A clinical research strategy using longitudinal observational data in the post-electronic health records era

Rae Woong Park

doi:10.5124/jkma.2012.55.8.711

J Korean Med Assoc > Volume 55(8); 2012 > Article

Park: A clinical research strategy using longitudinal observational data in the post-electronic health records era

Focused Issue of This Month

Medical Information

Journal of the Korean Medical Association

Journal of the Korean Medical Association 2012; 55(8): 711-719.

Published online: August 16, 2012

DOI: http://dx.doi.org/10.5124/jkma.2012.55.8.711

A clinical research strategy using longitudinal observational data in the post-electronic health records era

Rae Woong Park, MD

Department of Biomedical Informatics, Ajou University School of Medicine, Suwon, Korea.

Corresponding author: Rae Woong Park, veritas@ajou.ac.kr

Received June 29, 2012 Accepted July 12, 2012

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Adoption of electronic health records (EHRs) is increasing worldwide. The worldwide EHR adoption rate is estimated to be around 9% to 12%. Thus, the accumulation of medical records in electronic form is also sharply increasing and is expected to be a precious asset for clinical research. Longitudinal observational studies based on EHRs are also increasing. Observational studies covering more than a million people are not rare at present. However, much of the current EHR data are equivalent in form to those of paper records, but are just stored in electronic stor-age devices, rather than as electronic data that can be transferred and shared without loss of clinical semantics. Current EHR systems must be improved in many ways to be used for anal-yses to yield important clinical knowledge. These improvements, which are addressed in this review, include the adoption of clinical data warehouses, use of controlled vocabulary, avoidance of personal/departmental research databases, a standardized interface of many diagnostic devices with the EHR system, control of time-stamp granularity, preparedness for whole-genome sequencing of every patient, confederation or consolidation of multi-institutional EHR data, protection of privacy and confidentiality, and an education system for clinical informaticians.

Electronic health records; Data warehouse; Medical informatics; Longitudinal observation study

References

1. Ray WA, Murray KT, Hall K, Arbogast PG, Stein CM. Azithromycin and the risk of cardiovascular death. N Engl J Med 2012;366:1881-1890.

2. Yoon D, Chang BC, Kang SW, Bae H, Park RW. Adoption of electronic health records in Korean tertiary teaching and general hospitals. Int J Med Inform 2012;81:196-203.

3. Park RW, Shin SS, Choi YI, Ahn JO, Hwang SC. Computerized physician order entry and electronic medical record systems in Korean teaching and general hospitals: results of a 2004 survey. J Am Med Inform Assoc 2005;12:642-647.

4. Yoon D, Park MY, Choi NK, Park BJ, Kim JH, Park RW. Detection of adverse drug reaction signals using an electronic health records database: Comparison of the Laboratory Extreme Abnormality Ratio (CLEAR) algorithm. Clin Pharmacol Ther 2012;91:467-474.

5. Jha AK, DesRoches CM, Campbell EG, Donelan K, Rao SR, Ferris TG, Shields A, Rosenbaum S, Blumenthal D. Use of electronic health records in U.S. hospitals. N Engl J Med 2009;360:1628-1638.

6. Hubner U, Ammenwerth E, Flemming D, Schaubmayr C, Sellemann B. IT adoption of clinical information systems in Austrian and German hospitals: results of a comparative survey with a focus on nursing. BMC Med Inform Decis Mak 2010;10:8.

7. Yasunaga H, Imamura T, Yamaki S, Endo H. Computerizing medical records in Japan. Int J Med Inform 2008;77:708-713.

8. Park MY, Yoon D, Lee K, Kang SY, Park I, Lee SH, Kim W, Kam HJ, Lee YH, Kim JH, Park RW. A novel algorithm for detection of adverse drug reaction signals using a hospital electronic medical record database. Pharmacoepidemiol Drug Saf 2011;20:598-607.

9. Sheen SS, Choi JE, Park RW, Kim EY, Lee YH, Kang UG. Overdose rate of drugs requiring renal dose adjustment: data analysis of 4 years prescriptions at a tertiary teaching hospital. J Gen Intern Med 2008;23:423-428.

10. Lee SM, Park RW. Basic concepts and principles of data mining in clinical practice. J Korean Soc Med Inform 2009;15:175-189.

11. Han J, Kamber M. In: Han J, Kamber M, editor. Data warehouse and OLAP technology for data mining. Data mining: concepts and techniques 2001;San Francisco: Morgan Kaufmann Publishers. 39-43.

12. Prather JC, Lobach DF, Goodwin LK, Hales JW, Hage ML, Hammond WE. Medical data mining: knowledge discovery in a clinical data warehouse. Proc AMIA Annu Fall Symp 1997;101-105.

13. Friedman C, Hripcsak G, Shagina L, Liu H. Representing information in patient reports using natural language processing and the extensible markup language. J Am Med Inform Assoc 1999;6:76-87.

14. Meystre SM, Haug PJ. Randomized controlled trial of an automated problem list with improved sensitivity. Int J Med Inform 2008;77:602-612.

15. Xu H, Stenner SP, Doan S, Johnson KB, Waitman LR, Denny JC. MedEx: a medication information extraction system for clinical narratives. J Am Med Inform Assoc 2010;17:19-24.

16. Haerian K, Varn D, Vaidya S, Ena L, Chase HS, Friedman C. Detection of pharmacovigilance-related adverse events using electronic health records and automated methods. Clin Pharmacol Ther 2012;92:228-234.

17. Hripcsak G, Friedman C, Alderson PO, DuMouchel W, Johnson SB, Clayton PD. Unlocking clinical data from narrative reports: a study of natural language processing. Ann Intern Med 1995;122:681-688.

18. Park MY, Yoon D, Choi NK, Lee J, Lee K, Lim HS, Park BJ, Kim JH, Park RW. Construction of an open-access QT database for detecting the proarrhythmia potential of marketed drugs: ECG-ViEW. Clin Pharmacol Ther 2012;07. 25. [Epub]. DOI:10.1038/clpt.2012.93..

19. Murphy SN, Mendis ME, Berkowitz DA, Kohane I, Chueh HC. Integration of clinical and genetic data in the i2b2 architecture. AMIA Annu Symp Proc 2006;1040.

20. Platt R, Carnahan RM, Brown JS, Chrischilles E, Curtis LH, Hennessy S, Nelson JC, Racoosin JA, Robb M, Schneeweiss S, Toh S, Weiner MG. The U.S. Food and Drug Administration.s Mini-Sentinel program: status and direction. Pharmacoepidemiol Drug Saf 2012;21:Suppl 1. 1-8.

21. Trifiro G, Fourrier-Reglat A, Sturkenboom MC, Diaz Acedo C, Van Der Lei J. EU-ADR Group. The EU-ADR project: preliminary results and perspective. Stud Health Technol Inform 2009;148:43-49.

22. Cios KJ, Moore GW. Uniqueness of medical data mining. Artif Intell Med 2002;26:1-24.

23. U.S. Department of Health and Human Services. National Institutes of Health. Research repositories, databases, and the HIPAA privacy rule [Internet] 2004;cited 2012 Jun 27. Bethesda: National Institutes of Health. Available from: http://privacyruleandresearch.nih.gov/research_repositories.asp

24. El Emam K, Arbuckle L, Koru G, Eze B, Gaudette L, Neri E, Rose S, Howard J, Gluck J. De-identification methods for open health data: the case of the Heritage Health Prize claims dataset. J Med Internet Res 2012;14:e33.

25. Service RF. Gene sequencing. The race for the $1000 genome. Science 2006;311:1544-1546.

26. Dondorp WJ, de Wert GM. The 'thousand-dollar genome': an ethical exploration 2010;The Hague: Centre for Ethics and Health.