SBIR-STTR Award

Communicable diseases claim the lives of 29% of world's population and more than 15 million persons die as a result of bacterial and fungal diseases every year. Timely and accurate diagnosis can reduce debilitation and save lives, and nucleic acid testing (NAT) of biomedical samples is a powerful method for identifying microorganisms that can return results in just a few hours (or faster). However, NAT-based diagnostics have repeatedly failed to displace traditional tests that can take several days (or more) to deliver a definitive diagnosis. Diagnostic assays need to meet exacting standards of sensitivity, specificity, and repeatability; and for NAT- tests, the initial step of efficiently extracting high-quality nucleic acids is critical. Unfortunately, life-threatening diseases such as bloodstream infections and tuberculous meningitis often produce clinical samples with pathogen concentrations as low as 1 colony-forming unit per milliliter. Notably, Mycobacterium tuberculosis, the organism that causes TB, is notoriously difficult to lyse. In fact, many gram-positive bacteria, viruses and fungi are hard to break open using conventional approaches and, in roughly half of patients with bloodstream infections, the causative microbe falls into one of these categories. Physical and mechanical approaches used to improve microbial lysis efficiencies include bead beating, high-pressure homogenization, direct or indirect sonication, and freeze-thawing/boiling. These techniques commonly achieve only moderate success despite their need for specialized and expensive equipment or materials, making them unsuitable for routine point-of- care diagnostics. Indirect sonication - which works by initiating the formation and collapse of microscopic bubbles (a process called cavitation) - offers multiple benefits compared to alternative lysis methods including reduced cost and contamination, ease of use, and being scalable for portability. Nonetheless, like other approaches, indirect sonication struggles to achieve consistently high yields of nucleic acids from resilient microbes without sacrificing quality. Triangle Biotechnology is developing novel and proprietary sonication reagents that substantially improve the efficiency of nucleic acid extraction by reducing the acoustic energy required for cavitation. This Phase I SBIR will establish a proof-of-concept for our reagent-assisted sonication technology by identifying conditions that maximize microbial lysis efficiency (Aim 1) and demonstrating improved NAT results from DNA extracted using our approach compared to traditional methods (Aim 2). The non- pathogenic target microorganisms, M. smegmatis, E. faecalis, and B. subtilis are commonly used models for pathogenic mycobacteria, Gram-positive bacteria, and spore-forming bacteria that threaten public health and safety. The data collected in this project will provide the foundation for Phase II studies to validate our platform technology by establishing high sensitivity (low limits of detection) for multiple resilient microbes using NAT methods. Triangle's long-term objective is to productize the technology in the form of a kit (reagents, buffers) and integrate the platform with emerging applications for small and portable sonication devices, beginning with the generation of optimized protocols for use of the kit with existing, low-cost sonicators.

Public Health Relevance Statement:
Narrative Bacterial and fungal diseases claim 15 million lives every year, but timely and accurate diagnosis can reduce debilitating illness and save lives. Nucleic acid testing (NAT) of biomedical samples can identify microorganisms in just a few hours (or faster), but have repeatedly failed to displace traditional tests that can take days or weeks to deliver results. Triangle Biotechnology, Inc. is developing a technology to make the nucleic acids of hard-to- lyse microbes more accessible, both physically and economically, thereby eliminating key obstacles to the broad adoption of NAT-based diagnostics.

Project Terms:
Acoustics; Acoustic; Adoption; Affect; Bacillus subtilis; B subtilis; B. subtilis; Bacteria; Biological Sciences; Biologic Sciences; Bioscience; Life Sciences; Biotechnology; Biotech; Buffers; Cell Wall; Cells; Cell Body; Clinical Research; Clinical Study; Communicable Diseases; Infectious Disease Pathway; Infectious Diseases; Infectious Disorder; Diagnosis; Disease; Disorder; DNA; Deoxyribonucleic Acid; Bacterial DNA; Recombinant DNA; Recombinant DNA Molecular Biology; rDNA; Equipment; Fluorometry; Foundations; Freezing; fungus; Genes; Gram-Positive Bacteria; Human; Modern Man; Lead; Pb element; heavy metal Pb; heavy metal lead; Methods; Methodology; Genus Mycobacterium; Mycobacterium; Mycobacterium tuberculosis; M tb; M tuberculosis; M. tb; M. tuberculosis; mtb; Persons; Nucleic Acids; Organism; living system; Patients; pressure; Public Health; Reagent; Safety; Sensitivity and Specificity; Sonication; Reproduction spores; Spores; Enterococcus faecalis; E faecalis; E. faecalis; S faecalis; S. faecalis; Streptococcus Group D; Streptococcus faecalis; Technology; Testing; Time; Meningeal Tuberculosis; Tuberculosis Meningitis; Tuberculous Meningitis; Vagina; Vaginal; Virus; Work; Yeasts; Generations; Measures; falls; base; improved; Nucleic Acid Testing; Nucleic Acid Amplification Tests; Capillary Electrophoresis Fractionation; Capillary Electrophoresis; Clinical; Microscopic; Phase; Biological; Medical; Chemicals; Susceptibility; Predisposition; M smegmatis; M. smegmatis; Mycobacterium smegmatis; Diagnostic; Life; DNA Fragmentation; mechanical; Mechanics; Hour; milliliter; Protocol; Protocols documentation; microorganism; Techniques; Test Result; Colony-forming units; success; Accuracy of Diagnosis; diagnostic accuracy; microbial; Base Pairing; novel; Categories; Devices; Modeling; Sampling; portability; Pathogenicity; Lysis; Cytolysis; Thickness; Thick; Effectiveness; Address; Data; Detection; Diagnostic Sensitivity; Diagnostics Research; Molecular Target; Reproducibility; SBIR; Small Business Innovation Research; Small Business Innovation Research Grant; Process; microbiome; cost; nano droplet; nanoDroplet; blood infection; bloodstream infection; Sepsis; pathogen; Population; innovate; innovative; innovation; resistant; Resistance; community microbes; microbial community; Microbe; therapeutic agent development; therapeutic development; point-of-care diagnostics; phase II study; phase 2 study; NGS Method; NGS system; next gen sequencing; nextgen sequencing; next generation sequencing; accurate diagnosis; diagnostic assay; Formulation; microbial consortia; microbial flora; microflora; multispecies consortia; microbiota; preservation; bacterial community

Infectious diseases are a leading cause of global morbidity and mortality, accounting for 29% of worldwide deaths. Next-generation sequencing (NGS) is a useful tool in pathogen detection, strain identification, and drug susceptibility testing (among other applications). A primary issue for NGS for rapid pathogen genomic analysis is that raw patient samples typically have a low bacterial load, requiring culturing that can take weeks to months before a sufficient microbial load is generated. However, culturing is economically and logistically unsustainable and presents with other biological issues that may confound results. Additionally, enrichment of the pathogen- specific genes is highly dependent on sample extraction efficiency. Using nucleic acid testing (NAT) and NGS methods, efficient DNA extraction is essential for the successful and accurate identification of microorganisms or populations of microbes. Poor DNA extraction when analyzing clinical and environmental samples consisting of resilient microbes leads to inconclusive or inaccurate diagnostic results. There is a need for high-efficiency extraction of nucleic acids from hard-to-lyse microorganisms in direct patient samples to facilitate reliable clinical diagnostic workflows. Triangle Biotechnology (Triangle Bio) is developing a novel and proprietary technology for efficient, high-throughput, reproducible, and unbiased microbial lysis, based on a cavitation-enhancing nanodroplet reagent for use with low-cost sonication devices. The proposed nanodroplets preferentially target to microbes with resilient cell walls and deliver focused mechanical shear forces. In Phase I, Triangle Bio demonstrated a 6-100x and 2-5x improvement in DNA extraction from Mycobacterium smegmatis (a model for Mycobacterium tuberculosis [Mtb]) and Enterococcus faecalis (a Gram- positive bacteria), respectively, compared to commonly used commercial kits. In Phase II, the company will establish a platform of nanodroplet formulations applicable to a wide range of infectious pathogens with significant clinical impact. Triangle Bio will accomplish this research through the following three aims: 1) Identify targeting ligand candidates compatible with 12 representative microbial species and three clinical sample matrices (Y1), 2) Validate binding and cavitation performance of candidate formulations and optimize workflow conditions for clinical sample matrices spiked with four target microbial species (Y2-Y3), and 3) Evaluate workflows by demonstrating improved performance of targeted NGS for diagnosis of drug-resistant Mtb (Y3). Successful implementation of this technology could have significant impacts on a wide range of applications requiring reliable microbial lysis techniques, including but not limited to NGS for infectious disease detection and diagnosis, NGS based food safety testing for infectious pathogens, and clinical and environmental microbiome studies where resilient microbes can be underrepresented in metagenomic analysis.

Public Health Relevance Statement:
Narrative There is a growing need to improve next-generation sequencing (NGS) techniques for applications such as pathogen detection, strain identification, and drug susceptibility testing. Triangle Biotechnology is developing a novel lysis technology that drastically improves DNA extraction from lysis-resistant infectious pathogens, a current bottleneck in NGS workflows. The integration of this technology with in-vitro diagnostic platforms will assist in alleviating the public health burden of infectious diseases.

Project Terms:
Accounting; Acoustics; Acoustic; Antibodies; Bacteria; Biological Assay; Assay; Bioassay; Biologic Assays; Biotechnology; Biotech; Blood; Blood Reticuloendothelial System; California; Candida albicans; C albicans; C. albicans; C.albicans; Cell Nucleus; Nucleus; Cell Wall; Cells; Cell Body; Communicable Diseases; Infectious Disease Pathway; Infectious Diseases; Infectious Disorder; Communities; Cessation of life; Death; Diagnosis; DNA; Deoxyribonucleic Acid; Drug resistance; drug resistant; resistance to Drug; resistant to Drug; Pharmaceutical Preparations; Drugs; Medication; Pharmaceutic Preparations; drug/agent; Fluorometry; Foundations; Genes; Gram-Positive Bacteria; Health; Human; Modern Man; Lead; Pb element; heavy metal Pb; heavy metal lead; Lectin; Ligands; Methods; Methodology; Morbidity - disease rate; Morbidity; mortality; Genus Mycobacterium; Mycobacterium; Mycobacterium tuberculosis; M tb; M tuberculosis; M. tb; M. tuberculosis; mtb; Nucleic Acids; Patients; Peptides; Polymerase Chain Reaction; Public Health; Reagent; Research; Sonication; Sputum; statistics; E faecalis; E. faecalis; S faecalis; S. faecalis; Streptococcus Group D; Streptococcus faecalis; Enterococcus faecalis; Technology; Testing; Universities; Urine; Urine Urinary System; Measures; base; improved; Nucleic Acid Amplification Tests; Nucleic Acid Testing; Clinical; Phase; Biological; biologic; Chemicals; Susceptibility; Predisposition; Logistics; A baumanni; A baumannii; A. baumanni; A. baumannii; A.baumannii; Acinetobacter baumanni; Acinetobacter baumannii; M smegmatis; M. smegmatis; Mycobacterium smegmatis; tool; Diagnostic; mechanical; Mechanics; Protocol; Protocols documentation; microorganism; Techniques; Performance; microbial; novel; Cell surface; Devices; Modeling; Sampling; Molecular Interaction; Binding; Lysis; Cytolysis; Thickness; Thick; Address; Food Safety; Detection; Diagnostic Sensitivity; Molecular Analysis; Molecular Diagnosis; Reproducibility; Ligand Binding; technology validation; technology implementation; Development; developmental; microbiome; cost; design; designing; nanoDroplet; nano droplet; pathogen; Population; direct application; innovation; innovate; innovative; Resistance; resistant; Microbe; Pathogen detection; clinically relevant; clinical relevance; drug testing; drug detection; Metagenomics; Functional Metagenomics; novel diagnostics; new diagnostics; next generation diagnostics; safety testing; next generation sequencing; NGS Method; NGS system; next gen sequencing; nextgen sequencing; screening; Formulation; mechanical force; clinical diagnostics; medical diagnostic; microbiome research; Microbiomics; microbiome science; microbiome studies; preservation; pathogen genomics; in-vitro diagnostics; diagnostic platform; diagnostic system; Tuberculosis diagnosis; TB diagnosis; Drug resistant Mycobacteria Tuberculosis; Drug resistance in Mtb; Drug resistance in Mycobacterium Tuberculosis; Drug resistant M Tuberculosis; Drug resistant Mtb; Mtb drug resistance; drug resistance M Tuberculosis; drug resistance Mycobacteria Tuberculosis; drug resistant M.tb