Jump to content

Merative

From Wikipedia, the free encyclopedia
(Redirected from Watson Health)
Merative L.P.
Company typePrivate
PredecessorIBM Watson Health
FoundedJune 30, 2022; 2 years ago (2022-06-30)
HeadquartersAnn Arbor, Michigan
Key people
  • Gerry McCarthy (CEO)
OwnerFrancisco Partners
Number of employees
1,000–5,000
Websitemerative.com

Merative L.P., formerly IBM Watson Health, is an American medical technology company that provides products and services that help clients facilitate medical research, clinical research, real world evidence, and healthcare services, through the use of artificial intelligence, data analytics, cloud computing, and other advanced information technology. Merative is owned by Francisco Partners, an American private equity firm headquartered in San Francisco, California. In 2022, IBM divested and spun-off their Watson Health division into Merative. As of 2023, it remains a standalone company headquartered in Ann Arbor with innovation centers in Hyderabad, Bengaluru, and Chennai.[1]

History

[edit]

Thomson Healthcare was a division of Thomson Corporation until 2008, when, following Thomson's merger with Reuters, it became the healthcare unit of Thomson Reuters. On April 23, 2012, Thomson Reuters agreed to sell it to Veritas Capital for US$1.25 billion.[2] On June 6, 2012, the sale was finalized and the new company, Truven Health Analytics, became an independent organization solely focused on healthcare.[3]

IBM Corporation acquired Truven Health Analytics on February 18, 2016, and merged it with IBM's Watson Health unit.[4] Truven Health Analytics provided comprehensive healthcare data and analytics services,[5] Their solutions included information, analytic tools, benchmarks, research, and services to the healthcare industry, including hospitals, government agencies, employers, health plans, clinicians, pharmaceutical, biotech and medical device companies. The company name Truven is a portmanteau of the words "trusted" and "proven".[6]

In January 2022, IBM announced the sale of part of the Watson Health assets, including Truven to Francisco Partners for a reported $1 billion.[7] On June 30, 2022, Francisco Partners announced the completion of acquiring Watson Health and launched a healthcare data company named Merative.[8][9]

Advancements

[edit]

Watson's natural language, hypothesis generation, and evidence-based learning capabilities are being investigated to see how Watson may contribute to clinical decision support systems, and the increase in artificial intelligence in healthcare for use by medical professionals.[10] To aid physicians in the treatment of their patients, once a physician has posed a query to the system describing symptoms and other related factors, Watson first parses the input to identify the most important pieces of information; then mines patient data to find facts relevant to the patient's medical and hereditary history; then examines available data sources to form and test hypotheses;[10] and finally provides a list of individualized, confidence-scored recommendations.[11] The sources of data that Watson uses for analysis can include treatment guidelines, electronic medical record data, notes from healthcare providers, research materials, clinical studies, journal articles and patient information.[10] Despite being developed and marketed as a "diagnosis and treatment advisor", Watson has never been actually involved in the medical diagnosis process, only in assisting with identifying treatment options for patients who have already been diagnosed.[12]

In February 2011, it was announced that IBM would be partnering with Nuance Communications for a research project to develop a commercial product during the next 18 to 24 months, designed to exploit Watson's clinical decision support capabilities. Physicians at Columbia University would help to identify critical issues in the practice of medicine, where the system's technology may be able to contribute. And also, physicians at the University of Maryland would work to identify the best way that a technology like Watson could interact with medical practitioners to provide the maximum assistance.[13]

In September 2011, IBM and WellPoint (now Anthem) announced a partnership to utilize Watson's data crunching capability to help suggest treatment options to physicians.[14] Then, in February 2013, IBM and WellPoint gave Watson its first commercial application, for utilization management decisions in lung cancer treatment at Memorial Sloan–Kettering Cancer Center.[15]

IBM announced a partnership with Cleveland Clinic in October 2012. The company has sent Watson to the Cleveland Clinic Lerner College of Medicine of Case Western Reserve University, where it will increase its health expertise and assist medical professionals in treating patients. The medical facility will utilize Watson's ability to store and process large quantities of information to help speed up and increase the accuracy of the treatment process. "Cleveland Clinic's collaboration with IBM is exciting because it offers us the opportunity to teach Watson to 'think' in ways that have the potential to make it a powerful tool in medicine", said C. Martin Harris, MD, chief information officer of Cleveland Clinic.[16]

In 2013, IBM and MD Anderson Cancer Center began a pilot program to further the center's "mission to eradicate cancer".[17][18] However, after spending $62 million, the project did not meet its goals and it has been stopped.[19]

On February 8, 2013, IBM announced that oncologists at the Maine Center for Cancer Medicine and Westmed Medical Group in New York have started to test the Watson supercomputer system in an effort to recommend treatment for lung cancer.[20]

On July 29, 2016, IBM and Manipal Hospitals[21] (a leading hospital chain in India) announced the launch of IBM Watson for Oncology, for cancer patients. This product provides information and insights to physicians and cancer patients to help them identify personalized, evidence-based cancer care options. Manipal Hospitals is the second hospital[22] in the world to adopt this technology and first in the world to offer it to patients online as an expert second opinion through their website.[23] Manipal discontinued this contract in December 2018.

On January 7, 2017, IBM and Fukoku Mutual Life Insurance entered into a contract for IBM to deliver analysis to compensation payouts via its IBM Watson Explorer AI, this resulted in the loss of 34 jobs and the company said it would speed up compensation payout analysis via analysing claims and medical record and increase productivity by 30%. The company also said it would save ¥140m in running costs.[24]

It is said that IBM Watson will carry the knowledge-base of 1000 cancer specialists, which will bring a revolution in the field of healthcare. IBM is regarded as a disruptive innovation. However, the stream of oncology is still in its nascent stage.[25]

Several startups in the healthcare space have been effectively using seven business model archetypes to take solutions[buzzword] based on IBM Watson to the marketplace. These archetypes depends on the value generated for the target user (e.g. patient focus vs. healthcare provider and payer focus) and value capturing mechanisms (e.g. providing information or connecting stakeholders).[26]

In 2019, Eliza Strickland calls "the Watson Health story [...] a cautionary tale of hubris and hype" and provides a "representative sample of projects" with their status.[27] A 2021 post from the Association for Computing Machinery (ACM) titled "What Happened To Watson Health?" described the portfolio management challenges of Watson Health given the number of acquisitions involved in the division creation in 2015, and its near-total emphasis on the "Blue Washing" process over acquisition customer-base needs.[28]

On January 21, 2022, IBM announced that it would sell Watson Health to the private equity firm of Francisco Partners.[29]

Industry considerations and challenges

[edit]

The subsequent motive of large based health companies merging with other health companies, allows for greater health data accessibility.[30] Greater health data may allow for more implementation of AI algorithms.[31]

A large part of industry focus of implementation of AI in the healthcare sector is in the clinical decision support systems.[32] As the amount of data increases, AI decision support systems become more efficient. Numerous companies are exploring the possibilities of the incorporation of big data in the health care industry.[33]

IBM's Watson Oncology is in development at Memorial Sloan Kettering Cancer Center and Cleveland Clinic.[34] IBM is also working with CVS Health on AI applications in chronic disease treatment and with Johnson & Johnson on analysis of scientific papers to find new connections for drug development.[35] In May 2017, IBM and Rensselaer Polytechnic Institute began a joint project entitled Health Empowerment by Analytics, Learning and Semantics (HEALS), to be explored using AI technology to enhance healthcare.[36]

Some other large companies that have contributed to AI algorithms for use in healthcare include:

Microsoft

[edit]

Microsoft's Hanover project, in partnership with Oregon Health & Science University's Knight Cancer Institute, analyzes medical research to predict the most effective cancer drug treatment options for patients.[37] Other projects include medical image analysis of tumor progression and the development of programmable cells.[38]

Google

[edit]

Google's DeepMind platform is being used by the UK National Health Service (NHS) to detect certain health risks through data collected via a mobile app.[39] A second project with the NHS involves analysis of medical images collected from NHS patients to develop computer vision algorithms to detect cancerous tissues.[40]

Intel

[edit]

Intel's venture capital arm (Intel Capital) recently invested in startup Lumiata, which uses AI to identify at-risk patients and develop care options.[41]

Artificial intelligence in healthcare is the use of complex algorithms and software to emulate human cognition in the analysis of complicated medical data. Specifically, AI is the ability for computer algorithms to approximate conclusions without direct human input.

What distinguishes AI technology from traditional technologies in health care is the ability to gain information, process it and give a well-defined output to the end-user. AI does this through machine learning algorithms. These algorithms can recognize patterns in behavior and create its own logic. In order to reduce the margin of error, AI algorithms need to be tested repeatedly. AI algorithms behave differently from humans in two ways: (1) algorithms are literal: if you set a goal, the algorithm can't adjust itself and only understand what it has been told explicitly, (2) and algorithms are black boxes; algorithms can predict extremely precise, but not the cause or the why.[42]

The primary aim of health-related AI applications is to analyze relationships between prevention or treatment techniques and patient outcomes.[43] AI programs have been developed and applied to practices such as diagnosis processes, treatment protocol development, drug development, personalized medicine, and patient monitoring and care. Medical institutions such as The Mayo Clinic, Memorial Sloan Kettering Cancer Center,[44][45] and National Health Service,[46] have developed AI algorithms for their departments. Large technology companies such as IBM[47] and Google,[46] and startups such as Welltok and Ayasdi,[48] have also developed AI algorithms for healthcare. Additionally, hospitals are looking to AI solutions[buzzword] to support operational initiatives that increase cost saving, improve patient satisfaction, and satisfy their staffing and workforce needs.[49] Companies are developing predictive analytics solutions[buzzword] that help healthcare managers improve business operations through increasing utilization, decreasing patient boarding, reducing length of stay and optimizing staffing levels.[50]

The following medical fields are of interest in artificial intelligence research:

Radiology

[edit]

The ability to interpret imaging results with radiology may aid clinicians in detecting a minute change in an image that a clinician might accidentally miss. A study at Stanford created an algorithm that could detect pneumonia at that specific site, in those patients involved, with a better average F1 metric (a statistical metric based on accuracy and recall), than the radiologists involved in that trial.[51] The radiology conference in Radiological Society of North America has implemented presentations on AI in imaging during its annual meeting. The emergence of AI technology in radiology is perceived as a threat by some specialists, as the technology can achieve improvements in certain statistical metrics in isolated cases, as opposed to specialists.[52][53]

Imaging

[edit]

Recent advances have suggested the use of AI to describe and evaluate the outcome of maxillo-facial surgery or the assessment of cleft palate therapy in regard to facial attractiveness or age appearance.[54][55]

In 2018, a paper published in the journal of Annals of Oncology mentioned that skin cancer could be detected more accurately by an artificial intelligence system (which used a deep learning convolutional neural network) than by dermatologists. On average, the human dermatologists accurately detected 86.6% of skin cancers from the images, compared to 95% for the CNN machine.[56]

Disease Diagnosis

[edit]

There are many diseases out there but there are also many ways that AI has been used to efficiently and accurately diagnose them. Some of the diseases that are the most notorious are Diabetes, and Cardiovascular Disease (CVD), which are both in the top ten for causes of death worldwide, and have been the basis behind  a lot of the research/testing to help get an accurate diagnosis. Due to such a high mortality rate being associated with these diseases, there have been efforts to integrate various methods in helping get accurate diagnosis.

An article by Jiang, et al. (2017)[57] demonstrated that there are multiple different types of AI techniques that have been used for a variety of different diseases. Some of these techniques discussed by Jiang, et al. include: Support vector machines, neural networks, decision trees, and many more. Each of these techniques are described as having a “training goal” so “classifications agree with the outcomes as much as possible…”.[57]

To demonstrate some specifics for disease diagnosis/classification, there are two different techniques used in the classification of these diseases which include using "Artificial Neural Networks (ANN) and Bayesian Networks (BN)”.[58] From a review of multiple different papers within the timeframe of 2008–2017,[58] it was observed within them which of the two techniques were better.  The conclusion that was drawn was that “the early classification of these  diseases can be achieved by developing machine learning models such as Artificial Neural Network and Bayesian Network.”  In another conclusion, Alic, et al. (2017)[58] was able to draw was that between the two; ANN and BN is that ANN was better and could more accurately classify diabetes/CVD with a mean accuracy in “both cases (87.29 for diabetes and 89.38 for CVD).

Telehealth

[edit]

The increase of Telemedicine, has shown the rise of possible AI applications.[59] The ability to monitor patients using AI may allow for the communication of information to physicians if possible disease activity may have occurred.[60] A wearable device may allow for constant monitoring of a patient and also allow for the ability to notice changes that may be less distinguishable by humans.

Electronic health records

[edit]

Electronic health records are crucial to the digitalization and information spread of the healthcare industry. However logging all of this data comes with its own problems like cognitive overload and burnout for users. EHR developers are now automating much of the process and even starting to use natural language processing (NLP) tools to improve this process. One study conducted by the Centerstone research institute found that predictive modeling of EHR data has achieved 70–72% accuracy in predicting individualized treatment response at baseline.[61] Meaning that using an AI tool that scans EHR data would pretty accurately predict the cause of disease in a person.

Drug Interactions

[edit]

Improvements in Natural Language Processing led to the development of algorithms to identify drug-drug interactions in medical literature.[62][63][64][65] Drug-drug interactions pose a threat to those taking multiple medications simultaneously, and the danger increases with the number of medications being taken.[66] To address the difficulty of tracking all known or suspected drug-drug interactions, machine learning algorithms have been created to extract information on interacting drugs and their possible effects from medical literature. Efforts were consolidated in 2013 in the DDIExtraction Challenge, in which a team of researchers at Carlos III University assembled a corpus of literature on drug-drug interactions to form a standardized test for such algorithms.[67] Competitors were tested on their ability to accurately determine, from the text, which drugs were shown to interact and what the characteristics of their interactions were.[68] Researchers continue to use this corpus to standardize the measure of the effectiveness of their algorithms.[62][63][65]

Other algorithms identify drug-drug interactions from patterns in user-generated content, especially electronic health records and/or adverse event reports.[63][64] Organizations such as the FDA Adverse Event Reporting System (FAERS) and the World Health Organization’s (WHO) VigiBase allow doctors to submit reports of possible negative reactions to medications. Deep learning algorithms have been developed to parse these reports and detect patterns that imply drug-drug interactions.[69]

See also

[edit]

References

[edit]
  1. ^ "Merative Officially Welcomes Its India Global Capability and Innovation Centres Across Bangalore Hyderabad and Chennai". www.businesswireindia.com.
  2. ^ Official Press Release Archived April 25, 2012, at the Wayback Machine
  3. ^ "Veritas completes purchase of Thomson health unit". Reuters. 6 June 2012. Retrieved 2012-07-08.
  4. ^ "IBM Watson Health Announces Plans to Acquire Truven Health Analytics for $2.6B, Extending Its Leadership in Value-Based Care Solutions". IBM. 18 February 2016. Archived from the original on February 19, 2016. Retrieved 2016-02-19.
  5. ^ "IBM to acquire Truven Health Analytics for $2.6 billion". Reuters. 18 February 2016. Retrieved 24 August 2016.
  6. ^ Announcing Truven Health Analytics. June 6, 2012. http://truvenhealth.com/blog/announcing-truven-health-analytics
  7. ^ Davis, Michelle F.; Deveau, Scott; Davalos, Jackie (2022-01-23). "IBM Sells Some Watson Health Assets for More Than $1 Billion". Bloomberg News. Retrieved 2022-01-23.
  8. ^ "Francisco Partners - News - Francisco Partners Completes Acquisition of IBM's Healthcare Data and Analytics Assets; Launches Healthcare Data Company Merative". www.franciscopartners.com. 2022-06-30. Retrieved 2022-07-28.
  9. ^ Kreutzer, Laura; Cooper, Laura (July 12, 2022). "Francisco Partners Collects Nearly $17 Billion to Back Technology Deals". The Wall Street Journal.
  10. ^ a b c "Putting Watson to Work: Watson in Healthcare". IBM. Archived from the original on July 22, 2012. Retrieved November 11, 2013.
  11. ^ "IBM Watson Helps Fight Cancer with Evidence-Based Diagnosis and Treatment Suggestions" (PDF). IBM. Archived from the original (PDF) on April 26, 2013. Retrieved November 12, 2013.
  12. ^ Saxena, Manoj (February 13, 2013). "IBM Watson Progress and 2013 Roadmap (Slide 7)". IBM. Retrieved November 12, 2013.
  13. ^ Wakeman, Nick (February 17, 2011). "IBM's Watson heads to medical school". Washington Technology. Retrieved February 19, 2011.
  14. ^ Mathews, Anna Wilde (September 12, 2011). "Wellpoint's New Hire: What is Watson?". The Wall Street Journal.
  15. ^ Upbin, Bruce (February 8, 2013). "IBM's Watson Gets Its First Piece Of Business In Healthcare". Forbes.
  16. ^ Miliard, Mike (October 30, 2012). "Watson Heads to Medical School: Cleveland Clinic, IBM Send Supercomputer to College". Healthcare IT News. Retrieved November 11, 2013.
  17. ^ "MD Anderson Taps IBM Watson to Power "Moon Shots" Mission Aimed at Ending Cancer, Starting with Leukemia" (Press release). IBM. Archived from the original on October 18, 2013.
  18. ^ "IBM's Watson Now Tackles Clinical Trials At MD Anderson Cancer Center". Forbes.
  19. ^ "MD Anderson Benches IBM Watson In Setback For Artificial Intelligence In Medicine". Forbes.
  20. ^ Leske, Nikola (February 9, 2013). "Doctors Seek Help on Cancer Treatment from IBM Supercomputer". Reuters. Archived from the original on February 16, 2016. Retrieved November 11, 2013.
  21. ^ "MANIPAL HOSPITALS ANNOUNCES NATIONAL LAUNCH OF IBM WATSON FOR ONCOLOGY". www-03.ibm.com. 2016-07-29. Archived from the original on November 8, 2016. Retrieved 2017-01-17.
  22. ^ ANI (2016-10-28). "Manipal Hospitals to adopt IBM's 'Watson for Oncology' supercomputer for cancer treatment". Business Standard India. Retrieved 2017-01-17.
  23. ^ "Hospitals in Asia use Watson supercomputer for cancer treatment". STAT. 2016-08-19. Retrieved 2017-01-17.
  24. ^ McCurry, Justin (2017-01-05). "Japanese company replaces office workers with artificial intelligence". The Guardian. ISSN 0261-3077. Retrieved 2017-01-29.
  25. ^ Satell, Greg. "How IBM's Watson Will Change The Way We Work". Forbes. Retrieved 2017-08-08.
  26. ^ Garbuio, Massimo; Lin, Nidthida (2019). "Artificial Intelligence as a Growth Engine for Health Care Startups: Emerging Business Models". California Management Review. 61 (2): 59–83. doi:10.1177/0008125618811931. S2CID 158219917.
  27. ^ Strickland, Eliza (2019-04-02). "How IBM Watson Overpromised and Underdelivered on AI Health Care". IEEE Spectrum: Technology, Engineering, and Science News. Retrieved 2019-04-04.
  28. ^ Meil, Doug (2021-04-21). "What Happened To Watson Health?". Association for Computing Machinery:BLOG@CACM. Retrieved 2019-04-21.
  29. ^ Condon, Stephanie (January 21, 2022). "IBM sells Watson Health assets to investment firm Francisco Partners". ZDNet. Retrieved January 21, 2022.
  30. ^ La Monica PR. "What merger mania means for health care". CNNMoney. Retrieved 2018-04-11.
  31. ^ "Why You're the Reason For Those Health Care Mergers". Fortune. Retrieved 2018-04-10.
  32. ^ Horvitz EJ, Breese JS, Henrion M (July 1988). "Decision theory in expert systems and artificial intelligence". International Journal of Approximate Reasoning. 2 (3): 247–302. doi:10.1016/0888-613x(88)90120-x. ISSN 0888-613X.
  33. ^ Arnold D, Wilson T (June 2017). "What Doctor? Why AI and robotics will define New Health" (PDF). PwC. Retrieved 8 October 2018.
  34. ^ Cohn J (20 February 2013). "The Robot Will See You Now". The Atlantic. Retrieved 2018-10-26.
  35. ^ Lorenzetti, Laura (5 April 2016). "From Cancer to Consumer Tech: A Look Inside IBM's Watson Health Strategy". Fortune. Retrieved 2018-10-26.
  36. ^ "IBM and Rensselaer Team to Research Chronic Diseases with Cognitive Computing".
  37. ^ Bass D (20 September 2016). "Microsoft Develops AI to Help Cancer Doctors Find the Right Treatments". Bloomberg. Retrieved 2018-10-26.
  38. ^ Knapton, Sarah (20 September 2016). "Microsoft will 'solve' cancer within 10 years by 'reprogramming' diseased cells". The Telegraph. Retrieved 2018-10-16.
  39. ^ Bloch-Budzier, Sarah (22 November 2016). "NHS teams with Google to treat patients". BBC News. Retrieved 2018-10-16.
  40. ^ Baraniuk, Chris (31 August 2016). "Google gets access to cancer scans". BBC News. Retrieved 2018-10-16.
  41. ^ Primack, Dan (26 May 2016). "Intel Capital Cancels $1 Billion Portfolio Sale". Fortune. Retrieved 2018-10-26.
  42. ^ "Algorithms Need Managers, Too". Harvard Business Review. 2016-01-01. Retrieved 2018-10-08.
  43. ^ Coiera E (1997). Guide to medical informatics, the Internet and telemedicine. Chapman & Hall, Ltd.
  44. ^ Power B (19 March 2015). "Artificial Intelligence Is Almost Ready for Business". Harvard Business Review. Massachusetts General Hospital.
  45. ^ Bahl M, Barzilay R, Yedidia AB, Locascio NJ, Yu L, Lehman CD (March 2018). "High-Risk Breast Lesions: A Machine Learning Model to Predict Pathologic Upgrade and Reduce Unnecessary Surgical Excision". Radiology. 286 (3): 810–818. doi:10.1148/radiol.2017170549. PMID 29039725.
  46. ^ a b Bloch-Budzier S (22 November 2016). "NHS using Google technology to treat patients". BBC News.
  47. ^ Lorenzetti, L. (April 5, 2016). Here's How IBM Watson Health is Transforming the Health Care Industry. Retrieved from http://fortune.com/ibm-watson-health-business-strategy/
  48. ^ "CB Insights Artificial Intelligence report" (PDF). 28 June 2016.
  49. ^ HealthITAnalytics (2018-08-08). "Providers Embrace Predictive Analytics for Clinical, Financial Benefits". HealthITAnalytics. Retrieved 2019-01-16.
  50. ^ "Predictive analytics in healthcare helps improve OR utilization". SearchHealthIT. Retrieved 2019-01-16.
  51. ^ Rajpurkar P, Irvin J, Zhu K, Yang B, Mehta H, Duan T, Ding D, Bagul A, Langlotz C, Shpanskaya K, Lungren MP (2017-11-14). "CheXNet: Radiologist-Level Pneumonia Detection on Chest X-Rays with Deep Learning". arXiv:1711.05225 [cs.CV].
  52. ^ Chockley K, Emanuel E (December 2016). "The End of Radiology? Three Threats to the Future Practice of Radiology". Journal of the American College of Radiology. 13 (12 Pt A): 1415–1420. doi:10.1016/j.jacr.2016.07.010. PMID 27652572.
  53. ^ Jha S, Topol EJ (December 2016). "Adapting to Artificial Intelligence: Radiologists and Pathologists as Information Specialists". JAMA. 316 (22): 2353–2354. doi:10.1001/jama.2016.17438. PMID 27898975. S2CID 3662362.
  54. ^ Patcas R, Bernini DA, Volokitin A, Agustsson E, Rothe R, Timofte R (January 2019). "Applying artificial intelligence to assess the impact of orthognathic treatment on facial attractiveness and estimated age". International Journal of Oral and Maxillofacial Surgery. 48 (1): 77–83. doi:10.1016/j.ijom.2018.07.010. PMID 30087062.
  55. ^ Patcas R, Timofte R, Volokitin A, Agustsson E, Eliades T, Eichenberger M, Bornstein MM (August 2019). "Facial attractiveness of cleft patients: a direct comparison between artificial-intelligence-based scoring and conventional rater groups". European Journal of Orthodontics. 41 (4): 428–433. doi:10.1093/ejo/cjz007. hdl:20.500.11850/377316. PMID 30788496. S2CID 73507799.
  56. ^ "Computer learns to detect skin cancer more accurately than doctors". The Guardian. 29 May 2018.
  57. ^ a b Jiang F, Jiang Y, Zhi H, Dong Y, Li H, Ma S, et al. (December 2017). "Artificial intelligence in healthcare: past, present and future". Stroke and Vascular Neurology. 2 (4): 230–243. doi:10.1136/svn-2017-000101. PMC 5829945. PMID 29507784.
  58. ^ a b c Alić B, Gurbeta L, Badnjević A (June 2017). "Machine learning techniques for classification of diabetes and cardiovascular diseases". 2017 6th Mediterranean Conference on Embedded Computing (MECO). IEEE. pp. 1–4. doi:10.1109/meco.2017.7977152. ISBN 978-1-5090-6742-8. S2CID 22942669.
  59. ^ Pacis D (February 2018). "Trends in telemedicine utilizing artificial intelligence". AIP Conference Proceedings. 1933 (1): 040009. Bibcode:2018AIPC.1933d0009P. doi:10.1063/1.5023979.
  60. ^ "Artificial Intelligence | Types of AI | 7 Practical Usage of Artificial Intelligence". Talky Blog. 2019-07-12. Archived from the original on July 17, 2019. Retrieved 2019-07-27.
  61. ^ Bennett, Casey C.; Doub, Thomas W.; Selove, Rebecca (2012). "EHRs connect research and practice: Where predictive modeling, artificial intelligence, and clinical decision support intersect". Health Policy and Technology. 1 (2): 105–114. arXiv:1204.4927. doi:10.1016/j.hlpt.2012.03.001. S2CID 25022446.
  62. ^ a b B. Bokharaeian and A. Diaz, “Extraction of Drug-Drug Interaction from Literature through Detecting Linguistic-based Negation and Clause Dependency,” Journal of Artificial Intelligence and Data Mining, vol. 4, no. 2, pp. 203–212, 2016.
  63. ^ a b c R. Cai et al., “Identification of adverse drug-drug interactions through causal association rule discovery from spontaneous adverse event reports,” Artificial Intelligence In Medicine, vol. 76, pp. 7–15, 2017.
  64. ^ a b F. Christopoulou, T. T. Tran, S. K. Sahu, M. Miwa, and S. Ananiadou, “Adverse drug events and medication relation extraction in electronic health records with ensemble deep learning methods.,” J Am Med Inform Assoc, Aug. 2019.
  65. ^ a b D. Zhou, L. Miao, and Y. He, “Position-aware deep multi-task learning for drug–drug interaction extraction,” Artificial Intelligence In Medicine, vol. 87, pp. 1–8, 2018.
  66. ^ García Morillo, J.S. Optimización del tratamiento de enfermos pluripatológicos en atención primaria UCAMI HHUU Virgen del Rocio. Sevilla. Spain. Available for members of SEMI at: ponencias de la II Reunión de Paciente Pluripatológico y Edad Avanzada Archived 2013-04-14 at Archive.today
  67. ^ M. Herrero-Zazo, I. Segura-Bedmar, P. Martínez, and T. Declerck, “The DDI corpus: An annotated corpus with pharmacological substances and drug–drug interactions,” Journal of Biomedical Informatics, vol. 46, no. 5, pp. 914–920, Oct. 2013.
  68. ^ I. Segura-Bedmar, P. Martínez, and M. Herrero-Zazo, “SemEval-2013 Task 9: Extraction of drug-drug interactions from biomedical texts (DDIExtraction 2013),” Second Joint Conference on Lexical and Computational Semantics, vol. 2, pp. 341–350, Jun. 2013.
  69. ^ B. Xu et al., “Incorporating User Generated Content for Drug Drug Interaction Extraction Based on Full Attention Mechanism.,” IEEE Trans Nanobioscience, vol. 18, no. 3, pp. 360–367, Jul. 2019.
[edit]