Recent News
Partnering for success: Computer Science students represent UNM in NASA and Supercomputing Competitions
December 11, 2024
New associate dean interested in helping students realize their potential
August 6, 2024
Hand and Machine Lab researchers showcase work at Hawaii conference
June 13, 2024
Two from School of Engineering to receive local 40 Under 40 awards
April 18, 2024
News Archives
[Colloquium] Multiparameter Computational Modeling of Tumor Invasion
May 5, 2011
Watch Colloquium:
M4V file (744 MB)
- Date: Thursday, May 5, 2011
- Time: 11:00 am — 11:50 am
- Place: Mechanical Engineering 218
Vittorio Cristini
Victor & Ruby Hansen Surface Professor of Pathology, Chemical and Biomedical Engineering at the University of New Mexico
Clinical outcome prognostication in oncology is a guiding principle in therapeutic choice. A wealth of qualitative empirical evidence links disease progression with tumor morphology, histopathology, invasion, and associatedmolecular phenomena. However, the quantitative contribution of each of the known parameters in this progression remains elusive. Mathematical modeling can provide the capability to quantify the connection between variables governing growth, prognosis, and treatment outcome. By quantifying the link between the tumor boundary morphology and the invasive phenotype, this work provides a quantitative tool for the study of tumor progression and diagnostic/prognostic applications. This establishes a framework for monitoring system perturbation towards development of therapeutic strategies and correlation to clinical outcome for prognosis.
Clinical outcome prognostication in oncology is a guiding principle in therapeutic choice. A wealth of qualitative empirical evidence links disease progression with tumor morphology, histopathology, invasion, and associatedmolecular phenomena. However, the quantitative contribution of each of the known parameters in this progression remains elusive. Mathematical modeling can provide the capability to quantify the connection between variables governing growth, prognosis, and treatment outcome. By quantifying the link between the tumor boundary morphology and the invasive phenotype, this work provides a quantitative tool for the study of tumor progression and diagnostic/prognostic applications. This establishes a framework for monitoring system perturbation towards development of therapeutic strategies and correlation to clinical outcome for prognosis.