Exploring the advantages of intensity-modulated proton therapy: experimental validation of biological effects using two different beam intensity-modulation patterns

Ma, Duo; Bronk, Lawrence F.; Kerr, M.; Sobieski, Mary; Chen, Mei; Geng, Changran; Yiu, Joycelyn; Wang, Xiaochun; Cao, Wenhua; Zhang, Xiaodong; Stephan, Clifford; Mohan, Radhe; Grosshans, David R.; Guan, Fada

doi:10.1038/s41598-020-60246-5

Cited by 9 publications

(9 citation statements)

References 59 publications

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“…For the 1F/2F/3F treatments, maximum LET D (LET D , max ) was located at the distal-end/outside of the target, while for SHArc treatments, LET D , max was located within the central core of the target volume (~8 keV･µm -1 , ~30keV･µm -1 and ~150keV･µm -1 for p, 4 He and 12 C ions, respectively and intra-field iso-energy configurations, described in recent works (e.g. PATCH optimization) [45]. The PATCH technique, however, substantially increases entrance dose (Fig.…”

Section: Model Application and Analysismentioning

confidence: 99%

Spot-Scanning Hadron Arc (SHArc) Therapy: A Study With Light and Heavy Ions

Mein

Tessonnier

Kopp

et al. 2021

Advances in Radiation Oncology

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This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

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Section: Model Application and Analysismentioning

confidence: 99%

Spot-Scanning Hadron Arc (SHArc) Therapy: A Study With Light and Heavy Ions

Mein

Tessonnier

Kopp

et al. 2021

Advances in Radiation Oncology

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“…In our cohort, 9 patients (12%) were treated who had undergone prior radiation, and they tolerated re-treatment well. With future advancements in treatment optimization, a further benefit with IMPT may come in the form of optimizing plans based on linear energy transfer and RBE, which, by altering beamlet intensity (increasing the weighting of low-energy beams), the linear energy transfer can be elevated within a target and still maintain the same physical dose [ 9 , 21 ]. That would be ideal for SGCs, given the propensity for certain histologic subtypes (ie, adenoid cystic carcinoma) to harbor resistant cancer stem cells and may further improve the therapeutic index of PBT [ 22 ].…”

Section: Discussionmentioning

confidence: 99%

“…Robust single-field and multifield optimization (SFO/MFO) allow treatment of complex volumes and maintenance of dosimetric equipoise in surrounding structures at both the proximal and distal extent [7,8]. From a biologic perspective, patients with radioresistant tumors that are prone to recurrence may also stand to benefit from future advances in IMPT that allow linear energy transfer and relative biological effectiveness (RBE)-optimized radiation planning [9]. Further, the ability to safely reirradiate (with cumulative doses) is made possible with advancements in particle therapy [2,[10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Proton Therapy for Major Salivary Gland Cancer: Clinical Outcomes

Hanania

Zhang

Gunn

et al. 2021

International Journal of Particle Therapy

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Purpose To report clinical outcomes in terms of disease control and toxicity in patients with major salivary gland cancers (SGCs) treated with proton beam therapy. Materials and Methods Clinical and dosimetric characteristics of patients with SGCs treated from August 2011 to February 2020 on an observational, prospective, single-institution protocol were abstracted. Local control and overall survival were calculated by the Kaplan-Meier method. During radiation, weekly assessments of toxicity were obtained, and for patients with ≥ 90 days of follow-up, late toxicity was assessed. Results Seventy-two patients were identified. Median age was 54 years (range, 23-87 years). Sixty-three patients (88%) received postoperative therapy, and nine patients (12%) were treated definitively. Twenty-six patients (36%) received concurrent chemotherapy. Nine patients (12%) had received prior radiation. All (99%) but one patient received unilateral treatment with a median dose of 64 GyRBE (relative biological effectiveness) (interquartile range [IQR], 60-66), and 53 patients (74%) received intensity-modulated proton therapy with either single-field or multifield optimization. The median follow-up time was 30 months. Two-year local control and overall survival rates were 96% (95% confidence interval [CI] 85%-99%) and 89% (95% CI 76%-95%], respectively. Radiation dermatitis was the predominant grade-3 toxicity (seen in 21% [n = 15] of the patients), and grade ≥ 2 mucositis was rare (14%; n = 10 patients). No late-grade ≥ 3 toxicities were reported. Conclusion Proton beam therapy for treatment of major SGCs manifests in low rates of acute mucosal toxicity. In addition, the current data suggest a high rate of local control and minimal late toxicity.

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“…By contrast, biological treatment planning and LET-guided dose optimization have been developed and commercially available for testing and clinic planning studies. They are mainly used in generating reference plans with LET-based dose optimization for guiding the planning of complex treatment involving critical normal tissue structures [ 84 , 85 , 86 ]. Subject to satisfactory demonstration of clinical evidence, LET-based dose optimization may potentially improve the quality of PT treatment plans.…”

Section: Opportunities For Improvement With New Technologies and Inno...mentioning

confidence: 99%

Proton Therapy for Prostate Cancer: Challenges and Opportunities

Poon

et al. 2022

Cancers

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The dosimetric advantages of proton therapy (PT) treatment plans are demonstrably superior to photon-based external beam radiotherapy (EBRT) for localized prostate cancer, but the reported clinical outcomes are similar. This may be due to inadequate dose prescription, especially in high-risk disease, as indicated by the ASCENDE-RT trial. Alternatively, the lack of clinical benefits with PT may be attributable to improper dose delivery, mainly due to geometric and dosimetric uncertainties during treatment planning, as well as delivery procedures that compromise the dose conformity of treatments. Advanced high-precision PT technologies, and treatment planning and beam delivery techniques are being developed to address these uncertainties. For instance, external magnetic resonance imaging (MRI)-guided patient setup rooms are being developed to improve the accuracy of patient positioning for treatment. In-room MRI-guided patient positioning systems are also being investigated to improve the geometric accuracy of PT. Soon, high-dose rate beam delivery systems will shorten beam delivery time to within one breath hold, minimizing the effects of organ motion and patient movements. Dual-energy photon-counting computed tomography and high-resolution Monte Carlo-based treatment planning systems are available to minimize uncertainties in dose planning calculations. Advanced in-room treatment verification tools such as prompt gamma detector systems will be used to verify the depth of PT. Clinical implementation of these new technologies is expected to improve the accuracy and dose conformity of PT in the treatment of localized prostate cancers, and lead to better clinical outcomes. Improvement in dose conformity may also facilitate dose escalation, improving local control and implementation of hypofractionation treatment schemes to improve patient throughput and make PT more cost effective.

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Exploring the advantages of intensity-modulated proton therapy: experimental validation of biological effects using two different beam intensity-modulation patterns

Cited by 9 publications

References 59 publications

Spot-Scanning Hadron Arc (SHArc) Therapy: A Study With Light and Heavy Ions

Spot-Scanning Hadron Arc (SHArc) Therapy: A Study With Light and Heavy Ions

Proton Therapy for Major Salivary Gland Cancer: Clinical Outcomes

Proton Therapy for Prostate Cancer: Challenges and Opportunities

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