On the heating of linear conductive structures as guide wires and catheters in interventional MRI

Nitz, Wolfgang R.; Oppelt, A; Renz, Wolfgang; Manke, C.; Lenhart, Markus; Link, J.

doi:10.1002/1522-2586(200101)13:1<105::aid-jmri1016>3.0.co;2-0

Cited by 297 publications

(187 citation statements)

References 18 publications

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“…Here, the segmented cable heated up by 3.5 K, whereas the unsegmented cable showed a temperature increase of up to 30 K. It was confirmed that RF-induced heating is highly dependent on the position of the active tracking device within the transmitting body resonator [13,14]. Close to the magnet bore and to the end rings of the bird-cage body resonator high electric field components are present which lead to the strongest temperature increases.…”

Section: Discussionmentioning

confidence: 99%

“…In combination with fast projection measurements interventional devices can thus be localized in a few milliseconds [7][8][9][10]. Unfortunately, potentially dangerous resonant heating can occur with active devices [11][12][13][14], which arises from resonant coupling of the RF transmit field with conducting structures that are in contact with dissipative materials.…”

mentioning

confidence: 99%

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B1 field-insensitive transformers for RF-safe transmission lines

Krafft

Müller

Umathum

et al. 2006

Magn Reson Mater Phy

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

B1 field-insensitive transformers for RF-safe transmission lines

Krafft

Müller

Umathum

et al. 2006

Magn Reson Mater Phy

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“…Especially metallic parts surrounded by aqueous media tend to show resonance effects even for smaller extensions owing to shorter wavelengths [49][50][51]. The conditions for RF resonance circuits and for RF antennas are more easily obtained by implants and metallic instruments, e.g., aspiration needles.…”

Section: Safety Issuesmentioning

confidence: 99%

Whole-body MRI at high field: technical limits and clinical potential

2005

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This review seeks to clarify the most important implications of higher magnetic field strength for clinical examinations of the whole body. An overview is provided on the resulting advantages and disadvantages for anatomical, functional and biochemical magnetic resonance examinations in different regions of the body. It is demonstrated that susceptibility-dependent imaging, chemical shift selective (e.g., fat-suppressed) imaging, and spectroscopic techniques clearly gain from higher field strength. Problems due to shorter wavelength and higher radio frequency energy deposition at higher field strength are reported, especially in examinations of the body trunk. Thorax examinations provided sufficient homogeneity of the radio frequency field for common examination techniques in most cases, whereas abdominal and pelvic imaging was often hampered by undesired dielectric effects. Currently available and potential future strategies to overcome related limitations are discussed. Whole-body MRI at higher field strength currently leads to clearly improved image quality using a variety of established sequence types and for examination of many body regions. But some major problems at higher field strength have to be solved before high-field magnetic resonance systems can really replace the well-established and technically developed magnetic resonance systems operating at 1.5 T for each clinical application.

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“…Commercially available endovascular devices are in most cases not appropriate for MR imaging because (1) ferromagnetic components receive strong attractive forces from the magnet; (2) conductive materials could distort the radiofrequency (RF) field; and (3) long electrical conductors could cause significant heating effects in the MR environment [48]. It has been confirmed that long conductive instruments cause heating during the RF excitation (especially when using real-time sequences with high flip angles and short repetition times) [49]. Ladd and Quick placed resonant structures (chokes) into the conducting miniaturized cables to prevent the onset of RF-induced resonant waves on the cables [50].…”

Section: Mr Devicesmentioning

confidence: 65%

An overview on the advances in cardiovascular interventional MR imaging

Saborowski

Saeed

2007

Magn Reson Mater Phy

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Interventional cardiovascular magnetic resonance imaging (iCMR) represents a new discipline whose systematic development will foster minimally invasive interventional procedures without radiation exposure. New generations of open, wide and short bore MR scanners and real time sequences made cardiovascular intervention possible. MR compatible endovascular catheters and guide-wires are needed for delivery of devices such as stents or atrial septal defect (ASD) closures. Catheter tracking is based on active and passive approaches. Currently performed MR-guided procedures are used to monitor, navigate and track endovascular catheters and to deliver local therapeutic agents to targets, such as infarcted myocardium and vascular walls. Heating of endovascular MR catheters, guide-wires and devices during imaging still presents high safety risks. MR contrast media improve the capabilities of MR imaging by enhancing blood signal, pathologic targets (such as myocardial infarctions and atherosclerotic plaques), endovascular catheters and by tracking injected therapeutic agents. Labeling injected soluble therapeutic agents, genes or cells with MR contrast media enables interventionalists to ensure the administration of the drugs in the target and to trace their distribution in the targets. The future clinical use of this iCMR technique requires (1) high spatial and temporal resolution imaging, (2) special catheters and devices and (3) effective therapeutic agents, genes or cells. These conditions are available at a low scale at the present time and need to be developed in the near future. Such progress will lead to improved patient care and minimize invasiveness.

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On the heating of linear conductive structures as guide wires and catheters in interventional MRI

Cited by 297 publications

References 18 publications

B1 field-insensitive transformers for RF-safe transmission lines

B1 field-insensitive transformers for RF-safe transmission lines

Whole-body MRI at high field: technical limits and clinical potential

An overview on the advances in cardiovascular interventional MR imaging

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