Marc Guedea1, Antoni Castel2, Marc Arnalte2, Alex Mollera3, Victor Muñoz1, Ferran Guedea4. 1. FERT School, Barcelona, Spain. 2. L'Institut Universitari Dexeus, Barcelona, Spain. 3. Universitat de Girona, Girona, Spain. 4. Institut Català d'Oncologia, L'Hospitalet de Llobregat, Barcelona, Spain.
Abstract
AIM: To evaluate the differential effects of fractionated vs. high-dose radiotherapy on plant growth. BACKGROUND: Interest in hypofractionated radiotherapy has increased substantially in recent years as tumours (especially of the lung, prostate, and liver) can be irradiated with ever greater accuracy due to technological improvements. The effects of low-dose ionizing radiation on plant growth have been studied extensively, yet few studies have investigated the effect of high-dose, hypofractionated radiotherapy on plant growth development. MATERIALS AND METHODS:A total of 150 plants from the genus Capsicum annuum were randomized to receive fractionated radiotherapy (5 doses of 10 Gy each), single high-dose (SHD) radiotherapy (single 50 Gy dose), or no radiotherapy (control group). Irradiation was delivered via linear accelerator and all samples were followed daily for 26 days to assess and compare daily growth. RESULTS: On day 26, plants in the control, fractionated, and SHD groups had grown to a mean height of 7.55 cm, 4.32 cm, and 2.94 cm, respectively. These differences in overall growth were highly significant (P = 0.005). The SHD group showed the least amount of growth. CONCLUSIONS: SHD effectively stunts plant growth and development. Despite the evident differences between plant and animal cells, ionizing radiation is believed to work in a similar manner in all biological cells. These findings highlight the need to continue investigating the use of hypofractionated schemes in humans to improve cancer treatment outcomes.
RCT Entities:
AIM: To evaluate the differential effects of fractionated vs. high-dose radiotherapy on plant growth. BACKGROUND: Interest in hypofractionated radiotherapy has increased substantially in recent years as tumours (especially of the lung, prostate, and liver) can be irradiated with ever greater accuracy due to technological improvements. The effects of low-dose ionizing radiation on plant growth have been studied extensively, yet few studies have investigated the effect of high-dose, hypofractionated radiotherapy on plant growth development. MATERIALS AND METHODS: A total of 150 plants from the genus Capsicum annuum were randomized to receive fractionated radiotherapy (5 doses of 10 Gy each), single high-dose (SHD) radiotherapy (single 50 Gy dose), or no radiotherapy (control group). Irradiation was delivered via linear accelerator and all samples were followed daily for 26 days to assess and compare daily growth. RESULTS: On day 26, plants in the control, fractionated, and SHD groups had grown to a mean height of 7.55 cm, 4.32 cm, and 2.94 cm, respectively. These differences in overall growth were highly significant (P = 0.005). The SHD group showed the least amount of growth. CONCLUSIONS: SHD effectively stunts plant growth and development. Despite the evident differences between plant and animal cells, ionizing radiation is believed to work in a similar manner in all biological cells. These findings highlight the need to continue investigating the use of hypofractionated schemes in humans to improve cancer treatment outcomes.
Authors: Mojgan Taremi; Andrew Hope; Patricia Lindsay; Max Dahele; Sharon Fung; Thomas G Purdie; David Jaffray; Laura Dawson; Andrea Bezjak Journal: Radiat Oncol Date: 2012-09-17 Impact factor: 3.481