Supporting shared hypothesis testing in the biomedical domain

BackgroundPathogenesis of inflammatory diseases can be tracked by studying the causality relationships among the factors contributing to its development. We could, for instance, hypothesize on the connections of the pathogenesis outcomes to the observed conditions. And to prove such causal hypotheses we would need to have the full understanding of the causal relationships, and we would have to provide all the necessary evidences to support our claims. In practice, however, we might not possess all the background knowledge on the causality relationships, and we might be unable to collect all the evidence to prove our hypotheses.ResultsIn this work we propose a methodology for the translation of biological knowledge on causality relationships of biological processes and their effects on conditions to a computational framework for hypothesis testing. The methodology consists of two main points: hypothesis graph construction from the formalization of the background knowledge on causality relationships, and confidence measurement in a causality hypothesis as a normalized weighted path computation in the hypothesis graph. In this framework, we can simulate collection of evidences and assess confidence in a causality hypothesis by measuring it proportionally to the amount of available knowledge and collected evidences.ConclusionsWe evaluate our methodology on a hypothesis graph that represents both contributing factors which may cause cartilage degradation and the factors which might be caused by the cartilage degradation during osteoarthritis. Hypothesis graph construction has proven to be robust to the addition of potentially contradictory information on the simultaneously positive and negative effects. The obtained confidence measures for the specific causality hypotheses have been validated by our domain experts, and, correspond closely to their subjective assessments of confidences in investigated hypotheses. Overall, our methodology for a shared hypothesis testing framework exhibits important properties that researchers will find useful in literature review for their experimental studies, planning and prioritizing evidence collection acquisition procedures, and testing their hypotheses with different depths of knowledge on causal dependencies of biological processes and their effects on the observed conditions.

[1]  Julien Favre,et al.  Gait analysis of patients with knee osteoarthritis highlights a pathological mechanical pathway and provides a basis for therapeutic interventions , 2016, EFORT open reviews.

[2]  Christine Ortiz,et al.  Molecular Adhesion between Cartilage Extracellular Matrix Macromolecules , 2014, Biomacromolecules.

[3]  Riichiro Mizoguchi,et al.  Causality and the ontology of disease , 2015, Appl. Ontology.

[4]  L. Sandell Etiology of osteoarthritis: genetics and synovial joint development , 2012, Nature Reviews Rheumatology.

[5]  S. Abramson,et al.  Inflammation in osteoarthritis. , 2004, The Journal of rheumatology. Supplement.

[6]  Sion Glyn-Jones,et al.  Non-invasive imaging of cartilage in early osteoarthritis. , 2013, The bone & joint journal.

[7]  Ian Horrocks,et al.  The Even More Irresistible SROIQ , 2006, KR.

[8]  Domenico Lembo,et al.  Graph-Based Ontology Classification in OWL 2 QL , 2013, ESWC.

[9]  Xianrong Zhang,et al.  Nanoindentation modulus of murine cartilage: a sensitive indicator of the initiation and progression of post-traumatic osteoarthritis. , 2017, Osteoarthritis and cartilage.

[10]  P. M. van der Kraan,et al.  Osteophytes: relevance and biology. , 2007, Osteoarthritis and cartilage.

[11]  Edward M. Reingold,et al.  Graph drawing by force‐directed placement , 1991, Softw. Pract. Exp..

[12]  Giuseppe Patanè,et al.  Grontocrawler: Graph-Based Ontology Exploration , 2015, STAG.

[13]  Luciano Rossoni,et al.  Models and methods in social network analysis , 2006 .

[14]  W. B. van den Berg,et al.  Osteophytes: relevance and biology. , 2007, Osteoarthritis and cartilage.

[15]  V C Mow,et al.  The mechanical properties of articular cartilage. , 1983, Bulletin of the Hospital for Joint Diseases Orthopaedic Institute.

[16]  Lise Getoor,et al.  A short introduction to probabilistic soft logic , 2012, NIPS 2012.

[17]  Jane Hillston,et al.  Bio-PEPA: An Extension of the Process Algebra PEPA for Biochemical Networks , 2007, FBTC@CONCUR.

[18]  M. Bhargava,et al.  An in vitro model for the pathological degradation of articular cartilage in osteoarthritis. , 2014, Journal of biomechanics.

[19]  Nicola Guarino,et al.  Sweetening Ontologies with DOLCE , 2002, EKAW.

[20]  Christopher G. Chute,et al.  BioPortal: ontologies and integrated data resources at the click of a mouse , 2009, Nucleic Acids Res..

[21]  R. Kinne,et al.  Pro‐inflammatory IL‐1beta and/or TNF‐alpha up‐regulate matrix metalloproteases‐1 and ‐3 mRNA in chondrocyte subpopulations potentially pathogenic in osteoarthritis: in situ hybridization studies on a single cell level , 2016, International journal of rheumatic diseases.

[22]  Linda Troeberg,et al.  Proteases involved in cartilage matrix degradation in osteoarthritis. , 2012, Biochimica et biophysica acta.

[23]  Erdem Aktas,et al.  Serum TNF-alpha levels: potential use to indicate osteoarthritis progression in a mechanically induced model , 2012, European Journal of Orthopaedic Surgery & Traumatology.

[24]  James F. Allen Maintaining knowledge about temporal intervals , 1983, CACM.

[25]  Alexa T. McCray,et al.  An Upper-Level Ontology for the Biomedical Domain , 2003, Comparative and functional genomics.

[26]  Marta Ondrésik,et al.  Management of knee osteoarthritis. Current status and future trends , 2017, Biotechnology and bioengineering.

[27]  K. Spackman SNOMED RT and SNOMEDCT. Promise of an international clinical terminology. , 2000, M.D. computing : computers in medical practice.

[28]  S. Goldring,et al.  Changes in the osteochondral unit during osteoarthritis: structure, function and cartilage–bone crosstalk , 2016, Nature Reviews Rheumatology.

[29]  Laurence Pesesse,et al.  Targeting the synovial angiogenesis as a novel treatment approach to osteoarthritis , 2014, Therapeutic advances in musculoskeletal disease.

[30]  Michel C. A. Klein,et al.  Structure-Based Partitioning of Large Concept Hierarchies , 2004, SEMWEB.

[31]  M. Goldring,et al.  Chondrogenesis, chondrocyte differentiation, and articular cartilage metabolism in health and osteoarthritis , 2012, Therapeutic advances in musculoskeletal disease.

[32]  J. Pearl Causality: Models, Reasoning and Inference , 2000 .

[33]  Jane Hillston,et al.  Process algebras for quantitative analysis , 2005, 20th Annual IEEE Symposium on Logic in Computer Science (LICS' 05).

[34]  Matthew Richardson,et al.  Markov logic networks , 2006, Machine Learning.

[35]  Noriko Yoshimura,et al.  Epidemiology of knee osteoarthritis , 2013 .

[36]  Benjamin M. Good,et al.  Wikidata as a semantic framework for the Gene Wiki initiative , 2015, bioRxiv.

[37]  Giovanna Guerrini,et al.  Minimizing conservativity violations in ontology alignments: algorithms and evaluation , 2016, Knowledge and Information Systems.

[38]  Boris Motik,et al.  OWL 2: The next step for OWL , 2008, J. Web Semant..

[39]  Bernardo Cuenca Grau,et al.  LogMap: Logic-Based and Scalable Ontology Matching , 2011, SEMWEB.

[40]  Mark A. Musen,et al.  BioPortal as a dataset of linked biomedical ontologies and terminologies in RDF , 2013, Semantic Web.

[41]  R. Gorenflo,et al.  Multi-index Mittag-Leffler Functions , 2014 .

[42]  Emanuel Santos,et al.  The AgreementMakerLight Ontology Matching System , 2013, OTM Conferences.

[43]  Ian Horrocks,et al.  OptiqueVQS: A visual query system over ontologies for industry , 2018, Semantic Web.

[44]  Werner Ceusters,et al.  Toward an Ontological Treatment of Disease and Diagnosis , 2009, Summit on translational bioinformatics.

[45]  Evgeny Kharlamov,et al.  Faceted search over RDF-based knowledge graphs , 2016, J. Web Semant..

[46]  S J Bryant,et al.  Mechanical loading regimes affect the anabolic and catabolic activities by chondrocytes encapsulated in PEG hydrogels. , 2010, Osteoarthritis and cartilage.

[47]  Boris Motik,et al.  HermiT: An OWL 2 Reasoner , 2014, Journal of Automated Reasoning.

[48]  Johanne Martel-Pelletier,et al.  Role of proinflammatory cytokines in the pathophysiology of osteoarthritis , 2011, Nature Reviews Rheumatology.

[49]  M. Ashburner,et al.  Gene Ontology: tool for the unification of biology , 2000, Nature Genetics.

[50]  Alan L. Rector,et al.  Web ontology segmentation: analysis, classification and use , 2006, WWW '06.

[51]  Andreas Hotho,et al.  Semantic Network Analysis of Ontologies , 2006, LWA.

[52]  Franz Baader,et al.  Pushing the EL Envelope , 2005, IJCAI.

[53]  Sonja Zillner,et al.  Interpreting Patient Data using Medical Background Knowledge , 2012, ICBO.

[54]  Robert Arp,et al.  Building Ontologies with Basic Formal Ontology , 2015 .

[55]  Özgür L. Özçep,et al.  A Visual Query System for Stream Data Access over Ontologies , 2016, ESWC.

[56]  J. Pearl Causal inference in statistics: An overview , 2009 .

[57]  A. Rector,et al.  Relations in biomedical ontologies , 2005, Genome Biology.

[58]  Erik Schultes,et al.  Knowledge.Bio: A Web Application for Exploring, Building and Sharing Webs of Biomedical Relationships Mined from PubMed , 2016 .

[59]  Farshid Guilak,et al.  Biomechanical factors in osteoarthritis. , 2011, Best practice & research. Clinical rheumatology.

[60]  Stephen D. Larson,et al.  Rule-Based Reasoning With A Multi-Scale Neuroanatomical Ontology , 2007, OWLED.

[61]  Peter Mika,et al.  Ontologies are us: A unified model of social networks and semantics , 2005, J. Web Semant..

[62]  Olivier Bodenreider,et al.  The Unified Medical Language System (UMLS): integrating biomedical terminology , 2004, Nucleic Acids Res..