A Web-Based Institutional DICOM Distribution System with the Integration of the Clinical Trial Processor (CTP)

To develop and test a fast and easy rule-based web-environment with optional de-identification of imaging data to facilitate data distribution within a hospital environment. A web interface was built using Hypertext Preprocessor (PHP), an open source scripting language for web development, and Java with SQL Server to handle the database. The system allows for the selection of patient data and for de-identifying these when necessary. Using the services provided by the RSNA Clinical Trial Processor (CTP), the selected images were pushed to the appropriate services using a protocol based on the module created for the associated task. Five pipelines, each performing a different task, were set up in the server. In a 75 month period, more than 2,000,000 images are transferred and de-identified in a proper manner while 20,000,000 images are moved from one node to another without de-identification. While maintaining a high level of security and stability, the proposed system is easy to setup, it integrate well with our clinical and research practice and it provides a fast and accurate vendor-neutral process of transferring, de-identifying, and storing DICOM images. Its ability to run different de-identification processes in parallel pipelines is a major advantage in both clinical and research setting.

[1]  Chin-Ling Chen,et al.  A Secure Medical Data Exchange Protocol Based on Cloud Environment , 2014, Journal of Medical Systems.

[2]  I. Stoian,et al.  Current trends in medical imaging acquisition and communication , 2008, 2008 IEEE International Conference on Automation, Quality and Testing, Robotics.

[3]  Christian Lovis,et al.  Enterprise-wide PACS: beyond radiology, an architecture to manage all medical images. , 2005, Academic radiology.

[4]  G. Broll,et al.  Microsoft Corporation , 1999 .

[5]  Steve G. Langer Issues Surrounding PACS Archiving to External, Third-Party DICOM Archives , 2008, Journal of Digital Imaging.

[6]  H. K. Huang Enterprise PACS and image distribution. , 2003, Computerized medical imaging and graphics : the official journal of the Computerized Medical Imaging Society.

[7]  C. Parisot The DICOM standard , 1995, The International Journal of Cardiac Imaging.

[8]  Chien-Lung Hsu,et al.  The Role of Privacy Protection in Healthcare Information Systems Adoption , 2013, Journal of Medical Systems.

[9]  Sjaak Brinkkemper,et al.  A Situational Alignment Framework for PACS , 2011, Journal of Digital Imaging.

[10]  Elmar Kotter,et al.  Technologies for image distribution in hospitals , 2006, European Radiology.

[11]  Günter Pomaska,et al.  PHP Hypertext Preprocessor , 2012 .

[12]  T D Cradduck,et al.  National electrical manufacturers association , 1983, Journal of the A.I.E.E..

[13]  Oleg S. Pianykh,et al.  Digital Imaging and Communications in Medicine (DICOM) , 2017, Radiopaedia.org.

[14]  Sofia Ouhbi,et al.  Free Web-based Personal Health Records: An Analysis of Functionality , 2013, Journal of Medical Systems.

[15]  Prasun Dastidar,et al.  Development of a Research Dedicated Archival System (TARAS) in a University Hospital , 2010, Journal of Digital Imaging.

[16]  Eliot Siegel,et al.  Informatics in radiology: image exchange: IHE and the evolution of image sharing. , 2008, Radiographics : a review publication of the Radiological Society of North America, Inc.

[17]  H P DOUB THE RADIOLOGICAL SOCIETY OF NORTH AMERICA; FIFTY YEARS OF PROGRESS. , 1964, Radiology.

[18]  Willy Susilo,et al.  Security and Access of Health Research Data , 2006, Journal of Medical Systems.

[19]  Steve G. Langer,et al.  Challenges for Data Storage in Medical Imaging Research , 2011, Journal of Digital Imaging.