SNOMED CT

From LIMSWiki
Jump to navigationJump to search
SNOMED CT
Developer(s)SNOMED International
Typemedical terms
Websitewww.snomed.org
As of2007

SNOMED CT or SNOMED Clinical Terms is a systematically organized computer-processable collection of medical terms providing codes, terms, synonyms and definitions used in clinical documentation and reporting. SNOMED CT is considered to be the most comprehensive, multilingual clinical healthcare terminology in the world.[1][2] The primary purpose of SNOMED CT is to encode the meanings that are used in health information and to support the effective clinical recording of data with the aim of improving patient care. SNOMED CT provides the core general terminology for electronic health records. SNOMED CT comprehensive coverage includes: clinical findings, symptoms, diagnoses, procedures, body structures, organisms and other etiologies, substances, pharmaceuticals, devices and specimens.

SNOMED CT is maintained and distributed by SNOMED International, an international non-profit standards development organization, located in London, UK. SNOMED International is the trading name of the International Health Terminology Standards Development Organisation (IHTSDO), established in 2007.

SNOMED CT provides for consistent information interchange and is fundamental to an interoperable electronic health record. It provides a consistent means to index, store, retrieve, and aggregate clinical data across specialties and sites of care. It also helps in organizing the content of electronic health records systems by reducing the variability in the way data are captured, encoded and used for clinical care of patients and research.[3] SNOMED CT can be used to directly record clinical details of individuals in electronic patient records. It also provides the user with a number of linkages to clinical care pathways, shared care plans and other knowledge resources, in order to facilitate informed decision-making, and to support long-term patient care. The availability of free automatic coding tools and services, which can return a ranked list of SNOMED CT descriptors to encode any clinical report, could help healthcare professionals to navigate the terminology.

SNOMED CT is a terminology that can cross-map to other international standards and classifications.[4] Specific language editions are available which augment the international edition and can contain language translations, as well as additional national terms. For example, SNOMED CT-AU, released in December 2009 in Australia, is based on the international version of SNOMED CT, but encompasses words and ideas that are clinically and technically unique to Australia.[5]

History

SNOMED started in 1965 as a Systematized Nomenclature of Pathology (SNOP) and was further developed into a logic-based health care terminology.[6][7]

SNOMED CT was created in 1999 by the merger, expansion and restructuring of two large-scale terminologies: SNOMED Reference Terminology (SNOMED RT), developed by the College of American Pathologists (CAP); and the Clinical Terms Version 3 (CTV3) (formerly known as the Read codes), developed by the National Health Service of the United Kingdom (NHS).[8] The final product was released in January 2002.[9][10] The International Health Terminology Standards Development Organisation now considers SNOMED CT to be a brand name rather than an acronym. Previously SNOMED was an acronym of Systematized Nomenclature Of Medicine, but it lost that meaning when SNOMED was combined with CTV3 (Clinical Terms Version 3) into the merged product called SNOMED Clinical Terms, which was shortened to SNOMED CT.

The historical strength of SNOMED was its coverage of medical specialties. SNOMED RT, with over 120,000 concepts, was designed to serve as a common reference terminology for the aggregation and retrieval of pathology health care data recorded by multiple organizations and individuals. The strength of CTV3 was its terminologies for general practice. CTV3, with 200,000 interrelated concepts, was used for storing structured information about primary care encounters in individual, patient-based records.[11] The January 2020 release of the SNOMED CT International Edition included more than 350,000 concepts.[12]

In July 2003, the National Library of Medicine (NLM), on behalf of the United States Department of Health and Human Services, entered into an agreement with the College of American Pathologists to make SNOMED CT available to U.S. users at no cost through the National Library of Medicine's Unified Medical Language System UMLS Metathesaurus. The NLM negotiation team was led by Betsy Humphreys,[13] and the contract provided NLM with a perpetual license for the core SNOMED CT (in Spanish and English) and its ongoing updates.[9][14][15]

In April 2007, SNOMED CT intellectual property rights were transferred from the CAP to the International Health Terminology Standards Development Organisation (IHTSDO) in order to promote international adoption and use of SNOMED CT. Now trading as SNOMED International, the organization is responsible for "ongoing maintenance, development, quality assurance, and distribution of SNOMED CT" internationally[6][5][10]

and its Membership consists of a number of the world's leading e-health countries and territories, including: Argentina, Australia, Belgium, Brunei, Canada, Czech Republic, Chile, Denmark, Estonia, Hong Kong, Iceland, India, Ireland, Israel, Lithuania, Malaysia, Malta, Netherlands, New Zealand, Norway, Poland, Portugal, Singapore, Slovak Republic, Republic of Slovenia, Spain, Sweden, Switzerland, United Kingdom, United States and Uruguay.[16]

SNOMED CT is a multinational and multilingual terminology, which can manage different languages and dialects. SNOMED CT is currently available in American English, British English, Spanish, Danish and Swedish, with other translations underway or nearly completed in French and Dutch. SNOMED CT cross maps to other terminologies, such as: ICD-9-CM, ICD-10, ICD-O-3, ICD-10-AM, Laboratory LOINC and OPCS-4. It supports ANSI, DICOM, HL7, and ISO standards.

Structure

SNOMED CT consists of four primary core components:

  1. Concept Codes – numerical codes that identify clinical terms, primitive or defined, organized in hierarchies
  2. Descriptions – textual descriptions of Concept Codes
  3. Relationships – relationships between Concept Codes that have a related meaning
  4. Reference Sets – used to group Concepts or Descriptions into sets, including reference sets and cross-maps to other classifications and standards.[17]

SNOMED CT "Concepts" are representational units that categorize all the things that characterize healthcare processes and need to be recorded therein. In 2011, SNOMED CT included more than 311,000 concepts, which are uniquely identified by a concept ID, e.g. the concept 22298006 refers to Myocardial infarction. All SNOMED CT concepts are organized into acyclic taxonomic (is-a) hierarchies; for example, Viral pneumonia IS-A Infectious pneumonia IS-A Pneumonia IS-A Lung disease. Concepts may have multiple parents, for example Infectious pneumonia is also a child of Infectious disease. The taxonomic structure allows data to be recorded and later accessed at different levels of aggregation. SNOMED CT concepts are linked by approximately 1,360,000 links, called relationships.[18]

Concepts are further described by various clinical terms or phrases, called Descriptions, which are divided into Fully Specified Names (FSNs), Preferred Terms (PTs), and Synonyms. Each Concept has exactly one FSN, which is unique across all of SNOMED CT. It has, in addition, exactly one PT, which has been decided by a group of clinicians to be the most common way of expressing the meaning of the concept. It may have zero to many Synonyms. Synonyms are additional terms and phrases used to refer to this concept. They do not have to be unique or unambiguous.[citation needed]

Semantic tag

SNOMED CT assigns each concept a semantic tag. It is present in parentheses in Fully Specified Name of each concept. There can be multiple semantic tags used within each SNOMED CT top level hierarchy. For example, top level hierarchy of Pharmaceutical/biologic Product uses semantic tags of: product, medicinal product, medicinal product form and clinical drug. Only one semantic tag can be used for each concept.[citation needed]

The formal model underlying SNOMED CT

SNOMED CT statistics (as of November 2016). SD stands for sufficiently defined.

SNOMED CT can be characterized as a multilingual thesaurus with an ontological foundation. Thesaurus-like features are concept–term relations such as the synonymous descriptions "Acute coryza", "Acute nasal catarrh", "Acute rhinitis", "Common cold" (as well as Spanish "resfrío común" and "rinitis infecciosa") for the concept 82272006.

Under ontological scrutiny, SNOMED-CT is a class hierarchy (with extensive overlap of classes in contrast to typical statistical classifications like ICD).

This means that the SNOMED CT concept 82272006 defines the class of all the individual disease instances that match the criteria for "common cold" (e.g., one patient may have "head cold" noted in their record, and another may have "Acute coryza"; both can be found as instances of "common cold"). The superclass (Is-A) Relation relates classes in terms of inclusion of their members. That is, all individual "cold-processes" are also included in all superclasses of the class Common Cold, such as Viral upper respiratory tract infection (Figure).

Common cold as a primitive concept in SNOMED CT

SNOMED CT's relational statements are basically triplets of the form Concept1 – Relationx – Concept2, with Relationx being from a small number of relation types (called linkage concepts), e.g. finding site, due to, etc. The interpretation of these triplets is (implicitly) based on the semantics of a simple Description logic (DL). E.g., the triplet Common Coldcausative agentVirus, corresponds to the first-order expression

forall x: instance-of (x, Common cold) -> exists y: instance-of (y, Virus) and causative-agent (y, x)

or the more intuitive DL expression

Common cold subClassOf causative-agent some Virus

In the Common cold example the concept description is "primitive", which means that necessary criteria are given that must be met for each instance, without being sufficient for classifying a disorder as an instance of Common Cold . In contrast, the example Viral upper respiratory tract infection depicts a fully described concept, which is represented in description logic as follows:

Viral upper respiratory tract infection as a defined concept in SNOMED CT

 Viral upper respiratory tract infection equivalentTo
  Upper respiratory infection and Viral respiratory infection and
   Causative-agent some Virus and
   Finding-site some Upper respiratory tract structure and
   Pathological-process some Infectious process

This means that each and every individual disorder for which all definitional criteria are met can be classified as an instance of Viral upper respiratory tract infection.

Description logics

As of 2021, SNOMED CT content limits itself to a subset of the EL++ formalism, restricting itself to the following operators:

  • Top, bottom
  • Primitive roles and concepts with asserted parent(s) for each
  • Concept definition and conjunction but NOT disjunction or negation
  • Role hierarchy but not role composition
  • Domain and range constraints
  • Existential but not universal restriction
  • A restricted form of role inclusion axiom (xRy ^ ySz => xRz)
  • General Concept Inclusion axioms (A ⊆ B).

For understanding the modelling, it is also important to look at the stated view of a concept versus the inferred view of the concept. In further considering the state view, SNOMED CT used in the past a modelling approach referred to as 'proximal parent' approach. After 2015, a superior approach called "proximal primitive parent" has been adopted.

Precoordination and postcoordination

SNOMED CT provides a compositional syntax[19] that can be used to create expressions that represent clinical ideas which are not explicitly represented by SNOMED CT concepts. This mechanism exists because it is challenging to create and maintain all possible concepts upfront (as precoordinated concepts).

For example, there is no explicit concept for a "third degree burn of left index finger caused by hot water". However, using the compositional syntax it can be represented as

284196006 | burn of skin | :
   116676008 | associated morphology | = 80247002 | third degree burn injury |
 , 272741003 | laterality | = 7771000 | left |
 , 246075003 | causative agent | = 47448006 | hot water |
 , 363698007 | finding site | = 83738005 | index finger structure

Such expressions are said to have been 'postcoordinated'. Post-coordination avoids the need to create large numbers of defined Concepts within SNOMED CT. However, many systems only allow for precoordinated representations. Reliable analysis and comparison of post-coordinated expressions is possible using appropriate algorithms machinery to efficiently process the expression taking account of the underlying description logic.

Major Electronic Health Record Systems (EHRS) have repeatedly complained to IHTSDO and other standards organizations about the "complexity" of post-coordinated expressions.

For example, the postcoordinated expression above can be transformed using a set of standard rules to the following "normal form expression" which enables comparison with similar concepts.

64572001 | disease | :
   246075003 | causative agent | = 47448006 | hot water |
 , 363698007 | finding site | = ( 83738005 | index finger structure | :
          272741003 | laterality | = 7771000 | left | )
 , { 116676008 | associated morphology | = 80247002 | third degree burn injury |
 , 363698007 | finding site | = 39937001 | skin structure | }

Postcoordination is an important desirable feature of a terminology. Prior 2020, International Classification of Diseases (ICD) did not allow post-coordination and SNOMED CT was the only terminology that supported postcoordination. Since 2020, a new version of ICD-11 now also supports postcoordination.

Veterinary content

The International Edition of SNOMED CT only includes human terms. In 2014, clearly veterinary concepts were moved into a SNOMED CT veterinary extension. This extension is managed by the Veterinary Terminology Services Lab[20] at the Va-Md College of Veterinary Medicine at Virginia Tech.

Known deficiencies and mitigation strategies

Earlier SNOMED versions had faceted structure ordered by semantic axes, requiring that more complex situations required to be coded by a coordination of different codes. This had two major shortcomings. On the one hand, the necessity of post-coordination was perceived as a user-unfriendly obstacle, which has certainly contributed to the rather low adoption of early SNOMED versions. On the other hand, uniform coding was difficult to obtain. E.g.,Acute appendicitis could be post-coordinated in three different ways[21] with no means to compute semantic equivalences. SNOMED RT had addressed this problem by introducing description logic formula. With the addition of CTV3 a large number of concepts were redefined using formal expressions. However, the fusion with CTV3, as a historically grown terminology with many close-to user descriptions, introduced some problems which still affect SNOMED CT. In addition to a confusing taxonomic web of many hierarchical levels with massive multiple inheritance (e.g. there are 36 taxonomic ancestors for Acute appendicitis), many ambiguous, context-dependent concepts have found their way into SNOMED CT. Pre-coordination was sometimes pushed to extremes, so there are, for example, 350 different concepts for burns found on the head.[citation needed]

A further phenomenon which characterizes parts of SNOMED CT is the so-called epistemic intrusion.[22]

In principle, the task of terminology (and even an ontology) should be limited to providing context-free term or class meanings. The contextualization of these representational units should be ideally the task of an information model.[23] Human language is misleading here, as we use syntactically similar expression to represent categorically distinct entities, e.g. Ectopic pregnancy vs. Suspected pregnancy. The first one refers to a real pregnancy, the second one to a piece of (uncertain) information. In SNOMED CT most (but not all) of these context-dependent concepts are concentrated in the subhierachy Situation with explicit context. A major reason for why such concepts cannot be dispensed with is that SNOMED CT takes on, in many cases, the functionality of information models, as the latter do not exist in a given implementation.

With the establishment of IHTSDO, SNOMED CT became more accessible to a wider audience. Criticism of the state of the terminology was sparked by numerous substantive weaknesses as well as on the lack of quality assurance measures.[24] From the beginning IHTSDO was open regarding such (also academic) criticism. In the last few years considerable progress has been made regarding quality assurance and tooling.

The need for a more principled ontological foundation was gradually accepted, as well as a better understanding of description logic semantics. Redesign priorities were formulated regarding observables,[25] disorders, findings,[26] substances, organisms etc. Translation guidelines[27] were elaborated as well as guidelines for content submission requests and a strategy for the inclusion of pre-coordinated content. There are still known deficiencies regarding the "ontological commitment" of SNOMED CT,[28] e.g., the clarification of which kind of entity is an instance of a given SNOMED CT concept. The same term can be interpreted as a disorder or a patient with a disorder, for example Tumour might denote a process or a piece of tissue; Allergy may denote an allergic reaction or just an allergic disposition. A more recent strategy is the use of rigorously typed upper-level ontologies to disambiguate SNOMED CT content.

The increased take-up of SNOMED CT for research into applications in daily use across the world to support patient care is leading to a larger engaged community. This has led to an increase in the resource allocated to authoring SNOMED CT terms as well as to an increase in collaboration to take SNOMED CT into a robust industry used standard. This is leading to an increase in the number of software tools and development of materials that contribute to knowledge base to support implementation. A number of on-line communities that focus on particular aspects of SNOMED CT and its implementation are also developing.

In theory, description logic reasoning can be applied to any new candidate post-coordinated expressions in order to assess whether it is a parent or ancestor of, a child or other descendant of, or semantically equivalent to any existing concept from the existing pre-coordinated concepts. However, partly as the continuing fall-out from the merger with CTV3, SNOMED still contains undiscovered semantically duplicate primitive and defined concepts. Additionally, many concepts remain primitive whilst their semantics can also be legitimately defined in terms of other primitives and roles concurrently in the system. Because of these omissions and actual or possible redundancies of semantic content, real-world performance of algorithms to infer subsumption or semantic equivalence will be unpredictably imperfect.

SNOMED CT validation

Using consistent rules is important for the quality of SNOMED CT. To that end, in 2009, a prototype Machine Readable Concept Model (MRCM) was created by the SNOMED CT team. In a follow-up work, this model is being revised to utilize SNOMED CT expression constraints.

SNOMED CT and other terminologies

SNOMED CT and ICD

SNOMED CT is a clinical terminology designed to capture and represent patient data for clinical purposes.[29] The International Statistical Classification of Diseases and Related Health Problems (ICD) is an internationally used medical classification system; which is used to assign diagnostic and, in some national modifications, procedural codes in order to produce coded data for statistical analysis, epidemiology, reimbursement and resource allocation.[30] Both systems use standardized definitions and form a common medical language used within electronic health record (EHR) systems.[31] SNOMED CT enables information input into an EHR system during the course of patient care, while ICD facilitates information retrieval, or output, for secondary data purposes.[31][32] In 2010s, the advantage of SNOMED CT over ICD was the multiple parent hierarchy of SNOMED CT. Since 2020 release of ICD 11, this advantage is less important because ICD-11 foundational level allows an ICD 11 concept to have multiple parents.

SNOMED CT ICD (Mortality and Morbidity Statistics view)
Type Terminology System Classification System
Purpose Information Input Information Output
Function Describes and defines clinical information for primary data purposes Aggregates and categorizes clinical information for secondary data purposes

SNOMED CT and LOINC

LOINC is a terminology that contains laboratory tests. Since 2017, SNOMED International started creating terms for LOINC components and created a set of SNOMED CT expressions that capture the meaning of many LOINC terms.

SNOMED CT and MedDRA

There is overlap between MedDRA and SNOMED CT that is not beneficial for pharmaceutical industry. In 2021, two maps map between SNOMED CT and MedDRA were jointly published by both organizations (from SNOMED CT to MedDRA and from MedDRA to SNOMED CT).[33]

Use

SNOMED CT is used in a number of different ways, some of which are:

  • It captures clinical information at the level of detail needed for the provision of healthcare
  • Through sharing data it can reduce the need to repeat health history at each new encounter with a healthcare professional
  • Information can be recorded by different people in different locations and combined into simple information views within the patient record
  • Use of a common terminology decreases the potential for differing interpretation of information
  • Structured Data Capture medical forms and questionnaires based on the FHIR standard[34]
  • Electronic recording in a common way reduces errors and can help to ensure completeness in recording all relevant data
  • Standardised information makes analysis easier, supporting quality, cost effective practice, research and future clinical guideline development
  • A clinical terminology allows a health care provider to identify patients based on specified coded information, and more effectively manage screening, treatment and follow up

Use cases

More specifically, the following sample computer applications use SNOMED CT:

  • Electronic Health Record Systems
  • Computerized Provider Order Entry CPOE such as E-Prescribing or Laboratory Order Entry
  • Catalogues of clinical services; e.g., for Diagnostic Imaging procedures
  • Knowledge databases used in clinical decision support systems (CDSS)
  • Remote Intensive Care Unit Monitoring
  • Laboratory Reporting
  • Emergency Room Charting
  • Cancer Reporting
  • Genetic Databases

Access

SNOMED CT is maintained and distributed by SNOMED International, an international non-profit standards development organization, located in London, UK.

The use of SNOMED CT in production systems requires a license. There are two types of license:

  1. Country/territory membership in SNOMED International (charged according to gross national product).
  2. Affiliate license (dependent on the number of end users). LDCs (least developed countries) can use SNOMED CT without charges.

For scientific research in medical informatics, for demonstrations or evaluation purposes SNOMED CT sources can be freely downloaded and used. The original SNOMED CT sources in tabular form are accessible by registered users of the Unified Medical Language System (UMLS) who have signed an agreement. Numerous online and offline browsers are available.

Those wishing to obtain a license for its use and to download SNOMED CT should contact their National Release Centre, links to which are provided on the IHTSDO website.

License free subsets

To facilitate adoption of SNOMED CT and use of SNOMED CT in other standards, there are license free subsets. For example, a set of 7 314 codes and descriptions is free for use by users of DICOM-compliant software (without restriction to IHTSDO member countries).[35][36]

Global Patient Set (GPS) subset

GPS was released in Sep 2019 and contains 21 782 concepts.[37]

Top level concepts

SNOMED CT concepts typically belong to a single hierarchy (with the exception of drug-device combined concepts). Some hierarchies, have a concept model defined (e.g., clinical findings). For other domains (e.g., Organism, Substance, Qualifier value), there is no concept model yet defined.

Procedure

diagram of examle concept in SNOMED CT showing relationships
Procedure example

Concept in this hierarchy represent procedures performed on a patient. There is a well established defined concept model for procedures. Procedure site (direct or indirect) specifies on what part of body the procedure is performed. A separate set of rules exist for evaluation procedures. Evaluation procedures are procedures where evidence is evaluated to support the determination of a value, inference or conclusion. Evaluation procedures have additional attributes, such as 'Has specimen','Property' or 'Measurement method'.

Event

As of 2016, the Event hierarchy does not have a concept model defined. In 2006, some concepts from the 'Clinical Finding' hierarchy were moved to the Event hierarchy. Those concepts retained some of their attributes. (e.g., causative agent)

Observable entities

SNOMED International is working on creating a concept model for observable entities.[38]

Body Structure

Body parts represent one of the largest hierarchies within SNOMED CT. The modeling is based on Foundational Model of Anatomy but it differs from the model in some aspects (e.g., region is taken as 3D region and not a 2D region). Important attributes include: 'Laterality', several types of 'Part of' relationships, and 'Is a'.

Pharmaceutical / biologic product

Pharmaceutical product example

Pharmaceutical and biologic products are modeled using constructs of active ingredient, presentation strength, and basis of strength. Since 2018, harmonization of SNOMED CT drug content with IDMP standard is an editorial goal. The following types of entities are present:

Medicinal product

A higher level term grouping drugs. For example, 398731002 | Product containing sulfamethoxazole and trimethoprim (medicinal product) |

Clinical Drug

Concept that represents a concrete drug product as used in clinical practice. For example, 317335000 | Product containing precisely esomeprazole 20milligram/1 each conventional release oral tablet (clinical drug)|

Dose Form

Concept representing how the product is delivered. For example, 385219001 | Conventional release solution for injection (dose form) |.

Authoring conventions

A goal for SNOMED CT is consistency. Several mechanisms are employed to ensure this. Machine readable concept model is used to check for compliance with a set of rules. Rules for creating fully specified name for a concept define allowed and not allowed patterns.[39] When defining a concept, a proximal primitive parent rule is used (in stated definition) to employ best description logic derived classification of concepts.

Separate conventions govern grouping of relationships. Ability to group related relationships is an important strength of SNOMED CT. Rules in Machine Readable Concept Model (MRCM)[40] specify by domain which relationships are never grouped (e.g., 'Is a' or 'Laterality' attributes) and which relationships are always grouped (e.g., 'Finding site'). For correct subsumption inference, some relationships may be in a group but consist of a single relationship.

Another convention for SNOMED CT international edition is to avoid creating intermediate primitive concepts (unless medically necessary and impossible to define with existing concept model). An intermediate primitive (=not defined) concept is a non-defined concept that has children concepts and parent concepts. This convention is related to the use of description logic to facilitate terminology maintenance. Because primitive concepts can not be processed by the description logic classifier, the maintenance of such concepts relies solely on human editors. Adding new intermediate primitive concepts requires changes to all affected concepts and is demanding in terms of terminology maintenance.

See also

References

  1. ^ Benson, Tim (2012). Principles of Health Interoperability HL7 and SNOMED. London, England: Springer. ISBN 978-1-4471-2800-7.
  2. ^ "Health Information Technology and Health Data Standards at NLM". www.nlm.nih.gov.
  3. ^ Ruch, Patrick; Gobeill, Julien; Lovis, Christian; Geissbühler, Antoine (2008). "Automatic medical encoding with SNOMED categories". BMC Medical Informatics and Decision Making. 8 (Suppl 1): S6. doi:10.1186/1472-6947-8-S1-S6. PMC 2582793. PMID 19007443.
  4. ^ "Use SNOMED CT". www.snomed.org. International Health Terminology Standards Development Organisation. Retrieved 5 August 2020.
  5. ^ a b "Our Work: Clinical Terminology: SNOMED-CT-AU". Archived from the original on 27 April 2015. Retrieved 26 April 2015.
  6. ^ a b "History Of SNOMED CT". International Health Terminology Standards Development Organisation. Archived from the original on 26 November 2016. Retrieved 26 April 2015.
  7. ^ Cornet, Ronald; de Keizer, Nicolette (2008). "Forty years of SNOMED: a literature review". BMC Medical Informatics and Decision Making. 8 (Suppl 1): S2. doi:10.1186/1472-6947-8-S1-S2. PMC 2582789. PMID 19007439.
  8. ^ Price, Colin (2000). "Towards a "New" International Terminology for Health: Read Clinical Terms and SNOMED". Journal of Informatics in Primary Care. 9 (1): 15–17. Archived from the original on 2020-11-25. Retrieved 2020-12-01.
  9. ^ a b "SNOMED Clinical Terms To Be Added To UMLS Metathesaurus". United States National Library of Medicine. 24 May 2006. Archived from the original on 15 January 2023. Retrieved 26 April 2015.
  10. ^ a b "FAQs: SNOMED CT in the UMLS". United States National Library of Medicine. 22 May 2012. Archived from the original on 13 January 2023. Retrieved 26 April 2015.
  11. ^ Stearns, Michael Q.; Price, Colin; Spackman, Kent A.; Wang, Amy Y. (2001). "SNOMED Clinical Terms: Overview of the Development Process and Project Status". Proceedings of the AMIA Symposium. American Medical Informatics Association: 662–666. PMC 2243297. PMID 11825268.
  12. ^ "5-Step briefing". www.snomed.org. Retrieved 5 August 2020.
  13. ^ "Proposed Snomed licensing agreement could be 'watershed' development for healthcare". Modern Healthcare. 2003-02-21. Retrieved 2019-05-31.
  14. ^ "SNOMED license agreement". United States National Library of Medicine. 24 May 2006. Archived from the original on 13 September 2015. Retrieved 26 April 2015.
  15. ^ "SNOMED Clinical Terms® (SNOMED CT®)". www.nlm.nih.gov.
  16. ^ "Members". www.snomed.org. International Health Terminology Standards Development Organisation. Archived from the original on 25 July 2020. Retrieved 5 August 2020.
  17. ^ SNOMED CT and HL7 – Bringing Standards Together
  18. ^ SNOMED CT Documentation is publicly available at http://www.snomed.org/doc
  19. ^ SNOMED CT Compositional Grammar https://confluence.ihtsdotools.org/display/DOCSCG/Compositional+Grammar+-+Specification+and+Guide Archived 2024-09-06 at the Wayback Machine
  20. ^ "Veterinary Terminology Services Lab". Archived from the original on 2019-01-11. Retrieved 2018-10-18.
  21. ^ Spackman KA, Campbell KE. "Compositional concept representation using SNOMED: towards further convergence of clinical terminologies". Proc AMIA Symp. 1998: 740–744.
  22. ^ Ingenerf, J; Linder, R (2009). "Assessing applicability of ontological principles to different types of biomedical vocabularies". Methods of Information in Medicine. 48 (5): 459–467. doi:10.3414/me0628. PMID 19448888. S2CID 30468675. Archived from the original on 2016-03-04. Retrieved 2015-07-07.
  23. ^ Rector A. (2008) Barriers, approaches and research priorities for integrating biomedical ontologies. Semantic Health Deliverable 6.1 "Trading Reviews und Tests – Wir testen Broker" (PDF). Archived from the original (PDF) on 2012-04-13. Retrieved 2012-04-13.
  24. ^ Stefan Schulz; Boontawee Suntisrivaraporn; Franz Baader; Martin Boeker (April 2009). "SNOMED reaching its adolescence: Ontologists' and logicians' health check". International Journal of Medical Informatics. 78 (Supplement 1): S86–S94. doi:10.1016/j.ijmedinf.2008.06.004. PMID 18789754. Archived from the original on 2019-08-25. Retrieved 2016-05-23.
  25. ^ SNOMED CT® Style Guide: Observable Entities and Evaluation Procedures (Laboratory) Draft IHTSDO Standard v1.0, 2010-06-30, http://ihtsdo.org/fileadmin/user_upload/Docs_01/Publications/Drafts_for_review/SNOMED_CT_Style_Guide_Observables_v1.0.pdf Archived 2016-06-01 at the Wayback Machine
  26. ^ Schulz, S; Spackman, K; James, A; Cocos, C; Boeker, M (May 2011). "Scalable representations of diseases in biomedical ontologies" (PDF). Journal of Biomedical Semantics. 17 (2(Suppl 2)): S6. doi:10.1186/2041-1480-2-S2-S6. PMC 3102895. PMID 21624161. Archived (PDF) from the original on 2022-03-18. Retrieved 2019-09-05.
  27. ^ "Archived copy" (PDF). www.ihtsdo.org. Archived from the original (PDF) on 25 December 2010. Retrieved 15 January 2022.{{cite web}}: CS1 maint: archived copy as title (link)
  28. ^ Schulz, S; Cornet, R; Spackman, K Consolidating SNOMED CT's . Applied ontology. 2011; 6: 1-11.
  29. ^ Kostick, K. (2012) SNOMED CT Integral Part of Quality HER Documentation. Journal of AHIMA 83.10 (October 2012): 72-75.
  30. ^ "WHO - International Classification of Diseases, 11th Revision (ICD-11)". WHO. Archived from the original on 12 February 2014. Retrieved 5 August 2020.
  31. ^ a b Bowman, S. (2005) Coordinating SNOMED-CT and ICD-10: Getting the Most out of Electronic Health Record Systems. Journal of AHIMA 76(7):60-61. www.ahima.org/perspectives
  32. ^ Truran, D., Saad, P. Zhang, M., Innes, K. (2010) SNOMED CT and its place in health information management practice. Health Information Management Journal Vol 39 (2):37-39 ISSN 1833-3583 (Print) 1833-3575 (Online)
  33. ^ "MedDRA". www.meddra.org. Archived from the original on 2024-09-06. Retrieved 2021-07-13.
  34. ^ "SDC Home Page - Structured Data Capture v3.0.0". build.fhir.org. Archived from the original on 2024-01-12. Retrieved 2024-01-12.
  35. ^ "Blog - SNOMED International Confluence - SNOMED Confluence". confluence.ihtsdotools.org.
  36. ^ "SNOMED CT® LICENSE AGREEMENT" (PDF). dicomstandard.org. Archived (PDF) from the original on 6 September 2024. Retrieved 10 December 2022.
  37. ^ "The Global Patient Set". snomed.org. Archived from the original on 23 October 2020. Retrieved 5 August 2020.
  38. ^ "Observables Inception-Elaboration document - Observable and Investigation Model Project - SNOMED Confluence".
  39. ^ "Naming Patterns". SNOMED International. Archived from the original on 6 September 2024. Retrieved 18 March 2021.
  40. ^ "Browser". Archived from the original on 30 April 2021. Retrieved 28 April 2021.

Notes

This article is a direct transclusion of the Wikipedia article and therefore may not meet the same editing standards as LIMSwiki.