The number of cancer related deaths is predicted to reach over 13.1 million in 2030. Understanding the spatio-temporal evolution of tumours and their response to therapy is crucial to thwart this gloomy prognosis. Mathematical models have been used to elucidate the biological processes involved in tumour growth, but their complexity severely limits their clinical value. Eective models should base predictions on patient-specic data that can be obtained and tested in the clinic. This thesis aims to develop novel clinically-relevant methodologies to model solid tumour growth and reaction to therapy. Models are developed that predict the macroscopic tumour evolution as a result of complex biological processes happening at the microsco...