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Health Informatics Elmer V. Bernstam, MD, MSE, MS Assistant Professor School of Health Information Sciences and Internal Medicine UT - Houston.

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Presentation on theme: "Health Informatics Elmer V. Bernstam, MD, MSE, MS Assistant Professor School of Health Information Sciences and Internal Medicine UT - Houston."— Presentation transcript:

1 Health Informatics Elmer V. Bernstam, MD, MSE, MS Assistant Professor School of Health Information Sciences and Internal Medicine UT - Houston

2 2 Better information Better care

3 3 Definition Informatics: field of study concerned with information Health (Biomedical) informatics: informatics applied to health (biomedicine)

4 4 This is health informatics! Bioinformatics 1. Biological structure informatics 2. Computational biology 3. Expression profiling and microarrays 4. Genomic ontologies 5. Genomics 6. Linking the genotype and phenotype 7. Neuroinformatics 8. Pharmacogenomics 9. Proteomics Clinical Informatics 10. Barriers to clinical system implementation 11. Clinical systems in ambulatory care 12. Clinical systems in high intensity care 13. Careflow and process improvement systems 14. Disease management 15. E-health and clinical communication 16. Evaluation of health information systems 17. Health data warehousing 18. Health information systems 19. Integrated health and financial systems Education and Training 20. Computer-assisted medical education 21. Consumer health information 22. E-learning or distance learning 23. Education and training 24. Library information systems 25. Medical informatics teaching 26. Patient education and self-care 27. Professional education Human Information Processing and Organizational Behavior 28. Cognitive models and problem solving 29. Data visualization 30. Natural language understanding and text generation 31. Human factors and usability 32. Human factors and user interfaces 33. Human-computer interaction 34. Models of social and organizational behavior 35. Natural language processing Imaging and Signal Analysis 36. Image processing and transmission 37. Image recognition, registration, and segmentation methods 38. Imaging and signal standards 39. Knowledge representation and ontologies for imaging 40. Model-based imaging 41. Signal processing and transmission 42. Virtual reality and active vision methods and applications Innovative Technologies in Health Care 43. Computer-communication infrastructures 44. Internet applications 45. Mobile computing and communication 46. Portable patient records 47. Security and data protection 48. Software agents and distributed systems 49. Telemedicine 50. Virtual reality 51. Wireless applications and handheld devices Knowledge Management 52. Automated learning and discovery 53. Clinical guidelines and protocols 54. Controlled terminology, vocabularies, and ontologies 55. Intelligent data analysis and data mining 56. Decision support systems 57. Knowledge management 58. Knowledge representation 59. Neural network techniques 60. Pattern recognition/classification Nursing Informatics 61. Nursing informatics 62. Nursing care systems 63. Nursing vocabulary and terminology 64. Nursing education/Curriculum in nursing informatics 65. Nursing documentation Organizational Issues 66. Careflow management systems 67. Care delivery systems 68. Cooperative design and development 69. Economics of care 70. Ethical and legal issues 71. Health services evaluation: performance and quality 72. Organizational impact of information systems 73. Quality assessment and improvement 74. System implementation and management issues 75. Technology assessment Patient Record 76. Cryptography, database security, and anonymization 77. Database access and delivery 78. Database design and construction 79. Data standards and enterprise data sharing 80. Patient record management 81. Privacy, confidentiality, and information protection 82. Standard medical vocabularies 83. Standards for coding 84. Standards for data transfer Public Health Informatics 85. Administrative/financial systems 86. Biosurveillance 87. Consumer health informatics 88. Emergency and disaster response 89. Genetic epidemiology 90. Health intervention systems 91. Health promotion systems 92. Health outcomes assessment 93. Patient self-care and patient-provider interaction

5 5 Theme Informatics: not just application of computers to medicine Computers are [transforming] tools There are other tools drawn from: –Clinical and basic (biological) science –Decision analysis –Probability and statistics –Cognitive and social science, pedagogy –Etc.

6 6 Distance Overcoming physical separation Doctor/patient Teacher/learner Researcher/data

7 7 Social issues Dealing with people Change management Culture, roles, workflow Law, ethics, economics

8 8 Research themes in informatics Vocabularies, standards (Automatic) similarity determination Data presentation Decision making Evaluation

9 9 Vocabularies and standards Naming concepts and relating them to each other Standards: agreed-upon conventions –Allow communication –Ex: Start numbering with 0 vs. 1

10 10 Data presentation Dealing with information overload Knowledge-based information display –Knowledge about the task, environment, decision to be made

11 11 Decision making What makes a good decision? How do you help people make better decisions? Error prevention

12 12 Evaluation Does it work? Do people use it? Like it? Does it improve outcomes? Limitations of technology –Pen and paper are hard to beat

13 13 Bioinformatics challenges Lots of data  what does it mean? Collecting data  using data  predicting data Genome annotation (functional genomics) –What does this piece of DNA do? Protein structure is related to function (protein folding) –Can we predict structure from sequence and basic physics?

14 14 Bioinformatics future Build models of –Molecules –Cells –Tissues –Organisms –Systems Try a drug on a model, rather than a patient Opportunity is in combination of bio- and clinical informatics

15 15 Pharmacogenomics Different people respond to drugs differently –Many drugs –Many genetic differences between people In addition, genetics influence –Risk factors  are you going to get the disease? (e.g. smoking  emphysema, heart disease) –Operative risk How to collect and use these data? Memory is not enough, nseed tools

16 16 Clinical informatics Information in health care

17 17 Not there yet: EMR Electronic medical records “Holy Grail” of medical informatics –MI projects: Given an EMR, […] –Prevent errors, etc. But… –Not widely accepted in this country Depends on what you consider an EMR MD order entry? (4% of hospitals) –Difficult to get right: few successful implementations

18 18 Social barriers to EMR Who benefits? –Mismatch between costs and benefits –Physicians Weak case for time savings Often inconvenient – poor workflow integration –Payers Likely benefit  case becoming stronger –Patients Strong case for benefit What if I buy your EMR and your company goes out of business? –No single dominant player

19 19 Social barriers to EMR Technology is dominated by two types of people: those who understand what they do not manage, and those who manage what they do not understand. - Anonymous Computers make it easier to do a lot of things, but most of the things they make it easier to do don't need to be done. - Andy Rooney The case for biomedical informatics training: need people who understand both –What needs to get done: biomedicine –How to get it done: technology

20 20 Not there yet: decision support What do physicians do? –Gather information –MAKE DECISIONS –Execute Decision support: (technological) support for decision-making –Only effective way to influence decisions –Clinical practice guidelines Realization: practice variation that cannot be justified by science Little effect of published guidelines Integration into workflow required: CPOE

21 21 Problem Components of a decision –Knowledge about the world: difficult to encode Medical literature Experience –Patient information: requires EMR Age, sex, laboratory data, etc.

22 22 Trends Affecting Informatics Improvement in computer technology –Faster –Smaller –More portable: better displays and batteries Improvement in communication technology High-throughput biological techniques –Human genome project

23 23 Trends Affecting Informatics (Threat of) Terrorism Health care –Aging of the population –Increasing growth of knowledge –Increasing financial pressures –Increasing patient expectation and empowerment Increasing awareness and decreasing tolerance of medical errors Erosion of respect for physicians Decreasing physician autonomy

24 24 Medico-legal pressures

25 25 Opportunities in informatics Information overload –Providing better care: biological advances in clinical practice Overcoming distance –[Bio] Terrorism: detection and coordinating response –Telemedicine: frequent checks on the chronically ill Social issues –Facilitate change to better ways

26 26 Thank you! Elmer.V.Bernstam@uth.tmc.edu


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