Browsing by Author "Crannell, Zachary Austin"

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    A Nucleic Acid Test to Diagnose Cryptosporidiosis: Lab Assessment in Animal and Patient Specimens
    (American Chemical Society, 2014) Crannell, Zachary Austin; Castellanos-Gonzalez, Alejandro; Irani, Ayesha; Rohrman, Brittany; White, Arthur Clinton; Richards-Kortum, Rebecca
    Diarrheal diseases cause more morbidity and mortality around the world than HIV, malaria or tuberculosis. Given that effective treatment of persistent diarrheal illness requires knowledge of the causative organism, diagnostic tests are of paramount importance. The protozoan parasites of the genus Cryptosporidium are increasingly recognized to be responsible for a significant portion of diarrhea morbidity. We present a novel nucleic acid test to detect the presence of Cryptosporidium species in DNA extracted from stool samples. The assay uses the isothermal amplification technique Recombinase Polymerase Amplification (RPA) to amplify trace amounts of pathogen DNA extracted from stool to detectable levels in 30 minutes; products are then detected visually on simple lateral flow strips. The RPA-based Cryptosporidium assay (RPAC assay) was developed and optimized using DNA from human stool samples spiked with pathogen. It was then tested using DNA extracted from the stool of infected mice where it correctly identified the presence or absence of 27 out of 28 stool samples. It was finally tested using DNA extracted from the stool of infected patients where it correctly identified the presence or absence of 21 out of 21 stool samples. The assay was integrated into a foldable, paper and plastic device that enables DNA amplification with only the use of pipettes, pipette tips, and a heater. The performance of the integrated assay is comparable to or better than PCR, without requiring the use of thermal cycling equipment. This platform can easily be adapted to detect DNA from multiple pathogens.
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    Equipment-Free Incubation of Recombinase Polymerase Amplification Reactions Using Body Heat
    (Public Library of Science, 2014) Crannell, Zachary Austin; Rohrman, Brittany; Richards-Kortum, Rebecca
    The development of isothermal amplification platforms for nucleic acid detection has the potential to increase access to molecular diagnostics in low resource settings; however, simple, low-cost methods for heating samples are required to perform reactions. In this study, we demonstrated that human body heat may be harnessed to incubate recombinase polymerase amplification (RPA) reactions for isothermal amplification of HIV-1 DNA. After measuring the temperature of mock reactions at 4 body locations, the axilla was chosen as the ideal site for comfortable, convenient incubation. Using commonly available materials, 3 methods for securing RPA reactions to the body were characterized. Finally, RPA reactions were incubated using body heat while control RPA reactions were incubated in a heat block. At room temperature, all reactions with 10 copies of HIV-1 DNA and 90% of reactions with 100 copies of HIV-1 DNA tested positive when incubated with body heat. In a cold room with an ambient temperature of 10 degrees Celsius, all reactions containing 10 copies or 100 copies of HIV-1 DNA tested positive when incubated with body heat. These results suggest that human body heat may provide an extremely low-cost solution for incubating RPA reactions in low resource settings.
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    Quantification of HIV-1 DNA using Real-Time Recombinase Polymerase Amplification
    (American Chemical Society, 2014) Crannell, Zachary Austin; Rohrman, Brittany; Richards-Kortum, Rebecca
    Although recombinase polymerase amplification (RPA) has many advantages for the detection of pathogenic nucleic acids in point-of-care applications, RPA has not yet been applied for has not yet been implemented to quantify sample concentration using a standard curve. Here we describe a real-time RPA assay with an internal positive control and an algorithm that analyzes the real-time fluorescence data to quantify HIV-1 DNA. We show that DNA concentration and the onset of detectable amplification are correlated by an exponential standard curve. In a set of experiments in which the standard curve and algorithm were used to analyze and quantify additional DNA samples, the algorithm predicted an average concentration within one order of magnitude of the correct concentration for all HIV-1 DNA concentrations tested. These results suggest that qRPA may serve as a powerful tool for quantifying nucleic acids and may be adapted for use in single-sample point-of-care diagnostic systems.