Limitations of a simple technique for movement compensation via movement-modified fluence profiles
- 28 June 2005
- journal article
- Published by IOP Publishing in Physics in Medicine & Biology
- Vol. 50 (14) , N155-N161
- https://doi.org/10.1088/0031-9155/50/14/n02
Abstract
The delivery of intensity-modulated radiation therapy (IMRT) through the dynamic multileaf collimator (dMLC) technique is well known and recently it has been shown how this can be modified to deliver fluence to a body which is moving in a regular and totally predictable manner. This involves making the leaves 'breath' in tandem with the body motion. This note presents an entirely alternative suggestion in which the leaves do not 'breath' at all but the fluence profile to be mapped to the unbreathing leaf motions is modified so that, when sampled by the specified motion, the actual fluence delivered is close to the desired fluence. Limitations of the concept are discussed.Keywords
This publication has 9 references indexed in Scilit:
- The effect on IMRT conformality of elastic tissue movement and a practical suggestion for movement compensation via the modified dynamic multileaf collimator (dMLC) techniquePhysics in Medicine & Biology, 2005
- DMLC leaf‐pair optimal control for mobile, deforming targetMedical Physics, 2005
- DMLC leaf-pair optimal control of IMRT delivery for a moving rigid targetMedical Physics, 2004
- A method for incorporating organ motion due to breathing into 3D dose calculations in the liver: Sensitivity to variations in motionMedical Physics, 2003
- The leaf sweep algorithm for an immobile and moving target as an optimal control problem in radiotherapy deliveryMathematical and Computer Modelling, 2003
- Motion adaptive x-ray therapy: a feasibility studyPhysics in Medicine & Biology, 2000
- Dynamic X-ray compensation for conformal radiotherapy by means of multi-leaf collimationRadiotherapy and Oncology, 1994
- Generation of arbitrary intensity profiles by dynamic jaws or multileaf collimatorsMedical Physics, 1994
- An analytical solution for the dynamic control of multileaf collimatorsPhysics in Medicine & Biology, 1994