SBIR-STTR Award

The overall goal of this proposal is to develop an imaging agent and detection system for labeling and real- time detection of residual cancer in the tumor bed during sarcoma resection surgery that will be quickly adopted by surgeons/hospitals because it can eliminate or significantly reduce secondary surgeries and local recurrence. Failure to remove cancer cells during surgery is a leading risk factor for local tumor recurrence and subsequent reoperation. For 35% of sarcoma patients, limb-sparing surgery supported by frozen sections, which only analyze a small fraction of the resected tumor, results in local recurrence in the absence of adjuvant therapy, indicating microscopic residual cancer has been left behind. Furthermore, in other cancer surgeries, as in breast lumpectomies, positive margins and secondary surgeries can occur more than 50% of the time. Technology that can assess whether tumor cells have been adequately removed during surgery can have major impact on cancer therapy worldwide as more than two million people undergo cancer surgery every year. Such technology can reduce rates of local recurrence and eliminate the need for secondary surgeries and adjuvant radiation, reducing associated healthcare costs. Lumicell has developed an injectable imaging agent and hand-held imager that can detect single cells with a wide field of view. Our novel detection technology, developed at MIT and licensed to Lumicell, reliably detects microscopic residual cancer cells in vivo during sarcoma resection surgeries in mice. Based upon mouse and dog tests and using our computer simulation of the imaging agent performance we forecast a peak contrast in humans at 36-48 hours from injection. This timeframe is not ideal with the current preoperative procedures for cancer surgery and we wish to re-engineer the imaging agent to achieve the maximum tumor-to-background signal contrast within 18-24 hours from injection. We propose to re-design our cancer-activatable imaging agent with enhanced pharmacokinetics to rapidly reach the tumor and to increase clearance rates from the blood. To reach the level of signal that we believe can be achieved, we propose on Specific Aim 1 to engineer several designs of imaging agents and to characterize their performance in mice and dogs, and then simulate their performance in humans. On Specific Aim 2 we will select one or two candidate imaging agents with the desired performance between 18-24 hours after injection and conduct validation studies in mice (surgery and pathology).

Public Health Relevance:
The proposed project aims to address the unmet clinical need for intraoperative assessment of residual cancer cells in the tumor bed after gross tumor resection in cancer patients. A novel method for fast and thorough examination of the tumor bed in real-time will be developed by engineering an imaging agent suitable to for the typical hospital surgical protocols. This will require the refinement of the Lumicell molecular imaging agent design to achieve peak activation in 18-24 hours (current performance is 36-48 hours) from injection. This technology has the potential to save lives, prevent secondary surgeries, minimize patient discomfort and surgical risks, and provide substantial savings in healthcare costs.

Public Health Relevance Statement:
The proposed project aims to address the unmet clinical need for intraoperative assessment of residual cancer cells in the tumor bed after gross tumor resection in cancer patients. A novel method for fast and thorough examination of the tumor bed in real-time will be developed by engineering an imaging agent suitable to for the typical hospital surgical protocols. This will require the refinement of the Lumicell molecular imaging agent design to achieve peak activation in 18-24 hours (current performance is 36-48 hours) from injection. This technology has the potential to save lives, prevent secondary surgeries, minimize patient discomfort and surgical risks, and provide substantial savings in healthcare costs.

NIH Spending Category:
Bioengineering; Breast Cancer; Cancer; Nanotechnology; Patient Safety

Project Terms:
Academic Medical Centers; Address; Adjuvant; Adjuvant Therapy; Adopted; Affect; Amino Acid Sequence; base; Beds; Blinded; Blood; breast lumpectomy; cancer cell; Cancer Detection; cancer imaging; Cancer Patient; cancer surgery; cancer therapy; Canis familiaris; Cells; Clinical; Collaborations; Computer Simulation; Data; design; Detection; Development; Drug Formulations; Drug Kinetics; Engineering; Equipment; Excipients; Excision; Failure (biologic function); Fluorescence; fluorescence imaging; Frozen Sections; General Hospitals; Goals; Hand; Health Care Costs; Histopathology; Hospitals; Hour; Human; Image; Imaging Device; improved; in vivo; Injectable; Injection of therapeutic agent; Intervention; Investigational Drugs; Label; Left; Legal patent; Licensing; Limb structure; malignant breast neoplasm; Malignant Neoplasms; Massachusetts; mathematical model; Measurement; Measures; medical specialties; Metabolic Clearance Rate; Methods; Metric System; Microscopic; Molecular; molecular imaging; Mus; nanoparticle; neoplastic cell; novel; oncology; Operative Surgical Procedures; Orthopedics; Pathology; Patient Care; Patients; Performance; Phase; Predictive Value; Preoperative Procedure; Preparation; prevent; Proteins; Protocols documentation; Radiation; Recurrence; Repeat Surgery; Resected; Residual Cancers; Residual state; response; Risk; Risk Factors; sarcoma; Savings; Sensitivity and Specificity; Serum; Signal Transduction; Simulate; simulation; soft tissue; Specimen; Speed (motion); Surgeon; System; Techniques; Technology; Testing; Time; Tissues; tomography; Toxicology; tumor; Universities; Update; validation studies; Veterinary Schools

The overall goal of this application is to evaluate new imaging agents for (1) real-time detection of residual cancer in the tumor bed during surgery in primary colon and lung cancers in mice to eliminate or significantly reduce the need for repeat surgeries and local recurrence, and (2) guiding resection surgeries in canine patients with naturally occurring cancer. In a pilot study, we will also test our imaging technology to improve the detection of lesions during routine colonoscopy examination. Failure to remove cancer cells during surgery is a leading risk factor for local tumor recurrence and subsequent reoperation. Rates of secondary surgeries because of positive margins range between 10-50% depending on cancer type, grade and anatomical site. For colon cancer screening, many small lesions go undetected that are only found after progressing into malignant carcinomas. Furthermore, even for larger carcinomas, colonoscopy using white light will not identify these 22% of the time. Thus, a technology that can assess whether tumor cells have been adequately removed during surgery or can identify colon lesions with higher efficiency will have a major impact on cancer therapy worldwide as more than two million people undergo cancer surgery every year. During the SBIR Phase I work, Lumicell developed several imaging agents by using our novel mathematical model to predict their performance across species. The goal was to develop high-performance, lower cost imaging agents to satisfy the needs for colon cancer screening and eventually skin cancer surgeries. These imaging agents are based upon the design of our lead candidate for sarcoma and breast cancer indications, LUM015, which has been approved by the FDA to start first-in-human clinical trials with our clinical collaborators at Duke University Medical Center. Based upon modifications to LUM015, the new imaging agents cost about 66% less to manufacture with improved yields. After testing them in our baseline mouse model for breast cancer, these new agents proved equal or better performance than LUM015. A lower cost imaging agent is mandatory for entry into several of our new target markets and will be an additional offering for the other markets. For Phase II, we propose in Aims 1 and 2 to evaluate the performance of these imaging agents in state-of-the-art genetically engineered mouse models for lung cancer and colon cancer with our collaborators at Duke University and Massachusetts General Hospital. In Aim 3, we will move forward with the selected lead candidate (based upon results from Aims 1 and 2) into a veterinary clinical trial conducted at Duke/Veterinary Specialty Hospital of the Carolinas and Tufts University Cummings School of Veterinary Medicine. Canine patients suffering from any type of cancer will be recruited to evaluate the performance of the lead candidate in naturally occurring cancers. Aim 4 is focused on reaching the endpoint of this proposal: submit an IND to support a Phase I clinical trial for colon and lung cancer surgeries and colon cancer screening using our new lead candidate.

Public Health Relevance Statement:


Public Health Relevance:
The proposed project aims to address the unmet clinical need for intraoperative assessment of residual cancer cells in the tumor bed after tumor resection in colon and lung cancer patients, and to improve the efficacy of detecting small lesions during routine colonoscopy examinations. Lumicell has developed new imaging agents to address these needs that also reduce the cost by 66% over our original imaging agent. Their performance will be evaluated in mouse models for lung and colon cancer, and in naturally occurring cancers in canine patients before translating the technology for human use. A lower cost imaging agent is mandatory for entry into several of our new target markets and will be an additional offering for the other markets. This technology has the potential to save lives, prevent secondary surgeries, minimize patient discomfort and surgical risks, and provide substantial savings in healthcare costs.

NIH Spending Category:
Bioengineering; Breast Cancer; Cancer; Colo-Rectal Cancer; Digestive Diseases; Lung; Lung Cancer; Nanotechnology; Prevention

Project Terms:
Academic Medical Centers; Address; Adenocarcinoma; Animals; base; Beds; Biopsy; Breast Sarcoma; cancer cell; Cancer Detection; Cancer Patient; cancer surgery; cancer therapy; cancer type; Canis familiaris; Carcinoma; Cathepsins; Clinical; Clinical Research; Clinical Trials; Colon; Colon Carcinoma; Colonoscopy; Conduct Clinical Trials; cost; Data; Dermatologic; design; Detection; Development; Drug Kinetics; Dyes; Engineering; Excision; Failure (biologic function); FDA approved; General Hospitals; Genetically Engineered Mouse; Goals; Health Care Costs; Histocompatibility Testing; Histopathology; Hospitals; Human; Image; Imaging Device; Imaging technology; improved; intraoperative imaging; Label; Lead; Lesion; Light; Malignant - descriptor; malignant breast neoplasm; Malignant neoplasm of lung; Malignant Neoplasms; Marketing; Massachusetts; mathematical model; medical specialties; meetings; Metric; Modeling; Modification; Motivation; mouse model; Mus; nanoparticle; Neoplasm Metastasis; neoplastic cell; New Agents; Normal tissue morphology; novel; Operative Surgical Procedures; Patients; Performance; Phase; Phase I Clinical Trials; Pilot Projects; prevent; programs; public health relevance; Rattus; Recruitment Activity; Recurrence; Repeat Surgery; research study; Residual Cancers; Risk; Risk Factors; sarcoma; Savings; Schools; screening; Screening for Lung Cancer; Sensitivity and Specificity; Signal Transduction; Site; Skin Cancer; Small Business Innovation Research Grant; Surgical Pathology; Technology; Testing; Time; Toxic effect; Toxicity Tests; Toxicology; Translating; tumor; Tumor Tissue; Universities; Veterinary Medicine; Work