Evidence-Based Reviews

Artificial intelligence in psychiatry

Current Psychiatry. 2019 August;18(8):33-38

Potential uses of machine learning include predicting the risk of suicide, psychosis.

References

1. McCarthy J. What is AI? Basic questions. http://jmc.stanford.edu/artificial-intelligence/what-is-ai/index.html. Accessed July 19, 2019.
2. Oxford Reference. Artificial intelligence. http://www.oxfordreference.com/view/10.1093/oi/authority.20110803095426960. Accessed July 19, 2019.
3. Turing AM. Computing machinery and intelligence. Mind. 1950;49:433-460.
4. Robert C. Book review: machine learning, a probabilistic perspective. CHANCE. 2014;27:2:62-63.
5. Goodfellow I, Bengio Y, Courville A. Deep learning. Cambridge, MA: The MIT Press; 2016.
6. Brownlee J. Supervised and unsupervised machine learning algorithms. https://machinelearningmastery.com/supervised-and-unsupervised-machine-learning-algorithms/. Published March 16, 2016. Accessed July 19, 2019.
7. Russell S, Norvig P. Artificial intelligence: a modern approach. Upper Saddle River, NJ: Pearson; 1995.
8. Hamet P, Tremblay J. Artificial intelligence in medicine. Metabolism. 2017;69S:S36-S40.
9. The Johns Hopkins hospital launches capacity command center to enhance hospital operations. Johns Hopkins Medicine. https://www.hopkinsmedicine.org/news/media/releases/the_johns_hopkins_hospital_launches_capacity_command_center_to_enhance_hospital_operations. Published October 26, 2016. Accessed July, 19 2019.
10. U.S. healthcare leaders expect widespread adoption of artificial intelligence by 2023. Intel. https://newsroom.intel.com/news-releases/u-s-healthcare-leaders-expect-widespread-adoption-artificial-intelligence-2023/#gs.7j7yjk. Published July 2, 2018. Accessed July, 19 2019.
11. Gulshan V, Peng L, Coram M, et al. Development and validation of a deep learning algorithm for detection of diabetic retinopathy in retinal fundus photographs. JAMA. 2016;316(22):2402-2410.
12. Poplin R, Varadarajan AV, Blumer K, et al. Prediction of cardiovascular risk factors from retinal fundus photographs via deep learning. Nature Biomedical Engineering. 2018;2:158-164.
13. Weng SF, Reps J, Kai J, et al. Can machine-learning improve cardiovascular risk prediction using routine clinical data? PLoS One. 2017;12(4):e0174944. doi: 10.1371/journal.pone. 0174944.
14. Lakhani P, Sundaram B. Deep learning at chest radiography: Automated classification of pulmonary tuberculosis by using convolutional neural networks. Radiology. 2017;284(2):574-582.
15. Bluemke DA. Radiology in 2018: Are you working with ai or being replaced by AI? Radiology. 2018;287(2):365-366.
16. Kakar PN, Das J, Roy PM, et al. Robotic invasion of operation theatre and associated anaesthetic issues: A review. Indian J Anaesth. 2011;55(1):18-25.
17. World first: researchers develop completely automated anesthesia system. McGill University. https://www.mcgill.ca/newsroom/channels/news/world-first-researchers-develop-completely-automated-anesthesia-system-100263. Published May 1, 2008. Accessed July 19, 2019.
18. Esteva A, Kuprel B, Novoa RA, et al. Dermatologist-level classification of skin cancer with deep neural networks. Nature. 2017;542(7639):115-118.
19. Liu Y, Gadepalli K, Norouzi M, et al. Detecting cancer metastases on gigapixel pathology images. https://arxiv.org/abs/1703.02442. Published March 8, 2017. Accessed July 19, 2019.
20. Bassett C. The computational therapeutic: exploring Weizenbaum’s ELIZA as a history of the present. AI & Soc. 2018. https://doi.org/10.1007/s00146-018-0825-9.
21. Just MA, Pan L, Cherkassky VL, et al. Machine learning of neural representations of suicide and emotion concepts identifies suicidal youth. Nat Hum Behav. 2017;1:911-919.
22. Pestian J, Nasrallah H, Matykiewicz P, et al. Suicide note classification using natural language processing: a content analysis. Biomed Inform Insights. 2010;2010(3):19-28.
23. Walsh CG, Ribeiro JD, Franklin JC. Predicting risk of suicide attempts over time through machine learning. Clinical Psychological Science. 2017;5(3):457-469.
24. Pestian JP, Sorter M, Connolly B, et al; STM Research Group. A machine learning approach to identifying the thought markers of suicidal subjects: a prospective multicenter trial. Suicide Life Threat Behav. 2017;47(1):112-121.
25. Corcoran CM, Carrillo F, Fernández-Slezak D, et al. Prediction of psychosis across protocols and risk cohorts using automated language analysis. World Psychiatry. 2018;17(1):67-75.
26. Bedi G, Carrillo F, Cecchi GA, et al. Automated analysis of free speech predicts psychosis onset in high-risk youths. NPJ Schizophr. 2015;1:15030. doi:10.1038/npjschz.2015.30.
27. Tandon N, Tandon R. Will machine learning enable us to finally cut the Gordian Knot of schizophrenia. Schizophr Bull. 2018;44(5):939-941.
28. Char DS, Shah NH, Magnus D. Implementing machine learning in health care - addressing ethical challenges. N Engl J Med. 2018;378(11):981-983.
29. Nuffield Council on Bioethics. The big ethical questions for artificial intelligence (AI) in healthcare. http://nuffieldbioethics.org/news/2018/big-ethical-questions-artificial-intelligence-ai-healthcare. Published May 15, 2018. Accessed July 19, 2019.
30. Axt J. Artificial neural networks: a systematic review of their efficacy as an innovative resource for health care practice managers. https://www.researchgate.net/publication/322101587_Running_head_ANN_EFFICACY_IN_HEALTHCARE-A_SYSTEMATIC_REVIEW_1_Artificial_Neural_Networks_A_systematic_review_of_their_efficacy_as_an_innovative_resource_for_healthcare_practice_managers. Published October 2017. Accessed July 19, 2019.
31. Cecchi G. IBM 5 in 5: with AI, our words will be a window into our mental health. IBM Research Blog. https://www.ibm.com/blogs/research/2017/1/ibm-5-in-5-our-words-will-be-the-windows-to-our-mental-health/. Published January 5, 2017. Accessed July 19, 2019.
32. Constine J. Facebook rolls out AI to detect suicidal posts before they’re reported. TechCrunch. http://tcrn.ch/2hUBi3B. Published November 27, 2017. Accessed July 19, 2019.
33. Fitzpatrick KK, Darcy A, Vierhile M. Delivering cognitive behavior therapy to young adults with symptoms of depression and anxiety using a fully automated conversational agent (Woebot): a randomized controlled trial. JMIR Ment Health. 2017;4(2):e19. doi:10.2196/mental.7785.
34. UTA researchers use artificial intelligence to assess, enhance cognitive abilities in school-aged children. University of Texas at Arlington. https://www.uta.edu/news/releases/2016/10/makedon-children-learning-difficulties.php. Published October 13, 2016. Accessed July 19, 2019.
35. Nealon C. App for early autism detection launched on World Autism Awareness Day, April 2. University at Buffalo. http://www.buffalo.edu/news/releases/2018/04/001.html. Published April 2, 2018. Accessed July 19, 2019.
36. SimSensei. University of Southern California Institute for Creative Technologies. http://ict.usc.edu/prototypes/simsensei/. Accessed July 19, 2019.

For many people, artificial intelligence (AI) brings to mind some form of humanoid robot that speaks and acts like a human. However, AI is much more than merely robotics and machines. Professor John McCarthy of Stanford University, who first coined the term “artificial intelligence” in the early 1950s, defined it as “the science and engineering of making intelligent machines, especially intelligent computer programs”; he defined intelligence as “the computational part of the ability to achieve goals.^”1 Artificial intelligence also is commonly defined as the development of computer systems able to perform tasks that normally require human intelligence.² English Mathematician Alan Turing is considered one of the forefathers of AI research, and devised the first test to determine if a computer program was intelligent (Box 1³). Today, AI has established itself as an integral part of medicine and psychiatry.

Box 1

The Turing Test: How to tell if a computer program is intelligent

During World War II, the English Mathematician Alan Turing helped the British government crack the Enigma machine, a coding device used by the Nazi army. He went on to pioneer many research projects in the field of artificial intelligence, including developing the Turing Test, which can determine if a computer program is intelligent.³ In this test, a human questioner uses a computer interface to pose questions to 2 respondents in different rooms; one of the respondents is a human and the other a computer program. If the questioner cannot tell the difference between the 2 respondents’ answers, then the computer program is deemed to be “artificially intelligent” because it can pass

The semantics of AI

Two subsets of AI are machine learning and deep learning.^4,5 Machine learning is defined as a set of methods that can automatically detect patterns in data and then use the uncovered pattern to predict future data.⁴ Deep learning is a form of machine learning that enables computers to learn from experience and understand the world in terms of a hierarchy of concepts.⁵

Machine learning can be supervised, semi-supervised, or unsupervised. The majority of practical machine learning uses supervised learning, where all data are labeled and an algorithm is used to learn the mapping function from the input to the output. In unsupervised learning, all data are unlabeled and the algorithm models the underlying structure of the data by itself. Semi-supervised learning is a mixture of both.⁶

Many researchers also categorize AI into 2 types: general or “strong” AI, and narrow or “weak” AI. Strong AI is defined as computers that can think on a level at least equal to humans and are able to experience emotions and even consciousness.⁷ Weak AI includes adding “thinking-like” features to computers to make them more useful tools. Almost all AI technologies available today are considered to be weak AI.

AI in medicine

AI is being developed for a broad range of applications in medicine. This includes informatics approaches, including learning in health management systems such as electronic health records, and actively guiding physicians in their treatment decisions.⁸

AI has been applied to assist administrative workflows that reach beyond automated non-patient care activities such as chart documentation and placing orders. One example is the Judy Reitz Capacity Command Center, which was designed and built with GE Healthcare Partners.⁹ It combines AI technology in the form of systems engineering and predictive analytics to better manage multiple workflows in different administrative settings, including patient safety, volume, flow, and access to care.⁹

In April 2018, Intel Corporation surveyed 200 health-care decision makers in the United States regarding their use of AI in practice and their attitudes toward it.¹⁰ Overall, 37% of respondents reported using AI and 54% expected to increase their use of AI in the next 5 years. Clinical use of AI (77%) was more common than administrative use (41%) or financial use (26 %).¹⁰

Continue to: Box 2

Artificial intelligence in psychiatry

References

The semantics of AI

AI in medicine

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