Enhancing efficacy and safety of glioma treatment: optimization and evaluation of a novel dual-cavity capsule structure through orthogonal testing.

Existing glioma treatments face challenges in simultaneously combining radiotherapy and chemotherapy while achieving long-term, stable continuous irradiation at low doses. To address this clinical challenge, two types of radiochemotherapy integrated dual-cavity capsules, single-capsule dual-cavity, and dual-capsule dual-cavity, were designed in this research. We employed finite element simulation and the Monte Carlo method to conduct stress-deformation simulation and dose analysis on the structure and manufacturing materials of the capsules. Based on these simulations, the structure of the dual-cavity capsule was optimized through orthogonal tests to obtain optimal results for tumor radiation therapy. Dose analysis experiments revealed that the dual-capsule dual-cavity structure exhibited improved irradiation effects on the lesion while minimizing damage to surrounding tissues and organs compared to the single-capsule dual-cavity structure. Stress-deformation simulation indicated that using polyetheretherketone as the capsule material enabled higher central dose rates and reduced deformation. Furthermore, the material's ease of processing and low-cost characteristics facilitated the development of personalized and precise treatment approaches. The proposed capsule structure realizes the integrated combination of internal radiotherapy and internal chemotherapy, establishing a new mode of long-term stable local high-dose and peripheral low-dose radiation therapy. This scheme offers a novel treatment plan and advanced technical reserve for the integrated treatment of intracranial glioma radiotherapy and chemotherapy.

Monte Carlo-based optimization of glioma capsule design for enhanced brachytherapy.

The use of radiotherapy in tumor treatment has become increasingly prominent and has emerged as one of the main tools for treating malignant tumors. Current radiation therapy for glioma employs 125I seeds for brachytherapy, which cannot be combined with radiotherapy and chemotherapy. To address this limitation, this paper proposes a dual-microcavity capsule structure that integrates radiotherapy and chemotherapy. The Monte Carlo simulation method is used to simulate the structure of the dual-microcavity capsule with a 125I liquid radioactive source. Based on the simulation results, two kinds of dual-microcavity capsule structures are optimized, and the optimized dual-microcavity capsule structure is obtained. Finally, the dosimetric parameters of the two optimized dual-microcavity capsule structures are analyzed and compared with those of other 125I seeds. The optimization tests show that the improved dual-capsule dual-microcavity structure is more effective than the single-capsule dual-microcavity structure. At an activity of 5 mCi, the average absorbed dose rate is 71.2 cGy/h in the center of the optimized dual-capsule dual-microcavity structure and 45.8 cGy/h in the center of the optimized single-capsule dual-microcavity structure. Although the radial dose function and anisotropy function exhibite variations from the data of other 125I seeds, they are generally similar. The absorbed dose rate decreases exponentially with increasing distance from the center of the capsule, which can reduce the damage to the surrounding tissues and organs while increasing the dose. The capsule structure has a better irradiation effect than conventional 125I seeds and can accomplish long-term, stable, low-dose continuous irradiation to form local high-dose radiation therapy for glioma.