[en] Although 24 Gy single-dose radiation therapy (SDRT) renders >90% 5-year local relapse-free survival in human solid tumor lesions, SDRT delivery is not feasible in ∼50% of oligometastatic lesions owing to interference by dose/volume constraints of a serial organ at risk (OAR). Conformal OAR avoidance is based on a hypothetical model positing that the recently described SDRT biology specifically permits volumetric subdivision of the SDRT dose, such that high-intensity vascular drivers of SDRT lethality, generated within a major tumor subvolume exposed to a high 24 Gy dose (high-dose planning target volume [PTV_HD]), would equilibrate SDRT signaling intensity throughout the tumor interstitial space, rendering bystander radiosensitization of a minor subvolume (perfusion-modulated dose sculpting PTV [PTV_PMDS]), dose-sculpted to meet a serial OAR dose/volume constraint. An engineered PTV_PMDS may thus yield tumor ablation despite PMDS dose reduction and conformally avoiding OAR exposure to a toxic dose.

[en] Background and purpose: Single Dose Radiation Therapy (SDRT) provides remarkably high rates of control even for tumors resistant to fractionated radiotherapy. SDRT tumor control depends on acute acid sphingomyelinase-mediated endothelial cell injury and monoclonal antibodies targeting Vascular Endothelial Cell Growth Factor (VEGF) signaling radiosensitized tumor endothelium when delivered immediately prior to irradiation. Here we evaluate the ability of the oral VEGF receptor inhibitor, axitinib, to sensitize tumor endothelium and increase tumor control with SDRT. Methods and materials: Axitinib was added to primary cultured endothelial cells, or administered orally to Sv129/BL6 mice bearing radiosensitive MCA/129 sarcoma or radioresistant B16F1 melanoma flank tumors, followed by SDRT. Endothelial apoptosis was assessed by TUNEL assay or bis-benzamide staining. Mice with irradiated tumors were followed for 90 days to evaluate the impact of axitinib on SDRT tumor control. Results: Pre-treatment with axitinib increased acute endothelial cell apoptosis following SDRT in vitro, and in vivo for both MCA/129 and B16F1 tumors. Axitinib correspondingly increased SDRT tumor growth delay and complete response rate (by 40%) for both tumors. Administration precisely 1 h before SDRT was critical for radiosensitization. Conclusions: Axitinib radiosensitizes tumor endothelial cells and enhances tumor cure with SDRT, which may permit dose de-escalation and significantly expand the range of clinical indications for SDRT

[en] Purpose: To address in vivo the issue of whether Bax and Bak are functionally redundant in signaling apoptosis, capable of substituting for each other. Methods and Materials: Mice were exposed to whole-body radiation, and endothelial cell apoptosis was quantified using double immunostaining with TUNEL and anti-CD31 antibody. Crypt survival was determined at 3.5 days after whole-body radiation by the microcolony survival assay. Actuarial animal survival was calculated by the product-limit Kaplan-Meier method, and autopsies were performed to establish cause of death. Results: Radiation exposure of Bax- and Bak-deficient mice, both expressing a wild-type acid sphingomyelinase (ASMase) phenotype, indicated that Bax and Bak are both mandatory, though mutually independent, for the intestinal endothelial apoptotic response. However, neither affected epithelial apoptosis at crypt positions 4-5, indicating specificity toward endothelium. Furthermore, Bax deficiency and Bak deficiency each individually mimicked ASMase deficiency in inhibiting crypt lethality in the microcolony assay and in rescuing mice from the lethal gastrointestinal syndrome. Conclusions: The data indicate that Bax and Bak have nonredundant functional roles in the apoptotic response of the irradiated intestinal endothelium. The observation that Bax deficiency and Bak deficiency also protect crypts in the microcolony assay provides strong evidence that the microvascular apoptotic component is germane to the mechanism of radiation-induced damage to mouse intestines, regulating reproductive cell death of crypt stem cell clonogens