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Polymer gel dosimetry with MRI-readout for 3D dose verification - detector characteristics and clinical applications

Guldhill, Thi (2023) MSFT02 20232
Medical Physics Programme
Abstract
Background & Purpose:
Radiation therapy is an essential treatment for cancer patients with the ultimate goal to deliver radiation doses to the tumour with precision while minimizing exposure to surrounding healthy tissues. Treatment verification is crucial to ensure the accuracy of radiation delivery, for instance by measuring the radiation dose distribution. Among various dosimetry techniques, gel dosimetry has emerged as a promising method due to its ability to measure 3D dose distribution with high spatial resolution.
The overall aim of this thesis is to assess the applicability of normoxic polymer NIPAM gel dosimeters with MRI readout in clinical practice. Specific goals include 1) Investigating and optimizing the gel dosimetry... (More)
Background & Purpose:
Radiation therapy is an essential treatment for cancer patients with the ultimate goal to deliver radiation doses to the tumour with precision while minimizing exposure to surrounding healthy tissues. Treatment verification is crucial to ensure the accuracy of radiation delivery, for instance by measuring the radiation dose distribution. Among various dosimetry techniques, gel dosimetry has emerged as a promising method due to its ability to measure 3D dose distribution with high spatial resolution.
The overall aim of this thesis is to assess the applicability of normoxic polymer NIPAM gel dosimeters with MRI readout in clinical practice. Specific goals include 1) Investigating and optimizing the gel dosimetry workflow containing new laboratory equipment, new MRI sequences during readout and novel software for analysis 2) Evaluating different characteristics of the dosimeter for various types of radiation qualities and 3) Using the dosimeters for a 3D dose verification of a clinically novel radiotherapy treatment techniques.

Material & Method:
The NIPAM gel dosimeter was produced by dissolving gelatin in deionized water. N’-methylenebisacrylamide (BIS) and n-isopropyl acrylamide (NIPAM) together with antioxidant tetrakis (hydroxymethyl) phosphonium chloride (THPC) were added. The gel was then exposed to different radiation qualities (220 kV photon, 6 and 10 MV photon, and 120 MeV proton beams) with varying setups to investigate the dose-response for clinically relevant dose range, the resolution, the inter-batch & intra-batch variation and the dose rate & energy dependency. Readout was done using a clinical MRI (3 T). In the application of 3D measurement, the NIPAM gel dosimeter was used to verify a multiple brain metastases stereotactic HyperArc photon treatment. The dose distribution acquired from the gel measurement was compared with the dose distribution from the treatment planning system using different gamma criteria.

Result:
NIPAM-gel dosimeter exhibited an approximately linear dose response for various types of radiation, including 220 kV photons, 6 and 10 MV photons, and 120 MeV proton at the plateau region. The gel dosimeter demonstrated a high spatial resolution. Intra-batch variation showed good consistency with a standard deviation within 1%. The inter-batch deviation was found with a maximum of 7% at 26 Gy. No dose rate dependency was found for dose rates of 600 MU/min and 300 MU/min within the 0-15 Gy dose range. Similarly, no energy dependency was observed for 6 MV and 10 MV within the same dose range. When measuring the depth dose curve of the proton beam, the dosimeter exhibited a quenching effect of 40% to 45% in the Bragg peak due to higher linear energy transfer.
The result from verification of multiple brain metastases stereotactic HyperArc photon treatment showed pass rates of 99.94% and 99.87% (5%/5mm); 96.46% and 91.91% (3%/3mm) and 92.21% and 83.44% (3%/2mm) for 50% of dose and 90% of dose (global gamma), respectively when compared to treatment planning system.

Conclusion:
The work within this study has developed and improved a workflow for gel dosimetry, incorporating the use of new laboratory equipment, new MRI sequences during readout, and novel software for data analysis. Further, the results of this study enhance the understanding of NIPAM-gel dosimeter characteristics and showed potential use for clinical applications in accurately assessing 3D dose distribution. (Less)
Popular Abstract (Swedish)
Strålbehandling är en viktig behandling av cancer och det är avgörande att ge de föreskrivna stråldoserna exakt på rätt plats för att lyckas. Innan en patient behandlas verifieras strålbehandlingen genom kontrollmätningar. Dessa kontrollmätningar utförs med små detektorer som är placerade i ett fantom. Dessa mäter dosen endast i de punkter där de placeras. Stråldosen som ligger mellan dessa punkten har man dock liten kännedom till.
Geldosimetern är en detektor med hög upplösning och kan mäta dosfördelningar i en hel volym i tre dimensioner (3D), en unik och önskvärd egenskap. En sådan detektor är speciellt användbar för att kunna säkra att nya behandlingsmetoder med avancerade dosfördelningar kan levereras på ett korrekt sätt till en... (More)
Strålbehandling är en viktig behandling av cancer och det är avgörande att ge de föreskrivna stråldoserna exakt på rätt plats för att lyckas. Innan en patient behandlas verifieras strålbehandlingen genom kontrollmätningar. Dessa kontrollmätningar utförs med små detektorer som är placerade i ett fantom. Dessa mäter dosen endast i de punkter där de placeras. Stråldosen som ligger mellan dessa punkten har man dock liten kännedom till.
Geldosimetern är en detektor med hög upplösning och kan mäta dosfördelningar i en hel volym i tre dimensioner (3D), en unik och önskvärd egenskap. En sådan detektor är speciellt användbar för att kunna säkra att nya behandlingsmetoder med avancerade dosfördelningar kan levereras på ett korrekt sätt till en patient.

Geldosimetern består till mestadels av vatten och gelatin samt kemikalier som har förmåga att polymeriseras när den exponeras för strålning. Denna förändring av gelen kan detekteras med en magnetresonanskamera.
En typ av geldosimeter som undersöktes i detta arbete är N-Isopropylacrylamide (NIPAM) geldosimeter. I denna studie utvärderades dosimeters respons till strålning av olika strålslag. Som en klinisk applikation användes NIPAM-baserad geldosimeter för att verifiera stråldosen från en behandling av flera hjärnmetastaser för att visa dosimeterns tillämpning för 3D-mätningar. Gelen bestrålades med olika typer av strålning och kliniskt relevanta doser.

NIPAM geldosimeter uppvisade en bra uppskattad linjär respons för olika strålningstyper och dessutom hade geldetektorn en hög upplösning. Geldosimeter visade en oberoende respons för varierade energier och dosrater. En lägre signal visades vid protonstrålningsmätning vilket kräver korrigeringar för framtida mätningar. Beträffande den kliniska applikationen visade geldosimeters uppmätta 3D dos en god överensstämmelse med den planerade hjärnmetastas-behandlingen.
I denna studie har ett arbetsflöde för geldosimetri utvecklat, inklusive ny laboratorieutrustning, nya utläsningsmetoder samt nytt analysverktyg. Resultaten av denna studie har förbättrat förståelsen av NIPAM geldosimeters egenskaper och visar på kliniska tillämpningar för noggrann bedömning av 3D-dosfördelningar. (Less)
Please use this url to cite or link to this publication:
author
Guldhill, Thi
supervisor
organization
course
MSFT02 20232
year
type
H2 - Master's Degree (Two Years)
subject
language
English
id
9139571
date added to LUP
2023-10-04 20:00:10
date last changed
2023-10-04 20:00:10
@misc{9139571,
  abstract     = {{Background & Purpose:
Radiation therapy is an essential treatment for cancer patients with the ultimate goal to deliver radiation doses to the tumour with precision while minimizing exposure to surrounding healthy tissues. Treatment verification is crucial to ensure the accuracy of radiation delivery, for instance by measuring the radiation dose distribution. Among various dosimetry techniques, gel dosimetry has emerged as a promising method due to its ability to measure 3D dose distribution with high spatial resolution.
The overall aim of this thesis is to assess the applicability of normoxic polymer NIPAM gel dosimeters with MRI readout in clinical practice. Specific goals include 1) Investigating and optimizing the gel dosimetry workflow containing new laboratory equipment, new MRI sequences during readout and novel software for analysis 2) Evaluating different characteristics of the dosimeter for various types of radiation qualities and 3) Using the dosimeters for a 3D dose verification of a clinically novel radiotherapy treatment techniques. 

Material & Method:
The NIPAM gel dosimeter was produced by dissolving gelatin in deionized water. N’-methylenebisacrylamide (BIS) and n-isopropyl acrylamide (NIPAM) together with antioxidant tetrakis (hydroxymethyl) phosphonium chloride (THPC) were added. The gel was then exposed to different radiation qualities (220 kV photon, 6 and 10 MV photon, and 120 MeV proton beams) with varying setups to investigate the dose-response for clinically relevant dose range, the resolution, the inter-batch & intra-batch variation and the dose rate & energy dependency. Readout was done using a clinical MRI (3 T). In the application of 3D measurement, the NIPAM gel dosimeter was used to verify a multiple brain metastases stereotactic HyperArc photon treatment. The dose distribution acquired from the gel measurement was compared with the dose distribution from the treatment planning system using different gamma criteria.

Result:
NIPAM-gel dosimeter exhibited an approximately linear dose response for various types of radiation, including 220 kV photons, 6 and 10 MV photons, and 120 MeV proton at the plateau region. The gel dosimeter demonstrated a high spatial resolution. Intra-batch variation showed good consistency with a standard deviation within 1%. The inter-batch deviation was found with a maximum of 7% at 26 Gy. No dose rate dependency was found for dose rates of 600 MU/min and 300 MU/min within the 0-15 Gy dose range. Similarly, no energy dependency was observed for 6 MV and 10 MV within the same dose range. When measuring the depth dose curve of the proton beam, the dosimeter exhibited a quenching effect of 40% to 45% in the Bragg peak due to higher linear energy transfer.
The result from verification of multiple brain metastases stereotactic HyperArc photon treatment showed pass rates of 99.94% and 99.87% (5%/5mm); 96.46% and 91.91% (3%/3mm) and 92.21% and 83.44% (3%/2mm) for 50% of dose and 90% of dose (global gamma), respectively when compared to treatment planning system.

Conclusion:
The work within this study has developed and improved a workflow for gel dosimetry, incorporating the use of new laboratory equipment, new MRI sequences during readout, and novel software for data analysis. Further, the results of this study enhance the understanding of NIPAM-gel dosimeter characteristics and showed potential use for clinical applications in accurately assessing 3D dose distribution.}},
  author       = {{Guldhill, Thi}},
  language     = {{eng}},
  note         = {{Student Paper}},
  title        = {{Polymer gel dosimetry with MRI-readout for 3D dose verification - detector characteristics and clinical applications}},
  year         = {{2023}},
}