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000156893 1001_ $$0P:(DE-He78)d2d5be27f31d018fde38f5a195319620$$aBahn, Emanuel$$b0$$eFirst author$$udkfz
000156893 245__ $$aVolume-dependent dose-response of the intestinal stem cell niche and lymphoid tissue.
000156893 260__ $$aAmsterdam [u.a.]$$bElsevier Science$$c2020
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000156893 520__ $$aPlasticity of the intestinal stem cell compartment in response to radiation injury is regulated by a stem cell niche. We present here the first experimental observations of a dose-volume effect of the intestinal stem cell niche and of the solitary intestinal lymphoid tissues (SILT).Regeneration of intestinal crypts in mice was studied following irradiation of millimetre-size jejunal sections with single doses of 6 to 24 Gy and compared to total body irradiation (TBI). The statistical distribution of cells per crypt was scored and regressed to a biomathematical model. The number of SILTs was scored for different doses and field sizes and crypt regeneration was correlated with SILT proximity.We observed a differential dose-response of the intestinal stem cell niche at the centres of the irradiated sections, but only for field sizes below 10 mm. Irradiation of 5 mm jejunum results in an increase in crypt survival by up to an order of magnitude, compared to TBI. Distributions of cell-per-crypt numbers and comparison to biomathematical modelling suggest that these observations stem from a field size-dependent regeneration rate. The density of SILTs also exhibits a volume-dependent dose-response and increased crypt survival correlates with a proximity to SILTs.Our findings present the first observation of a field-size dependent dose-response of the intestinal stem cell niche. Its regeneration process does apparently not rely on distant radiation-sensitive resources of the organism, such as the bone marrow. Yet, our observations suggest that the niche interacts with intact tissue in millimetres distance, leading to faster crypt regeneration. The field-size dependent dose-response of SILTs posits a role of the immune system on the dose-volume effect.
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000156893 7001_ $$avan Heerden, Michelle$$b1
000156893 7001_ $$aSachse, Karl Nicholas$$b2
000156893 7001_ $$aGueulette, John$$b3
000156893 7001_ $$aSlabbert, Jacobus P$$b4
000156893 7001_ $$aAlber, Markus$$b5
000156893 7001_ $$aShaw, William$$b6
000156893 773__ $$0PERI:(DE-600)1500707-8$$a10.1016/j.radonc.2020.06.003$$gVol. 150, p. 51 - 56$$p51 - 56$$tRadiotherapy and oncology$$v150$$x0167-8140$$y2020
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