A study of the clinical, treatment planning and dosimetric feasibility of dose painting in external beam radiotherapy of prostate cancer

Blake, S.; Stapleton, Alison; Brown, A. C.; Curtis, Siân L.; Ash-Miles, Janice; Dennis, Emma; Masson, Susan; Bowers, Dawn; Hilman, Serena

doi:10.1016/j.phro.2020.07.005

Cited by 6 publications

(9 citation statements)

References 32 publications

(49 reference statements)

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“…One of the leading reasons for the focal boost approach not being feasible was in instances of overlap between the boost volume and OARs. In the research undertaken by Blake et al [60], the boost volume of 83% of patients overlapped with surrounding OARs. In 42% of patients, the intended boost dose of 86 Gy was limited due to the overlap between the boost volume and the urethra.…”

Section: Dose-limiting Factorsmentioning

confidence: 99%

“…The longest reported follow-up time was 124 months [49]. In the planning studies, as shown in Table 2, the majority of studies utilized mpMRI for GTV delineation [10,18,45,[57][58][59][60][61][62][63][64][65][66][67][68][69][70][71][72][73][74][75]. Five studies utilized PET-CT [12,[76][77][78][79][80], and four studies used "other methods" such as histopathology data or hypothetical IPLs [81][82][83][84].…”

Section: Statistics Of Reviewed Studiesmentioning

confidence: 99%

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Focal Boost in Prostate Cancer Radiotherapy: A Review of Planning Studies and Clinical Trials

Zhao,

Haworth,

Rowshanfarzad

et al. 2023

Cancers

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Background: Focal boost radiotherapy was developed to deliver elevated doses to functional sub-volumes within a target. Such a technique was hypothesized to improve treatment outcomes without increasing toxicity in prostate cancer treatment. Purpose: To summarize and evaluate the efficacy and variability of focal boost radiotherapy by reviewing focal boost planning studies and clinical trials that have been published in the last ten years. Methods: Published reports of focal boost radiotherapy, that specifically incorporate dose escalation to intra-prostatic lesions (IPLs), were reviewed and summarized. Correlations between acute/late ≥G2 genitourinary (GU) or gastrointestinal (GI) toxicity and clinical factors were determined by a meta-analysis. Results: By reviewing and summarizing 34 planning studies and 35 trials, a significant dose escalation to the GTV and thus higher tumor control of focal boost radiotherapy were reported consistently by all reviewed studies. Reviewed trials reported a not significant difference in toxicity between focal boost and conventional radiotherapy. Acute ≥G2 GU and late ≥G2 GI toxicities were reported the most and least prevalent, respectively, and a negative correlation was found between the rate of toxicity and proportion of low-risk or intermediate-risk patients in the cohort. Conclusion: Focal boost prostate cancer radiotherapy has the potential to be a new standard of care.

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Section: Dose-limiting Factorsmentioning

confidence: 99%

Section: Statistics Of Reviewed Studiesmentioning

confidence: 99%

Focal Boost in Prostate Cancer Radiotherapy: A Review of Planning Studies and Clinical Trials

Zhao,

Haworth,

Rowshanfarzad

et al. 2023

Cancers

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“…The dose redistribution can also be achieved by dose escalation to the detected IPLs. Boosting IPLs without violating the dose constrains of OARs has been shown to be feasible, [59][60][61] and an increased tumor control relative to uniform dose prescription has been reported. 38 However, the undetected lesions or the uncertainty in delineating IPLs from MRI or PET images 62 may lead to underdosing of sub-volumes of the prostate.…”

Section: Similar Studiesmentioning

confidence: 99%

Towards optimal heterogeneous prostate radiotherapy dose prescriptions based on patient‐specific or population‐based biological features

Zhao,

Haworth,

Reynolds

et al. 2024

Medical Physics

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BackgroundEscalation of prescribed dose in prostate cancer (PCa) radiotherapy enables improvement in tumor control at the expense of increased toxicity. Opportunities for reduction of treatment toxicity may emerge if more efficient dose escalation can be achieved by redistributing the prescribed dose distribution according to the known heterogeneous, spatially‐varying characteristics of the disease.PurposeTo examine the potential benefits, limitations and characteristics of heterogeneous boost dose redistribution in PCa radiotherapy based on patient‐specific and population‐based spatial maps of tumor biological features.MethodHigh‐resolution prostate histology images, from a cohort of 63 patients, annotated with tumor location and grade, provided patient‐specific “maps” and a population‐based “atlas” of cell density and tumor probability. Dose prescriptions were derived for each patient based on a heterogeneous redistribution of the boost dose to the intraprostatic lesions, with the prescription maximizing patient tumor control probability (TCP). The impact on TCP was assessed under scenarios where the distribution of population‐based biological data was ignored, partially included, or fully included in prescription generation. Heterogeneous dose prescriptions were generated for three combinations of maps and atlas, and for conventional fractionation (CF), extreme hypo‐fractionation (EH), moderate hypo‐fractionation (MH), and whole Pelvic RT + SBRT Boost (WPRT + SBRT). The predicted efficacy of the heterogeneous prescriptions was compared with equivalent homogeneous dose prescriptions.ResultsTCPs for heterogeneous dose prescriptions were generally higher than those for homogeneous dose prescriptions. TCP escalation by heterogeneous dose prescription was the largest for CF. When only using population‐based atlas data, the generated heterogeneous dose prescriptions of 55 to 58 patients (out of 63) had a higher TCP than for the corresponding homogeneous dose prescriptions. The TCPs of the heterogeneous dose prescriptions generated with the population‐based atlas and tumor probability maps did not differ significantly from those using patient‐specific biological information. The generated heterogeneous dose prescriptions achieved significantly higher TCP than homogeneous dose prescriptions in the posterior section of the prostate.ConclusionHeterogeneous dose prescriptions generated via biologically‐optimized dose redistribution can produce higher TCP than the homogeneous dose prescriptions for the majority of the patients in the studied cohort. For scenarios where patient‐specific biological information was unavailable or partially available, the generated heterogeneous dose prescriptions can still achieve TCP improvement relative to homogeneous dose prescriptions.

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“…Ling et al 1 introduced the concept of a biological target volume (BTV) and proposed the idea of delivering radiation dose distributions based on functional sub-volumes within a target. This has led to multiple studies introducing the concept of a "boost volume" in prostate cancer (PCa) radiotherapy, [2][3][4][5][6][7] whereby a sub-region within the prostate gland is defined to receive an escalated dose of radiation whilst preserving standard doses to the remaining target to minimize risk of increased toxicity. In current standard boost-dose strategies,there is no deliberate attempt to vary the dose distribution through the boost volume, however, in practice, a non-uniform distribution arises as a result of dose gradients generated in an attempt to maintain dose to organs at risk below threshold levels.…”

Section: Introductionmentioning

confidence: 99%

Patient‐specific voxel‐level dose prescription for prostate cancer radiotherapy considering tumor cell density and grade distribution

et al. 2023

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Background: In prostate radiation therapy, recent studies have indicated a benefit in increasing the dose to intraprostatic lesions (IPL) compared with standard whole gland radiation therapy. Such approaches typically aim to deliver a target dose to the IPL(s) with no deliberate effort to modulate the dose within the IPL. Prostate cancers demonstrate intra-tumor heterogeneity and hence it is hypothesized that further gains in the optimal delivery of radiation therapy can be achieved through modulation of the dose distribution within the tumor. To account for tumor heterogeneity, biologically targeted radiation therapy (BiRT) aims to utilize a voxel-wise approach to IPL dose prescription by incorporating knowledge of the spatial distribution of tumor characteristics. Purpose:The aim of this study was to develop a workflow for generating voxelwise optimal dose prescriptions that maximize patient tumor control probability (TCP), and evaluate the feasibility and benefits of applying this workflow on a cohort of 62 prostate cancer patients. Method: The source data for this proof -of -concept study included high resolution histology images annotated with tumor location and grade. Image processing techniques were used to compute voxel-level cell density distribution maps. An absolute tumor cell distribution was calculated via linearly scaling according to published estimated tumor cell numbers. For the IPLs of each patient, optimal dose prescriptions were obtained via three alternative methods for redistribution of IPL boost doses according to maximization of TCP. The radiosensitivity uncertainties were considered using a truncated log-normally distributed linear radiosensitivity parameter (𝛼 k ) and compared with Gleason pattern (GP) dependent radiosensitivity parameters that were derived based on previously published methods. An ensemble machine learning method was implemented to identify patient-specific features that predict the TCP improvement resulting from dose redistribution relative to a uniform dose distribution. Results:The Gleason pattern-dependent radiosensitivity parameters were calculated for 20 published prostate cancer 𝛼∕𝛽 ratios. Optimal voxel-level dose prescriptions were generated for all 62 PCa patients. For all dose redistribution scenarios, the optimal dose distribution always shows a higher (or equivalent) TCP level than the uniform dose distribution. The applied random forest regressor could predict patient-specific TCP improvement with low root mean square error (≤1.5%) by using total tumor number, volume of IPLs and the standard deviation of tumor cell number among all voxels.

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A study of the clinical, treatment planning and dosimetric feasibility of dose painting in external beam radiotherapy of prostate cancer

Cited by 6 publications

References 32 publications

Focal Boost in Prostate Cancer Radiotherapy: A Review of Planning Studies and Clinical Trials

Focal Boost in Prostate Cancer Radiotherapy: A Review of Planning Studies and Clinical Trials

Towards optimal heterogeneous prostate radiotherapy dose prescriptions based on patient‐specific or population‐based biological features

Patient‐specific voxel‐level dose prescription for prostate cancer radiotherapy considering tumor cell density and grade distribution

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