DICOM

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== Software ==
 
== Software ==
  
Software that reads DICOM files is pretty much everywhere. Most neuroimaging analysis packages have some way of importing DICOMs and turning them in to a higher-dimensional file; open-source stand-alone libraries abound, as well:
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Software that reads DICOM files is pretty much everywhere. Most neuroimaging analysis packages have some way of importing DICOMs and turning them in to a higher-dimensional file; open-source stand-alone libraries abound, as well.
  
 
* [http://code.google.com/p/pydicom/ PyDICOM]
 
* [http://code.google.com/p/pydicom/ PyDICOM]
 
* [http://www.cabiatl.com/mricro/mricron/dcm2nii.html dcm2nii]
 
* [http://www.cabiatl.com/mricro/mricron/dcm2nii.html dcm2nii]
 
* [http://sourceforge.net/apps/mediawiki/gdcm/index.php?title=Main_Page Grassroots DICOM]
 
* [http://sourceforge.net/apps/mediawiki/gdcm/index.php?title=Main_Page Grassroots DICOM]
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* [http://www.healthcare.philips.com/main/about/connectivity/ Philips DICOM Viewer] For Microsoft Windows. Linked to in the sidebar of pages such as this one.
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== Sample files ==
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* [http://www.aycan.de/lp/sample-dicom-images.html Examples of DICOM images]
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== Specifications ==
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* [http://medical.nema.org/standard.html The DICOM Standard]

Revision as of 01:30, 22 February 2013

File Format
Name DICOM
Ontology
Extension(s) .dcm, others

Contents

General description

DICOM (Digital Imaging and Communications in Medicine) is far and away the most widely-used (and probably the oldest) electronic file format in medical imaging. Nearly every device that acquires medical images -- ultrasound, CT, PET, and MRI -- acquire DICOM images in normal operation. There's a 20-part specification detailing the file format and its ecosystem. The IANA has assigned TCP and UDP port 104 to DICOM-related traffic.

It's kind of a big deal.

However, as with any sufficiently-adopted standard, there are splinter factions. The most common format is 2-dimensional images or "slices" that can be formed into a 3-dimensional image; however, some manufacturers have extended the standard to save 3 or even 4-dimensional images in a "mosaic" format.

File format

While there are many complications involved in decoding a DICOM file, fundamentally it is simply a sequence of data blocks called attributes or elements. Each attribute contains a 16-bit group number and a 16-bit element number, conventionally written in hexadecimal and separated with a comma, e.g. (0028,0011).

Standard attributes

If an attribute's group number is even, then it is a standard attribute defined in the DICOM specification, and the group and element number together uniquely identify the meaning of the attribute.

Private attributes

If the group number is odd, then it is a private attribute, and it will have been preceded by a special attribute supplying a "private creator" identification string. A private attribute is uniquely identified by the combination of its creator identifier, group number, and the low byte of its element number.

Some examples of creator identifiers are GEMS_IMAG_01 and Philips Imaging DD 001. An identifier is usually specific to a manufacturer of medical equipment, not to a particular medical device. Unfortunately, instead of having one specification per manufacturer, private attributes are usually only documented in device-specific "DICOM Conformance Statements", which list only the attributes used by that one device.

Examples of DICOM Conformance Statements (search the documents for "private creator"):

Compilations:

Software

Software that reads DICOM files is pretty much everywhere. Most neuroimaging analysis packages have some way of importing DICOMs and turning them in to a higher-dimensional file; open-source stand-alone libraries abound, as well.

Sample files

Specifications

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