Enhancing dosimetric practices through knowledge-based predictive models: a case study on VMAT prostate irradiation.
| Autor: | Hadj Henni A; Radiation Oncology Department, Centre Frederic Joliot, Rouen, France., Arhoun I; Radiation Oncology Department, Centre Frederic Joliot, Rouen, France., Boussetta A; Mohammed VI Polytechnic University, Ben Guerir, Morocco., Daou W; Mohammed VI Polytechnic University, Ben Guerir, Morocco., Marque A; Radiation Oncology Department, Centre Frederic Joliot, Rouen, France.; Oncology Department, Clinique Saint Hilaire, Rouen, France. |
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| Jazyk: | angličtina |
| Zdroj: | Frontiers in oncology [Front Oncol] 2024 Jan 17; Vol. 14, pp. 1320002. Date of Electronic Publication: 2024 Jan 17 (Print Publication: 2024). |
| DOI: | 10.3389/fonc.2024.1320002 |
| Abstrakt: | Introduction: Acquisition of dosimetric knowledge by radiation therapy planners is a protracted and complex process. This study delves into the impact of empirical predictive models based on the knowledge-based planning (KBP) methodology, aimed at detecting suboptimal results and homogenizing and improving existing practices for prostate cancer. Moreover, the dosimetric effect of implementing these models into routine clinical practice was also assessed. Materials and Methods: Based on the KBP method, we analyzed 25 prostate treatment plans performed using VMAT by expert operators, aiming to correlate dose indicators with patient geometry. The D a v g C a v ( G y ) , V 45 G y C a v ( c c ) , and V 15 G y C a v ( c c ) of the peritoneal cavity and the V 60 G y ( % ) and V 70 G y ( % ) of the rectum and bladder were linked to geometric characteristics such as the distance from the planning target volume (PTV) to the organs at risk (OAR), the volume of the OAR, or the overlap between the PTV and the OAR. In the second phase, the KBP was used in routine clinical practice in a prospective cohort of 25 patients and compared with the 41 patient plans calculated before implementing the tool. Results: Using linear regression, we identified strong geometric predictive factors for the peritoneal cavity, rectum, and bladder ( R 2 > 0.8), with an average prescribed dose of 97.8%, covering 95% of the target volume. The use of the model led to a significant dose reduction ( Δ ) for all evaluated OARs. This trend was most notable for Δ V 15 G y C a v = - 171.5 cc ( p = 0.003 ) . Significant reductions were also obtained in average doses to the rectum and bladder, Δ D a v g R e c t = - 2.3 G y ( p = 0.040 ) , and Δ D a v g V e s s = - 3.3 G y ( p = 0.039 ) respectively. Based on this model, we reduced the number of plans with OAR constraints above the clinical recommendations from 19% to 8%. Conclusions: The KBP methodology established a robust and personalized predictive model for dose estimation to organs at risk in prostate cancer. Implementing the model resulted in improved sparing of these organs. Notably, it yields a solid foundation for harmonizing dosimetric practices, alerting us to suboptimal results, and improving our knowledge. Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest. (Copyright © 2024 Hadj Henni, Arhoun, Boussetta, Daou and Marque.) |
| Databáze: | MEDLINE |
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