A. Berg et al., High resolution polymer gel dosimetry by parameter selective MR-microimaging on a whole body scanner at 3 T, MED PHYS, 28(5), 2001, pp. 833-843
Citations number
26
Categorie Soggetti
Radiology ,Nuclear Medicine & Imaging","Medical Research Diagnosis & Treatment
High dose variations across small spatial distances, as present in brachyth
erapeutic applications or radiosurgery and especially gamma -knife therapy,
are difficult to quantify by standard dosimetry. We demonstrate the possib
ility to obtain planar spatial resolutions for dose imaging at pixel sizes
below 200 mum within multislice parameter selective MR imaging on polymer g
els. The sensitivity of the transversal and longitudinal relaxation time as
well as diffusivity on dose is shown. High spatial resolution is achieved
by parameter selective microimaging of polymer gels on a high-field (3 T) w
hole-body MR system equipped with a dedicated strong gradient system and a
small probe head matched to the sample size. In addition to the spin-spin r
elaxation rate R2 = 1/T2 we investigate the sensitivity of the longitudinal
relaxation rate R1 = 1/T1 and the diffusivity D-app in acrylic polymer gel
s on irradiation up to dose levels of about 20 Gy. Dose images are obtained
after calibration of the corresponding MR parameters by known dose levels
of gamma irradiation. Also the MR-parameter T1 may be used for dose imaging
. The impact of all of the three parameters T1, T2, and diffusivity on obta
ined signal intensities in irradiated regions has to be taken into account
in nonoptimized pulse sequences. Further, very high spatial resolution impo
ses several restrictions on the evaluation of R2, which have to be consider
ed for quantitative dosimetry. These restrictions are discussed in detail.
We also demonstrate the importance of such a high spatial resolution in cas
e of a set of differently sized gamma -knife stereotactic irradiation schem
es. Gel dosimetry based on MR parameter selective microimaging represents a
potent alternative for the detection of dose distributions characterized b
y steep dose gradients, typical in brachytherapeutic and radiosurgical appl
ications. (C) 2001 American Association of Physicists in Medicine.