PURPOSE: The development of an experimental model of radiation-induced myelopathy in the pig which would facilitate the study of the effects of clinically relevant treatment volumes. METHODS AND MATERIALS: The effects of local spinal cord irradiation, to a standard 10 x 5 cm field, have been evaluated in mature (37-42.5 weeks) and immature (15.5-23 weeks) pigs. Irradiation was with single doses of 60Co gamma-rays at a dose-rate of 0.21-0.65 Gy/min. The incidence of paralysis was used as an endpoint. RESULTS: Irradiation of mature animals resulted in the development of frank paralysis with animals showing combined parenchymal and vascular pathologic changes in their white matter. These lesions, in common with those seen in patients, had a clear evidence of an inflammatory component. The latency for paralysis was short, 7.5-16.5 weeks, but within the wide range reported for patients. However, it was shorter than that reported in other large animal models. The ED50 value (+/- SE) for paralysis was 27.02 +/- 0.36 Gy, similar to that in rats taking into account dose-rate factors. The irradiation of immature pigs only resulted in transient neurological changes after doses comparable to those used in the mature animals, ED50 value (+/- SE) 26.09 +/- 0.37 Gy. The reasons for these transient neurological symptoms are uncertain. CONCLUSION: A reliable experimental model of radiation-induced myelopathy has been developed for mature pigs. This model is suitable for the study of clinically relevant volume effects.
PURPOSE: The development of an experimental model of radiation-induced myelopathy in the pig which would facilitate the study of the effects of clinically relevant treatment volumes. METHODS AND MATERIALS: The effects of local spinal cord irradiation, to a standard 10 x 5 cm field, have been evaluated in mature (37-42.5 weeks) and immature (15.5-23 weeks) pigs. Irradiation was with single doses of 60Co gamma-rays at a dose-rate of 0.21-0.65 Gy/min. The incidence of paralysis was used as an endpoint. RESULTS: Irradiation of mature animals resulted in the development of frank paralysis with animals showing combined parenchymal and vascular pathologic changes in their white matter. These lesions, in common with those seen in patients, had a clear evidence of an inflammatory component. The latency for paralysis was short, 7.5-16.5 weeks, but within the wide range reported for patients. However, it was shorter than that reported in other large animal models. The ED50 value (+/- SE) for paralysis was 27.02 +/- 0.36 Gy, similar to that in rats taking into account dose-rate factors. The irradiation of immature pigs only resulted in transient neurological changes after doses comparable to those used in the mature animals, ED50 value (+/- SE) 26.09 +/- 0.37 Gy. The reasons for these transient neurological symptoms are uncertain. CONCLUSION: A reliable experimental model of radiation-induced myelopathy has been developed for mature pigs. This model is suitable for the study of clinically relevant volume effects.
Authors: M E P Philippens; G Gambarota; J A Pikkemaat; W J M Peeters; A J van der Kogel; A Heerschap Journal: MAGMA Date: 2004-12-21 Impact factor: 2.310
Authors: John Kuluz; Amer Samdani; David Benglis; Manuel Gonzalez-Brito; Juan P Solano; Miguel A Ramirez; Ali Luqman; Roosevelt De los Santos; David Hutchinson; Mike Nares; Kyle Padgett; Dansha He; Tingting Huang; Allan Levi; Randal Betz; Dalton Dietrich Journal: J Spinal Cord Med Date: 2010 Impact factor: 1.985
Authors: Paul M Medin; Ryan D Foster; Albert J van der Kogel; James W Sayre; William H McBride; Timothy D Solberg Journal: Int J Radiat Oncol Biol Phys Date: 2010-10-08 Impact factor: 7.038