Your search keyword '"Troy Sincomb"' showing total 6 results

1. Human immunoglobulin gene allelic variation impacts germline-targeting vaccine priming

Author

Allan C. deCamp, Martin M. Corcoran, William J. Fulp, Jordan R. Willis, Christopher A. Cottrell, Daniel L. V. Bader, Oleksandr Kalyuzhniy, David J. Leggat, Kristen W. Cohen, Ollivier Hyrien, Sergey Menis, Greg Finak, Lamar Ballweber-Fleming, Abhinaya Srikanth, Jason R. Plyler, Farhad Rahaman, Angela Lombardo, Vincent Philiponis, Rachael E. Whaley, Aaron Seese, Joshua Brand, Alexis M. Ruppel, Wesley Hoyland, Celia R. Mahoney, Alberto Cagigi, Alison Taylor, David M. Brown, David R. Ambrozak, Troy Sincomb, Tina-Marie Mullen, Janine Maenza, Orpheus Kolokythas, Nadia Khati, Jeffrey Bethony, Mario Roederer, David Diemert, Richard A. Koup, Dagna S. Laufer, Juliana M. McElrath, Adrian B. McDermott, Gunilla B. Karlsson Hedestam, and William R. Schief

Subjects

Immunologic diseases. Allergy, RC581-607, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Vaccine priming immunogens that activate germline precursors for broadly neutralizing antibodies (bnAbs) have promise for development of precision vaccines against major human pathogens. In a clinical trial of the eOD-GT8 60mer germline-targeting immunogen, higher frequencies of vaccine-induced VRC01-class bnAb-precursor B cells were observed in the high dose compared to the low dose group. Through immunoglobulin heavy chain variable (IGHV) genotyping, statistical modeling, quantification of IGHV1-2 allele usage and B cell frequencies in the naive repertoire for each trial participant, and antibody affinity analyses, we found that the difference between dose groups in VRC01-class response frequency was best explained by IGHV1-2 genotype rather than dose and was most likely due to differences in IGHV1-2 B cell frequencies for different genotypes. The results demonstrate the need to define population-level immunoglobulin allelic variations when designing germline-targeting immunogens and evaluating them in clinical trials.

Published

2024

2. Extending and using anatomical vocabularies in the stimulating peripheral activity to relieve conditions project

Author

Monique C. Surles-Zeigler, Troy Sincomb, Thomas H. Gillespie, Bernard de Bono, Jacqueline Bresnahan, Gary M. Mawe, Jeffrey S. Grethe, Susan Tappan, Maci Heal, and Maryann E. Martone

Subjects

SPARC, InterLex, ontologies, peripheral nervous system (PNS), anatomical terms, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The stimulating peripheral activity to relieve conditions (SPARC) program is a US National Institutes of Health-funded effort to improve our understanding of the neural circuitry of the autonomic nervous system (ANS) in support of bioelectronic medicine. As part of this effort, the SPARC project is generating multi-species, multimodal data, models, simulations, and anatomical maps supported by a comprehensive knowledge base of autonomic circuitry. To facilitate the organization of and integration across multi-faceted SPARC data and models, SPARC is implementing the findable, accessible, interoperable, and reusable (FAIR) data principles to ensure that all SPARC products are findable, accessible, interoperable, and reusable. We are therefore annotating and describing all products with a common FAIR vocabulary. The SPARC Vocabulary is built from a set of community ontologies covering major domains relevant to SPARC, including anatomy, physiology, experimental techniques, and molecules. The SPARC Vocabulary is incorporated into tools researchers use to segment and annotate their data, facilitating the application of these ontologies for annotation of research data. However, since investigators perform deep annotations on experimental data, not all terms and relationships are available in community ontologies. We therefore implemented a term management and vocabulary extension pipeline where SPARC researchers may extend the SPARC Vocabulary using InterLex, an online vocabulary management system. To ensure the quality of contributed terms, we have set up a curated term request and review pipeline specifically for anatomical terms involving expert review. Accepted terms are added to the SPARC Vocabulary and, when appropriate, contributed back to community ontologies to enhance ANS coverage. Here, we provide an overview of the SPARC Vocabulary, the infrastructure and process for implementing the term management and review pipeline. In an analysis of >300 anatomical contributed terms, the majority represented composite terms that necessitated combining terms within and across existing ontologies. Although these terms are not good candidates for community ontologies, they can be linked to structures contained within these ontologies. We conclude that the term request pipeline serves as a useful adjunct to community ontologies for annotating experimental data and increases the FAIRness of SPARC data.

Published

2022

3. Everything Matters: The ReproNim Perspective on Reproducible Neuroimaging

Author

David N. Kennedy, Sanu A. Abraham, Julianna F. Bates, Albert Crowley, Satrajit Ghosh, Tom Gillespie, Mathias Goncalves, Jeffrey S. Grethe, Yaroslav O. Halchenko, Michael Hanke, Christian Haselgrove, Steven M. Hodge, Dorota Jarecka, Jakub Kaczmarzyk, David B. Keator, Kyle Meyer, Maryann E. Martone, Smruti Padhy, Jean-Baptiste Poline, Nina Preuss, Troy Sincomb, and Matt Travers

Subjects

reproducibility, neuroimaging, data model, publication, re-executability, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

There has been a recent major upsurge in the concerns about reproducibility in many areas of science. Within the neuroimaging domain, one approach is to promote reproducibility is to target the re-executability of the publication. The information supporting such re-executability can enable the detailed examination of how an initial finding generalizes across changes in the processing approach, and sampled population, in a controlled scientific fashion. ReproNim: A Center for Reproducible Neuroimaging Computation is a recently funded initiative that seeks to facilitate the “last mile” implementations of core re-executability tools in order to reduce the accessibility barrier and increase adoption of standards and best practices at the neuroimaging research laboratory level. In this report, we summarize the overall approach and tools we have developed in this domain.

Published

2019

4. Extending and using anatomical vocabularies in the Stimulating Peripheral Activity to Relieve Conditions (SPARC) program

Author

Jacqueline C. Bresnahan, Monique C Surles-Zeigler, Maryann E. Martone, Jeffrey S. Grethe, Bernard de Bono, Maci Heal, Susan Tappan, Troy Sincomb, Tom Gillespie, and Gary M. Mawe

Subjects

Vocabulary, Process (engineering), business.industry, Computer science, media_common.quotation_subject, Interoperability, Pipeline (software), World Wide Web, Annotation, Knowledge base, Management system, business, Set (psychology), media_common

Abstract

The Stimulating Peripheral Activity to Relieve Conditions (SPARC) program is a US National Institutes of Health-funded effort to improve our understanding of the neural circuitry of the autonomic nervous system in support of bioelectronic medicine. As part of this effort, the SPARC program is generating multi-species, multimodal data, models, simulations, and anatomical maps supported by a comprehensive knowledge base of autonomic circuitry. To facilitate the organization of and integration across multi-faceted SPARC data and models, SPARC is implementing the FAIR data principles to ensure that all SPARC products are findable, accessible, interoperable, and reusable. We are therefore annotating and describing all products with a common FAIR vocabulary. The SPARC Vocabulary is built from a set of community ontologies covering major domains relevant to SPARC, including anatomy, physiology, experimental techniques, and molecules. The SPARC Vocabulary is incorporated into tools researchers use to segment and annotate their data, facilitating the application of these ontologies for annotation of research data. However, since investigators perform deep annotations on experimental data, not all terms and relationships are available in community ontologies. We therefore implemented a term management and vocabulary extension pipeline where SPARC researchers may extend the SPARC Vocabulary using InterLex, an online vocabulary management system. To ensure the quality of contributed terms, we have set up a curated term request and review pipeline specifically for anatomical terms involving expert review. Accepted terms are added to the SPARC Vocabulary and, when appropriate, contributed back to community ontologies to enhance autonomic nervous system coverage. Here, we provide an overview of the SPARC Vocabulary, the infrastructure and process for implementing the term management and review pipeline. In an analysis of > 300 anatomical contributed terms, the majority represented composite terms that necessitated combining terms within and across existing ontologies. Although these terms are not good candidates for community ontologies, they can be linked to structures contained within these ontologies. We conclude that the term request pipeline serves as a useful adjunct to community ontologies for annotating experimental data and increases the FAIRness of SPARC data.

Published

2021

5. Everything Matters: The ReproNim Perspective on Reproducible Neuroimaging

Author

Jeffrey S. Grethe, Sanu Ann Abraham, Julianna F. Bates, Matt Travers, Troy Sincomb, Mathias Goncalves, Jean-Baptiste Poline, Christian Haselgrove, Yaroslav O. Halchenko, Tom Gillespie, Steven M. Hodge, Nina Preuss, Michael Hanke, Dorota Jarecka, Satrajit S. Ghosh, Kyle Meyer, Albert Crowley, Jakub Kaczmarzyk, David N. Kennedy, Smruti Padhy, David Keator, and Maryann E. Martone

Subjects

Computer science, Best practice, Population, Biomedical Engineering, Neuroscience (miscellaneous), 050105 experimental psychology, GeneralLiterature_MISCELLANEOUS, lcsh:RC321-571, Domain (software engineering), 03 medical and health sciences, Substance Misuse, data model, 0302 clinical medicine, Neuroimaging, Clinical Research, re-executability, 0501 psychology and cognitive sciences, education, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Implementation, reproducibility, education.field_of_study, neuroimaging, 05 social sciences, Perspective (graphical), Substance Abuse, Neurosciences, Data science, Computer Science Applications, publication, Perspective, Cognitive Sciences, Last mile, 030217 neurology & neurosurgery, Neuroscience

Abstract

There has been a recent major upsurge in the concerns about reproducibility in many areas of science. Within the neuroimaging domain, one approach is to promote reproducibility is to target the re-executability of the publication. The information supporting such re-executability can enable the detailed examination of how an initial finding generalizes across changes in the processing approach, and sampled population, in a controlled scientific fashion. ReproNim: A Center for Reproducible Neuroimaging Computation is a recently funded initiative that seeks to facilitate the "last mile" implementations of core re-executability tools in order to reduce the accessibility barrier and increase adoption of standards and best practices at the neuroimaging research laboratory level. In this report, we summarize the overall approach and tools we have developed in this domain.

Published

2019

6. Everything Matters: The ReproNim Perspective on Reproducible Neuroimaging

Author

David N. Kennedy, Satrajit S Ghosh, Tom Gillespie, Mathias Goncalves, Jeffrey Sean Grethe, Yaroslav O Halchenko, Michael Hanke, Dorota Jarecka, Jakub Kaczmarzyk, David Keator, Kyle Meyer, Maryann Elizabeth Martone, Jean-Baptiste Poline, Nina Preuss, Sanu Ann Abraham, Julianna F. Bates, Albert Crowley, Christian Haselgrove, Steven M. Hodge, Smruti Padhy, and Troy Sincomb

Subjects

GeneralLiterature_MISCELLANEOUS

Abstract

There has been a recent major upsurge in the concerns about reproducibility in many areas of science. Within the neuroimaging domain, one approach is to promote reproducibility is to target the re-executability of the publication. The information supporting such re-executability can enable the detailed examination of how an initial finding generalizes across changes in the processing approach, and sampled population, in a controlled scientific fashion. ReproNim: A Center for Reproducible Neuroimaging Computation is a recently funded initiative that seeks to facilitate the ‘last mile’ implementations of core re-executability tools in order to reduce the accessibility barrier and increase adoption of standards and best practices at the neuroimaging research laboratory level. In this report, we summarize the overall approach and tools we have developed in this domain.

Published

2018