Abstract
The current technologies that trend in digital radiology (DR) are toward systems using portable smart mobile as patient-centered care. We aimed to develop a mini-mobile DR system by using smart devices for wireless connection into medical information systems. We developed a mini-mobile DR system consisting of an X-ray source and a Complementary Metal–Oxide Semiconductor (CMOS) sensor based on a flat panel detector for small-field diagnostics in patients. It is used instead of the systems that are difficult to perform with a fixed traditional device. We also designed a method for embedded systems in the development of portable DR systems. The external interface used the fast and stable IEEE 802.11n wireless protocol, and we adapted the device for connections with Picture Archiving and Communication System (PACS) and smart devices. The smart device could display images on an external monitor other than the monitor in the DR system. The communication modules, main control board, and external interface supporting smart devices were implemented. Further, a smart viewer based on the external interface was developed to display image files on various smart devices. In addition, the advantage of operators is to reduce radiation dose when using remote smart devices. It is integrated with smart devices that can provide X-ray imaging services anywhere. With this technology, it can permit image observation on a smart device from a remote location by connecting to the external interface. We evaluated the response time of the mini-mobile DR system to compare to mobile PACS. The experimental results show that our system outperforms conventional mobile PACS in this regard.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Cho HM, Kim HJ, Lee CL, Nam S, Jung JY: Imaging characteristics of the direct and mobile indirect digital radiographic systems. IEEE Nucl Sci Symp Conf Rec 5:3840–3846, 2007
Lanc¸a L, Silva A: Digital radiography detectors- a technical overview part 1. Radiogr Elsevier 15(1):9–19, 2009
Jeong MH, Kim HS, Lee BS, Han BS, Lee SC, Kim EK: Development of a portable digital radiographic system based on FOP-coupled CMOS image sensor and its performance evaluation. IEEE Trans Nucl Sci 52(5):1604–1609, 2005
Cowen AR, Kengyelics SM, Davies AG: Solid-state, flat-panel, digital radiography detectors and their physical imaging characteristics. Clin Radiol 64:487–498, 2008
Williams MB, Krupinski EA, Strauss KJ, Breeden WK, Rzeszotarski MS, Applegate K, Wyattg M, Bjork S, Seibert JA: Digital radiography image quality: image acquisition. Am Coll Radiol 4(6):371–388, 2007
Gauntt DM, Barnes GT: An automatic and accurate x-ray tube focal spot/grid alignment system for mobile radiography: system description and alignment accuracy. Med Phys 37(12):6402–6410, 2010
Lehnert T, Naguib NN, Ackermann H, Schomerus C, Jacobi V, Balzer JO, Vogl TJ: Novel, portable, cassette-sized, and wireless flat-panel digital radiography system: initial workflow results versus computed radiography. Am J Roentgenol 196(6):1368–1371, 2011
Tzeng W-S, Kuo K-M, Liu C-F, Yao H-C, Chen C-Y, Lin H-W: Managing repeat digital radiography image—a systematic approach and improvement. J Med Syst 36(4):2697–2704, 2012
Langer SG: A flexible database architecture for mining DICOM objects: the DICOM data warehouse. J Digit Imaging 25(2):206–212, 2012
Lee HJ, Lee KH, Hwang SI, Kim H-C, Seo EH, Kim TG, Ha K-S: The effect of wireless LAN-based PACS device for portable imaging modalities. J Digit Imaging 23(2):185–191, 2010
Hsiao C-H, Shiau C-Y, Liu Y-M, Chao MM, Lien C-Y, Chen C-H, Yen S-H, Tang S-T: Use of a rich internet application solution to present medical images. J Digit Imaging 24(6):967–978, 2011
Sakai S, Yabuuchi H, Matsuo Y, Okafuji T, Kamitani T, Honda H, Yamamoto K, Fujiwara K, Sugiyama N, Doi K: Integration of temporal subtraction and nodule detection system for digital chest radiographs into picture archiving and communication system (PACS): four-year experience. J Digit Imaging 21(1):91–98, 2008
Kim DK, Kim EY, Yang KH, Lee CK, Yoo SK: A mobile tele-radiology imaging system with JPEG2000 for an emergency care. J Digit Imaging 24(4):709–718, 2011
Bui AAT, Morioka C, Dionisio JDN, Johnson DB, Sinha U, Ardekani S, Taira RK, Aberle DR, El-Saden S, Kangarloo H: openSourcePACS: an extensible infrastructure for medical image management. IEEE Trans Inf Technol Biomed 11(1):94–109, 2007
Spyropoulou VA, Fountos GP, Kalyvas NI, Valais IG, Kandarakis IS, Panayiotakis GS: Experimental and theoretical evaluation of a high resolution CMOS based detector under x-ray imaging conditions. IEEE Trans Nucl Sci 58(1):314–322, 2011
Rinkel J, Gerfault L, Est’eve F, Dinten J-M: A new method for x-ray scatter correction: first assessment on a cone-beam CT experimental setup. Phys Med Biol 52(15):4633–4653, 2007
Open Source Clinical Image and Object Management. Available at http://www.dcm4che.org/. Accessed 1 October 2012
Acknowledgments
This study was supported by the grant of the Korean Health Technology R&D Project, Ministry of Health & Welfare, Republic of Korea (A120152).
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Jeong, CW., Joo, SC., Ryu, JH. et al. Development of a Mini-Mobile Digital Radiography System by Using Wireless Smart Devices. J Digit Imaging 27, 443–448 (2014). https://doi.org/10.1007/s10278-013-9659-7
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10278-013-9659-7