Title: Teleradiology
1Teleradiology
2- Introduction
- PACS
- Teleradiology systems state of the art
- Image acquisition, display, interpretation
- Image transmission
- Networks
- Image compression
- Lossless image compression
- Lossy image compression
- Examples
- The ACR-NEMA DICOM standard
- Information modelling in DICOM
- Network environment support in DICOM
- Conformance in DICOM
- The ACR standard for Teleradiology
3Introduction
- High band with communication capability - low
cost acquisition of medical data in digital form - Definition of teleradiology
- Description of possible applications
- Key points in teleradiology
- Teleradiology is the most mature of Telemedicine
areas
4PACS
- Teleradiology originated from the need to manage
images within departments and among departments. - Research on Picture Archiving and Communication
Systems (PACS) has brought about new capabilities
for radiologists - Major advantages of PACS
5Teleradiology systems state of the art
- Image acquisition and display
- Communication networks
- Image interpretation
6Image acquisition, display, interpretation
- Film digitization
- Computed radiography (CR)
- CT and MR scanners
- Frame grabbing
- Amounts of data to be transmitted
7Image transmission
- Networks
- main aspects to be taken into account
- Internet
- ISDN
- ATM
8Image transmission
- Image compression
- lossless image compression
- major advanced lossless tecniques DPCM, HINT,
DP, BPE, MAR - compression ratios 1.51 - 31
- lossy image compression
- growing evidence that lossy compression can be
implemented without compromising diagnostic
content - requirements
- JPEG,
- subband coding wavelets
9Compression examples
Original image size 1,177,864 bytes
10GIF compression 545,463 bytes ratio 12.2
JPEG compression Optimized quality 127,246
bytes ratio 19.3
JPEG compression Optimized size 26,141
bytes ratio 145
11Original image size 1,989,536 bytes
12GIF compression 1,175,620 bytes ratio 11.7
JPEG compression Optimized quality 283,557
bytes ratio 17
JPEG compression Optimized size 39,690
bytes ratio 150
13Original image size 746,786 bytes
14GIF compression 315,683 bytes ratio 12.4
JPEG compression Optimized quality 89,200
bytes ratio 18.4
JPEG compression Optimized size 24,783
bytes ratio 130
15Zoom of previous image
Original size 65,589
JPEG compression Optimized quality 14,411
bytes ratio 14.6
JPEG compression Optimized size 3,731 bytes ratio
117.6
16The ACR-NEMA DICOM standard
- Introduction
- Version 1.0 1985
- Version 2.0
- Version 3.0 1992/1993 (DICOM)
- most important innovations with respect to
version 1.0 and 2.0 use of information
modelling, applicability to a networked
environment, conformance
17The ACR-NEMA DICOM standard
- Information modelling
- advantages reduction of redundancy and ambiguity
- normalised object classes composite object
classes - established technique for uniquely identifying
any object
18The ACR-NEMA DICOM standard
- Network environment support
- The International Standard Organisation (ISO) has
set up a reference model for network
communication - DICOM fully conforms to ISO
- Communication protocols specified by DICOM are
general purpose (OSI, TCP/IP).
19The ACR-NEMA DICOM standard
- Conformance
- DICOM defines the principles to be met by
implementations claiming conformance - DICOM specifies levels of conformance
20The ACR standard for teleradiology
- In 1994 the ACR has developed a standard for
teleradiology - This standard defines goals, qualification of
personnel, equipement guidelines, licensing,
credentialing, liability, communication, quality
control and quality improvement