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ECOR European Centre for Ontological Research Ontology and Referent Tracking for Neurodegenerative Disorders Dr. Werner Ceusters European Centre for Ontological Research Saarland University, Saarbrücken, Germany ECOR European Centre for Ontological Research Part I. Neurodegenerative disorders: modern history ECOR European Centre for Ontological Research Examples of neurodegenerative diseases • Involving the central nervous system: – – – – – – – Alzheimer's Disease Parkinson Disease ALS (Lou Gehrig's Disease) Frontal Temporal Dementia Huntington's Disease Cerebellar Ataxias Hereditary Spastic Paraplegias • Involving the peripheral nervous system: – Charcot-Marie Tooth Hereditary Neuropathies – Muscular Dystrophy. ECOR European Centre for Ontological Research Some disease characteristics • Neurodegeneration is a major element. – But some disorders with ND are not usually classified as degenerative e.g. multiple sclerosis, epilepsy, some inborn errors of metabolism, schizophrenia, and even tumours. • selective, at least initially, for a particular neuronal pool • both genetic and environmental risk factors play a part in the etiology • a long run-in period until sufficient protein accumulates, followed by a cascade of symptoms over 2-20 years, with increasing disability leading to death A. Williams. Defining neurodegenerative diseases. BMJ 2002;324:1465-1466 ( 22 June ) ECOR Wide range of phenotypes in same category, e.g. cerebellar ataxias (SCA) European Centre for Ontological Research • SCA 1: hypermetric saccades and hyperreflexia. • SCA 2: reduced velocity of saccadic eye movements, areflexia and changes similar to those seen in olivopontocerebellar atrophy on brain imaging. • SCA 3: protruded eyes, muscle fasciculations, spasticity, chorea, gaze-evoked nystagmus, parkinsonism and peripheral neuropathy. • SCAs 5, 6, 10 and 11: pure cerebellar signs. • SCA 7: macular degeneration. • SCA 8: mild sensory neuropathy, late-onset spasticity. • SCA 10: seizures with ataxia. • SCA 12: head and hand tremors. • SCA 17: Intellectual deterioration and dysphagia. T.E. King. Molecular diagnosis of adult neurodegenerative diseases and movement disorders. April 2005. http://www.bioethics-singapore.org/resources/pdf/GeneticTestingMovementDisorders_tanek.pdf ECOR Histopathological phenomena in some central NDs European Centre for Ontological Research L. Bertram and R.E. Tanzi. The genetic epidemiology of neurodegenerative disease. J. Clin. Invest. 115:1449-1457 (2005). ECOR Multi-factorial with cross-relations, e.g. genetic epidemiology of Alzheimer European Centre for Ontological Research L. Bertram and R.E. Tanzi. The genetic epidemiology of neurodegenerative disease. J. Clin. Invest. 115:1449-1457 (2005). ECOR European Centre for Ontological Research Main research epochs • Early 1900 – Microscopic study of stained tissues – Alzheimer, Lewy, Pick, ... – NDs classified as clinicopathological entities • Last decade: – Molecular genetics and molecular biology – Advanced functional and sequential imaging – NDs classified by means of pathological biochemical pathways ECOR European Centre for Ontological Research Research purposes for ND • characterize the clinical, laboratory, and pathological phenotypes of the various disorders included in this category; • identify and clone genes directly causing or functioning as risk factors for these disorders; • understand basic mechanisms underlying the biochemical and molecular pathogenesis of these disorders; • Find application to treatment and prevention ECOR European Centre for Ontological Research Research purposes from an –omics perspective • understand the normal functions of genes and proteins involved in neurodegenerative diseases, • characterize their role in pathogenic disease mechanisms, • model their functions in animals, • explore their roles in the diagnosis, treatment and prevention ECOR European Centre for Ontological Research Technical strategy for analysing ND pathogenesis • identify pathogenic genes – by positional cloning, – by cloning genes that encode proteins involved in the disease, – or by combining the two approaches; • find pathogenic mutations; • model and study the disease – in cells by transfection and – in mice by transgenesis D. L. Price, S. S. Sisodia, D. R. Borchelt, Science 282, 1078 (1998) ECOR European Centre for Ontological Research E.g.: ‘positional cloning’ • identify large multigenerational families with a long history of carrying the disorder • determine linkage with polymorphic genetic markers • look for cytogenetic rearrangements associated with the disease • isolate overlapping DNA clones from the region • identifying the gene that is responsible ECOR Another strategy for ND gene detection European Centre for Ontological Research L. Bertram and R.E. Tanzi. The genetic epidemiology of neurodegenerative disease. J. Clin. Invest. 115:1449-1457 (2005). ECOR European Centre for Ontological Research New NDs are discovered • a previously unrecognized adult-onset dominantly inherited ND that affects the basal ganglia associated with iron accumulation. • Phenotype: – extrapyramidal symptoms and low ferritin serum levels. – lesions in the globus pallidus with abundant spherical inclusions containing aggregates of ferritin and iron. – axonal swellings throughout the brain – organs such as the pancreas, liver, and heart that are typically affected in iron accumulation disease, appear to function normally Curtis ARJ, Fey C, Morris CM, et al. Mutation in the gene encoding ferritin light polypeptide causes dominant adult-onset basal ganglia disease. Nature Genetics 2001; 28: 350-354. ECOR European Centre for Ontological Research Intermediate conclusions • NDs are challenging with respect to ‘reality representation’ – Involve entities of diverse nature – ‘true’ nature of some entities not yet understood – Type of relationships unclear ECOR European Centre for Ontological Research Part II. Role of ontology ECOR European Centre for Ontological Research Ontology • ‘Ontology’: the study of being as a science • ‘An ontology’ : a representation of some preexisting domain of reality which – (1) reflects the properties of the objects within its domain in such a way that there obtains a systematic correlation between reality and the representation itself, – (2) is intelligible to a domain expert – (3) is formalized in a way that allows it to support automatic information processing • ‘ontological’ (as adjective): – Within an ontology. – Derived by applying the methodology of ontology – ... ECOR European Centre for Ontological Research Need for widely accepted Top Level Ontology (TLO) • TLO: an ontology that describes by means of theories or specifications the most general, domain-independent categories of reality such as time, space, inherence, instantiation, identity, processes, events, attributes, relations, ... • Ongoing efforts: – BFO – DOLCE – SUMO ECOR Need for widely accepted Biomedical Domain Ontology (BMO) European Centre for Ontological Research • domain ontology: – an ontology that describes the most general categories within a specific domain, using the framework of the top level ontology. In our case: the domain is biomedicine. • Where a top level ontology describes entities such as objects and processes, a biomedical domain ontology: – describes entities such as genes and insulin, and transcription and hormon secretion. – further classifies these entities within the framework of the top level ontology, thereby adding new descriptive elements that are relevant at that level of reality. ECOR Essential (and missing) components for a biomedical domain ontology European Centre for Ontological Research – Ontology for functions and processes • levels of granularity for functions: • localizing functions and processes to understand their mutual relationships: • functional states of molecules – Ontology for anatomical levels of granularities • levels of granularity based on grains and structure • determination of parthood relations across entities in different levels of granularity – Pathophysiology ontology • Dependence relations between physiological entities and pathology • Determination of parthood relations for pathological entities – An upper ontology for health information stored in public health information databases ECOR European Centre for Ontological Research Links to ongoing efforts • Use BMO: – To make more DB semantics explicit and formal – to make the various databases semantically interoperable at both structure and content level. ECOR Example: KEGG Pathway Database on Neurodegenerative Disorders European Centre for Ontological Research • • • • • Alzheimer's disease Parkinson's disease Amyotrophic lateral sclerosis (ALS) Huntington's disease Dentatorubropallidoluysian atrophy (DRPLA) • Prion disease ECOR European Centre for Ontological Research KEGG Pathway ND ECOR European Centre for Ontological Research KEGG Pathway Alzheimer ECOR European Centre for Ontological Research KEGG Pathway notation ECOR European Centre for Ontological Research Part III. Referent Tracking ECOR European Centre for Ontological Research The missing link • ‘From genotype to phenotype’ – Most DBs contain data without reference to particular patients – Some DBs (usually not publicly accessible) just have snapshots of correlations – No DBs provide a dynamically growing pool of data about interrelated patient phenomena – Note: • NOT “interrelated data” • Relationships between data are distinct from relationships amongst the entities the data are about – The right approach: Referent Tracking ECOR European Centre for Ontological Research Referent Tracking ... • Corrects the overemphasis on data and information and too little attention to reality: – – • “data modelling” “information modelling” Does right what the “Object Oriented” model claims to do right. – – objects are said to be those things that exist in reality But: ‘The object-oriented model is based on a collection of objects’ – – An object contains values stored in instance variables within the object. Unlike the record-oriented models, these values are themselves objects. ECOR A look at the database: Use of SNOMED codes for ‘unambiguous’ understanding European Centre for Ontological Research PtID Date ObsCode Narrative How many closed fracture of shaft numerically of femur different disorders are Fracture, closed, spiral closed fracture of shaft?of femur listed here 5572 04/07/1990 26442006 5572 04/07/1990 81134009 5572 12/07/1990 26442006 5572 12/07/1990 9001224 5572 04/07/1990 79001 0939 24/12/1991 255174002 2309 21/03/1992 26442006 2309 21/03/1992 9001224 47804 03/04/1993 58298795 Other lesion on other specified region 5572 17/05/1993 79001 Essential hypertension 298 22/08/1993 2909872 298 22/08/1993 9001224 5572 01/04/1997 26442006 How many disorders have patients 5572, 2309 Closed fracture of radial head and in298 thus Accident publiceach buildinghad (supermarket) closed of shaftlifetime of femur farfracture in their ? 5572 01/04/1997 79001 Essential hypertension 0939 20/12/1998 255087006 malignant polyp of biliary tract * Accident in public building (supermarket) How many different benign polypof of biliary tract types disorders are closed fracture of shaft of femur listed here ? Essential hypertension * * Accident in public building (supermarket) * cause, not disorder ECOR European Centre for Ontological Research Would it be easier if you could see the code labels ? PtID Date ObsCode Narrative 5572 04/07/1990 26442006 closed fracture of shaft of femur 5572 04/07/1990 81134009 Fracture, closed, spiral 5572 12/07/1990 26442006 closed fracture of shaft of femur 5572 12/07/1990 9001224 Accident in public building (supermarket) 5572 04/07/1990 79001 Essential hypertension 0939 24/12/1991 255174002 benign polyp of biliary tract 2309 21/03/1992 26442006 closed fracture of shaft of femur 2309 21/03/1992 9001224 Accident in public building (supermarket) 47804 03/04/1993 58298795 Other lesion on other specified region 5572 17/05/1993 79001 Essential hypertension 298 22/08/1993 2909872 Closed fracture of radial head 298 22/08/1993 9001224 Accident in public building (supermarket) 5572 01/04/1997 26442006 closed fracture of shaft of femur 5572 01/04/1997 79001 Essential hypertension 0939 20/12/1998 255087006 malignant polyp of biliary tract ECOR Proposed solution: European Centre for Ontological Research Referent Tracking • Purpose: – explicit reference to the concrete individual entities relevant to the accurate description of each patient’s condition, therapies, outcomes, ... • Method: – Introduce an Instance Unique Identifier (IUI) for each relevant individual (= particular, = instance). – Distinguish between • IUI assignment: for instances that do exist • IUI reservation: for entities expected to come into existence in the future ECOR European Centre for Ontological Research PtID No confusion with explicit references Date ObsCode Narrative 5572 04/07/1990 26442006 IUI-001 closed fracture of shaft of femur 5572 04/07/1990 81134009 IUI-001 Fracture, closed, spiral 5572 12/07/1990 26442006 IUI-001 closed fracture of shaft of femur 5572 12/07/1990 9001224 5572 04/07/1990 79001 IUI-005 Essential hypertension 0939 24/12/1991 255174002 IUI-004 benign polyp of biliary tract 2309 21/03/1992 26442006 IUI-002 closed fracture of shaft of femur 2309 21/03/1992 9001224 IUI-007 Accident in public building (supermarket) 47804 03/04/1993 58298795 Other lesion on other specified region 5572 17/05/1993 79001 IUI-005 Essential hypertension 298 22/08/1993 2909872 IUI-003 Closed fracture of radial head 298 22/08/1993 9001224 5572 01/04/1997 26442006 IUI-012 closed fracture of shaft of femur 5572 01/04/1997 79001 IUI-005 Essential hypertension 0939 20/12/1998 255087006 IUI-004 malignant polyp of biliary tract IUI-007 Accident in public building (supermarket) IUI-007 Accident in public building (supermarket) ECOR European Centre for Ontological Research Essentials of Referent Tracking • Generation of universally unique identifiers; • deciding what particulars should receive a IUI; • finding out whether or not a particular has already been assigned a IUI (each particular should receive maximally one IUI); • using IUIs in the EHR, i.e. issues concerning the syntax and semantics of statements containing IUIs; • determining the truth values of statements in which IUIs are used; • correcting errors in the assignment of IUIs. ECOR European Centre for Ontological Research Architecture of a Referent Tracking System (RTS) • RTS: system in which all statements referring to particulars contain the IUIs for those particulars judged to be relevant. • Ideally set up as broad as possible: – some metrics: • % of particulars referred to by means of IUI • % of HCs active in a region – Geographic region – functional region: defined by contacts amongst patients • % of patients referred to within a region • Services: – IUI generator – IUI repository: statements about assignments and reservations – Referent Tracking ‘Database’ (RTDB): index (LSID) to statements relating instances to instances and classes ECOR European Centre for Ontological Research Ultimate goal Ontology continuant disorder person CAG repeat EHR Juvenile HD #IUI-1 ‘affects’ #IUI-2 #IUI-3 ‘affects’ #IUI-2 #IUI-1 ‘causes’ #IUI-3 ... Referent Tracking Database
