Cell organization in soft media due to active mechanosensing
I. B. Bischofs and U. S. Schwarz*
Max Planck Institute of Colloids and Interfaces, 14424 Potsdam, Germany
Communicated by Tom C. Lubensky, University of Pennsylvania, Philadelphia, PA, June 10, 2003 (received for review January 21, 2003)
Until recently, biologists have considered an adherent cell’s physiological function to be the main influence on its mechanical activity. Scientists suggest a new theory: adherent cells orient themselves in their environments to maximize effective stiffness. This theory relies on fairly complex mathematical equations whose derivations were far from trivial. Before constructing any formulas, scientists had to find a way to calculate the stress and strain on a cell due to its surroundings. They then tried to measure how much work a cell must do on its surroundings to build up a certain force at its point of contact. They came up with a complicated integral calculating the work, where minimum work corresponded to the cell sensing maximum stiffness. Note that they are not implying that cells actually execute this minimal work; rather, the effectiveness of the measurement lies in allowing them to compare different values of work in different elastic environments. Thus, they can see the varying degrees of effectiveness in extracting information through mechanosensing.
The results showed that cells interacting with homogeneous external strains orient themselves with the direction of stretch. Specifically, experiments with fibroblasts on elastic substrates and collagen gels support this orientation corresponding to minimal work. The scientist’s model also agrees with preexisting results regarding the mechanical activity of cells on boundaries. They also investigated cooperative effects of cells. Their work-minimizing model suggested that two neighboring cells would completely align their dipoles to maximize stiffness. This agrees with experimental results where strings of cells align themselves parallel to the external strain. Thus, this paper proposed various mathematical formulas for calculating the work done by various types of cells. Then, with the equations, found the orientations of the cells that minimized the work. Then, the paper compared these predictions with previously found experimental results. The consistent agreement between the predictions and experimental results provides a strong case supporting the validity of the optimization principle of cells in soft media.
I chose to read and summarize this article because of its substantial mathematical and physical content. I think work is a fascinating physical phenomenon. When I glossed over the articles, all the integrals and equations for work in this paper sparked my interest. I wanted to understand what the formulas represented biologically. Explaining biological phenomena with the tools in math and physics is, in my opinion, a very precise and beautiful way of understanding why cells behave the ways they do. This paper, in particular, is important because it presents a theory to describe previously observed experimental results on cell orientation. Understanding why cells orient themselves in a certain way is so much more exciting, to me, than just learning how they orient themselves. With math and physics, we have found ways to deepen our understandings of observed phenomena.
7 comments:
This phenomenon seems very interesting relating to cell polarity in tissues. Did the researchers investigate the physiological basis for such an alignment?
What kinds of assumptions did the scientists make when deriving the equations, if any?
You mentioned that they only worked with fibroblasts on different ECM substrates that are especially aligned (collagen and elastin). Should this mechanosensing apply if they are cultured on other substrates that does not align by itself anyway?
This could be of further research with other cell types as well.
Response to Elise:
To keep their calculation feasible, they assumed that the extracellular environment is described by isotropic linear elasticity theory. This assumption holds true for most synthetic elastic substrates and might be reasonable for hydrogels. Hence, there are two elastic moduli, the Young modules E (describes rigidity), and the Poisson ratio v (describes the relative weight of compression and shear modes).
Response to David:
“If fiber alignment has resulted in some anisotropic mechanical environment, the cell might sense the anisotropic mechanical properties of the matrix and orient itself correspondingly. This orientation might explain why cells have been found to align to a greater extent with respect to external strain than the surrounding collagen fibrils and why our modeling is also successful for hydrogels. In general, further experiments are needed to clarify the relative importance of topographic versus mechanical clues for cell organization in hydrogels, and further modeling is needed to account for the mechanical properties of hydrogels.”
to mchen
im dont know if this mechanosensing should be applied if they are cultured on other substrates that does not align by itself! the artical did not mention anything about that! sorry to disappoint you :D
Post a Comment