Quantitative MR thermometry based on phase-drift correction PRF shift method at 0.35 T

Chen, Yuping; Ge, Mengke; Ali, Rizwan; Jiang, Hua; Huang, Xiaoyan; Qiu, Bensheng

doi:10.1186/s12938-018-0472-x

Cited by 8 publications

(6 citation statements)

References 49 publications

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“…Field drifts are most likely responsible for consistent underestimation of lesion sizes listed in Table 1. This phenomenon has been widely reported on in the literature [12,[29][30][31][32] and several methods have been proposed to mitigate it for improved accuracy of PRFS [33,34]. Real-time corrections for field drifts at the ablation site are currently being investigated by our group.…”

Section: Tablementioning

confidence: 87%

Practical implementation of robust MR-thermometry during clinical MR-guided microwave ablations in the liver at 1.5 T

Gorny

Favazza

et al. 2019

Physica Medica

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Practical non-invasive equipment modifications and effective acquisition methods to achieve robust and reliable real-time MR thermometry for monitoring of clinical hepatic microwave ablations were implemented. These included selection of the microwave generator location (inside versus outside the MR scan room), the number of radiofrequency chokes added to the microwave generator's coaxial lines, and the use of copper wool to maximize their electrical grounding. Signal-to-noise ratio (SNR) of MR thermometry images of a small fluid-filled phantom acquired during activation of microwave antenna were used to evaluate image quality as a function of each modification. SNR measurements corresponding to both locations of the microwave generator were comparable and so it was located outside the MR scan room. For this location, addition of one RF choke on the power and four chokes on the sensor coaxial lines was found to be optimal, corresponding to a 68% increase in SNR. Furthermore, image quality strongly depended on the proper electrical grounding of the power and sensor lines. SNR ratio (relative to SNR of baseline images) during activation of microwave generator was found to be 0.49 ± 0.28 without adequate grounding, and 0.88 ± 0.08 with adequate grounding (p = 0.002, Student's ttest). These SNR measurements were sufficiently sensitive to detect issues related to equipment performance and hence formed part of the quality assurance testing performed prior to each clinical treatment. Incorporating these non-invasive approaches resulted in significant improvements to image quality and, importantly while maintaining the clinical integrity of the microwave system which is of paramount importance in a highly regulated healthcare environment.

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Section: Tablementioning

confidence: 87%

Practical implementation of robust MR-thermometry during clinical MR-guided microwave ablations in the liver at 1.5 T

Gorny

Favazza

et al. 2019

Physica Medica

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“…Open-configuration MR scanners are characterized by lower fields (<1 T) and also involve a lower purchase price and reduced operational cost compared with high-field instruments. Therefore, Chen et al showed by in vitro experiments with phantoms and porcine liver that MRT based on drift-correction phase PRFS with first-order polynomial fitting can be applied to monitor temperature changes during MW ablation in a low-field (0.35 T) configuration whole-body MR scanner designed for applications in humans (Chen et al, 2018). However, work on high-field PRFS (cited above) consistently indicated that discrepancies between PRFS and fiber optic probe-measured temperatures are on the order of %1 C, whereas errors may increase to about 2 C for fields as low as 0.35 T (Chen et al, 2018).…”

Section: Destroying Tissue By Heating With Ultrasound: Mrt Applications In Tissue Ablationmentioning

confidence: 99%

“…Therefore, Chen et al showed by in vitro experiments with phantoms and porcine liver that MRT based on drift-correction phase PRFS with first-order polynomial fitting can be applied to monitor temperature changes during MW ablation in a low-field (0.35 T) configuration whole-body MR scanner designed for applications in humans (Chen et al, 2018). However, work on high-field PRFS (cited above) consistently indicated that discrepancies between PRFS and fiber optic probe-measured temperatures are on the order of %1 C, whereas errors may increase to about 2 C for fields as low as 0.35 T (Chen et al, 2018). Phase PRFS tests in vivo on volunteers showed that drift correction had a marked effect on the stability of temperature measurements in the human brain, setting the stage for future clinical tests involving MW hyperthermia.…”

Section: Destroying Tissue By Heating With Ultrasound: Mrt Applications In Tissue Ablationmentioning

confidence: 99%

Contactless Thermometry by MRI and MRS: Advanced Methods for Thermotherapy and Biomaterials

Lutz¹,

Bernard²

2020

iScience

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Control of temperature variation is of primordial importance in particular areas of biomedicine. In this context, medical treatments such as hyperthermia and cryotherapy, but also the development and use of hydrogel-based biomaterials are of particular concern. To enable accurate temperature measurement without perturbing or even destroying the biological tissue or material to be monitored, contactless thermometry methods are preferred. Among these, the most suitable are based on magnetic resonance imaging and spectroscopy (MRI, MRS). Here, we address the latest developments in this field as well as their current and anticipated practical applications. We highlight recent progress aimed at rendering MR thermometry faster and more reproducible, versatile and sophisticated, and provide our perspective on how these new techniques broaden the range of applications in medical treatments and biomaterial development by enabling insight into finer details of thermal behavior. Thus, these methods facilitate optimization of clinical and industrial heating and cooling protocols.

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“…For several thermometry studies, magnetic resonance (MR)-based analysis (spectroscopy and imaging) is a valuable analytical tool among other things for biological objects. [1][2][3] Furthermore, knowledge of in vivo temperature changes is important in clinical diagnostic, therapy (such as hypothermia [4,5] or hyperthermia [6] ) or investigation of implants distortions. [7] Conventional thermometers cannot be used for temperature measurements in strong magnetic fields.…”

Section: Introductionmentioning

confidence: 99%

“…Whether solids, liquids or gases, knowledge of the local temperature or the temperature distribution can lead to the optimization of processes and structures or improve the diagnosis and therapy of diseases (theranostics). For several thermometry studies, magnetic resonance (MR)‐based analysis (spectroscopy and imaging) is a valuable analytical tool among other things for biological objects [1–3] . Furthermore, knowledge of in vivo temperature changes is important in clinical diagnostic, therapy (such as hypothermia [4,5] or hyperthermia [6] ) or investigation of implants distortions [7] .…”

Section: Introductionmentioning

confidence: 99%

Organic Fluorine Compounds and Their Uses as Molecular MR‐Based Temperature Sensors

Bruns,

Ringleb,

Prediger

et al. 2023

ChemPhysChem

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The interest in fluorinated substances has increased significantly in recent decades due to their diverse properties and possible uses. An important analytical method in this context is NMR spectroscopy, which provides information on the structure as well as on intermolecular interactions or generally on changes in the environment of the nucleus under consideration. A physical quantity that is of great importance in most studies is temperature. However, this is not always easy, e.g. in shielded systems or within an organism. However, the application potential in chemical reactors or in medical diagnosis and therapy is very high and for this reason 13 fluorinated organic compound were chosen for a first 19F NMR signal temperature sensitivity examination for determination of local temperatures in solution. Polyfluorinated molecules with separate 19F MR signals are particularly suitable for temperature determination. Those can be serve as internal error‐correcting thermometers without the need of a reference substance. Under these conditions, a 19F MR signal shift of up to 0.03 ppm/K was detectable. Fluorine position and chemical environment were very important for the temperature sensitivity.

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Quantitative MR thermometry based on phase-drift correction PRF shift method at 0.35 T

Cited by 8 publications

References 49 publications

Practical implementation of robust MR-thermometry during clinical MR-guided microwave ablations in the liver at 1.5 T

Practical implementation of robust MR-thermometry during clinical MR-guided microwave ablations in the liver at 1.5 T

Contactless Thermometry by MRI and MRS: Advanced Methods for Thermotherapy and Biomaterials

Organic Fluorine Compounds and Their Uses as Molecular MR‐Based Temperature Sensors

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Quantitative MR thermometry based on phase-drift correction PRF shift method at 0.35 T

Cited by 8 publications

References 49 publications

Practical implementation of robust MR-thermometry during clinical MR-guided microwave ablations in the liver at 1.5 T

Practical implementation of robust MR-thermometry during clinical MR-guided microwave ablations in the liver at 1.5 T

Contactless Thermometry by MRI and MRS: Advanced Methods for Thermotherapy and Biomaterials

Organic Fluorine Compounds and Their Uses as Molecular MR‐Based Temperature Sensors

Contact Info

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Resources

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Practical implementation of robust MR-thermometry during clinical MR-guided microwave ablations in the liver at 1.5 T

Practical implementation of robust MR-thermometry during clinical MR-guided microwave ablations in the liver at 1.5 T