Frerker, BerndBerndFrerkerEngels, EletteEletteEngelsPaino, Jason R.Jason R.PainoRover, Vincent deVincent deRoverBustillo, John PaulJohn PaulBustilloWegner, MarieMarieWegnerCameron, MatthewMatthewCameronFiedler, StefanStefanFiedlerHausermann, DanielDanielHausermannHildebrandt, GuidoGuidoHildebrandtLerch, MichaelMichaelLerchSchültke, ElisabethElisabethSchültke2025-08-062025-08-062025-07-03Biomimetics 10 (7): 440 (2025)https://hdl.handle.net/11420/56469The results of radiotherapy in patients with primary malignant brain tumors are extremely dissatisfactory: the overall survival after a diagnosis of glioblastoma is typically less than three years. The development of spatially fractionated radiotherapy techniques could help to improve this bleak prognosis. In order to develop technical equipment and organ-specific therapy plans, dosimetry studies as well as radiobiology studies are conducted. Although perfect spheres are considered optimal phantoms by physicists, this does not reflect the wide variety of head sizes and shapes in our patient community. Depth from surface and X-ray dose absorption by tissue between dose entry point and target, two key parameters in medical physics planning, are largely determined by the shape and thickness of the skull bone. We have, therefore, designed and produced a biomimetic tool to correlate measured technical dose and biological response in human cancer cells: a brain phantom, produced from tissue-equivalent materials. In a first pilot study, utilizing our phantom to correlate technical dose measurements and metabolic response to radiation in human cancer cell lines, we demonstrate why an anthropomorphic phantom is preferable over a simple spheroid phantom.en2313-76732025Multidisciplinary Digital Publishing Institutehttps://creativecommons.org/licenses/by/4.0/Technology::610: Medicine, HealthJournal Article2025-07-25https://doi.org/10.15480/882.1542710.3390/biomimetics1007044010.15480/882.15427Journal Article