PURPOSE: The effects of dose distribution on dose-effect relationships have been evaluated and, from this, iso-effective doses (ED(50)) established. METHODS AND MATERIALS: Wistar rats were irradiated on the cervical spinal cord with single doses of unmodulated protons (150 MeV) to obtain sharp lateral penumbras, using the shoot-through technique, which employs the plateau of the depth-dose profile rather than the Bragg peak. Two types of inhomogeneous dose distributions have been administered: (1) 2 4-mm fields with 8- or 12-mm spacing between the center of the fields (referred to as split-field) were irradiated with variable single doses and (2) cervical spinal cord was irradiated with various combinations of relatively low doses to a large volume (20 mm) combined with high doses to a small volume (4 mm) (referred to as bath and shower). The endpoint for estimating the dose-response relationships was paralysis of the fore or hind limbs. RESULTS: The split-field experiments (2 x 4 mm) showed a shift in the dose-response curves, giving significant higher ED(50) values of 45.4 Gy and 41.6 Gy for 8- and 12-mm spacing, respectively, compared with the ED(50) of 24.9 Gy for the single 8 mm (same total tissue volume irradiated). These values were closer to the ED(50) for a single 4-mm field of 53.7 Gy. The bath and shower experiments showed a large decrease of the ED(50) values from 15-22 Gy when compared with the 4-mm single field, even with a bath dose as low as 4 Gy. There were no histologic changes found in the low dose bath regions of the spinal cord at postmortem. CONCLUSIONS: Not only the integral irradiated volume is a determining factor for the ED(50) of rat cervical spinal cord, but also the shape of the dose distribution is of great importance. The high ED(50) values of a small region or shower (4 mm) decreases significantly when the adjacent tissue is irradiated with a subthreshold dose (bath), even as low as 4 Gy. The significant shift to lower ED(50) values for induction of paralysis of the limbs by adding a low-dose bath was not accompanied by changes in histologic lesions. These observations may have implications for the interpretation of complex treatment plans and normal tissue complication probability in intensity-modulated radiotherapy.
PURPOSE: The effects of dose distribution on dose-effect relationships have been evaluated and, from this, iso-effective doses (ED(50)) established. METHODS AND MATERIALS: Wistar rats were irradiated on the cervical spinal cord with single doses of unmodulated protons (150 MeV) to obtain sharp lateral penumbras, using the shoot-through technique, which employs the plateau of the depth-dose profile rather than the Bragg peak. Two types of inhomogeneous dose distributions have been administered: (1) 2 4-mm fields with 8- or 12-mm spacing between the center of the fields (referred to as split-field) were irradiated with variable single doses and (2) cervical spinal cord was irradiated with various combinations of relatively low doses to a large volume (20 mm) combined with high doses to a small volume (4 mm) (referred to as bath and shower). The endpoint for estimating the dose-response relationships was paralysis of the fore or hind limbs. RESULTS: The split-field experiments (2 x 4 mm) showed a shift in the dose-response curves, giving significant higher ED(50) values of 45.4 Gy and 41.6 Gy for 8- and 12-mm spacing, respectively, compared with the ED(50) of 24.9 Gy for the single 8 mm (same total tissue volume irradiated). These values were closer to the ED(50) for a single 4-mm field of 53.7 Gy. The bath and shower experiments showed a large decrease of the ED(50) values from 15-22 Gy when compared with the 4-mm single field, even with a bath dose as low as 4 Gy. There were no histologic changes found in the low dose bath regions of the spinal cord at postmortem. CONCLUSIONS: Not only the integral irradiated volume is a determining factor for the ED(50) of rat cervical spinal cord, but also the shape of the dose distribution is of great importance. The high ED(50) values of a small region or shower (4 mm) decreases significantly when the adjacent tissue is irradiated with a subthreshold dose (bath), even as low as 4 Gy. The significant shift to lower ED(50) values for induction of paralysis of the limbs by adding a low-dose bath was not accompanied by changes in histologic lesions. These observations may have implications for the interpretation of complex treatment plans and normal tissue complication probability in intensity-modulated radiotherapy.
Authors: Daniel Pak; Karen Vineberg; Felix Feng; Randall K Ten Haken; Avraham Eisbruch Journal: Int J Radiat Oncol Biol Phys Date: 2012-01-26 Impact factor: 7.038
Authors: V E M Mul; J M A de Jong; L H P Murrer; P L A van den Ende; R M A Houben; M Lacko; P Lambin; B G Baumert Journal: Strahlenther Onkol Date: 2011-12-23 Impact factor: 3.621
Authors: Paul M Medin; Ryan D Foster; Albert J van der Kogel; James W Sayre; William H McBride; Timothy D Solberg Journal: Radiother Oncol Date: 2012-09-14 Impact factor: 6.280
Authors: M N Duma; T Schuster; N Aswathanarayana; L-S Fromm; M Molls; H Geinitz; S Kampfer Journal: Strahlenther Onkol Date: 2013-10-10 Impact factor: 3.621