Phenex: Ontological Annotation of Phenotypic Diversity

Balhoff, James P.; Dahdul, Wasila; Kothari, Cartik R.; Lapp, Hilmar; Lundberg, John G.; Mabee, Paula M.; Midford, Peter E.; Westerfield, Monte

doi:10.1371/journal.pone.0010500

Cited by 81 publications

(69 citation statements)

References 34 publications

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“…Recent efforts to automate the description and measurement of organisms [3,6,23] accelerate the pace of data generation. While semantic annotation and open access publishing are likely to become an integral part of modern scientific workflows, standardization across data sets and domains remains in its infancy [12].…”

Section: Implications For Interoperabilitymentioning

confidence: 99%

“…Most of this information survives in the form of free text or data tables in published papers, if it survives at all [20]. Lately communities have started to annotate those papers [3], extract information from text [28,40], and build special-purpose databases of trait data, for example, TRY 1 for plants [24] and SeaLifeBase 2 for marine organisms. In addition, modern researchers are more likely to archive and share data sets associated with their published studies in open data repositories such as Dryad 3 [42], Ecological Archives 4 and PANGAEA.…”

Section: Introductionmentioning

confidence: 99%

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TraitBank: Practical semantics for organism attribute data

Parr

Schulz

Hammock

et al. 2016

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Abstract. Encyclopedia of Life (EOL) has developed TraitBank (http://eol.org/traitbank), a new repository for organism attribute (trait) data. TraitBank aggregates, manages and serves attribute data for organisms across the tree of life, including life history characteristics, habitats, distributions, ecological relationships and other data types. We describe how TraitBank ingests and manages these data in a way that leverages EOL's existing infrastructure and semantic annotations to facilitate reasoning across the TraitBank corpus and interoperability with other resources. We also discuss TraitBank's impact on users and collaborators and the challenges and benefits of our lightweight, scalable approach to the integration of biodiversity data.

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Section: Implications For Interoperabilitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

TraitBank: Practical semantics for organism attribute data

Parr

Schulz

Hammock

et al. 2016

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“…An EQ representation may be defined under a number of categories [19], with the example below taken from the process of heart morphogenesis.…”

Section: Case Studymentioning

confidence: 99%

Progress with a Multiscale Systems Engineering Approach to Cardiac Development

et al. 2011

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Original scientific paperMultiscale systems engineering provides a way to integrate models of real-world phenomena that allows a holistic understanding of component interactions at different levels of scale simultaneously. The discipline draws upon information engineering to provide ontological representations that are derived from digital libraries of terms, themselves found at distributed locations around the world. Cardiac development is well understood within discrete levels of analysis. The application of the multiscale framework gives added value by unlocking the relationships between genetic-based information at one level of analysis and the phenotype it encodes for at the cell and organ levels of abstraction. The multiscale-based relationships have begun to demonstrate new insights into normal cardiac development and conditions that give rise to congenital heart diseases such as the tetralogy of Fallot. This paper describes progress made in combining ontology-based information models and explains the importance of the role of multiscale systems engineering.Key words: Cardiac development, Information engineering, Multiscale, Ontology Napredak koncepta višerazinskog sustavskog inženjerstva u razumijevanju srčanog razvoja. Višerazin-sko sustavsko inženjerstvo pruža mogućnost integracije modela različitih pojava iz stvarnog svijeta, što omogućuje cjelovito razumijevanje interakcija komponenti sustava istovremeno na različitim razinama skale. Disciplina je to koja koristi informatiku za omogućavanje ontoloških reprezentacija koje se izvode iz digitalnih knjižnica pojmova smještenih na raspodijeljnim lokacijama širom svijeta. Unutar pojedinačnih razina analize postoji dobro razmijevanje srčanog razvoja. Primjena višerazinskog okvira daje dodatnu vrijednost otključavajući vezu izmeu genetski temeljenih informacija na jednoj razini analize i fenotipa koji kodira na razinama apstrakcije stanice i organa. Višerazinski temeljene veze počele su donositi nove spoznaje normalnog srčanog razvoja i uvjeta koji vode k pojavi priroenih srčanih grešaka kao što je Fallotova tetralogija. Ovaj rad opisuje napredak postignut kombiniranjem ontologijski temeljenih infomacijskih modela i objašnjava važnost uloge višerazinskog sustavskog inženjerstva.

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“…However, the majority of information in these scientific articles remains in the form of free text, and is therefore, opaque to computational analyses [2]. In several data intensive fields such as Biology, ontologies have been adopted as the de-facto mode of data representation to enable data integration, sharing, and, to make data computationally amenable [3].…”

Section: Introductionmentioning

confidence: 99%

Comparison of natural language processing tools for automatic gene ontology annotation of scientific literature

Beasley¹,

Manda²

2018

Preprint

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Abstract-Manual curation of scientific literature for ontologybased knowledge representation has proven infeasible and unscalable to the large and growing volume of scientific literature. Automated annotation solutions that leverage text mining and Natural Language Processing (NLP) have been developed to ameliorate the problem of literature curation. These NLP approaches use parsing, syntactical, and lexical analysis of text to recognize and annotate pieces of text with ontology concepts. Here, we conduct a comparison of four state of the art NLP tools at the task of recognizing Gene Ontology concepts from biomedical literature using the Colorado Richly Annotated Full-Text (CRAFT) corpus as a gold standard reference. We demonstrate the use of semantic similarity metrics to compare NLP tool annotations to the gold standard.

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Phenex: Ontological Annotation of Phenotypic Diversity

Cited by 81 publications

References 34 publications

TraitBank: Practical semantics for organism attribute data

TraitBank: Practical semantics for organism attribute data

Progress with a Multiscale Systems Engineering Approach to Cardiac Development

Comparison of natural language processing tools for automatic gene ontology annotation of scientific literature

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