Your search keyword '"Shaw, Bennett"' showing total 33 results

1. Clinical Whole-Genome Sequencing Assay for Rapid Mycobacterium tuberculosis Complex First-Line Drug Susceptibility Testing and Phylogenetic Relatedness Analysis.

Author

Shaw, Bennett, von Bredow, Benjamin, Tsan, Allison, Garner, Omai, and Yang, Shangxin

Subjects

Mycobacterium tuberculosis complex, clinical evaluation, drug susceptibility testing, phylogenetic relatedness analysis, whole-genome sequencing

Abstract

The global rise of drug resistant tuberculosis has highlighted the need for improved diagnostic technologies that provide rapid and reliable drug resistance results. Here, we develop and validate a whole genome sequencing (WGS)-based test for identification of mycobacterium tuberculosis complex (MTB) drug resistance to rifampin, isoniazid, pyrazinamide, ethambutol, and streptomycin. Through comparative analysis of drug resistance results from WGS-based testing and phenotypic drug susceptibility testing (DST) of 38 clinical MTB isolates from patients receiving care in Los Angeles, CA, we found an overall concordance between methods of 97.4% with equivalent performance across culture media. Critically, prospective analysis of 11 isolates showed that WGS-based testing provides results an average of 36 days faster than phenotypic culture-based methods. We showcase the additional benefits of WGS data by investigating a suspected laboratory contamination event and using phylogenetic analysis to search for cryptic local transmission, finding no evidence of community spread amongst our patient population in the past six years. WGS-based testing for MTB drug resistance has the potential to greatly improve diagnosis of drug resistant MTB by accelerating turnaround time while maintaining accuracy and providing additional benefits for infection control, lab safety, and public health applications.

Published

2023

2. Accurate subspecies-level identification of clinically significant Mycobacterium avium and Mycobacterium intracellulare by whole-genome sequencing

Author

Chawla, Rachit, Shaw, Bennett, von Bredow, Benjamin, Chong, Cathrine, Garner, Omai B, Zangwill, Kenneth M, and Yang, Shangxin

Subjects

Microbiology, Biological Sciences, Bioinformatics and Computational Biology, Genetics, Biotechnology, Lung, Infectious Diseases, Human Genome, Rare Diseases, 4.1 Discovery and preclinical testing of markers and technologies, 2.2 Factors relating to the physical environment, Infection, Good Health and Well Being, Animals, Humans, Mycobacterium avium Complex, Mycobacterium avium, Mycobacterium avium-intracellulare Infection, Paratuberculosis, Whole Genome Sequencing, Mycobacterium avium complex, Mycobacterium intracellulare, Whole-genome sequencing, Subspecies identification, rpoB, groEL, hsp65, Medical Microbiology

Abstract

Whole genome sequencing (WGS) of Mycobacterium avium complex (MAC) isolates in the clinical laboratory setting allows for rapid and reliable subspecies identification of a closely related complex of human pathogens. We developed a bioinformatics pipeline for accurate subspecies identification and tested 74 clinical MAC isolates from various anatomical sites. We demonstrate that reliable subspecies level identification of these common and clinically significant MAC isolates, including M. avium subsp. hominissuis (most dominant in causing lower respiratory tract infections in our cohort), M. avium subsp. avium, M. intracellulare subsp. intracellulare, and M. intracellulare subsp. chimaera, can be achieved by analysis of only two marker genes (rpoB and groEL/hsp65). We then explored the relationship between these subspecies and anatomical site of infection. Further, we conducted an in silico analysis and showed our algorithm also performed well for M. avium subsp. paratuberculosis but failed to consistently identify M. avium subsp. silvaticum and M. intracellulare subsp. yongonense, likely due to a lack of available reference genome sequences; all the 3 subspecies were not found in our clinical isolates and rarely reported to cause human infections. Accurate MAC subspecies identification may provide the tool and opportunity for better understanding of the disease-subspecies dynamics in MAC infections.

Published

2023

3. Multiplexed CRISPR-based microfluidic platform for clinical testing of respiratory viruses and identification of SARS-CoV-2 variants

Author

Welch, Nicole L., Zhu, Meilin, Hua, Catherine, Weller, Juliane, Mirhashemi, Marzieh Ezzaty, Nguyen, Tien G., Mantena, Sreekar, Bauer, Matthew R., Shaw, Bennett M., Ackerman, Cheri M., Thakku, Sri Gowtham, Tse, Megan W., Kehe, Jared, Uwera, Marie-Martine, Eversley, Jacqueline S., Bielwaski, Derek A., McGrath, Graham, Braidt, Joseph, Johnson, Jeremy, Cerrato, Felecia, Moreno, Gage K., Krasilnikova, Lydia A., Petros, Brittany A., Gionet, Gabrielle L., King, Ewa, Huard, Richard C., Jalbert, Samantha K., Cleary, Michael L., Fitzgerald, Nicholas A., Gabriel, Stacey B., Gallagher, Glen R., Smole, Sandra C., Madoff, Lawrence C., Brown, Catherine M., Keller, Matthew W., Wilson, Malania M., Kirby, Marie K., Barnes, John R., Park, Daniel J., Siddle, Katherine J., Happi, Christian T., Hung, Deborah T., Springer, Michael, MacInnis, Bronwyn L., Lemieux, Jacob E., Rosenberg, Eric, Branda, John A., Blainey, Paul C., Sabeti, Pardis C., and Myhrvold, Cameron

Published

2022

4. Synthetic DNA spike-ins (SDSIs) enable sample tracking and detection of inter-sample contamination in SARS-CoV-2 sequencing workflows

Author

Lagerborg, Kim A., Normandin, Erica, Bauer, Matthew R., Adams, Gordon, Figueroa, Katherine, Loreth, Christine, Gladden-Young, Adrianne, Shaw, Bennett M., Pearlman, Leah R., Berenzy, Daniel, Dewey, Hannah B., Kales, Susan, Dobbins, Sabrina T., Shenoy, Erica S., Hooper, David, Pierce, Virginia M., Zachary, Kimon C., Park, Daniel J., MacInnis, Bronwyn L., Tewhey, Ryan, Lemieux, Jacob E., Sabeti, Pardis C., Reilly, Steven K., and Siddle, Katherine J.

Published

2022

5. Intrathecal inflammatory responses in the absence of SARS-CoV-2 nucleic acid in the CSF of COVID-19 hospitalized patients

Author

Normandin, Erica, Holroyd, Kathryn B., Collens, Sarah I., Shaw, Bennett M., Siddle, Katherine J., Adams, Gordon, Rudy, Melissa, Solomon, Isaac H., Anahtar, Melis N., Lemieux, Jacob E., Trombetta, Bianca A., Kivisakk, Pia, Arnold, Steven E., Rapalino, Otto, Piantadosi, Anne L., Sen, Pritha, Rosenberg, Eric S., Branda, John, Sabeti, Pardis C., and Mukerji, Shibani S.

Published

2021

6. Author Correction: Multiplexed CRISPR-based microfluidic platform for clinical testing of respiratory viruses and identification of SARS-CoV-2 variants

Author

Welch, Nicole L., primary, Zhu, Meilin, additional, Hua, Catherine, additional, Weller, Juliane, additional, Mirhashemi, Marzieh Ezzaty, additional, Nguyen, Tien G., additional, Mantena, Sreekar, additional, Bauer, Matthew R., additional, Shaw, Bennett M., additional, Ackerman, Cheri M., additional, Thakku, Sri Gowtham, additional, Tse, Megan W., additional, Kehe, Jared, additional, Uwera, Marie-Martine, additional, Eversley, Jacqueline S., additional, Bielwaski, Derek A., additional, McGrath, Graham, additional, Braidt, Joseph, additional, Johnson, Jeremy, additional, Cerrato, Felecia, additional, Moreno, Gage K., additional, Krasilnikova, Lydia A., additional, Petros, Brittany A., additional, Gionet, Gabrielle L., additional, King, Ewa, additional, Huard, Richard C., additional, Jalbert, Samantha K., additional, Cleary, Michael L., additional, Fitzgerald, Nicholas A., additional, Gabriel, Stacey B., additional, Gallagher, Glen R., additional, Smole, Sandra C., additional, Madoff, Lawrence C., additional, Brown, Catherine M., additional, Keller, Matthew W., additional, Wilson, Malania M., additional, Kirby, Marie K., additional, Barnes, John R., additional, Park, Daniel J., additional, Siddle, Katherine J., additional, Happi, Christian T., additional, Hung, Deborah T., additional, Springer, Michael, additional, MacInnis, Bronwyn L., additional, Lemieux, Jacob E., additional, Rosenberg, Eric, additional, Branda, John A., additional, Blainey, Paul C., additional, Sabeti, Pardis C., additional, and Myhrvold, Cameron, additional

Published

2023

7. Streamlined inactivation, amplification, and Cas13-based detection of SARS-CoV-2

Author

Arizti-Sanz, Jon, Freije, Catherine A., Stanton, Alexandra C., Petros, Brittany A., Boehm, Chloe K., Siddiqui, Sameed, Shaw, Bennett M., Adams, Gordon, Kosoko-Thoroddsen, Tinna-Solveig F., Kemball, Molly E., Uwanibe, Jessica N., Ajogbasile, Fehintola V., Eromon, Philomena E., Gross, Robin, Wronka, Loni, Caviness, Katie, Hensley, Lisa E., Bergman, Nicholas H., MacInnis, Bronwyn L., Happi, Christian T., Lemieux, Jacob E., Sabeti, Pardis C., and Myhrvold, Cameron

Published

2020

8. Accurate subspecies-level identification of clinically significant Mycobacterium avium and Mycobacterium intracellulare by whole-genome sequencing

Author

Chawla, Rachit, primary, Shaw, Bennett, additional, von Bredow, Benjamin, additional, Chong, Cathrine, additional, Garner, Omai B., additional, Zangwill, Kenneth M., additional, and Yang, Shangxin, additional

Published

2023

9. Distinguishing Severe Acute Respiratory Syndrome Coronavirus 2 Persistence and Reinfection: A Retrospective Cohort Study

Author

Turbett, Sarah E, primary, Tomkins-Tinch, Christopher H, additional, Anahtar, Melis N, additional, Dugdale, Caitlin M, additional, Hyle, Emily P, additional, Shenoy, Erica S, additional, Shaw, Bennett, additional, Egbuonu, Kenechukwu, additional, Bowman, Kathryn A, additional, Zachary, Kimon C, additional, Adams, Gordon C, additional, Hooper, David C, additional, Ryan, Edward T, additional, LaRocque, Regina C, additional, Bassett, Ingrid V, additional, Triant, Virginia A, additional, Siddle, Katherine J, additional, Rosenberg, Eric, additional, Sabeti, Pardis C, additional, Schaffner, Stephen F, additional, MacInnis, Bronwyn L, additional, Lemieux, Jacob E, additional, and Charles, Richelle C, additional

Published

2022

10. Distinguishing Severe Acute Respiratory Syndrome Coronavirus 2 Persistence and Reinfection: A Retrospective Cohort Study.

Author

Turbett, Sarah E, Tomkins-Tinch, Christopher H, Anahtar, Melis N, Dugdale, Caitlin M, Hyle, Emily P, Shenoy, Erica S, Shaw, Bennett, Egbuonu, Kenechukwu, Bowman, Kathryn A, Zachary, Kimon C, Adams, Gordon C, Hooper, David C, Ryan, Edward T, LaRocque, Regina C, Bassett, Ingrid V, Triant, Virginia A, Siddle, Katherine J, Rosenberg, Eric, Sabeti, Pardis C, and Schaffner, Stephen F

Subjects

SARS-CoV-2, COVID-19, ACADEMIC medical centers, REINFECTION, RNA, RETROSPECTIVE studies, ACQUISITION of data, RISK assessment, GENOMES, MEDICAL records, DESCRIPTIVE statistics, GENETIC techniques, LONGITUDINAL method, NUCLEIC acid amplification techniques

Abstract

Background Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) reinfection is poorly understood, partly because few studies have systematically applied genomic analysis to distinguish reinfection from persistent RNA detection related to initial infection. We aimed to evaluate the characteristics of SARS-CoV-2 reinfection and persistent RNA detection using independent genomic, clinical, and laboratory assessments. Methods All individuals at a large academic medical center who underwent a SARS-CoV-2 nucleic acid amplification test (NAAT) ≥45 days after an initial positive test, with both tests between 14 March and 30 December 2020, were analyzed for potential reinfection. Inclusion criteria required having ≥2 positive NAATs collected ≥45 days apart with a cycle threshold (Ct) value <35 at repeat testing. For each included subject, likelihood of reinfection was assessed by viral genomic analysis of all available specimens with a Ct value <35, structured Ct trajectory criteria, and case-by-case review by infectious diseases physicians. Results Among 1569 individuals with repeat SARS-CoV-2 testing ≥45 days after an initial positive NAAT, 65 (4%) met cohort inclusion criteria. Viral genomic analysis characterized mutations present and was successful for 14/65 (22%) subjects. Six subjects had genomically supported reinfection, and 8 subjects had genomically supported persistent RNA detection. Compared to viral genomic analysis, clinical and laboratory assessments correctly distinguished reinfection from persistent RNA detection in 12/14 (86%) subjects but missed 2/6 (33%) genomically supported reinfections. Conclusions Despite good overall concordance with viral genomic analysis, clinical and Ct value-based assessments failed to identify 33% of genomically supported reinfections. Scaling-up genomic analysis for clinical use would improve detection of SARS-CoV-2 reinfections. [ABSTRACT FROM AUTHOR]

Published

2023

11. Intrathecal inflammatory responses in the absence of SARS-CoV-2 nucleic acid in the CSF of COVID-19 hospitalized patients (S18.004)

Author

Normandin, Erica, primary, Holroyd, Kathryn, additional, Collens, Sarah, additional, Shaw, Bennett, additional, Siddle, Katherine, additional, Adams, Gordon, additional, Rudy, Melissa, additional, Solomon, Isaac H., additional, Anahatar, Melis, additional, Lemieux, Jacob, additional, Trombetta, Bianca, additional, Webb, Pia K., additional, Arnold, Steven, additional, Rapalino, Otto, additional, Piantadosi, Anne, additional, Sen, Pritha, additional, Rosenberg, Eric, additional, Branda, John, additional, Sabeti, Pardis, additional, and Mukerji, Shibani, additional

Published

2022

12. Multiplexed CRISPR-based microfluidic platform for clinical testing of respiratory viruses and SARS-CoV-2 variants

Author

Welch, Nicole L, primary, Zhu, Meilin, additional, Hau, Catherine, additional, Weller, Juliane, additional, Ezzaty Mirhashemi, Marzieh, additional, Mantena, Sreekar, additional, Nguyen, Tien G, additional, Shaw, Bennett, additional, Ackerman, Cheri M, additional, Thakku, Sri Gowtham, additional, Tse, Megan W, additional, Kehe, Jared, additional, Bauer, Matthew R, additional, Uwera, Maria-Martine, additional, Eversley, Jacqueline S, additional, Bielawski, Derek A, additional, McGrath, Graham, additional, Braidt, Joseph, additional, Johnson, Jeremy, additional, Cerrato, Felecia, additional, Petros, Brittany A, additional, Gionet, Gabi L, additional, Jalbert, Samantha K, additional, Cleary, Michael L, additional, Siddle, Katherine J, additional, Happi, Christain T, additional, Hung, Deborah T, additional, Springer, Michael, additional, MacInnis, Bronwyn, additional, Lemieux, Jacob, additional, Rosenberg, Eric S, additional, Branda, John A, additional, Blainey, Paul C, additional, Sabeti, Pardis, additional, and Myhrvold, Cameron, additional

Published

2021

13. Synthetic DNA spike-ins (SDSIs) enable sample tracking and detection of inter-sample contamination in SARS-CoV-2 sequencing workflows

Author

Lagerborg, Kim A., primary, Normandin, Erica, additional, Bauer, Matthew R., additional, Adams, Gordon, additional, Figueroa, Katherine, additional, Loreth, Christine, additional, Gladden-Young, Adrianne, additional, Shaw, Bennett M., additional, Pearlman, Leah R., additional, Berenzy, Daniel, additional, Dewey, Hannah B., additional, Kales, Susan, additional, Dobbins, Sabrina T., additional, Shenoy, Erica S., additional, Hooper, David, additional, Pierce, Virginia M., additional, Zachary, Kimon C., additional, Park, Daniel J., additional, MacInnis, Bronwyn L., additional, Tewhey, Ryan, additional, Lemieux, Jacob E., additional, Sabeti, Pardis C., additional, Reilly, Steven K., additional, and Siddle, Katherine J., additional

Published

2021

14. Susceptibility-weighted imaging reveals cerebral microvascular injury in severe COVID-19

Author

Conklin, John, Frosch, Matthew P., Mukerji, Shibani S., Rapalino, Otto, Maher, Mary D., Schaefer, Pamela W., Lev, Michael H., Gonzalez, R.G., Das, Sudeshna, Champion, Samantha N., Magdamo, Colin, Sen, Pritha, Harrold, G. Kyle, Alabsi, Haitham, Normandin, Erica, Shaw, Bennett, Lemieux, Jacob E., Sabeti, Pardis C., Branda, John A., Brown, Emery N., Westover, M. Brandon, Huang, Susie Y., and Edlow, Brian L.

Published

2021

15. Determining the Incidence of Asymptomatic SARS-CoV-2 Among Early Recipients of COVID-19 Vaccines (DISCOVER-COVID-19): A Prospective Cohort Study of Healthcare Workers Before, During and After Vaccination

Author

North, Crystal M, primary, Barczak, Amy, additional, Goldstein, Robert H, additional, Healy, Brian C, additional, Finkelstein, Dianne M, additional, Ding, Delaney D, additional, Kim, Andy, additional, Boucau, Julie, additional, Shaw, Bennett, additional, Gilbert, Rebecca F, additional, Vyas, Tammy, additional, Reynolds, Zahra, additional, Siddle, Katherine J, additional, MacInnis, Bronwyn L, additional, Regan, James, additional, Flynn, James P, additional, Choudhary, Manish C, additional, Vyas, Jatin M, additional, Laskowski, Karl, additional, Dighe, Anand S, additional, Lemieux, Jacob E, additional, Li, Jonathan Z, additional, Baden, Lindsey R, additional, Siedner, Mark J, additional, Woolley, Ann E, additional, and Sacks, Chana A, additional

Published

2021

16. Susceptibility-weighted imaging reveals cerebral microvascular injury in severe COVID-19

Author

Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Conklin, John, Frosch, Matthew, Mukerji, Shibani S., Rapalino, Otto, Maher, Mary D., Schaefer, Pamela W., Lev, Michael H., Gonzalez, R.G., Das, Sudeshna, Champion, Samantha N., Magdamo, Colin, Sen, Pritha, Harrold, G. Kyle, Alabsi, Haitham, Normandin, Erica, Shaw, Bennett, Lemieux, Jacob E., Sabeti, Pardis, Branda, John A., Brown, Emery Neal, Westover, M Brandon, Huang, Susie Y., Edlow, Brian L., Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Conklin, John, Frosch, Matthew, Mukerji, Shibani S., Rapalino, Otto, Maher, Mary D., Schaefer, Pamela W., Lev, Michael H., Gonzalez, R.G., Das, Sudeshna, Champion, Samantha N., Magdamo, Colin, Sen, Pritha, Harrold, G. Kyle, Alabsi, Haitham, Normandin, Erica, Shaw, Bennett, Lemieux, Jacob E., Sabeti, Pardis, Branda, John A., Brown, Emery Neal, Westover, M Brandon, Huang, Susie Y., and Edlow, Brian L.

Abstract

We evaluated the incidence, distribution, and histopathologic correlates of microvascular brain lesions in patients with severe COVID-19. Sixteen consecutive patients admitted to the intensive care unit with severe COVID-19 undergoing brain MRI for evaluation of coma or neurologic deficits were retrospectively identified. Eleven patients had punctate susceptibility-weighted imaging (SWI) lesions in the subcortical and deep white matter, eight patients had >10 SWI lesions, and four patients had lesions involving the corpus callosum. The distribution of SWI lesions was similar to that seen in patients with hypoxic respiratory failure, sepsis, and disseminated intravascular coagulation. Brain autopsy in one patient revealed that SWI lesions corresponded to widespread microvascular injury, characterized by perivascular and parenchymal petechial hemorrhages and microscopic ischemic lesions. Collectively, these radiologic and histopathologic findings add to growing evidence that patients with severe COVID-19 are at risk for multifocal microvascular hemorrhagic and ischemic lesions in the subcortical and deep white matter., National Institute of Neurological Disorders and Stroke (Grants R21NS109627, R21AG067562, RF1NS115268), NIH Director’s Office (Grant DP2HD101400), NIH National Institute of Mental Health (Grant K23MH115812), NIH National Institutes of Allergy and Infectious Diseases (Grant 2U19AI110818)

Published

2021

17. Development of a qualitative real-time RT-PCR assay for the detection of SARS-CoV-2: a guide and case study in setting up an emergency-use, laboratory-developed molecular microbiological assay

Author

Anahtar, Melis N, primary, Shaw, Bennett M, additional, Slater, Damien, additional, Byrne, Elizabeth H, additional, Botti-Lodovico, Yolanda, additional, Adams, Gordon, additional, Schaffner, Stephen F, additional, Eversley, Jacqueline, additional, McGrath, Graham E G, additional, Gogakos, Tasos, additional, Lennerz, Jochen, additional, Marble, Hetal Desai, additional, Ritterhouse, Lauren L, additional, Batten, Julie M, additional, Georgantas, N Zeke, additional, Pellerin, Rebecca, additional, Signorelli, Sylvia, additional, Thierauf, Julia, additional, Kemball, Molly, additional, Happi, Christian, additional, Grant, Donald S, additional, Ndiaye, Daouda, additional, Siddle, Katherine J, additional, Mehta, Samar B, additional, Harris, Jason B, additional, Ryan, Edward T, additional, Pierce, Virginia M, additional, LaRocque, Regina C, additional, Lemieux, Jacob E, additional, Sabeti, Pardis C, additional, Rosenberg, Eric S, additional, Branda, John A, additional, and Turbett, Sarah E, additional

Published

2021

18. DNA spike-ins enable confident interpretation of SARS-CoV-2 genomic data from amplicon-based sequencing

Author

Lagerborg, Kim A., primary, Normandin, Erica, additional, Bauer, Matthew R., additional, Adams, Gordon, additional, Figueroa, Katherine, additional, Loreth, Christine, additional, Gladden-Young, Adrianne, additional, Shaw, Bennett, additional, Pearlman, Leah, additional, Shenoy, Erica S., additional, Hooper, David, additional, Pierce, Virginia M., additional, Zachary, Kimon C., additional, Park, Daniel J., additional, MacInnis, Bronwyn L., additional, Lemieux, Jacob E., additional, Sabeti, Pardis C., additional, Reilly, Steven K, additional, and Siddle, Katherine J., additional

Published

2021

19. Streamlined inactivation, amplification, and Cas13-based detection of SARS-CoV-2

Author

Harvard University--MIT Division of Health Sciences and Technology, Arizti-Sanz, Jon, Freije, Catherine A., Stanton, Alexandra C., Petros, Brittany A., Boehm, Chloe K., Siddiqui, Sameed, Shaw, Bennett M., Adams, Gordon, Kosoko-Thoroddsen, Tinna-Solveig F., Kemball, Molly E., Uwanibe, Jessica N., Ajogbasile, Fehintola V., Eromon, Philomena E., Gross, Robin, Wronka, Loni, Caviness, Katie, Hensley, Lisa E., Bergman, Nicholas H., MacInnis, Bronwyn L., Happi, Christian T., Lemieux, Jacob E., Sabeti, Pardis C., Myhrvold, Cameron, Harvard University--MIT Division of Health Sciences and Technology, Arizti-Sanz, Jon, Freije, Catherine A., Stanton, Alexandra C., Petros, Brittany A., Boehm, Chloe K., Siddiqui, Sameed, Shaw, Bennett M., Adams, Gordon, Kosoko-Thoroddsen, Tinna-Solveig F., Kemball, Molly E., Uwanibe, Jessica N., Ajogbasile, Fehintola V., Eromon, Philomena E., Gross, Robin, Wronka, Loni, Caviness, Katie, Hensley, Lisa E., Bergman, Nicholas H., MacInnis, Bronwyn L., Happi, Christian T., Lemieux, Jacob E., Sabeti, Pardis C., and Myhrvold, Cameron

Abstract

The COVID-19 pandemic has highlighted that new diagnostic technologies are essential for controlling disease transmission. Here, we develop SHINE (Streamlined Highlighting of Infections to Navigate Epidemics), a sensitive and specific diagnostic tool that can detect SARS-CoV-2 RNA from unextracted samples. We identify the optimal conditions to allow RPA-based amplification and Cas13-based detection to occur in a single step, simplifying assay preparation and reducing run-time. We improve HUDSON to rapidly inactivate viruses in nasopharyngeal swabs and saliva in 10 min. SHINE’s results can be visualized with an in-tube fluorescent readout — reducing contamination risk as amplification reaction tubes remain sealed — and interpreted by a companion smartphone application. We validate SHINE on 50 nasopharyngeal patient samples, demonstrating 90% sensitivity and 100% specificity compared to RT-qPCR with a sample-to-answer time of 50 min. SHINE has the potential to be used outside of hospitals and clinical laboratories, greatly enhancing diagnostic capabilities.

Published

2020

20. Phylogenetic analysis of SARS-CoV-2 in Boston highlights the impact of superspreading events

Author

Lemieux, Jacob E., primary, Siddle, Katherine J., additional, Shaw, Bennett M., additional, Loreth, Christine, additional, Schaffner, Stephen F., additional, Gladden-Young, Adrianne, additional, Adams, Gordon, additional, Fink, Timelia, additional, Tomkins-Tinch, Christopher H., additional, Krasilnikova, Lydia A., additional, DeRuff, Katherine C., additional, Rudy, Melissa, additional, Bauer, Matthew R., additional, Lagerborg, Kim A., additional, Normandin, Erica, additional, Chapman, Sinéad B., additional, Reilly, Steven K., additional, Anahtar, Melis N., additional, Lin, Aaron E., additional, Carter, Amber, additional, Myhrvold, Cameron, additional, Kemball, Molly E., additional, Chaluvadi, Sushma, additional, Cusick, Caroline, additional, Flowers, Katelyn, additional, Neumann, Anna, additional, Cerrato, Felecia, additional, Farhat, Maha, additional, Slater, Damien, additional, Harris, Jason B., additional, Branda, John A., additional, Hooper, David, additional, Gaeta, Jessie M., additional, Baggett, Travis P., additional, O’Connell, James, additional, Gnirke, Andreas, additional, Lieberman, Tami D., additional, Philippakis, Anthony, additional, Burns, Meagan, additional, Brown, Catherine M., additional, Luban, Jeremy, additional, Ryan, Edward T., additional, Turbett, Sarah E., additional, LaRocque, Regina C., additional, Hanage, William P., additional, Gallagher, Glen R., additional, Madoff, Lawrence C., additional, Smole, Sandra, additional, Pierce, Virginia M., additional, Rosenberg, Eric, additional, Sabeti, Pardis C., additional, Park, Daniel J., additional, and MacInnis, Bronwyn L., additional

Published

2021

21. Determining the Incidence of Asymptomatic SARS-CoV-2 Among Early Recipients of COVID-19 Vaccines (DISCOVER-COVID-19): A Prospective Cohort Study of Healthcare Workers Before, During and After Vaccination.

Author

North, Crystal M, Barczak, Amy, Goldstein, Robert H, Healy, Brian C, Finkelstein, Dianne M, Ding, Delaney D, Kim, Andy, Boucau, Julie, Shaw, Bennett, Gilbert, Rebecca F, Vyas, Tammy, Reynolds, Zahra, Siddle, Katherine J, MacInnis, Bronwyn L, Regan, James, Flynn, James P, Choudhary, Manish C, Vyas, Jatin M, Laskowski, Karl, and Dighe, Anand S

Subjects

COVID-19, IMMUNIZATION, CONFIDENCE intervals, COVID-19 vaccines, VIRAL load, RNA, SURVEYS, DESCRIPTIVE statistics, COVID-19 testing, DATA analysis software, LONGITUDINAL method

Abstract

The impact of coronavirus disease 2019 vaccination on viral characteristics of breakthrough infections is unknown. In this prospective cohort study, incidence of severe acute respiratory syndrome coronavirus 2 infection decreased following vaccination. Although asymptomatic positive tests were observed following vaccination, the higher cycle thresholds, repeat negative tests, and inability to culture virus raise questions about their clinical significance. [ABSTRACT FROM AUTHOR]

Published

2022

22. Development of a qualitative real-time RT-PCR assay for the detection of SARS-CoV-2: A guide and case study in setting up an emergency-use, laboratory-developed molecular assay

Author

Anahtar, Melis N., primary, Shaw, Bennett, additional, Slater, Damien, additional, Byrne, Elizabeth, additional, Botti-Lodovico, Yolanda, additional, Adams, Gordon, additional, Schaffner, Stephen, additional, Eversley, Jacqueline, additional, McGrath, Graham, additional, Gogakos, Tasos, additional, Lennerz, Jochen, additional, Marble, Hetal Desai, additional, Ritterhouse, Lauren L., additional, Batten, Julie, additional, Georgantas, N. Zeke, additional, Pellerin, Rebecca, additional, Signorelli, Sylvia, additional, Thierauf, Julia, additional, Kemball, Molly, additional, Happi, Christian, additional, Grant, Donald S., additional, Ndiaye, Daouda, additional, Siddle, Katherine J., additional, Mehta, Samar B., additional, Harris, Jason, additional, Ryan, Edward T., additional, Pierce, Virginia, additional, LaRocque, Regina, additional, Lemieux, Jacob E., additional, Sabeti, Pardis, additional, Rosenberg, Eric, additional, Branda, John, additional, and Turbett, Sarah E., additional

Published

2020

23. Phylogenetic analysis of SARS-CoV-2 in the Boston area highlights the role of recurrent importation and superspreading events

Author

Lemieux, Jacob E., primary, Siddle, Katherine J., additional, Shaw, Bennett M., additional, Loreth, Christine, additional, Schaffner, Stephen F., additional, Gladden-Young, Adrianne, additional, Adams, Gordon, additional, Fink, Timelia, additional, Tomkins-Tinch, Christopher H., additional, Krasilnikova, Lydia A., additional, DeRuff, Katherine C., additional, Rudy, Melissa, additional, Bauer, Matthew R., additional, Lagerborg, Kim A., additional, Normandin, Erica, additional, Chapman, Sinead B., additional, Reilly, Steven K., additional, Anahtar, Melis N., additional, Lin, Aaron E., additional, Carter, Amber, additional, Myhrvold, Cameron, additional, Kemball, Molly E., additional, Chaluvadi, Sushma, additional, Cusick, Caroline, additional, Flowers, Katelyn, additional, Neumann, Anna, additional, Cerrato, Felecia, additional, Farhat, Maha, additional, Slater, Damien, additional, Harris, Jason B., additional, Branda, John, additional, Hooper, David, additional, Gaeta, Jessie M., additional, Baggett, Travis P., additional, O’Connell, James, additional, Gnirke, Andreas, additional, Lieberman, Tami D., additional, Philippakis, Anthony, additional, Burns, Meagan, additional, Brown, Catherine M., additional, Luban, Jeremy, additional, Ryan, Edward T., additional, Turbett, Sarah E., additional, LaRocque, Regina C., additional, Hanage, William P., additional, Gallagher, Glen R., additional, Madoff, Lawrence C., additional, Smole, Sandra, additional, Pierce, Virginia M., additional, Rosenberg, Eric, additional, Sabeti, Pardis C., additional, Park, Daniel J., additional, and Maclnnis, Bronwyn L., additional

Published

2020

24. Cerebral Microvascular Injury in Severe COVID-19

Author

Conklin, John, primary, Frosch, Matthew P., additional, Mukerji, Shibani, additional, Rapalino, Otto, additional, Maher, Mary D., additional, Schaefer, Pamela W., additional, Lev, Michael H., additional, Gonzalez, R. G., additional, Das, Sudeshna, additional, Champion, Samantha N., additional, Magdamo, Colin, additional, Sen, Pritha, additional, Harrold, G. Kyle, additional, Alabsi, Haitham, additional, Normandin, Erica, additional, Shaw, Bennett, additional, Lemieux, Jacob E., additional, Sabeti, Pardis C., additional, Branda, John A., additional, Brown, Emery N., additional, Westover, M. Brandon, additional, Huang, Susie Y., additional, and Edlow, Brian L., additional

Published

2020

25. Integrated sample inactivation, amplification, and Cas13-based detection of SARS-CoV-2

Author

Arizti-Sanz, Jon, primary, Freije, Catherine A., additional, Stanton, Alexandra C., additional, Boehm, Chloe K., additional, Petros, Brittany A., additional, Siddiqui, Sameed, additional, Shaw, Bennett M., additional, Adams, Gordon, additional, Kosoko-Thoroddsen, Tinna-Solveig F., additional, Kemball, Molly E., additional, Gross, Robin, additional, Wronka, Loni, additional, Caviness, Katie, additional, Hensley, Lisa E., additional, Bergman, Nicholas H., additional, MacInnis, Bronwyn L., additional, Lemieux, Jacob E., additional, Sabeti, Pardis C., additional, and Myhrvold, Cameron, additional

Published

2020

26. Author Correction: Multiplexed CRISPR-based microfluidic platform for clinical testing of respiratory viruses and identification of SARS-CoV-2 variants

Author

Welch, Nicole L., Zhu, Meilin, Hua, Catherine, Weller, Juliane, Mirhashemi, Marzieh Ezzaty, Nguyen, Tien G., Mantena, Sreekar, Bauer, Matthew R., Shaw, Bennett M., Ackerman, Cheri M., Thakku, Sri Gowtham, Tse, Megan W., Kehe, Jared, Uwera, Marie-Martine, Eversley, Jacqueline S., Bielwaski, Derek A., McGrath, Graham, Braidt, Joseph, Johnson, Jeremy, Cerrato, Felecia, Moreno, Gage K., Krasilnikova, Lydia A., Petros, Brittany A., Gionet, Gabrielle L., King, Ewa, Huard, Richard C., Jalbert, Samantha K., Cleary, Michael L., Fitzgerald, Nicholas A., Gabriel, Stacey B., Gallagher, Glen R., Smole, Sandra C., Madoff, Lawrence C., Brown, Catherine M., Keller, Matthew W., Wilson, Malania M., Kirby, Marie K., Barnes, John R., Park, Daniel J., Siddle, Katherine J., Happi, Christian T., Hung, Deborah T., Springer, Michael, MacInnis, Bronwyn L., Lemieux, Jacob E., Rosenberg, Eric, Branda, John A., Blainey, Paul C., Sabeti, Pardis C., and Myhrvold, Cameron

Published

2024

27. The Mother and the Stern Master: Selected Poems

Author

Sandra Shaw Bennett, Christine D. Tomei, and Mariya Shkapskaya

Subjects

Cultural Studies, Literature, Linguistics and Language, Stern, Literature and Literary Theory, Poetry, business.industry, media_common.quotation_subject, Art, business, Language and Linguistics, media_common

Published

1999

28. A simple and sensitive test for Candida auris colonization, surveillance, and infection control suitable for near patient use.

Author

Banik S, Ozay B, Trejo M, Zhu Y, Kanna C, Santellan C, Shaw B, Chandrasekaran S, Chaturvedi S, Vejar L, Chakravorty S, Alland D, and Banada P

Subjects

Humans, Infection Control methods, Epidemiological Monitoring, Skin microbiology, Limit of Detection, Point-of-Care Systems, Nucleic Acid Amplification Techniques methods, Molecular Diagnostic Techniques methods, Candida isolation & purification, Candida genetics, Candida classification, Candidiasis diagnosis, Candidiasis microbiology, Sensitivity and Specificity, Candida auris genetics

Abstract

Candida auris is a multidrug-resistant fungal pathogen with a propensity to colonize humans and persist on environmental surfaces. C. auris invasive fungal disease is being increasingly identified in acute and long-term care settings. We have developed a prototype cartridge-based C. auris surveillance assay (CaurisSurV cartridge; "research use only") that includes integrated sample processing and nucleic acid amplification to detect C. auris from surveillance skin swabs in the GeneXpert instrument and is designed for point-of-care use. The assay limit of detection (LoD) in the skin swab matrix was 10.5 and 14.8 CFU/mL for non-aggregative (AR0388) and aggregative (AR0382) strains of C. auris , respectively. All five known clades of C. auris were detected at 2-3-5× (31.5-52.5 CFU/mL) the LoD. The assay was validated using a total of 85 clinical swab samples banked at two different institutions (University of California Los Angeles, CA and Wadsworth Center, NY). Compared to culture, sensitivity was 96.8% (30/31) and 100% (10/10) in the UCLA and Wadsworth cohorts, respectively, providing a combined sensitivity of 97.5% (40/41), and compared to PCR, the combined sensitivity was 92% (46/50). Specificity was 100% with both clinical ( C. auris negative matrix, N = 31) and analytical (non- C . auris strains, N = 32) samples. An additional blinded study with N = 60 samples from Wadsworth Center, NY yielded 97% (29/30) sensitivity and 100% (28/28) specificity. We have developed a completely integrated, sensitive, specific, and 58-min prototype test, which can be used for routine surveillance of C. auris and might help prevent colonization and outbreaks in acute and chronic healthcare settings., Importance: This study has the potential to offer a better solution to healthcare providers at hospitals and long-term care facilities in their ongoing efforts for effective and timely control of Candida auris infection and hence quicker response for any potential future outbreaks., Competing Interests: D.A. receives research support and royalty payments from Cepheid. B.O. and S.C. are employees of Cepheid. The other authors do not declare any competing interests.

Published

2024

29. DNA spike-ins enable confident interpretation of SARS-CoV-2 genomic data from amplicon-based sequencing.

Author

Lagerborg KA, Normandin E, Bauer MR, Adams G, Figueroa K, Loreth C, Gladden-Young A, Shaw B, Pearlman L, Shenoy ES, Hooper D, Pierce VM, Zachary KC, Park DJ, MacInnis BL, Lemieux JE, Sabeti PC, Reilly SK, and Siddle KJ

Abstract

The rapid global spread and continued evolution of SARS-CoV-2 has highlighted an unprecedented need for viral genomic surveillance and clinical viral sequencing. Amplicon-based sequencing methods provide a sensitive, low-cost and rapid approach but suffer a high potential for contamination, which can undermine lab processes and results. This challenge will only increase with expanding global production of sequences by diverse research groups for epidemiological and clinical interpretation. We present an approach which uses synthetic DNA spike-ins (SDSIs) to track samples and detect inter-sample contamination through a sequencing workflow. Applying this approach to the ARTIC Consortium's amplicon design, we define a series of best practices for Illumina-based sequencing and provide a detailed characterization of approaches to increase sensitivity for low-viral load samples incorporating the SDSIs. We demonstrate the utility and efficiency of the SDSI method amidst a real-time investigation of a suspected hospital cluster of SARS-CoV-2 cases., Competing Interests: Competing interests J.E.L. has received consulting fees from Sherlock Biosciences. P.C.S. is a co-founder of, shareholder in, and scientific advisor to Sherlock Biosciences, Inc., as well as a Board member of and shareholder in Danaher Corporation. M.R.B., K.A.L., E.N., S.K.R., K.J.S., P.C.S are co-inventors on a patent application filed by Broad Institute relating to methods of this manuscript.

Published

2021

30. Development of a qualitative real-time RT-PCR assay for the detection of SARS-CoV-2: A guide and case study in setting up an emergency-use, laboratory-developed molecular assay.

Author

Anahtar MN, Shaw B, Slater D, Byrne E, Botti-Lodovico Y, Adams G, Schaffner S, Eversley J, McGrath G, Gogakos T, Lennerz J, Desai Marble H, Ritterhouse LL, Batten J, Georgantas NZ, Pellerin R, Signorelli S, Thierauf J, Kemball M, Happi C, Grant DS, Ndiaye D, Siddle KJ, Mehta SB, Harris J, Ryan ET, Pierce V, LaRocque R, Lemieux JE, Sabeti P, Rosenberg E, Branda J, and Turbett SE

Abstract

Developing and deploying new diagnostic tests is difficult, but the need to do so in response to a rapidly emerging pandemic such as COVID-19 is crucially important for an effective response. In the early stages of a pandemic, laboratories play a key role in helping health care providers and public health authorities detect active infection, a task most commonly achieved using nucleic acid-based assays. While the landscape of diagnostics is rapidly evolving, polymerase chain reaction (PCR) remains the gold-standard of nucleic acid-based diagnostic assays, in part due to its reliability, flexibility, and wide deployment. To address a critical local shortage of testing capacity persisting during the COVID-19 outbreak, our hospital set up a molecular based laboratory developed test (LDT) to accurately and safely diagnose SARS-CoV-2. We describe here the process of developing an emergency-use LDT, in the hope that our experience will be useful to other laboratories in future outbreaks and will help to lower barriers to fast and accurate diagnostic testing in crisis conditions.

Published

2020

31. Phylogenetic analysis of SARS-CoV-2 in the Boston area highlights the role of recurrent importation and superspreading events.

Author

Lemieux JE, Siddle KJ, Shaw BM, Loreth C, Schaffner SF, Gladden-Young A, Adams G, Fink T, Tomkins-Tinch CH, Krasilnikova LA, DeRuff KC, Rudy M, Bauer MR, Lagerborg KA, Normandin E, Chapman SB, Reilly SK, Anahtar MN, Lin AE, Carter A, Myhrvold C, Kemball ME, Chaluvadi S, Cusick C, Flowers K, Neumann A, Cerrato F, Farhat M, Slater D, Harris JB, Branda J, Hooper D, Gaeta JM, Baggett TP, O'Connell J, Gnirke A, Lieberman TD, Philippakis A, Burns M, Brown CM, Luban J, Ryan ET, Turbett SE, LaRocque RC, Hanage WP, Gallagher GR, Madoff LC, Smole S, Pierce VM, Rosenberg E, Sabeti PC, Park DJ, and Maclnnis BL

Abstract

SARS-CoV-2 has caused a severe, ongoing outbreak of COVID-19 in Massachusetts with 111,070 confirmed cases and 8,433 deaths as of August 1, 2020. To investigate the introduction, spread, and epidemiology of COVID-19 in the Boston area, we sequenced and analyzed 772 complete SARS-CoV-2 genomes from the region, including nearly all confirmed cases within the first week of the epidemic and hundreds of cases from major outbreaks at a conference, a nursing facility, and among homeless shelter guests and staff. The data reveal over 80 introductions into the Boston area, predominantly from elsewhere in the United States and Europe. We studied two superspreading events covered by the data, events that led to very different outcomes because of the timing and populations involved. One produced rapid spread in a vulnerable population but little onward transmission, while the other was a major contributor to sustained community transmission, including outbreaks in homeless populations, and was exported to several other domestic and international sites. The same two events differed significantly in the number of new mutations seen, raising the possibility that SARS-CoV-2 superspreading might encompass disparate transmission dynamics. Our results highlight the failure of measures to prevent importation into MA early in the outbreak, underscore the role of superspreading in amplifying an outbreak in a major urban area, and lay a foundation for contact tracing informed by genetic data., Competing Interests: Competing interests: J.E.L. has received consulting fees from Sherlock Biosciences. J.B. has been a consultant for T2 Biosystems, DiaSorin, and Roche Diagnostics. A.P. is a Venture Partner at Google Ventures. P.C.S. is a co-founder and shareholder of Sherlock Biosciences, and a Board member and shareholder of Danaher Corporation.

Published

2020

32. Cerebral Microvascular Injury in Severe COVID-19.

Author

Conklin J, Frosch MP, Mukerji S, Rapalino O, Maher M, Schaefer PW, Lev MH, Gonzalez RG, Das S, Champion SN, Magdamo C, Sen P, Harrold GK, Alabsi H, Normandin E, Shaw B, Lemieux J, Sabeti P, Branda JA, Brown EN, Westover MB, Huang SY, and Edlow BL

Abstract

Importance: Microvascular lesions are common in patients with severe COVID-19. Radiologic-pathologic correlation in one case suggests a combination of microvascular hemorrhagic and ischemic lesions that may reflect an underlying hypoxic mechanism of injury, which requires validation in larger studies., Objective: To determine the incidence, distribution, and clinical and histopathologic correlates of microvascular lesions in patients with severe COVID-19., Design: Observational, retrospective cohort study: March to May 2020., Setting: Single academic medical center., Participants: Consecutive patients (16) admitted to the intensive care unit with severe COVID-19, undergoing brain MRI for evaluation of coma or focal neurologic deficits., Exposures: Not applicable., Main Outcome and Measures: Hypointense microvascular lesions identified by a prototype ultrafast high-resolution susceptibility-weighted imaging (SWI) MRI sequence, counted by two neuroradiologists and categorized by neuroanatomic location. Clinical and laboratory data (most recent measurements before brain MRI). Brain autopsy and cerebrospinal fluid PCR for SARS-CoV 2 in one patient who died from severe COVID-19., Results: Eleven of 16 patients (69%) had punctate and linear SWI lesions in the subcortical and deep white matter, and eight patients (50%) had >10 SWI lesions. In 4/16 patients (25%), lesions involved the corpus callosum. Brain autopsy in one patient revealed that SWI lesions corresponded to widespread microvascular injury, characterized by perivascular and parenchymal petechial hemorrhages and microscopic ischemic lesions., Conclusions and Relevance: SWI lesions are common in patients with neurological manifestations of severe COVID-19 (coma and focal neurologic deficits). The distribution of lesions is similar to that seen in patients with hypoxic respiratory failure, sepsis, and disseminated intravascular coagulation. Collectively, these radiologic and histopathologic findings suggest that patients with severe COVID-19 are at risk for multifocal microvascular hemorrhagic and ischemic lesions in the subcortical and deep white matter.

Published

2020

33. Integrated sample inactivation, amplification, and Cas13-based detection of SARS-CoV-2.

Author

Arizti-Sanz J, Freije CA, Stanton AC, Boehm CK, Petros BA, Siddiqui S, Shaw BM, Adams G, Kosoko-Thoroddsen TF, Kemball ME, Gross R, Wronka L, Caviness K, Hensley LE, Bergman NH, MacInnis BL, Lemieux JE, Sabeti PC, and Myhrvold C

Abstract

The COVID-19 pandemic has highlighted that new diagnostic technologies are essential for controlling disease transmission. Here, we develop SHINE (SHERLOCK and HUDSON Integration to Navigate Epidemics), a sensitive and specific integrated diagnostic tool that can detect SARS-CoV-2 RNA from unextracted samples. We combine the steps of SHERLOCK into a single-step reaction and optimize HUDSON to accelerate viral inactivation in nasopharyngeal swabs and saliva. SHINE's results can be visualized with an in-tube fluorescent readout - reducing contamination risk as amplification reaction tubes remain sealed - and interpreted by a companion smartphone application. We validate SHINE on 50 nasopharyngeal patient samples, demonstrating 90% sensitivity and 100% specificity compared to RT-PCR with a sample-to-answer time of 50 minutes. SHINE has the potential to be used outside of hospitals and clinical laboratories, greatly enhancing diagnostic capabilities., Competing Interests: Competing interests: C.A.F., P.C.S., and C.M. are inventors on patent filings related to this work. J.E.L. consults for Sherlock Biosciences, Inc. P.C.S. is a co-founder of, shareholder in, and advisor to Sherlock Biosciences, Inc, as well as a Board member of and shareholder in Danaher Corporation.

Published

2020