Bio-Heat Transfer in Cancer Treatment: A Mathematical Framework for Hyperthermia-Assisted Radiotherapy Using Monte Carlo Simulation

Tuka Fattal; Birnur Bozdoğan; Recep Yumrutaş

TR EN

Kanser Tedavisinde Biyo-Isı Transferi: Monte Carlo Simülasyonu Kullanılarak Hipertermi Destekli Radyoterapi İçin Matematiksel Bir Çerçeve

Abstract

Bu çalışma, kanser hücrelerine yönelik radyasyon tedavisi (radyoterapi) sırasında hipertermi yoluyla gerçekleşen biyoısı transferini özel olarak incelemeyi amaçlamaktadır. Bu inceleme, tedavi sonuçlarını optimize etmek, kanser hücrelerini yok etmek ve sağlıklı dokular üzerindeki yan etkileri (toksisiteyi) önlemek açısından önem taşımaktadır. Tedavi sırasında gerçekleşen ısı transferi sürecinin anlaşılması, hekimlerin tedavi etkilerini maksimize etmesine, uygulanan dozlara bağlı tepkileri öngörmesine ve yan etkileri en aza indirmesine yardımcı olabilir. X-ışını kullanan radyoterapi ile hiperterminin kombinasyonu, kanser hücrelerinin tedavisinde kullanılan yöntemler arasında özel olarak araştırılmıştır. Bu araştırma, her iki yöntemin avantajlarını bir araya getirmeyi ve bunlarla ilişkili istenmeyen yan etkileri azaltmayı hedeflemektedir. İki hipertermi darbesi arasındaki dinlenme süresi boyunca, biyolojik sistem uygulanan yüksek sıcaklıklara (43°C, 45°C, 47°C) karşı tepki vermeye çalışırken, radyoterapi dozu uygulanmaktadır. Ana fikir şudur: Kanser hücrelerinin ısıtılması, onları radyasyon tedavisine karşı daha hassas hale getirir; bu da tedavi süresini kısaltabilir, yan etkileri azaltabilir ve hayatta kalma oranlarını artırabilir. Yapılan literatür taramasına göre, kanser hücrelerinin artışı daha fazla doku hasarına yol açmaktadır. Bu bağlamda, Arrhenius modeli kullanılarak sıcaklık ve ısıya maruz kalma süresinin artmasının, kanser hücrelerine verilen hasarı artırdığı gösterilmiştir. Bu model, sıcaklık ve maruziyet süresi parametrelerini, geri dönüşü olmayan doku hasarını yansıtan tek bir parametreye (Ω) dönüştürmektedir. Son olarak, Pennes’in biyoısı denklemini çözmek için Monte Carlo Simülasyonu kullanılarak radyoterapi tedavisine yönelik genel bir biyoısı transferi matematiksel çerçevesi sunulmuştur.

Keywords

: Isı transferi, Pennes’in biyoısı denklemi, kanser tedavisi, radyoterapi, X-ışını hipertermisi, Monte Carlo simülasyonu.

Bio-Heat Transfer in Cancer Treatment: A Mathematical Framework for Hyperthermia-Assisted Radiotherapy Using Monte Carlo Simulation

Abstract

This study explores bio-heat transfer during radiotherapy combined with hyperthermia, with the goal of improving cancer treatment by maximizing tumor destruction while minimizing harm to surrounding healthy tissue. Understanding thermal dynamics during therapy allows clinicians to enhance treatment effectiveness, anticipate biological responses based on dose parameters, and reduce side effects. In this work, we focus on the synergistic use of hyperthermia and X-ray radiotherapy. During short recovery periods between hyperthermia pulses—when tissue responds to elevated temperatures (43 °C, 45 °C, 47 °C)—radiation is delivered. The central hypothesis is that heating tumor tissue increases its radiosensitivity, potentially shortening treatment time and improving outcomes. Evidence from current literature supports this synergy, showing that higher temperatures amplify cellular damage. To quantify this effect, we applied the Arrhenius damage model, which converts temperature and exposure duration into a single thermal damage parameter (Ω) representing irreversible tissue injury. Finally, we developed a mathematical framework to simulate this process, using Monte Carlo photon transport to generate spatial heat sources and solving Pennes’ bio-heat equation to model heat transfer across layered biological tissue.

Keywords

Heat transfer, Pennes’ bioheat equation, cancer treatment, radiotherapy, X-ray hyperthermia, Monti Carlo simulation.

Supporting Institution

Gaziantep University

Ethical Statement

As the author of this paper, I declare that I conducted this research, and no ethical issues or review committee were required.

Thanks

Thanks to my supervisor, Prof. Dr. Recep YUMURTAS

References

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Details

Primary Language

English

Subjects

Biomechanic

Journal Section

Research Article

Authors

Tuka Fattal ^*
0009-0007-5413-6148
Türkiye

Birnur Bozdoğan
0000-0003-0314-837X
Türkiye

Recep Yumrutaş
0000-0001-9006-198X
Türkiye

Publication Date

December 25, 2025

Submission Date

October 27, 2025

Acceptance Date

December 10, 2025

Published in Issue

Year 2025 Volume: 1 Number: 2

IZ

https://izlik.org/JA67ZT84SL

APA

Fattal, T., Bozdoğan, B., & Yumrutaş, R. (2025). Bio-Heat Transfer in Cancer Treatment: A Mathematical Framework for Hyperthermia-Assisted Radiotherapy Using Monte Carlo Simulation. Adana Alparslan Türkeş Bilim Ve Teknoloji Üniversitesi Bilim Dergisi, 1(2), 96-109. https://izlik.org/JA67ZT84SL

AMA

1.Fattal T, Bozdoğan B, Yumrutaş R. Bio-Heat Transfer in Cancer Treatment: A Mathematical Framework for Hyperthermia-Assisted Radiotherapy Using Monte Carlo Simulation. Adana Alparslan Türkeş Bilim ve Teknoloji Üniversitesi Bilim Dergisi. 2025;1(2):96-109. https://izlik.org/JA67ZT84SL

Chicago

Fattal, Tuka, Birnur Bozdoğan, and Recep Yumrutaş. 2025. “Bio-Heat Transfer in Cancer Treatment: A Mathematical Framework for Hyperthermia-Assisted Radiotherapy Using Monte Carlo Simulation”. Adana Alparslan Türkeş Bilim Ve Teknoloji Üniversitesi Bilim Dergisi 1 (2): 96-109. https://izlik.org/JA67ZT84SL.

EndNote

Fattal T, Bozdoğan B, Yumrutaş R (December 1, 2025) Bio-Heat Transfer in Cancer Treatment: A Mathematical Framework for Hyperthermia-Assisted Radiotherapy Using Monte Carlo Simulation. Adana Alparslan Türkeş Bilim ve Teknoloji Üniversitesi Bilim Dergisi 1 2 96–109.

IEEE

[1]T. Fattal, B. Bozdoğan, and R. Yumrutaş, “Bio-Heat Transfer in Cancer Treatment: A Mathematical Framework for Hyperthermia-Assisted Radiotherapy Using Monte Carlo Simulation”, Adana Alparslan Türkeş Bilim ve Teknoloji Üniversitesi Bilim Dergisi, vol. 1, no. 2, pp. 96–109, Dec. 2025, [Online]. Available: https://izlik.org/JA67ZT84SL

ISNAD

Fattal, Tuka - Bozdoğan, Birnur - Yumrutaş, Recep. “Bio-Heat Transfer in Cancer Treatment: A Mathematical Framework for Hyperthermia-Assisted Radiotherapy Using Monte Carlo Simulation”. Adana Alparslan Türkeş Bilim ve Teknoloji Üniversitesi Bilim Dergisi 1/2 (December 1, 2025): 96-109. https://izlik.org/JA67ZT84SL.

JAMA

1.Fattal T, Bozdoğan B, Yumrutaş R. Bio-Heat Transfer in Cancer Treatment: A Mathematical Framework for Hyperthermia-Assisted Radiotherapy Using Monte Carlo Simulation. Adana Alparslan Türkeş Bilim ve Teknoloji Üniversitesi Bilim Dergisi. 2025;1:96–109.

MLA

Fattal, Tuka, et al. “Bio-Heat Transfer in Cancer Treatment: A Mathematical Framework for Hyperthermia-Assisted Radiotherapy Using Monte Carlo Simulation”. Adana Alparslan Türkeş Bilim Ve Teknoloji Üniversitesi Bilim Dergisi, vol. 1, no. 2, Dec. 2025, pp. 96-109, https://izlik.org/JA67ZT84SL.

Vancouver

1.Tuka Fattal, Birnur Bozdoğan, Recep Yumrutaş. Bio-Heat Transfer in Cancer Treatment: A Mathematical Framework for Hyperthermia-Assisted Radiotherapy Using Monte Carlo Simulation. Adana Alparslan Türkeş Bilim ve Teknoloji Üniversitesi Bilim Dergisi [Internet]. 2025 Dec. 1;1(2):96-109. Available from: https://izlik.org/JA67ZT84SL

Kanser Tedavisinde Biyo-Isı Transferi: Monte Carlo Simülasyonu Kullanılarak Hipertermi Destekli Radyoterapi İçin Matematiksel Bir Çerçeve

Abstract

Keywords

Bio-Heat Transfer in Cancer Treatment: A Mathematical Framework for Hyperthermia-Assisted Radiotherapy Using Monte Carlo Simulation

Abstract

Keywords

Supporting Institution

Ethical Statement

Thanks

References

Details

Primary Language

Subjects

Journal Section

Authors

Publication Date

Submission Date

Acceptance Date

Published in Issue

IZ

Cite