EFSUMB Newsletter
EFSUMB Newsletter European Federation of Societies for Ultrasound in Medicine and Biology
New Technology
Fusion Imaging and Interventional Ultrasound Image fusion can be carried out between all image modalities provided they are geometrically consistent. Fusion ultrasound (FUS) is the application of image fusion, where dynamic ultrasound images are presented simultaneously with corresponding images obtained from a previously acquired CT, CT/PET or MRI volume. Fusion of a live on-going US-examination with a previously acquired US-examination may be performed as well. In the former EJU-newsletter, Dr Caroline Ewertsen and Dr Adrian Săftoiu presented a fine overview of this new technique. In the following, we report and illustrate some of our experience with FUS and interventional procedures.
Technical Requirements for FUS. ▼▼
The first step on a FUS procedure is to load a dataset (CT, CT/PET or MRI) into the USsystem by means of an USB-memory stick, a CD-ROM, a hard drive, or via the network cable and a DICOM query/retrieve connection to PACS (Picture Archiving and Communication System). Obviously, the CT-scan is obtained under other conditions than the US-scan regarding parameters such as patient position and respiration depth and the examiner must consider these limitations for a successful outcome of the image fusion including the interventional procedure. A magnetic field is created around the patient by a magnetic transmitter and position sensors mounted on the US-transducer enable definition of the actual threedimensional transducer position (qFig. 1).
Definition of three points defines a plane, by which alignment (registration) can be established between an US-image and the corresponding slice from the uploaded dataset of the previously acquired CTexam. The US-exam is carried out as usual and images are shown in real-time (master) side-by-side and simultaneously with the corresponding dynamic virtual CT-image (slave). The two images can also be shown superimposed on each other. CEUS (Contrast enhanced ultrasound) may be conducted as CEUS-CT fusion (qFig. 2).
FUS and Interventional Procedures ▼▼
Ultrasound currently is the only real-time image modality available and the technique provides better time resolution by means of higher frame rate than any other imaging modality. Furthermore, US enables free choice of scan plane, which is advantageous for intervention, e.g. biopsies, drainage and minimally invasive therapies (MIT). On the down side US may have difficulties visualizing all parts of the abdomen due to anatomically conditions or artifacts. FUS may merge the advantages of US with the advantages of other imaging modalities to overcome or reduce these difficulties, thus improving the diagnostic and therapeutic outcome (qFig. 2).
FUS and Biopsy ▼▼
Cancer patients are often followed with CT after the primary treatment. In many
institutions including our own department, when CT shows sign of recurrence and histopathology confirmation is necessary, the next step usually is an US guided biopsy. Small liver metastases or small retroperitoneal lymph nodes, however, might be difficult to find with US, and in this situation FUS in our experience can often provide a helpful guide to the cor-
Fig. 1 Fusion imaging (US and CT). The magnetic transmitter (covering the face of the “patient”) and the position sensors (mounted on the transducer) are seen. On the monitor, real time US and “fusion” CT are seen side by side.
Fig. 2 US-guided biopsy of a liver metastasis. a. US-CT-fusion. The liver metastasis is located near the dome and is clearly visualized on CT (right image), but partly invisible on US (left image) due to pleural air artifact. b. CEUS-CT-fusion. On CEUS (left image) the metastasis becomes more visible.
Ultraschall in Med 2011; 32
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