@article {1224, title = {Towards Implementation of OMOP in a German University Hospital Consortium.}, journal = {Appl Clin Inform}, volume = {9}, year = {2018}, month = {2018 01}, pages = {54-61}, abstract = {

BACKGROUND: In 2015, the German Federal Ministry of Education and Research initiated a large data integration and data sharing research initiative to improve the reuse of data from patient care and translational research. The Observational Medical Outcomes Partnership (OMOP) common data model and the Observational Health Data Sciences and Informatics (OHDSI) tools could be used as a core element in this initiative for harmonizing the terminologies used as well as facilitating the federation of research analyses across institutions.

OBJECTIVE: To realize an OMOP/OHDSI-based pilot implementation within a consortium of eight German university hospitals, evaluate the applicability to support data harmonization and sharing among them, and identify potential enhancement requirements.

METHODS: The vocabularies and terminological mapping required for importing the fact data were prepared, and the process for importing the data from the source files was designed. For eight German university hospitals, a virtual machine preconfigured with the OMOP database and the OHDSI tools as well as the jobs to import the data and conduct the analysis was provided. Last, a federated/distributed query to test the approach was executed.

RESULTS: While the mapping of ICD-10 German Modification succeeded with a rate of 98.8\% of all terms for diagnoses, the procedures could not be mapped and hence an extension to the OMOP standard terminologies had to be made.Overall, the data of 3 million inpatients with approximately 26 million conditions, 21 million procedures, and 23 million observations have been imported.A federated query to identify a cohort of colorectal cancer patients was successfully executed and yielded 16,701 patient cases visualized in a Sunburst plot.

CONCLUSION: OMOP/OHDSI is a viable open source solution for data integration in a German research consortium. Once the terminology problems can be solved, researchers can build on an active community for further development.

}, keywords = {Cooperative Behavior, Germany, Health Plan Implementation, Hospitals, University, Humans, Outcome Assessment (Health Care), Surveys and Questionnaires, Vocabulary}, issn = {1869-0327}, doi = {10.1055/s-0037-1617452}, author = {Maier, C and Lang, L and Storf, H and Vormstein, P and Bieber, R and Bernarding, J and Herrmann, T and Haverkamp, C and Horki, P and Laufer, J and Berger, F and H{\"o}ning, G and Fritsch, H W and Sch{\"u}ttler, J and Ganslandt, T and Prokosch, H U and Sedlmayr, M} } @article {1047, title = {[Central online quality assurance in radiology: an IT solution exemplified by the German Breast Cancer Screening Program].}, journal = {Rofo}, volume = {183}, year = {2011}, month = {2011 Sep}, pages = {849-54}, abstract = {

PURPOSE: Physical-technical quality assurance is one of the essential tasks of the National Reference Centers in the German Breast Cancer Screening Program. For this purpose the mammography units are required to transfer the measured values of the constancy tests on a daily basis and all phantom images created for this purpose on a weekly basis to the reference centers. This is a serious logistical challenge. To meet these requirements, we developed an innovative software tool.

MATERIALS AND METHODS: By the end of 2005, we had already developed web-based software (MammoControl) allowing the transmission of constancy test results via entry forms. For automatic analysis and transmission of the phantom images, we then introduced an extension (MammoControl DIANA). This was based on Java, Java Web Start, the NetBeans Rich Client Platform, the Pixelmed Java DICOM Toolkit and the ImageJ library.

RESULTS: MammoControl DIANA was designed to run locally in the mammography units. This allows automated on-site image analysis. Both results and compressed images can then be transmitted to the reference center. We developed analysis modules for the daily and monthly consistency tests and additionally for a homogeneity test.

CONCLUSION: The software we developed facilitates the immediate availability of measurement results, phantom images, and DICOM header data in all reference centers. This allows both targeted guidance and short response time in the case of errors. We achieved a consistent IT-based evaluation with standardized tools for the entire screening program in Germany.

}, keywords = {Data Compression, Female, Germany, Guideline Adherence, Humans, Image Processing, Computer-Assisted, Mammography, Mass Screening, Online Systems, Phantoms, Imaging, Quality Assurance, Health Care, Radiology Information Systems, Reference Standards, Software}, issn = {1438-9010}, doi = {10.1055/s-0031-1281599}, author = {Czwoydzinski, J and Girnus, R and Sommer, A and Heindel, W and Lenzen, H} } @article {496, title = {Establishing a personal electronic health record in the Rhine-Neckar region.}, journal = {Studies in health technology and informatics}, volume = {150}, year = {2009}, month = {2009}, pages = {119}, abstract = {We present an approach to establish a personal and electronic health record (PEHR) system in our region, and describe the underlying vision, the technical aspects, the current status as well as the gained experiences. Applied are international standards (HL7, DICOM) and technologies existing today. Obstacles to overcome during the implementation have been the management of access rights, data privacy as well as the integration of the primary systems.}, keywords = {Germany, Medical Records Systems, Computerized, Organizational Case Studies, Program Development, Regional Health Planning}, issn = {0926-9630}, author = {Heinze, Oliver and Brandner, Antje and Bergh, Bj{\"o}rn} }