Susceptibility artifact correction in MR thermometry for monitoring of mild radiofrequency hyperthermia using total field inversion

Boehm, Christof; Goeger-Neff, M.; Mulder, Hendrik Thijmen; Zilles, Benjamin; Lindner, Lars H.; Rhoon, Gerard C. van; Karampinos, Dimitrios C.; Wu, Mingming

doi:10.1002/mrm.29191

Cited by 11 publications

(6 citation statements)

References 39 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Noninvasive MR imaging during treatment could provide very valuable additional information to support this. Dedicated MR methods can be applied to map perfusion and hypoxia, but also 3 D temperature (estimations) during treatment [91,98,99]. These data can be very useful to further improve the quantitative reliability of temperature predictions by hyperthermia treatment planning, using the advanced discrete vasculature (DIVA) thermal model [100,101] and also to improve the reliability of on-line adaptive strategies during hyperthermia treatment [102,103].…”

Section: Future Developments Toward Routine Clinical Usementioning

confidence: 99%

Biological modeling in thermoradiotherapy: present status and ongoing developments toward routine clinical use

Kok

Rhoon

Herrera

et al. 2022

International Journal of Hyperthermia

Self Cite

View full text Add to dashboard Cite

Biological modeling for anti-cancer treatments using mathematical models can be very supportive in gaining more insight into dynamic processes responsible for cellular response to treatment, and predicting, evaluating and optimizing therapeutic effects of treatment. This review presents an overview of the current status of biological modeling for hyperthermia in combination with radiotherapy (thermoradiotherapy). Various distinct models have been proposed in the literature, with varying complexity; initially aiming to model the effect of hyperthermia alone, and later on to predict the effect of the combined thermoradiotherapy treatment. Most commonly used models are based on an extension of the linear-quadratic (LQ)-model enabling an easy translation to radiotherapy where the LQ model is widely used. Basic predictions of cell survival have further progressed toward 3 D equivalent dose predictions, i.e., the radiation dose that would be needed without hyperthermia to achieve the same biological effect as the combined thermoradiotherapy treatment. This approach, with the use of temperature-dependent model parameters, allows theoretical evaluation of the effectiveness of different treatment strategies in individual patients, as well as in patient cohorts. This review discusses the significant progress that has been made in biological modeling for hyperthermia combined with radiotherapy. In the future, when adequate temperature-dependent LQ-parameters will be available for a large number of tumor sites and normal tissues, biological modeling can be expected to be of great clinical importance to further optimize combined treatments, optimize clinical protocols and guide further clinical studies.

show abstract

Section: Future Developments Toward Routine Clinical Usementioning

confidence: 99%

Biological modeling in thermoradiotherapy: present status and ongoing developments toward routine clinical use

Kok

Rhoon

Herrera

et al. 2022

International Journal of Hyperthermia

Self Cite

View full text Add to dashboard Cite

show abstract

“…Moreover, this identical algorithm has successfully rectified the temperature error caused by magnetic susceptibility in gas/carbonized tissues within a microwave ablation zone [22]. Additionally, applying background field removal and quantitative susceptibility mapping to the original phase images in the PRFS process enables the elimination of magnetic susceptibility effects due to motion-related artifacts and background phase drifts [23,24]. This approach has been shown to yield temperatures with an acceptable error range when compared to FOSs.…”

Section: Introductionmentioning

confidence: 99%

Straightforward Magnetic Resonance Temperature Measurements Combined with High Frame Rate and Magnetic Susceptibility Correction

Kim,

2023

Bioengineering

View full text Add to dashboard Cite

Proton resonance frequency shift (PRFS) is an MRI-based simple temperature mapping method that exhibits higher spatial and temporal resolution than temperature mapping methods based on T1 relaxation time and diffusion. PRFS temperature measurements are validated against fiber-optic thermal sensors (FOSs). However, the use of FOSs may introduce temperature errors, leading to both underestimation and overestimation of PRFS measurements, primarily due to material susceptibility changes caused by the thermal sensors. In this study, we demonstrated susceptibility-corrected PRFS (scPRFS) with a high frame rate and accuracy for suitably distributed temperatures. A single-echo-based background removal technique was employed for phase variation correction, primarily owing to magnetic susceptibility, which enabled fast temperature mapping. The scPRFS was used to validate the temperature fidelity by comparing the temperatures of fiber-optic sensors and conventional PRFS through phantom-mimicked human and ex vivo experiments. This study demonstrates that scPRFS measurements in agar-gel are in good agreement with the thermal sensor readings, with a root mean square error (RMSE) of 0.33–0.36 °C in the phantom model and 0.12–0.16 °C in the ex vivo experiment. These results highlight the potential of scPRFS for precise thermal monitoring and ablation in both low- and high-temperature non-invasive therapies.

show abstract

“…There, the microbubbles begin to oscillate and enhance the conversion from mechanical to thermal energy 4 . A limiting factor of that method is that temperature effects must be carefully controlled and monitored during therapy, for which several techniques exist 9 – 11 . Additionally, correction techniques have been proposed to address baseline drifts in the proton resonant frequency (PRF) method for improved accuracy 12 .…”

Section: Introductionmentioning

confidence: 99%

MR-guided ultrasound-stimulated microbubble therapy enhances radiation-induced tumor response

McNabb

Sharma

Sannachi

et al. 2023

Sci Rep

View full text Add to dashboard Cite

High intensity focused ultrasound (HIFU) systems have been approved for therapeutic ultrasound delivery to cause tissue ablation or induced hyperthermia. Microbubble agents have also been used in combination with sonication exposures. These require temperature feedback and monitoring to prevent unstable cavitation and prevent excess tissue heating. Previous work has utilized lower power and pressure to oscillate microbubbles and transfer energy to endothelial cells in the absence of thermally induced damage that can radiosensitize tumors. This work investigated whether reduced acoustic power and pressure on a commercial available MR-integrated HIFU system could result in enhanced radiation-induced tumor response after exposure to ultrasound-stimulated microbubbles (USMB) therapy. A commercially available MR-integrated HIFU system was used with a hyperthermia system calibration provided by the manufacturer. The ultrasound transducer was calibrated to reach a peak negative pressure of − 750 kPa. Thirty male New Zealand white rabbits bearing human derived PC3 tumors were grouped to receive no treatment, 14 min of USMB, 8 Gy of radiation in a separate irradiation cabinet, or combined treatments. In vivo temperature changes were collected using MR thermometry at the tumor center and far-field muscle region. Tissues specimens were collected 24 h post radiation therapy. Tumor cell death was measured and compared to untreated controls through hematoxylin and eosin staining and immunohistochemical analysis. The desired peak negative pressure of − 750 kPa used for previous USMB occurred at approximately an input power of 5 W. Temperature changes were limited to under 4 °C in ten of twelve rabbits monitored. The median temperature in the far-field muscle region of the leg was 2.50 °C for groups receiving USMB alone or in combination with radiation. Finally, statistically significant tumor cell death was demonstrated using immunohistochemical analysis in the combined therapy group compared to untreated controls. A commercial MR-guided therapy HIFU system was able to effectively treat PC3 tumors in a rabbit model using USMB therapy in combination with radiation exposures. Future work could find the use of reduced power and pressure levels in a commercial MR-guided therapy system to mechanically stimulate microbubbles and damage endothelial cells without requiring high thermal doses to elicit an antitumor response.

show abstract

Susceptibility artifact correction in MR thermometry for monitoring of mild radiofrequency hyperthermia using total field inversion

Cited by 11 publications

References 39 publications

Biological modeling in thermoradiotherapy: present status and ongoing developments toward routine clinical use

Biological modeling in thermoradiotherapy: present status and ongoing developments toward routine clinical use

Straightforward Magnetic Resonance Temperature Measurements Combined with High Frame Rate and Magnetic Susceptibility Correction

MR-guided ultrasound-stimulated microbubble therapy enhances radiation-induced tumor response

Contact Info

Product

Resources

About