On Simulating Growth and Form

Simulations can teach us how young bodies and faces develop; how an artery compensates for decades of fatty plaque deposits by growing and thickening its walls; how tissue engineers can best coax endothelial cells to develop into organized sheets of skin for burn patients; and how cancerous tumors invade neighboring tissue.

For better or for worse, and on many levels, our tissues never stop growing and changing. While developing from childhood to old age, we grow not only bone, cartilage, fat, muscle and skin, but also...
Apr, 01, 2008
Computational Biology Catches the Flu: Modeling the bug, the host, the world
The flu virus is an evolutionary marvel. Teams of experts design an appropriate flu vaccine annually just to keep up with the microbe’s ability to evade the human immune system. Multiple...
Jul, 01, 2006
Computational Biomechanics: Making Strides Toward Patient Care

Moving from intuition to evidence-based intervention

To understand how muscles contract and joints flex, researchers have dissected cadavers and experimented with animals. They can describe how bones, muscles, and tendons connect in a complicated...
Jan, 01, 2007
Vertex Classification in Graphs

How can they help us understand proteins?

Graphs, or networks, have been widely adopted in computational biology, with examples including protein-protein interaction networks, gene regulatory networks, and residue interaction networks in...
Jun, 20, 2013
Teaching Biology and Physics Together
While science educators actively debate the relative merits of teaching natural science in an integrated fashion, some authors are writing texts that will make it happen. Philip Nelson’s book,...
Jun, 01, 2005
The Eyes Have It: Biomechanical Models Explore Disorders of the Eye

Biomechanical models contribute to a better understanding of both the normal and the diseased eye.

Squint, and you can almost  make out that bird soaring over the horizon. But determining whether it’s a hawk or a raven will be nearly impossible for someone with myopia, also known as...
Feb, 19, 2013
Packing It All In: Curricula for Biomedical Computing

Balancing Breadth and Depth

The last decade saw a proliferation of training programs at the intersection of life science and computation, with more than 60 new degree and certificate programs launched in the United States alone...
Sep, 01, 2005
From SNPs to Prescriptions: Can Genes Predict Drug Response?

Decades of steady progress in pharmacogenetics have unearthed hundreds of associations between genes and drug response. But the field has to solve some theoretical and practical issues before it can deliver on the promise of personalized drug therapy.

As algorithms go, it’s deceptively simple. Just add together eight weighted pieces of patient information—age, height, weight, race, data about two genes, and a pair of clinical...
Jul, 01, 2009
Point/Counterpoint: Should there be a separate funding mechanism for the development and maintenance of software and infrastructure?
  POINT/   NO:  Grant applications for the development and maintenance of software and infrastructure should compete with basic research applications. Biomedicine has a strong...
Jul, 01, 2009
Dogs, Doses, and Devices: The FDA's Ambitious Plans for Computational Modeling

Computational modeling can help fill gaps in how we develop and review new drugs and devices

What role does computational modeling play at the United States Food and Drug Administration (FDA)?  If you ask Paul Watkins, MD, director of the Hamner—University of North Carolina...
devices, drug discovery, FDA, modeling
Sep, 01, 2011