The Influence of Influence Diagrams in Medicine

Stephen G. Pauker
Stephen G. Pauker
[email protected]
Division of Clinical Decision Making, Informatics and Telemedicine, Department of Medicine, Tufts–New England Medical Center, Tufts University School of Medicine, 750 Washington St., NEMC 302, Boston, Massachusetts 02111
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,
John B. Wong
John B. Wong
[email protected]
Division of Clinical Decision Making, Informatics and Telemedicine, Department of Medicine, Tufts–New England Medical Center, Tufts University School of Medicine, 750 Washington St., NEMC 302, Boston, Massachusetts 02111
Search for more papers by this author

Division of Clinical Decision Making, Informatics and Telemedicine, Department of Medicine, Tufts–New England Medical Center, Tufts University School of Medicine, 750 Washington St., NEMC 302, Boston, Massachusetts 02111

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John B. Wong

[email protected]

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Published Online:1 Dec 2005https://doi.org/10.1287/deca.1060.0060

References

Ambalavanan N., Carlo W. A. Comparison of the prediction of extremely low birth weight neonatal mortality by regression analysis and neural networks. Early Human Development (2001) 65:123–137Crossref, Google Scholar
Baxt W. G. A neural network trained to identify the presence of myocardial infarction bases some decisions on clinical associations that differ from accepted clinical teaching. Medical Decision Making (1994) 14:217–222Crossref, Google Scholar
Beck J. R., Pauker S. G. The Markov process in medical decision making. Medical Decision Making (1983) 3:419–458Crossref, Google Scholar
Bostwick D. G., Burke H. B. Prediction if individual patient outcome in cancer: Comparison of artificial neural networks and Kaplan-Meir methods. Cancer (2001) 91(Supplement):1643–1646Crossref, Google Scholar
Bravata D. M., McDonald K. M., Shojania K. G., Sundaram V., Owens D. K. Challenges in systematic reviews: Synthesis of topics related to the delivery, organization, and financing of health care. Ann. Internal Medicine (2005) 142:1056–1065Crossref, Google Scholar
Burnside E. S. Bayesian networks: Computer-assisted diagnosis support in radiology. Acad. Radiology (2005) 12:422–430Crossref, Google Scholar
Chapman G. B., Sonnenberg F. A.Decision Making in Health Care: Theory, Psychology and Applications (2000) (Cambridge University Press, Cambridge, UK) Google Scholar
Clemen R. T.Making Hard Decisions (1991) (PWS-Kent, Boston, MA) Google Scholar
Clemen R. T., Reilly T.Making Hard Decisions with Decision Tools (2001) (Dunbury, Pacific Grove, CA) Google Scholar
Eftekhar B., Mohammad K., Ardebili H. E., Ghodsi M., Ketabchi E. Comparison of artificial neural network and logistic regression models for prediction of mortality in head trauma based on initial clinical data. BMC Medical Informatics Decision Making (2005) 5(3). http://www.biomedcentral.com/1472-6747/5/3Google Scholar
Harmanec D., Leong T.-Y., et al. Decision analytic approach to severe head injury management. AMIA 99: Transforming Health Care Through Informatics (1999) (American Medical Informatics Association, Washington, DC) Google Scholar
Harrison R. F., Kennedy R. L. Artificial neural network models for prediction of acute coronary syndromes using clinical data from the time of presentation. Ann. Emergency Medicine (2005) 46:41–439Crossref, Google Scholar
Helfand S. G. Pauker. Influence diagrams: A new dimension for decision models. Medical Decision Making (1997) 17:351–352Crossref, Google Scholar
Henrion M.Analytica (2005) (Lumina Decision Systems, Los Gatos, CA) Google Scholar
Holtzman S.Intelligent Decision Systems (1989) (Addison-Wesley, Reading, MA) Crossref, Google Scholar
Horvitz E., Rutledge G. Time-dependent utility and action under uncertainty. Seventh Conf. Uncertainty Artificial Intelligence, Los Angeles (1991) (Morgan Kaufmann, San Mateo, CA) Crossref, Google Scholar
Horvitz E., Seiver A. Time-critical action: Representations and application. Thirteenth Conf. Uncertainty Artificial Intelligence (UAI-97), Providence, RI (1997) (Morgan Kaufmann, San Mateo, CA) Google Scholar
Horvitz E. J., Breese J. S., et al. Decision theory in expert systems and artificial intelligence. Internat. J. Approximate Reasoning (1988) 2:247–302Crossref, Google Scholar
Howard R. A., Matheson J. E., Howard R. A., Matheson J. E. Influence diagrams. Readings on the Principles and Applications of Decision Analysis (1984/2005) 2(Strategic Decisions Group, Menlo Park, CA) 720–762Reprinted, Decision Anal. 2(3) 127-143Google Scholar
Hunink M., Glasziou P., Siegel J., Weeks J., Pliskin J., Elstein A., Weinstein M.Decision Making in Health and Medicine (2001) (Cambridge University Press, Cambridge, UK) Google Scholar
Kahn C. E., Roberts L. M., Shapper K. A., Haddawy P. Construction of a Bayesian network for mammographic diagnosis of breast cancer. Comput. Biol. Medicine (1997) 27:19–29Crossref, Google Scholar
Kline J. A., Novobliski A. J., Kabrhel C., Richman P. B., Courtney D. M. Derivation and validation of a Bayesian network to predict pretest probability of venous thromboembolism. Ann. Emergency Medicine (2005) 45:282–290Crossref, Google Scholar
Lee S.-M., Kang J.-O., Suh Y.-M. Comparison of hospital charge prediction models for colorectal cancer patients: Neural network vs. decision tree models. J. Korean Medical Sci. (2004) 19:677–681Crossref, Google Scholar
Lehmann H. P., Hinton R., Morello P., Santoli J. Developmental dysplasia of the hip practice guideline: Technical report. Pediatrics (2000) 105(4):E57Crossref, Google Scholar
Lucas P. J. F., deDruijn N. C., Schurink K., Hoepelman A. A probabilistic and decision-theoretic approach to the management of infectious disease at the ICU. Artificial Intelligence Medicine (2000) 19:251–279Crossref, Google Scholar
Luciani D., Marchesi M., Bertolini G. The role of Bayesian networks in the diagnosis of pulmonary embolism. J. Thrombosis Haemostasis (2003) 1:698–707Crossref, Google Scholar
Magni P., Bellazzi R. DT-planner: An environment for managing dynamic decision problems. Comput. Methods Programs Biomedicine (1997) 54:183–200Crossref, Google Scholar
Magni P., Quaglini S., Marchetti M., Barosi G. Deciding when to intervene: A Markov decision approach. Internat. J. Medical Informatics (2000) 60:237–253Crossref, Google Scholar
Meyer J., Phillips M. H., Cho P. S., Kalet I., Doctor J. N. Application of influence diagrams to prostate intensity-modulated radiation therapy plan selection. Physics Medicine Biol. (2004) 49:1637–1653Crossref, Google Scholar
Miller A. C., Merkhofer M. W., Howard R. A., Matheson J. E., Rice T. R. Development of automated aids for decision analysis. (1976) . Stanford Research Institute, Menlo Park, CAGoogle Scholar
Nease R. F., Owens D. K. Use of influence diagrams to structure medical decisions. Medical Decision Making (1997) 17:263–275Crossref, Google Scholar
Nguyen T., Malley R., Inkelis S. H., Kupperman N. Comparison of prediction models for adverse outcome in pediatric memingococcal disease using artificial neural network and logistic regression analyses. J. Clinical Epidemiology (2002) 55:687–695Crossref, Google Scholar
Ottenbacher K. J., Linn R. T., Smith P. M., Illig B. B., Mancuso M., Granger C. V. Comparison of logistic regression and neural network analysis applied to predicting living setting after hip fracture. Ann. Epidemiology (2004) 2004:551–559Crossref, Google Scholar
Owen D. L., Howard R. A., Matheson J. E. The use of influence diagrams in structuring complex decision problems. Readings on the Principles and Applications of Decision Analysis (1984) 2(Strategic Decisions Group, Menlo Park, CA) 763–772Google Scholar
Owens D. K., Shachter R. D., Nease R. F. Representation and analysis of medical decision problems with influence diagrams. Medical Decision Making (1997) 17:351–352Crossref, Google Scholar
Pauker S. G., Kassirer J. P. Therapeutic decision making: A cost-benefit analysis. New England J. Medicine (1975) 293:229–234Crossref, Google Scholar
Pauker S. G., Kassirer J. P. Medical progress: Decision analysis. New England J. Medicine (1987) 316:250–258Crossref, Google Scholar
Pauker S. G., Sonnenberg F. A., Wong J. B., Haggerty C. G.DecisionMaker; Windows DecisionMaker (2005) (Pratt Medical Group, Boston, MA) Google Scholar
Peot M. A., Shachter R. D. Learning from what you don’t observe. Fourteenth Conf. Uncertainty Artificial Intelligence (UIA’98), Madison, WI (1998) (Morgan Kaufmann, San Francisco, CA) Google Scholar
Provan G. M., Clarke J. R. Dynamic network construction and updating techniques for the diagnosis of acute abdominal pain. IEEE Trans. Pattern Anal. Mach. Intelligence (1993) 15:299–307Crossref, Google Scholar
Quaglini S., Bellazzi R., Locatelli F., Stefanelli M., Salvaneschi C. An influence diagram for assessing GVHD prophylaxis after bone marrow transplantation in children. Medical Decision Making (1994) 14:223–235Crossref, Google Scholar
Raker M. TreeAge Pro. (2004) . TreeAge Software, Williamstown, MAGoogle Scholar
Rege A., Agogino A. M. Topological framework for representing and solving probabilistic inference in expert systems. IEEE Trans. Systems, Man Cybernetics (1988) 18:402–414Crossref, Google Scholar
Sato F., Shimada Y., Selaru F. M., Shibata D., Maeda M., Watanabe G., Mori Y., Stass S. A., Imamura M., Meltzer S. J. Prediction of survival in patients with esophageal cancer using artificial neural networks. Cancer (2005) 103:1596–1605Crossref, Google Scholar
Shachter R. D. Evaluating influence diagrams. Oper. Res. (1986) 34:871–882Link, Google Scholar
Shachter R. D., Lemmer J. F., Kanal L. N. DAVID: Influence diagram processing system for the Macintosh. Uncertainty in Artificial Intelligence (1988a) 2(North-Holland, Amsterdam) 191–196Crossref, Google Scholar
Shachter R. D. Probabilistic inference and influence diagrams. Oper. Res. (1988b) 36:589–604Link, Google Scholar
Society for Medical Decision Making (2005) . Philadelphia, PA, http://www.smdm.orgGoogle Scholar
Sonnenberg A. The benefit of negative tests in non-ulcer dyspepsia. (2002) 22:199–207Google Scholar
Sonnenberg F. A., Beck J. R. Markov models in medical decision making: A practical guide. Medical Decision Making (1993) 13:322–338Crossref, Google Scholar
Sonnenberg F. A., Hagerty C. G., Kulikowski C. A. An architecture for knowledge-based construction of decision models. (1994) 14:27–39Google Scholar
Srinivas S., Breese J. IDEAL: A software package for analysis of influence diagrams. Sixth Conf. Uncertainty Artificial Intelligence, Cambridge (1990) (Morgan Kaufman, San Francisco, CA) Google Scholar
Szpurek D., Moszynski R., Smolen M., Sajdak S. Artificial neural network computer prediction of ovarian malignancy in women with adnexal masses. Gynecology Obstetrics (2005) 89:108–113Google Scholar
Wellman M. P. Fundamental concepts of qualitative probabilistic networks. Artificial Intelligence (1990) 44:257–303Crossref, Google Scholar
Wellman M. P., Eckman M. H., Marshall S. L., Sonnenberg F., Pauker S. G. Automated critiquing of decision trees. Medical Decision Making (1989) 9:272–284Crossref, Google Scholar
Westwig E.Precision Tree (2000) (Palisade, Ithaca, NY) Google Scholar
Wiederhold G., Shortliffe E. H.Medical Informatics: Computer Applications in Health Care and Biomedicine (2000) (Springer, New York) Google Scholar
Wong J. B. Pharmacogenomics of hepatitis C and decision analysis: A glimpse into the future. Hepatology (2002) 36:252–254Crossref, Google Scholar

Volume 2, Issue 4

December 2005

Pages 183-244

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Received:December 12, 2005
Accepted:January 05, 2006
Published Online:December 01, 2005

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Stephen G. Pauker, John B. Wong, (2005) The Influence of Influence Diagrams in Medicine. Decision Analysis 2(4):238-244.

https://doi.org/10.1287/deca.1060.0060

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