SBIR-STTR Award

Accurate and timely detection of circulating autoantibodies against pancreatic islet antigens is critical to both research and clinical care for patients with type 1 diabetes (T1D). However this measurement remains highly variable across commercially available assays, and such assays also may not adequately detect particularly low but clinically relevant levels of circulating autoantibodies. This deficit translates into missed opportunities for both the timely initiation of the most appropriate treatment regimens and to support much needed research into novel and improved disease-modifying interventions. Additionally, large-scale public health screening efforts for T1D are hampered by the low throughput nature of current bioassays, and/or their requirement for expensive and specialized instrumentation. We have developed a proprietary patent-pending PCR-based technology termed Antibody Detection by Agglutination-PCR (ADAP). ADAP is a high-throughput assay that can be used for simultaneous detection of multiple antibodies while requiring only a very small amount of patient serum (2 ?L). ADAP also detects autoantibodies with 1,000 to 10,000 times greater sensitivity than the currently used immunometric and radio-immuno assays, and can be readily integrated into common quantitative PCR (qPCR) workflows using pre-existing instrumentation that is available at many hospitals, clinics and public health screening sites. Importantly, ADAP represents a significant departure from less effective PCR-driven platforms such as immuno-PCR, overcoming many of the deficits inherent to this class of assays to afford a high-throughput, ultrasensitive, robust, reliable, and specific detection method. In this Phase 1 application, we propose to develop an ADAP-based assay kit for detection of the four autoantibodies that form the basis for T1D diagnosis. The corresponding GAD65, IA-2, insulin, and ZnT8 antigens will be barcoded by conjugation to unique single-stranded DNA sequences. Agglutination of an antigen upon incubation with its cognate antibody brings the DNA sequences near to each other. An appropriate “bridge oligo” is then supplied which, upon ligation, affords an amplifiable DNA duplex. This antigen-autoantibody binding event provides a PCR amplicon that enables ultrasensitive detection with minimal background signal. Next we will use these appropriately validated reagents for analysis of patient serum samples in the context of T1D, both before and after diagnosis. Finally, it is increasingly appreciated that high-affinity autoantibodies are privileged indicators of disease severity. In anticipation of the diagnostic value of this new finding, we also propose to create an innovative variant of the ADAP assay which we term ?ADAP to enable high throughput quantification of high-affinity autoantibodies. Deployment of such an assay may allow more accurate determination of T1D prognosis, and enable improved choices of therapeutic interventions. In summary, we seek to establish the ADAP T1D assay kit not only as an effective alternative to current T1D diagnostic platforms, but one with significantly expanded capabilities in terms of sensitivity, speed, reproducibility and multiplexability that can be cost-effectively integrated into existing laboratory and clinical workflows.

Public Health Relevance Statement:
PROJECT NARRATIVE 70-80% of individuals newly diagnosed with type 1 diabetes (T1D) have no affected relatives, and this disease remains the most common form of diabetes affecting children – resulting in serious and often life-threatening problems if the disease is not diagnosed and treated effectively in a timely manner. The current tests for T1D are costly and difficult to perform, and are therefore not suitable for large-scale public health screening of neonates and those with affected first-degree relatives. We propose to develop a new method of detection that we call ADAP which is inexpensive, fast, 1,000 to 10,000 times more sensitive than existing methods and be easily performed on-site in hospitals, clinics and public health screening sites using existing equipment.

NIH Spending Category:
Autoimmune Disease; Biotechnology; Diabetes; Pediatric

Project Terms:
Affect; Affinity; Agglutination; Antibodies; Antigens; Autoantibodies; Autoimmune Diseases; base; Binding; Biological Assay; Child; Clinical; clinical care; clinically relevant; Clinics and Hospitals; cost; Data; Detection; Development; Diabetes autoantibodies; Diabetes Mellitus; Diagnosis; Diagnostic; Diagnostic Sensitivity; Diagnostic Specificity; Disease; Disease Management; DNA; DNA Sequence; Early Diagnosis; Effectiveness; Equipment; Evaluation; Event; First Degree Relative; Gold; head-to-head comparison; high throughput screening; improved; Individual; innovation; instrumentation; Insulin; Insulin-Dependent Diabetes Mellitus; Intervention; Islets of Langerhans; Laboratories; Legal patent; Life; Ligation; Link; Measurement; Methods; Monitor; multiplex detection; Nature; neonate; Newly Diagnosed; novel; Oligonucleotides; Onset of illness; Outcome; outcome forecast; Patients; Phase; Plasma; Preparation; prognostic value; Public Health; Radio; Reagent; Reproducibility; Research; Sampling; screening; Serum; Severity of illness; Signal Transduction; Single-Stranded DNA; Site; Solid; Source; Speed; Statistical Data Interpretation; Statistical Models; Technology; Testing; Therapeutic Intervention; Time; tool; Translating; Treatment Protocols; Validation; Variant; Vendor

Type 1 diabetes (T1D) is a devastating autoimmune disease that destroys islet-cell insulin production. Millions of Americans, especially children, are affected and must rely on lifelong insulin administration and struggle with life-threatening co-morbidities. Most new cases of T1D are diagnosed in emergency settings with presentation in potentially deadly diabetic ketoacidosis (DKA). Current pre-clinical diagnostic tests that can permit preventive action for T1D are slow and not readily available outside of tertiary care centers. In this proposal Enable Biosciences will further develop and validate a novel low-cost and high-throughput immunoassay to rapidly and sensitively screen for the four cardinal autoantibody markers that predict risk for type 1 diabetes. Such a test could supplant the current expensive, slow radioactive method. By reducing costs while retaining sensitivity and specificity with a robust very low-sample volume assay, Enable Biosciences' product will permit increased testing to reveal incipient T1D in the general population at the optimal time for intervention. During the Phase I funding period, Enable prototyped a 3-member T1D autoantibody panel using their core Antibody Detection by Agglutination-PCR (ADAP) technology and demonstrated substantial equivalence with the gold-standard assay while removing reliance on radioactive reagents. In this Phase 2 proposal, Enable presents a comprehensive plan to enhance this panel via automation using a dedicated robotic liquid handling system, greatly increasing assay throughput and reliability while further reducing costs. We will also adapt our assay chemistry to be able to use Taqman probes. This will result in further throughput acceleration and cost reductions. Building upon promising preliminary results from Phase 1 work, we will incorporate the fourth and final T1D autoantibody (ZnT8) to create the world's first ever ?4-in-1? screening panel, creating a product that provides the highest level of risk assessment for T1D screening and diagnosis. These optimized and automated panels will then be rigorously validated with thousands of clinical samples provided by our wide network of enthusiastic academic and institutional partners that include the Joslin Diabetes Center, Stanford School of Medicine, the T1D Exchange and Tufts Children's Hospital. This data will be used to plan and direct commercialization efforts that will include a phased approach from delivering a CLIA-certified laboratory service to FDA-approved reagent kits with companion integrated sample-to-answer hardware devices for easy, low-skill use and deployment across research and clinical laboratories and screening sites worldwide.

Thesaurus Terms:
Acceleration; Affect; Agglutination; Agreement; American; Antibodies; Autoantibodies; Autoimmune Diseases; Autoimmunity; Automation; Base; Beta Cell; Biobank; Biological Assay; Biological Sciences; Cessation Of Life; Chemistry; Child; Clia Certified; Clinical; Clinical Diagnostics; Cohort; Color; Commercialization; Comorbidity; Companions; Consumption; Cost; Data; Decentralization; Design; Detection; Development; Devices; Diabetes Autoantibodies; Diabetes Control; Diabetes Mellitus; Diabetic Ketoacidosis; Diagnosis; Diagnostic Tests; Disease; Dna; Dna Probes; Dna Sequence; Early Diagnosis; Emergency Settings; Fda Approved; Fluorophore; Funding; General Population; Gold; Hemoglobin; Immunoassay; Improved; Insulin; Insulin-Dependent Diabetes Mellitus; Intervention; Islet Cell; Islet Cell Antibody; Laboratories; Life; Lipids; Liquid Substance; Manuals; Manufacturing Process; Medical Schools; Member; Methods; Monoclonal Antibodies; Novel; Output; Patients; Pediatric Hospitals; Phase; Population; Pre-Clinical; Predictive Marker; Prevent; Preventive; Procedures; Process; Production; Prototype; Quality Assurance; Quality Control; Radioactive; Radioimmunoassay; Reagent; Reproducibility; Research; Resources; Risk; Risk Assessment; Robotics; Sampling; Screening; Screening Panel; Sensitivity And Specificity; Serum; Services; Site; Skills; Software Development; Source; System; Technology; Tertiary Care; Test Result; Testing; Therapeutic; Time; Validation; Variant; Work;