In addition to genetic mutations, biomechanical factors also affect the structures and
functions of the tumors during tumor growth, including solid stress, interstitial fluid pressure …

The uncontrolled proliferation of cancer cells causes the growth of the tumor mass.
Consequently, the normal surrounding tissue exerts a compressive force on the tumor mass …

Pennes' bioheat equation is considered one of the most prevalent mathematical equations
used to estimate the temperature profile of a tumor in a human body when subjected to …

Metastatic lesions compromise the mechanical integrity of vertebrae, increasing the fracture
risk. Screw fixation is usually performed to guarantee spinal stability and prevent dramatic …

Among different hallmarks of cancer, understanding biomechanics of tumor growth and
remodeling benefits the most from the theoretical framework of continuum mechanics. Tumor …

Objective. Compression-induced solid stress (SSc) and fluid pressure (FPc) during
ultrasound poroelastography (USPE) experiments are correlated with two markers of cancer …

A hallmark of biological cells is their ability to proliferate and of tissues their ability to grow.
This is common in morphogenesis and embryogenesis, but also in pathological conditions …

Glioblastoma is the most aggressive and infiltrative glioma, classified as Grade IV, with the
poorest survival rate among patients. Accurate and rigorously tested mechanistic in silico …

Simple Summary Biomechanical forces aggravate brain tumor progression. In this study,
magnetic resonance elastography (MRE) is employed to extract tissue biomechanical …

Poromechanics plays a key role in modelling hard and soft tissue behaviours, by providing a
thermodynamic framework in which chemo-mechanical mutual interactions among fluid and …