CD46 Antigen; cell bank; cell killing; Cell Line; Cell surface; Cells; chemotherapy; Clinical; clinical application; Clinical Research; Clinical Trials; Clinical Trials Design; combination cancer therapy; Combined Modality Therapy; Complement; cost; Cyclic GMP; Data; Development; Dose; Enhancing Antibodies; Feedback; Fund Raising; Funding; Funding Applicant; Future; Goals; Grant; Hematopoietic Neoplasms; Human; Immune; improved; in vivo; Investigational Drugs; leukemia/lymphoma; Licensing; Licensure; Lymphoma; Malignant Neoplasms; meetings; Minority; Modeling; Monoclonal Antibodies; Monoclonal Antibody CD20; Monoclonal Antibody Therapy; MS4A1 gene; Mus; Non-Hodgkin's Lymphoma; nonhuman primate; oncology; Patients; Peripheral; Phase; preclinical study; Process; Production; programs; Proteins; public health medicine (field); public health relevance; Published Comment; Qualifying; Recombinant Proteins; Recurrence; Recurrent disease; Refractory; Reporting; Research; research clinical testing; Resistance; Resistance development; rituximab; Small Business Innovation Research Grant; success; Survival Rate; System; Technology; Testing; Therapeutic; Therapeutic Effect; Toxicology; Transgenic Mice; Translating; Treatment Efficacy; Treatment outcome; tumor; Universities; Washington; Work