Introduction to passive electron intensity modulation

Hogstrom, Kenneth R.; Carver, Robert L.; Chambers, E. L.; Erhart, Kevin

doi:10.1002/acm2.12163

Cited by 11 publications

(32 citation statements)

References 36 publications

(35 reference statements)

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“…Island blocks were placed on a 0.6‐cm hexagonal grid (specified at 93.5 cm source to collimator distance). For each grid point on the hexagonal grid the algorithm first calculated the island block diameter

d

based on fraction of area blocked using 15

d (r, I R F) = r {[\frac{2 \sqrt{3}}{π} ()(1 ‐ I R F)]}^{1 /2},

where

r

is the distance separating the hexagonally packed circular island blocks of diameter d , and

italicIRF

is the intensity reduction factor, which equals the ratio of the desired underlying intensity to that in the absence of the intensity modulator, that is,

()(, w_{i, j})

. Then, the algorithm selected an island block diameter closest from a set of available tungsten island block diameters ( cf .…”

Section: Methodsmentioning

confidence: 99%

“…Recently, Hogstrom et al 15 developed a simple, potentially economical method for design and fabrication of a passive radiotherapy intensity modulator for electrons (PRIME) device, 16 analogous to the utilization of x‐ray compensators for IMXT prior to the widespread availability of x‐ray multi‐leaf collimators (MLCs). 17 , 18 The objective of this paper is to describe a process that should be suitable for planning and delivery of IM‐BECT.…”

Section: Introductionmentioning

confidence: 99%

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Planning and delivery of intensity modulated bolus electron conformal therapy

Hilliard

Carver

Chambers

et al. 2021

J Applied Clin Med Phys

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Purpose Bolus electron conformal therapy (BECT) is a clinically useful, well‐documented, and available technology. The addition of intensity modulation (IM) to BECT reduces volumes of high dose and dose spread in the planning target volume (PTV). This paper demonstrates new techniques for a process that should be suitable for planning and delivering IM‐BECT using passive radiotherapy intensity modulation for electrons (PRIME) devices. Methods The IM‐BECT planning and delivery process is an addition to the BECT process that includes intensity modulator design, fabrication, and quality assurance. The intensity modulator (PRIME device) is a hexagonal matrix of small island blocks (tungsten pins of varying diameter) placed inside the patient beam‐defining collimator (cutout). Its design process determines a desirable intensity‐modulated electron beam during the planning process, then determines the island block configuration to deliver that intensity distribution (segmentation). The intensity modulator is fabricated and quality assurance performed at the factory (.decimal, LLC, Sanford, FL). Clinical quality assurance consists of measuring a fluence distribution in a plane perpendicular to the beam in a water or water‐equivalent phantom. This IM‐BECT process is described and demonstrated for two sites, postmastectomy chest wall and temple. Dose plans, intensity distributions, fabricated intensity modulators, and quality assurance results are presented. Results IM‐BECT plans showed improved D90‐10 over BECT plans, 6.4% versus 7.3% and 8.4% versus 11.0% for the postmastectomy chest wall and temple, respectively. Their intensity modulators utilized 61 (single diameter) and 246 (five diameters) tungsten pins, respectively. Dose comparisons for clinical quality assurance showed that for doses greater than 10%, measured agreed with calculated dose within 3% or 0.3 cm distance‐to‐agreement (DTA) for 99.9% and 100% of points, respectively. Conclusion These results demonstrated the feasibility of translating IM‐BECT to the clinic using the techniques presented for treatment planning, intensity modulator design and fabrication, and quality assurance processes.

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d

based on fraction of area blocked using 15

d (r, I R F) = r {[\frac{2 \sqrt{3}}{π} ()(1 ‐ I R F)]}^{1 /2},

where

r

is the distance separating the hexagonally packed circular island blocks of diameter d , and

italicIRF

is the intensity reduction factor, which equals the ratio of the desired underlying intensity to that in the absence of the intensity modulator, that is,

()(, w_{i, j})

. Then, the algorithm selected an island block diameter closest from a set of available tungsten island block diameters ( cf .…”

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Planning and delivery of intensity modulated bolus electron conformal therapy

Hilliard

Carver

Chambers

et al. 2021

J Applied Clin Med Phys

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“…As the HEE delivery machines currently deliver beam pulses every few milliseconds, and the pulses are typically on the order of one or more Gray-per-pulse, this would require a very fast moving MLC to achieve the desired field modulation and such a technology is not currently yet available [36]. Alternatively, there has been development of intensity modulated passive scattering applicator devices to achieve conformal and homogeneous dose, without compromising substantially maximum depths that can be treated [37,38]. Rahman et al [39] demonstrated the feasibility of plan and dose calculation with the use of this passive delivery method for an electron UHDR beam produced from a modified medical linac.…”

Section: Uhdr Hee Delivery Techniques and Challengesmentioning

confidence: 99%

FLASH radiotherapy treatment planning and models for electron beams

Rahman

Trigilio

Franciosini

et al. 2022

Radiotherapy and Oncology

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“…Initially, delivery of intensity modulation was envisioned using eMLCs, such as those reported by Hogstrom et al 20 and Gauer et al 21 ; however, access to said devices by the typical clinic has not been forthcoming. As an alternative, Hogstrom et al 22 reported a passive method for electron intensity modulation, which consists of a matrix of variable small‐diameter, high‐density island blocks, as shown in Fig. 2.…”

Section: Introductionmentioning

confidence: 99%

“…The fraction of area locally blocked, which controls the intensity reduction factor (IRF) locally, is governed by the ratio of block diameter (d) to hexagonal grid spacing (r), 22

IRF = 1.0 ‐ \frac{π}{2 \sqrt{3}} {(\frac{d}{r})}^{2} .

…”

Section: Introductionmentioning

confidence: 99%

Useful island block geometries of a passive intensity modulator used for intensity‐modulated bolus electron conformal therapy

Chambers

Carver

Hogstrom

2020

J Applied Clin Med Phys

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Purpose: This project determined the range of island block geometric configurations useful for the clinical utilization of intensity-modulated bolus electron conformal therapy (IM-BECT). Methods: Multiple half-beam island block geometries were studied for seven electron energies 7-20 MeV at 100 and 103 cm source-to-surface distance (SSD). We studied relative fluence distributions at 0.5 cm and 2.0 cm depths in water, resulting in 28 unique beam conditions. For each beam condition, we studied intensity reduction factor (IRF) values of 0.70, 0.75, 0.80, 0.85, 0.90, and 0.95, and hexagonal packing separations for the island blocks of 0.50, 0.75, 1.00, 1.25, and 1.50 cm, that is, 30 unique IM configurations and 840 unique beam-IM combinations. A combination was deemed acceptable if the average intensity downstream of the intensity modulator agreed within 2% of that intended and the variation in fluence was less than AE2%. Results: For 100 cm SSD, and for 0.5 cm depth, results showed that beam energies above 13 MeV did not exhibit sufficient scatter to produce clinically acceptable fluence (intensity) distributions for all IRF values (0.70-0.95). In particular, 20 MeV fluence distributions were unacceptable for any values, and acceptable 16 MeV fluence distributions were limited to a minimum IRF of 0.85. For the 2.0 cm depth, beam energies up to and including 20 MeV had acceptable fluence distributions. For 103 cm SSD and for 0.5 cm and 2.0 cm depths, results showed that all beam energies (7-20 MeV) had clinically acceptable fluence distributions for all IRF values (0.70-0.95). In general, the more clinically likely 103 cm SSD had acceptable fluence distributions with larger separations (r), which allow larger block diameters. Conclusion: The geometric operating range of island block separations and IRF values (block diameters) producing clinically appropriate IM electron beams has been determined.

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Introduction to passive electron intensity modulation

Cited by 11 publications

References 36 publications

Planning and delivery of intensity modulated bolus electron conformal therapy

Planning and delivery of intensity modulated bolus electron conformal therapy

FLASH radiotherapy treatment planning and models for electron beams

Useful island block geometries of a passive intensity modulator used for intensity‐modulated bolus electron conformal therapy

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