Comparing conformal, arc radiotherapy and helical tomotherapy in craniospinal irradiation planning.

Pamela A Myers,Panayiotis Mavroidis,Nikos Papanikolaou,Sotirios Stathakis

doi:10.1120/jacmp.v15i5.4724

Abstract

Currently, radiotherapy treatment plan acceptance is based primarily on dosimetric performance measures. However, use of radiobiological analysis to assess benefit in terms of tumor control and harm in terms of injury to normal tissues can be advantageous. For pediatric craniospinal axis irradiation (CSI) patients, in particular, knowing the technique that will optimize the probabilities of benefit versus injury can lead to better long‐term outcomes. Twenty‐four CSI pediatric patients (median age 10) were retrospectively planned with three techniques: three‐dimensional conformal radiation therapy (3D CRT), volumetric‐modulated arc therapy (VMAT), and helical tomotherapy (HT). VMAT plans consisted of one superior and one inferior full arc, and tomotherapy plans were created using a 5.02 cm field width and helical pitch of 0.287. Each plan was normalized to 95% of target volume (whole brain and spinal cord) receiving prescription dose 23.4 Gy in 13 fractions. Using an in‐house MATLAB code and DVH data from each plan, the three techniques were evaluated based on biologically effective uniform dose (D¯¯), the complication‐free tumor control probability (P+), and the width of the therapeutically beneficial range. Overall, 3D CRT and VMAT plans had similar values of D¯¯ (24.1 and 24.2 Gy), while HT had a D¯¯ slightly lower (23.6 Gy). The average values of the P+ index were 64.6, 67.4, and 56.6% for 3D CRT, VMAT, and HT plans, respectively, with the VMAT plans having a statistically significant increase in P+. Optimal values of D¯¯ were 28.4, 33.0, and 31.9 Gy for 3D CRT, VMAT, and HT plans, respectively. Although P+ values that correspond to the initial dose prescription were lower for HT, after optimizing the D¯¯ prescription level, the optimal P+ became 94.1, 99.5, and 99.6% for 3D CRT, VMAT, and HT, respectively, with the VMAT and HT plans having statistically significant increases in P+. If the optimal dose level is prescribed using a radiobiological evaluation method, as opposed to a purely dosimetric one, the two IMRT techniques, VMAT and HT, will yield largest overall benefit to CSI patients by maximizing tumor control and limiting normal tissue injury. Using VMAT or HT may provide these pediatric patients with better long‐term outcomes after radiotherapy.PACS number: 87.55.dk

Highlights

Treatment plan acceptance is largely based on dosimetric data such as dose-volume histogram (DVH) statistics for targets, and normal tissues and isodose line distributions
Treatment planning techniques A total of twenty-four (n = 24) pediatric patients, including 11 females and 13 males, who were treated for various central nervous system (CNS) diseases (14 medulloblastoma, 3 germ cell tumors, 2 primitive neuroectodermal tumors (PNET), 2 pre-B-cell acute lymphoblastic leukemia (ALL), 1 meningeal carcinomatosis, 1 pineoblastoma, and 1 atypical teratoid rhabdoid tumor of the brain) with craniospinal axis irradiation (CSI) were retrospectively planned with three-dimensional conformal radiation therapy (3D CRT), and two IMRT techniques: volumetric-modulated arc therapy (VMAT) and helical tomotherapy (HT)
With the exception of the kidneys for the 3D conformal radiation therapy (3D CRT) technique, injury probabilities are zero. At this level of dose prescribed, the results indicate that the risk of injuring the surrounding organs at risk (OAR) is low for all treatment techniques

Summary

Introduction

Treatment plan acceptance is largely based on dosimetric data such as dose-volume histogram (DVH) statistics for targets, and normal tissues and isodose line distributions. While these parameters do offer insight into the dosimetric capability of a given plan, the radiobiological effects on the involved tumor and normal tissues may convey a significantly different outlook regarding the acceptability of the plan. In children treated with CSI, there is a large percentage of the patient’s anatomy that is exposed to some level of radiation dose due to the large target involved in the treatment.[4,5] For these reasons, a treatment plan evaluation, which would use the patient-specific planned dose distribution and would focus on normal tissue complication rates and tumor control probabilities, should be performed

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