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Picture archiving and communication system - Wikipedia, the free encyclopedia

Picture archiving and communication system

From Wikipedia, the free encyclopedia

An image as stored on a picture archiving and communication system (PACS)
An image as stored on a picture archiving and communication system (PACS)
The same image following contrast adjustment, sharpening and measurement tags added by the system
The same image following contrast adjustment, sharpening and measurement tags added by the system

In medical imaging, picture archiving and communication systems (PACS) are computers or networks dedicated to the storage, retrieval, distribution and presentation of images. The medical images are stored in an independent format. The most common format for image storage is DICOM (Digital Imaging and Communications in Medicine).

Contents

[edit] Types of images

Most PACSs handle images from various medical imaging instruments, including ultrasound, magnetic resonance, PET, computed tomography, endoscopy, mammograms, etc. (see DICOM Application areas).

[edit] Uses

PACS has three main uses:

  • Hard copy replace: PACS replaces hard-copy based means of managing medical images, such as film archives.
  • Remote access: Additionally, it enables practitioners at various physical locations to access the same information simultaneously, (teleradiology). With the decreasing price of digital storage, PACSs provide a growing cost and space advantage over film archives.
  • Tele-education: It expands on the possibilities of such conventional systems by providing capabilities of off-site viewing and reporting (distance education, telediagnosis).

PACS is offered by virtually all the major medical imaging equipment manufacturers, medical IT companies and many independent software companies.

The most difficult area for PACS is interpreting the DICOM image format. DICOM has enough latitude to allow various vendors of medical imaging equipment to create DICOM compliant and uncompliant files that differ in the internal tags used to label the data and the metadata. A feature common to most PACS is to read the metadata from all the images into a central database. This allows the PACS user to retrieve all images with a common feature no matter the originating instrument. The differences between vendors' DICOM implementations make this a difficult task.

A PACS allows to store volumic exams and to reconstruct 3D images
A PACS allows to store volumic exams and to reconstruct 3D images

[edit] Architecture

Typically a PACS network consists of a central server that stores a database containing the images connected to one or more clients via a LAN or a WAN which provide or utilize the images.

More and more PACS include web-based interfaces to utilize the Internet as their means of communication, usually via VPN (Virtual Private Network) or SSL (Secure Sockets Layer). The software is loaded via ActiveX, Java, or .NET Framework.

Definitions vary, but most claim that for a system to be truly web based, each individual image should have its own URL.

Client workstations can use local peripherals for scanning image films into the system, printing image films from the system and interactive display of digital images. PACS workstations offer means of manipulating the images (crop, rotate, zoom, brightness, contrast and others).

Modern radiology equipment, modalities, feed patient images directly to the PACS in digital form. For backwards compatibility, most hospital imaging departments and radiology practices employ a film digitizer.

[edit] Integration

A chest image displayed via a PACS
A chest image displayed via a PACS

A full PACS should provide a single point of access for images and their associated data (i.e. it should support multiple modalities). It should also interface with existing hospital information systems: Hospital information system (HIS) and Radiology Information System (RIS).

Interfacing between multiple systems provides a more consistent and more reliable dataset:

  • Less risk of entering an incorrect patient ID for a study – modalities that support DICOM worklists can retrieve identifying patient information (patient name, patient number, accession number) for upcoming cases and present that to the technologist, preventing data entry errors during acquisition. Once the acquisition is complete, the PACS can compare the embedded image data with a list of scheduled studies from RIS, and can flag a warning if the image data does not match a scheduled study.
  • Data saved in the PACS can be tagged with unique patient identifiers (such as a social security number or NHS number) obtained from HIS. Providing a robust method of merging datasets from multiple hospitals, even where the different centers use different ID systems internally.

An interface can also improve workflow patterns:

  • When a study has been reported by a radiologist the PACS can mark it as read. This avoids needless double-reading. The report can be attached to the images and be viewable via a single interface.
  • Improved use of online storage and nearline storage in the image archive. The PACS can obtain lists of appointments and admissions in advance, allowing images to be pre-fetched from nearline storage (for example, tape libraries or DVD jukeboxes) onto online disk storage (RAID array).

Recognition of the importance of integration has led a number of suppliers to develop fully integrated RIS/PACS. These may offer a number of advanced features:

  • Dictation of reports can be integrated into a single system. The recording is automatically sent to a transcriptionist's workstation for typing, but it can also be made available for access by physicians, avoiding typing delays for urgent results, or retained in case of typing error.
  • Provides a single tool for quality control and audit purposes. Rejected images can be tagged, allowing later analysis (as may be required under radiation protection legislation). Workloads and turn-around time can be reported automatically for management purposes.

[edit] History

The principles of PACS were first discussed at meetings of radiologists in 1982. Various people are credited with the coinage of the term PACS. Cardiovascular radiologist Dr Andre Duerinckx reported in 1983 that he had first used the term in 1981.[1] Dr Samuel Dwyer, though, credits Dr Judith M. Prewitt for introducing the term.[2]

Dr Harold Glass, a medical physicist working in London in the early 1990s secured UK Government funding and managed the project over many years which transformed Hammersmith Hospital in London as the first filmless hospital in the United Kingdom.[3] Dr Glass passed away a few months after the project came live but is credited with being one of the pioneers of PACS.

[edit] References

  1. ^ Duerinckx AJ, Pisa EJ. Filmless Picture Archiving and Communication System (PACS) in Diagnostic Radiology. Proc SPIE 1982;318;9-18. Reprinted in IEEE Computer Society Proceedings of PACS'82, order No 388.
  2. ^ Samuel J. Dwyer III. A personalized view of the history of PACS in the USA. In: Proceedings of the SPIE, "Medical Imaging 2000: PACS Design and Evaluation: Engineering and Clinical Issues", edited by G. James Blaine and Eliot L. Siegel. 2000;3980:2-9.
  3. ^ Bryan S, Weatherburn GC, Watkins JR, Buxton MJ (1999). "The benefits of hospital-wide picture archiving and communication systems: a survey of clinical users of radiology services". Br J Radiol 72 (857): 469–78. PMID 10505012. 

[edit] See also

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