MedPath

Gamma Knife Dosimetric Differences, TMR 10 Versus Convolution Algorithm

Conditions
Gamma Knife Radiosurgery
Interventions
Other: Gamma knife radiosurgery re-planning with convolution algorithm
Registration Number
NCT02374983
Lead Sponsor
University College, London
Brief Summary

Gamma Knife Radiosurgery (GKR) is a well established treatment modality for brain tumors and functional disorders of the brain. It relies on mathematical algorithms to predict dose distribution and to calculate the dose at arbitrary points in the head. For the last 25 years, doses applied using Gamma Knife Radiosurgery have been calculated using a simple algorithm, called the Tissue Maximum Ratio algorithm (TMR). Dose planning using this algorithm, relies on a number of approximations to enable fast isodose computation during treatment planning. One of the most significant of these is the approximation of the head to water-equivalent density. The increased electron density of brain and bone (relative to water) and the near-zero density of air cavities in the skull may make significant perturbations to isodose and beam-on time calculations.

With the advent of faster workstations, the effect of tissue in-homogeneities can finally be calculated in reasonable time during the treatment planning process; a newer, more modern algorithm known as convolution algorithm is now commercially available. It uses the values of density indicated in the CT scan to predict the dose distribution and is expected to more accurately calculate radiation dose, although it needs further investigation before clinical implementation. Inter- and intra-indication differences between the old and new algorithms need to be understood before this method can be confidently employed in a clinical setting. It is the aim of this study to understand the dosimetric differences between these dose calculation algorithms and to evaluate the implications of using the convolution algorithm for GKR. A large number of treatments will be re-planned using the convolution algorithm and compared to the TMR plans used to treat the patients. Beam-on-time, which is proportional to dose and a number of commonly used metrics for the targets such as coverage, selectivity, gradient index, and mean and maximum dose, will be estimated with both algorithms. Subgroup analysis will be done to assess whether any factor such as diagnosis, size of the head or location of the target could impact on the relative difference between the methods. The treatment plans will be compared and the potential implications on treatment planning will be elucidated.

Detailed Description

Not available

Recruitment & Eligibility

Status
UNKNOWN
Sex
All
Target Recruitment
100
Inclusion Criteria
  • Adult patients receiving Gamma Knife treatment for any diagnosis in the Gamma Knife centre at QSRC.
  • The subject consents to participate in the study and consent to have a stereotactic non contrast CT scan of the brain after GKR has finished.
Exclusion Criteria
  • Inability to consent
  • Younger than 18 years of age: Children are not eligible to give consent by themselves and at the moment only adults are being treated at the QSRC.
  • Patient is not suitable for CT scan: There are no absolute clinical contraindications for CT scan. However, for the purpose of the study, pregnancy is considered an absolute contraindication. Claustrophobia or anxiety disorders are considered a relative contraindication; however, this is more likely to affect the subject ability to tolerate Gamma Knife treatment and MRI scanning, which would make the patient not eligible or the study.
  • Co-morbidity or previous treatment in the patient is not to be considered as exclusion criteria.

Study & Design

Study Type
OBSERVATIONAL
Study Design
Not specified
Arm && Interventions
GroupInterventionDescription
Research groupGamma knife radiosurgery re-planning with convolution algorithmThe group will consist of 100 patients (200 observations) receiving Gamma Knife treatment. Radiosurgery treatments will be re-planned using the convolution algorithm and compared to the TMR plans used to treat the patients.
Primary Outcome Measures
NameTimeMethod
Beam-on time (difference in the Beam-on-time of the treatment plans obtained using TMR 10 and convolution algorithm for each lesion treated)Beam-on time obtained with the TMR 10 algorithm at the time of treatment (baseline) vs Beam-on time observed when the treatment is re-planned with the convolution algorithm, that being a few hours after the actual treatment is delivered (maximum 1 day)

The difference in the Beam-on-time of the treatment plans obtained using TMR 10 and convolution algorithm for each lesion treated will be the primary outcome of the study

Secondary Outcome Measures
NameTimeMethod

Trial Locations

Locations (1)

The Gamma Knife Centre at Queen Square

🇬🇧

London, London,City of, United Kingdom

Related Trials

Comparative Evaluation of Two Different Radiosurgery

CompletedNot Applicable
Istituto Clinico Humanitas
Posted 2/4/2015
Updated 5/4/2022

Comparaison Between MRI Alone or Combined With Positron Emission Tomography for Brain Metastasis Diagnosis

Completed
Centre de recherche du Centre hospitalier universitaire de Sherbrooke
Posted 10/27/2021
Updated 8/23/2024

Cognitive Outcome after Gamma Knife Radiosurgery in Patients with Brain Metastases

Recruiting
St Elisabeth Hospital, Tilburg and Tilburg University
Updated 2/28/2024

Cognitive Outcome After Gamma Knife Radiosurgery in Patients With Brain Metastases (CAR-Study A)

Completed
Elisabeth-TweeSteden Ziekenhuis
Posted 11/3/2016
Updated 8/14/2020

Chronotherapy for Radiotherapy of Glioma

Unknown Status
General Hospital of Ningxia Medical University
Posted 2/3/2021
© Copyright 2025. All Rights Reserved by MedPath
HomeTerms & ConditionsPrivacy Policy