Effect of different dynamic microvasculature in a solid tumor with the necrotic region during magnetic hyperthermia: An in-silico study

“…3 shows the use of advanced tumor models to better understand heat distribution, particularly by varying the density of tumor vasculature ( Fig. 3A1 and A2 ), 254 and by using Fe 3 O 4 MNPs for MH ( Fig. 3B1–B4 ).…”

“…Moreover, it is difficult to confirm the veracity of the obtained results due to the lack of experiments performed in clinical settings. 254 Currently, researchers are dedicated to improving mechanisms to predict heat delivery in tissues by introducing variables such as the size and morphology of the NPs. 231 Significant advances in this direction are expected in the upcoming years, especially considering that 3D hyperthermic simulations are an important tool to accelerate the clinical translation of nano-hyperthermia.…”

Advances in screening hyperthermic nanomedicines in 3D tumor models

“…3 shows the use of advanced tumor models to better understand heat distribution, particularly by varying the density of tumor vasculature ( Fig. 3A1 and A2 ), 254 and by using Fe 3 O 4 MNPs for MH ( Fig. 3B1–B4 ).…”

“…Moreover, it is difficult to confirm the veracity of the obtained results due to the lack of experiments performed in clinical settings. 254 Currently, researchers are dedicated to improving mechanisms to predict heat delivery in tissues by introducing variables such as the size and morphology of the NPs. 231 Significant advances in this direction are expected in the upcoming years, especially considering that 3D hyperthermic simulations are an important tool to accelerate the clinical translation of nano-hyperthermia.…”

Advances in screening hyperthermic nanomedicines in 3D tumor models

Enzymatically crosslinked magnetic starch-grafted poly(tannic acid) hydrogel for “smart” cancer treatment: An in vitro chemo/hyperthermia therapy study

Effects of magnetic nanoparticle distribution in cancer therapy through hyperthermia