Your search keyword '"Volken, W."' showing total 5 results

1. Benchmarking Monte-Carlo dose calculation for MLC CyberKnife treatments

Author

Mackeprang, P.-H., Vuong, D., Volken, W., Henzen, D., Schmidhalter, D., Malthaner, M., Mueller, S., Frei, D., Kilby, W., Aebersold, D. M., Fix, M. K., and Manser, P.

Published

2019

2. Organ-at-risk sparing with dynamic trajectory radiotherapy for head and neck cancer: comparison with volumetric arc therapy on a publicly available library of cases.

Author

Bertholet J, Mackeprang PH, Mueller S, Guyer G, Loebner HA, Wyss Y, Frei D, Volken W, Elicin O, Aebersold DM, Fix MK, and Manser P

Subjects

Humans, Neoplasm Recurrence, Local, Organs at Risk radiation effects, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted methods, Head and Neck Neoplasms radiotherapy, Nasopharyngeal Neoplasms, Radiotherapy, Intensity-Modulated methods

Abstract

Background: Dynamic trajectory radiotherapy (DTRT) extends volumetric modulated arc therapy (VMAT) with dynamic table and collimator rotation during beam-on. The aim of the study is to establish DTRT path-finding strategies, demonstrate deliverability and dosimetric accuracy and compare DTRT to state-of-the-art VMAT for common head and neck (HN) cancer cases., Methods: A publicly available library of seven HN cases was created on an anthropomorphic phantom with all relevant organs-at-risk (OARs) delineated. DTRT plans were generated with beam incidences minimizing fractional target/OAR volume overlap and compared to VMAT. Deliverability and dosimetric validation was carried out on the phantom., Results: DTRT and VMAT had similar target coverage. For three locoregionally advanced oropharyngeal carcinomas and one adenoid cystic carcinoma, mean dose to the contralateral salivary glands, pharynx and oral cavity was reduced by 2.5, 1.7 and 3.1 Gy respectively on average with DTRT compared to VMAT. For a locally recurrent nasopharyngeal carcinoma, D 0.03 cc to the ipsilateral optic nerve was above tolerance (54.0 Gy) for VMAT (54.8 Gy) but within tolerance for DTRT (53.3 Gy). For a laryngeal carcinoma, DTRT resulted in higher dose than VMAT to the pharynx and brachial plexus but lower dose to the upper oesophagus, thyroid gland and contralateral carotid artery. For a single vocal cord irradiation case, DTRT spared most OARs better than VMAT. All plans were delivered successfully on the phantom and dosimetric validation resulted in gamma passing rates of 93.9% and 95.8% (2%/2 mm criteria, 10% dose threshold)., Conclusions: This study provides a proof of principle of DTRT for common HN cases with plans that were deliverable on a C-arm linac with high accuracy. The comparison with VMAT indicates substantial OAR sparing could be achieved., (© 2022. The Author(s).)

Published

2022

3. Evaluation of a new software prototype for frameless radiosurgery of arteriovenous malformations.

Author

Schmidhalter D, Henzen D, Herrmann E, Volken W, Mackeprang PH, Ermis E, Hemmatazad H, Honegger J, Haas B, Fix MK, and Manser P

Subjects

Arteriovenous Malformations diagnostic imaging, Arteriovenous Malformations pathology, Head diagnostic imaging, Humans, Angiography, Digital Subtraction methods, Arteriovenous Malformations surgery, Image Processing, Computer-Assisted methods, Imaging, Three-Dimensional methods, Phantoms, Imaging, Radiosurgery methods, Software

Abstract

Background: In order to locate an arteriovenous malformation, typically, a digital subtraction angiography (DSA) is carried out. To use the DSA for target definition an accurate image registration between CT and DSA is required. Carrying out a non-invasive, frameless procedure, registration of the 2D-DSA images with the CT is critical. A new software prototype is enabling this frameless procedure. The aim of this work was to evaluate the prototype in terms of targeting accuracy and reliability based on phantom measurements as well as with the aid of patient data. In addition, the user's ability to recognize registration mismatches and quality was assessed., Methods: Targeting accuracy was measured with a simple cubic, as well as with an anthropomorphic head phantom. Clearly defined academic targets within the phantoms were contoured on the CT. These reference structures were compared with the structures generated within the prototype. A similar approach was used with patient data, where the clinically contoured target served as the reference structure. An important error source decreasing the target accuracy comes from registration errors between CT and 2D-DSA. For that reason, the tools in BC provided to the user to check these registrations are very important. In order to check if the user is able to recognize registration errors, a set of different registration errors was introduced to the correctly registered CT and 2D-DSA image data sets of three different patients. Each of six different users rated the whole set of registrations within the prototype., Results: The target accuracy of the prototype was found to be below 0.04 cm for the cubic phantom and below 0.05 cm for the anthropomorphic head phantom. The mean target accuracy for the 15 patient cases was found to be below 0.3 cm. In the registration verification part, almost all introduced registration errors above 1° or 0.1 cm were detected by the six users. Nevertheless, in order to quantify and categorize the possibility to detect mismatches in the registration process more data needs to be evaluated., Conclusion: Our study shows, that the prototype is a useful tool that has the potential to fill the gap towards a frameless procedure when treating AVMs with the aid of 2D-DSA images in radiosurgery. The target accuracy of the prototype is similar to other systems already established in clinical routine.

Published

2019

4. Adaptive step size algorithm to increase efficiency of proton macro Monte Carlo dose calculation.

Author

Kueng R, Frei D, Volken W, Stuermlin F, M Stampanoni MF, Aebersold DM, Manser P, and Fix MK

Subjects

Humans, Organs at Risk radiation effects, Radiometry methods, Radiotherapy Dosage, Algorithms, Head and Neck Neoplasms radiotherapy, Monte Carlo Method, Phantoms, Imaging, Proton Therapy methods, Radiotherapy Planning, Computer-Assisted methods

Abstract

Purpose: To provide fast and accurate dose calculation in voxelized geometries for proton radiation therapy by implementing an adaptive step size algorithm in the proton macro Monte Carlo (pMMC) method., Methods: The in-house developed local-to-global MMC method for proton dose calculation is extended with an adaptive step size algorithm for efficient proton transport through a voxelized geometry by sampling transport parameters from a pre-simulated database. Adaptive choice of an adequate slab size in dependence of material interfaces in the proton's longitudinal and lateral vicinity is investigated. The dose calculation algorithm is validated against the non-adaptive pMMC and full MC simulation for pencil and broad beams with various energies impinging on academic phantoms as well as a head and neck patient CT., Results: For material interfaces perpendicular to a proton's direction, choice of nearest neighbor slab thickness shows best trade-off between dosimetric accuracy and calculation efficiency. Adaptive reduction of chosen slab size is shown to be required for material interfaces closer than 0.5 mm in lateral direction. For the academic phantoms, dose differences of within 1% or 1 mm compared to full Geant4 MC simulation are found, while achieving an efficiency gain of up to a factor of 5.6 compared to the non-adaptive algorithm and 284 compared to Geant4. For the head and neck patient CT, dose differences are within 1% or 1 mm with an efficiency gain factor of up to 3.4 compared to the non-adaptive algorithm and 145 compared to Geant4., Conclusion: An adaptive step size algorithm for proton macro Monte Carlo was implemented and evaluated. The dose calculation provides the accuracy of full MC simulations, while achieving an efficiency gain factor of three compared to the non-adaptive algorithm and two orders of magnitude compared to full MC for a complex patient CT.

Published

2019

5. Primary tumor volume delineation in head and neck cancer: missing the tip of the iceberg?

Author

Elicin O, Terribilini D, Shelan M, Volken W, Mathier E, Dal Pra A, Aebersold DM, Fix MK, and Manser P

Subjects

Aged, Female, Humans, Male, Middle Aged, Tomography, X-Ray Computed, Tumor Burden, Head and Neck Neoplasms diagnostic imaging, Head and Neck Neoplasms radiotherapy, Radiotherapy Planning, Computer-Assisted methods

Abstract

Background: The aim was to evaluate the geometric and corresponding dosimetric differences between two delineation strategies for head and neck tumors neighboring air cavities., Methods: Primary gross and clinical tumor volumes (GTV and CTV) of 14 patients with oropharynx or larynx tumors were contoured using a soft tissue window (S). In a second strategy, the same volumes were contoured with an extension to include the parts which became visible on lung window (L). For the calculation of Hausdorff-distances (HD) between contoured volumes of the two strategies, triangular meshes were exported. Two radiotherapy plans with identical goals and optimization parameters were generated for each case. Plan_S were optimized on CTV_S, and Plan_L on CTV_L. The dose coverages of CTV_L and CTV_Δ (CTV_L minus CTV_S) were evaluated in Plan_S. OAR doses were compared among Plan_S and Plan_L., Results: Median three-dimensional HD for GTVs and CTVs were 5.7 (±2.6) and 9.3 (±2.8) mm, respectively. The median volume differences between structures contoured using L and S windows were 9% (±5%) and 9% (±4%) for GTV and CTV, respectively. In 13 out of 14 cases, Plan_S met the plan acceptance criteria for CTV_L. In 8 cases CTV_Δ was covered insufficiently in Plan_S. Mean and median differences in OAR dose-volume histogram parameters between Plan_S and Plan_L were within 3%., Conclusion: For the current practice in radiotherapy planning for head and neck cancer, the delineation of L-based volumes seems unnecessary. However, in special settings, where smaller or no PTV margins are used, this approach may play an important role for local control.

Published

2017