Your search keyword '"Corrin Graue"' showing total 3 results

1. Practical Comparison of the BioFire FilmArray Pneumonia Panel to Routine Diagnostic Methods and Potential Impact on Antimicrobial Stewardship in Adult Hospitalized Patients with Lower Respiratory Tract Infections

Author

Amanda T. Harrington, Amy Leber, Nathan A. Ledeboer, Joan-Miquel Balada-Llasat, Sukantha Chandrasekaran, Andrew Bonwit, Jennifer Dien Bard, Sam Windham, Del A Warren, Blake W. Buchan, Matthew L. Faron, Amanda Carroll, Corrin Graue, Shira Ronen, Christina Kwong, Romney M. Humphries, Shelley Campeau, Rebecca J. Buckner, Ryan F. Relich, Holly K. Huse, Amanda M. Hopp, Randal C. Fowler, Derya Mahmutoglu, Caitlin N. Murphy, Samia N. Naccache, Hannah Stone, Oluseun Akerele, Angela Huang, and Kathy Everhart

Subjects

Adult, Microbiology (medical), medicine.medical_specialty, Microbiological culture, medicine.drug_class, Antibiotics, Antimicrobial Stewardship, stewardship, Internal medicine, medicine, pneumonia, Humans, Antimicrobial stewardship, Respiratory Tract Infections, Respiratory tract infections, medicine.diagnostic_test, business.industry, medical outcomes, Medical record, Bacteriology, medicine.disease, Discontinuation, multiplex, Pneumonia, Bronchoalveolar lavage, Molecular Diagnostic Techniques, business, Multiplex Polymerase Chain Reaction

Abstract

Lower respiratory tract infections, including hospital-acquired and ventilator-associated pneumonia, are common in hospitalized patient populations. Standard methods frequently fail to identify the infectious etiology due to the polymicrobial nature of respiratory specimens and the necessity of ordering specific tests to identify viral agents. The potential severity of these infections combined with a failure to clearly identify the causative pathogen results in administration of empirical antibiotic agents based on clinical presentation and other risk factors., Lower respiratory tract infections, including hospital-acquired and ventilator-associated pneumonia, are common in hospitalized patient populations. Standard methods frequently fail to identify the infectious etiology due to the polymicrobial nature of respiratory specimens and the necessity of ordering specific tests to identify viral agents. The potential severity of these infections combined with a failure to clearly identify the causative pathogen results in administration of empirical antibiotic agents based on clinical presentation and other risk factors. We examined the impact of the multiplexed, semiquantitative BioFire FilmArray Pneumonia panel (PN panel) test on laboratory reporting for 259 adult inpatients submitting bronchoalveolar lavage (BAL) specimens for laboratory analysis. The PN panel demonstrated a combined 96.2% positive percent agreement (PPA) and 98.1% negative percent agreement (NPA) for the qualitative identification of 15 bacterial targets compared to routine bacterial culture. Semiquantitative values reported by the PN panel were frequently higher than values reported by culture, resulting in semiquantitative agreement (within the same log10 value) of 43.6% between the PN panel and culture; however, all bacterial targets reported as >105 CFU/ml in culture were reported as ≥105 genomic copies/ml by the PN panel. Viral targets were identified by the PN panel in 17.7% of specimens tested, of which 39.1% were detected in conjunction with a bacterial target. A review of patient medical records, including clinically prescribed antibiotics, revealed the potential for antibiotic adjustment in 70.7% of patients based on the PN panel result, including discontinuation or de-escalation in 48.2% of patients, resulting in an average savings of 6.2 antibiotic days/patient.

Published

2020

2. Multicenter Evaluation of the BioFire FilmArray Pneumonia/Pneumonia Plus Panel for Detection and Quantification of Agents of Lower Respiratory Tract Infection

Author

Jennifer Dien Bard, Andrew Bonwit, Blake W. Buchan, Sam Windham, Corrin Graue, Samia N. Naccache, Romney Humphries, Rebecca J. Buckner, Oluseun Akerele, Christina Kwong, Joan-Miquel Balada-Llasat, Cory Rindlisbacher, Angela Clark, Holly K. Huse, Ryan F. Relich, Shelly Campeau, Del A Warren, Cynthia Zimmerman, Amanda M. Hopp, Shira Ronen, Maggie Buccambuso, Amanda T. Harrington, Caitlin N. Murphy, Amanda Carroll, Barbara Jones, Randal C. Fowler, Suki Chandrasekaran, Amy Leber, Margarita Rogatcheva, Kevin M. Bourzac, Kathy Everhart, and Hanna Stone

Subjects

Microbiology (medical), medicine.medical_specialty, Atypical bacteria, respiratory pathogens, Sensitivity and Specificity, Lower respiratory tract infection, Internal medicine, respiratory viruses, medicine, Antimicrobial stewardship, Humans, Respiratory Tract Infections, Respiratory tract infections, medicine.diagnostic_test, business.industry, Bacteriology, Pneumonia, medicine.disease, Bronchoalveolar lavage, medicine.anatomical_structure, Molecular Diagnostic Techniques, Viruses, Sputum, syndromic panel, medicine.symptom, business, Multiplex Polymerase Chain Reaction, Respiratory tract

Abstract

The ability to provide timely identification of the causative agents of lower respiratory tract infections can promote better patient outcomes and support antimicrobial stewardship efforts. Current diagnostic testing options include culture, molecular testing, and antigen detection. These methods may require collection of various specimens, involve extensive sample treatment, and can suffer from low sensitivity and long turnaround times. This study assessed the performance of the BioFire FilmArray Pneumonia Panel (PN panel) and Pneumonia Plus Panel (PNplus panel), an FDA-cleared sample-to-answer assay that enables the detection of viruses, atypical bacteria, bacteria, and antimicrobial resistance marker genes from lower respiratory tract specimens (sputum and bronchoalveolar lavage [BAL] fluid)., The ability to provide timely identification of the causative agents of lower respiratory tract infections can promote better patient outcomes and support antimicrobial stewardship efforts. Current diagnostic testing options include culture, molecular testing, and antigen detection. These methods may require collection of various specimens, involve extensive sample treatment, and can suffer from low sensitivity and long turnaround times. This study assessed the performance of the BioFire FilmArray Pneumonia Panel (PN panel) and Pneumonia Plus Panel (PNplus panel), an FDA-cleared sample-to-answer assay that enables the detection of viruses, atypical bacteria, bacteria, and antimicrobial resistance marker genes from lower respiratory tract specimens (sputum and bronchoalveolar lavage [BAL] fluid). Semiquantitative results are also provided for the bacterial targets. This paper describes selected analytical and clinical studies that were conducted to evaluate performance of the panel for regulatory clearance. Prospectively collected respiratory specimens (846 BAL and 836 sputum specimens) evaluated with the PN panel were also tested by quantitative reference culture and molecular methods for comparison. The PN panel showed a sensitivity of 100% for 15/22 etiologic targets using BAL specimens and for 10/24 using sputum specimens. All other targets had sensitivities of ≥75% or were unable to be calculated due to low prevalence in the study population. Specificity for all targets was ≥87.2%, with many false-positive results compared to culture that were confirmed by alternative molecular methods. Appropriate adoption of this test could provide actionable diagnostic information that is anticipated to impact patient care and antimicrobial stewardship decisions.

Published

2020

3. 322. Evaluation of the BioFire® Bone and Joint Infection (BJI) Panel for the Detection of Microorganisms and Antimicrobial Resistance Genes in Synovial Fluid Specimens

Author

Corrin Graue, Bryan H Schmitt, Amy Waggoner, Frederic Laurent, Lelia Abad, Thomas Bauer, Irving Mazariegos, Joan-Miquel Balada-Llasat, Jarid Horn, Donna Wolk, Alexa Jefferis, Mirjam Hermans, Irma Verhoofstad, Susan Butler-Wu, Minette Umali-Wilcox, Caitlin N Murphy, Barbara J Cabrera, Jaime Esteban, Alicia Macias-Valcayo, David Craft, Benjamin von Bredow, Amy Leber, Kathy Everhart, Jennifer Dien Bard, Javier Mestas, Judy Daly, Rebecca Barr, Bart Kensinger, Benedicte Pons, and Corinne Jay

Subjects

business.industry, Microorganism, medicine.medical_treatment, Arthrocentesis, Knee Joint, Pathogenicity, Microbiology, AcademicSubjects/MED00290, Infectious Diseases, Oncology, Bsnd gene, Poster Abstracts, Antimicrobial resistance genes, Synovial fluid, Medicine, Anaerobic bacteria, business

Abstract

Background Bone and Joint Infections (BJIs) present with non-specific symptoms that may include pain, swelling, and fever and are associated with high morbidity and significant risk of mortality. BJIs can be caused by a variety of bacteria and fungi, including anaerobes and microorganisms that can be challenging to culture or identify by traditional microbiological methods. Clinicians primarily rely on culture to identify the pathogen(s) responsible for infection. The BioFire® Bone and Joint Infection (BJI) Panel (BioFire Diagnostics, Salt Lake City, UT) is designed to detect 15 gram-positive bacteria (including seven anaerobes), 14 gram-negative bacteria (including one anaerobe), two yeast, and eight antimicrobial resistance (AMR) genes from synovial fluid specimens in about an hour. The objective of this study was to evaluate the performance of an Investigational Use Only (IUO) version of the BioFire BJI Panel compared to various reference methods. Methods Remnant synovial fluid specimens, which were collected for routine clinical care at 13 study sites in the US and Europe, underwent testing using an IUO version of the BioFire BJI Panel. Performance of this test was determined by comparison to Standard of Care (SoC) consisting of bacterial culture performed at each study site according to their routine procedures. Results A total of 1544 synovial fluid specimens were collected and tested with the BioFire BJI Panel. The majority of specimens were from knee joints (77.9%) and arthrocentesis (79.4%) was the most common collection method. Compared to SoC culture, overall sensitivity was 90.2% and specificity was 99.8%. The BioFire BJI Panel yielded a total of 268 Detected results, whereas SoC yielded a total of 215 positive results for on-panel analytes. Conclusion The BioFire BJI Panel is a sensitive, specific, and robust test for rapid detection of a wide range of analytes in synovial fluid specimens. The number of microorganisms and resistance genes included in the BioFire BJI Panel, together with a reduced time-to-result and increased diagnostic yield compared to culture, is expected to aid in the timely diagnosis and appropriate management of BJIs. Disclosures Benjamin von Bredow, PhD, BioFire (Grant/Research Support) Jennifer Dien Bard, PhD, BioFire Diagnostic (Consultant, Scientific Research Study Investigator) Bart Kensinger, PhD, BioFire Diagnostics (Employee) Benedicte Pons, PhD, bioMerieux SA (Employee) Corinne Jay, PhD, bioMerieux SA (Employee)

Published

2020