Application of the ESHO-QA guidelines for determining the performance of the LCA superficial hyperthermia heating system

Carolina Carrapiço-Seabra; Mattia De Lazzari; Abdelali Ameziane; Gerard C. van Rhoon; Hana Dobšícek Trefná; Sergio Curto

doi:10.1080/02656736.2023.2272578

Application of the ESHO-QA guidelines for determining the performance of the LCA superficial hyperthermia heating system

Carolina Carrapiço-Seabra^*
, Mattia De Lazzari
, Abdelali Ameziane
, Gerard C. van Rhoon
, Hana Dobšícek Trefná
, Sergio Curto

^*Corresponding author for this work

Radiotherapy

Research output: Contribution to journal › Article › Academic › peer-review

3 Citations (Scopus)

55 Downloads (Pure)

Abstract

Purpose:

This study aimed to assess the quality of the lucite cone applicator (LCA), the standard applicator for superficial hyperthermia at the Erasmus MC Cancer Institute, using the most recent quality assurance guidelines, thus verifying their feasibility.

Materials and methods:

The assessment was conducted on each of the six LCAs available for clinical treatments. The temperature distribution was evaluated using an infrared camera across different layers of a fat-muscle mimicking phantom. The maximum temperature increase, thermal effective penetration depth (TEPD), and thermal effective field size (TEFS) were used as quality metrics. The experimental results were validated through comparison with simulated results, using a canonical phantom model and a realistic phantom model segmented from CT imaging.

Results:

A maximum temperature increase above 6 °C at 2 cm depth in the fat-muscle phantom for all the experiments was found. A mean negative difference between simulated and experimental data was of 1.3 °C when using the canonical phantom model. This value decreased to a mean negative difference of 0.4 °C when using the realistic model. Simulated and measured TEPD showed good agreement for both in silico scenarios, while discrepancies were present for TEFS.

Conclusions:

The LCAs passed all QA guidelines requirements for superficial hyperthermia delivery when used singularly or in an array configuration. A further characterization of parameters such as antenna efficiency and heat transfer coefficients would be beneficial for translating experimental results to simulated values. Implementing the QA guidelines was time-consuming and demanding, requiring careful preparation and correct setup of antenna elements.

Original language	English
Article number	2272578
Journal	International Journal of Hyperthermia
Volume	40
Issue number	1
Early online date	23 Oct 2023
DOIs	https://doi.org/10.1080/02656736.2023.2272578
Publication status	Published - 2023

Bibliographical note

Publisher Copyright:
© 2023 The Author(s). Published with license by Taylor & Francis Group, LLC.

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Application of the ESHO-QA guidelines for determining the performance of the LCA superficial hyperthermia heating systemFinal published version, 2.09 MBLicence: CC BY

Cite this

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title = "Application of the ESHO-QA guidelines for determining the performance of the LCA superficial hyperthermia heating system",

abstract = "Purpose: This study aimed to assess the quality of the lucite cone applicator (LCA), the standard applicator for superficial hyperthermia at the Erasmus MC Cancer Institute, using the most recent quality assurance guidelines, thus verifying their feasibility. Materials and methods: The assessment was conducted on each of the six LCAs available for clinical treatments. The temperature distribution was evaluated using an infrared camera across different layers of a fat-muscle mimicking phantom. The maximum temperature increase, thermal effective penetration depth (TEPD), and thermal effective field size (TEFS) were used as quality metrics. The experimental results were validated through comparison with simulated results, using a canonical phantom model and a realistic phantom model segmented from CT imaging. Results: A maximum temperature increase above 6 °C at 2 cm depth in the fat-muscle phantom for all the experiments was found. A mean negative difference between simulated and experimental data was of 1.3 °C when using the canonical phantom model. This value decreased to a mean negative difference of 0.4 °C when using the realistic model. Simulated and measured TEPD showed good agreement for both in silico scenarios, while discrepancies were present for TEFS. Conclusions: The LCAs passed all QA guidelines requirements for superficial hyperthermia delivery when used singularly or in an array configuration. A further characterization of parameters such as antenna efficiency and heat transfer coefficients would be beneficial for translating experimental results to simulated values. Implementing the QA guidelines was time-consuming and demanding, requiring careful preparation and correct setup of antenna elements.",

author = "Carolina Carrapi{\c c}o-Seabra and \{De Lazzari\}, Mattia and Abdelali Ameziane and \{van Rhoon\}, \{Gerard C.\} and \{Dob{\v s}{\'i}cek Trefn{\'a}\}, Hana and Sergio Curto",

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doi = "10.1080/02656736.2023.2272578",

language = "English",

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AU - Carrapiço-Seabra, Carolina

AU - De Lazzari, Mattia

AU - Ameziane, Abdelali

AU - van Rhoon, Gerard C.

AU - Dobšícek Trefná, Hana

AU - Curto, Sergio

PY - 2023

Y1 - 2023

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AB - Purpose: This study aimed to assess the quality of the lucite cone applicator (LCA), the standard applicator for superficial hyperthermia at the Erasmus MC Cancer Institute, using the most recent quality assurance guidelines, thus verifying their feasibility. Materials and methods: The assessment was conducted on each of the six LCAs available for clinical treatments. The temperature distribution was evaluated using an infrared camera across different layers of a fat-muscle mimicking phantom. The maximum temperature increase, thermal effective penetration depth (TEPD), and thermal effective field size (TEFS) were used as quality metrics. The experimental results were validated through comparison with simulated results, using a canonical phantom model and a realistic phantom model segmented from CT imaging. Results: A maximum temperature increase above 6 °C at 2 cm depth in the fat-muscle phantom for all the experiments was found. A mean negative difference between simulated and experimental data was of 1.3 °C when using the canonical phantom model. This value decreased to a mean negative difference of 0.4 °C when using the realistic model. Simulated and measured TEPD showed good agreement for both in silico scenarios, while discrepancies were present for TEFS. Conclusions: The LCAs passed all QA guidelines requirements for superficial hyperthermia delivery when used singularly or in an array configuration. A further characterization of parameters such as antenna efficiency and heat transfer coefficients would be beneficial for translating experimental results to simulated values. Implementing the QA guidelines was time-consuming and demanding, requiring careful preparation and correct setup of antenna elements.

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Application of the ESHO-QA guidelines for determining the performance of the LCA superficial hyperthermia heating system

Abstract

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