Extracellular fluid | EPFL Graph Search

In cell biology, extracellular fluid (ECF) denotes all body fluid outside the cells of any multicellular organism. Total body water in healthy adults is about 60% (range 45 to 75%) of total body weight; women and the obese typically have a lower percentage than lean men. Extracellular fluid makes up about one-third of body fluid, the remaining two-thirds is intracellular fluid within cells. The main component of the extracellular fluid is the interstitial fluid that surrounds cells. Extracellular fluid is the internal environment of all multicellular animals, and in those animals with a blood circulatory system, a proportion of this fluid is blood plasma. Plasma and interstitial fluid are the two components that make up at least 97% of the ECF. Lymph makes up a small percentage of the interstitial fluid. The remaining small portion of the ECF includes the transcellular fluid (about 2.5%). The ECF can also be seen as having two components – plasma and lymph as a delivery system, and

Poroelastic modelling of peri-implnat gap

Evert Robberecht

Micromotion affects the tissue outcome at the peri-implant site. Interstitial fluid flow, induced by micromotion, may play a curtail part in the mesenchymal stem cell differentiation pathway necessary for bone regeneration. The aim of this project is to model the fluid flow at the peri-implant site composed of a soft tissue, for a glenoid implant for different gap sizes at physiological loading.

2008

Effects of dynamic environments on extracellular morphogen gradients

Mark Fleury

Tissue morphogenesis and remodeling is often orchestrated by cell-secreted proteins, referred to as morphogens that can trigger cellular responses in addition to modifying the local extracellular matrix (ECM). Of specific interest is the distribution of cell secreted proteins in the cell microenvironment and how this distribution can lead to varied responses. Morphogens often provide directional cues, and as such their specific distribution is critical to the signaling that they induce, in other words cells are sensitive to morphogen gradients and not just absolute amounts. Natural cellular environments in native tissue involve three dimensional ECM and are typically subjected to dynamic conditions such as interstitial flow (IF). Despite the importance of the extracellular environment in signaling, very little is known regarding the effects of mechanical stresses and subtle interstitial flows. This thesis examines the role of IF on morphogen gradients using mass transport models to elucidate mechanisms responsible for several specific biological phenomena including in vitro capillary formation and lymphatic metastasis of tumor cells. In vitro capillary formation had been shown in our lab to be separately enhanced by bound VEGF alone and slow IF alone, with the combination of these two conditions resulting in marked increase in organization. Using our computational model we were able to propose a novel mechanistic model to explain this synergy. Specifically showed how, through the combined effects of IF and matrix-bound growth factors, cells could create their own biased chemokine gradients without recourse to internal amplification methods. This process, which we have termed "autologous chemotaxis," drives directional signaling and migration in the direction of flow. This can occur even at very low Peclet numbers, when diffusion still dominates the overall transport, but convection changes the shape of the gradient, which is what a cell responds to. We then examined the effects of IF on tumor cell migration to explore a novel mechanism of lymphatic metastasis. Tumors often produce high amounts of proteoglycans creating a microenvironment is rich in morphogen binding sites, and tumors are also a source of interstitial flow due to their leaky vasculature. The lymphatic system drains interstitial fluid, therefore IF is always directed toward lymphatic capillaries. The lymphatic system is also a common route of tumor metastasis, which is what lead us to study the role of IF mediated chemotaxis. A computational model of an in vitro tumor invasion assay was constructed that predicted tumor cell migration that was in very good agreement with the in vitro experimental results. This phenomenon was further studied by modeling an in vivo geometry and examining the factors controlling autologous gradient formation in a physiological setting. In conclusion, we have demonstrated the importance of convective mass transport at very low flow velocities in a biological context. While these velocities are low enough that the convective effects would typically be ignored, their subtle effects on pericellular mass transport can be translated into relevant and observable morphogenic responses.

EPFL2007

Effects of dynamic environments on extracellular morphogen gradients

Mark Fleury

EPFL2007