Monday, January 7, 2013

Living cells behave like fluid-filled sponges

Living cells behave like fluid-filled sponges [ Back to EurekAlert! ] Public release date: 6-Jan-2013
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Contact: Clare Ryan
clare.ryan@ucl.ac.uk
44-077-475-65056
University College London

Animal cells behave like fluid-filled sponges in response to being mechanically deformed according to new research published today in Nature Materials.

Scientists from the London Centre for Nanotechnology (LCN) at UCL have shown that animal cells behave according to the theory of 'poroelasticity' when mechanically stimulated in a way similar to that experienced in organs within the body. The results indicate that the rate of cell deformation in response to mechanical stress is limited by how quickly water can redistribute within the cell interior.

Poroelasticity was originally formulated to describe the behaviour of water-saturated soils and has important applications in the fields of rock engineering and petro-physics. It is commonly used in the petroleum industry. Poroelastic models describe cells as being analogous to fluid-filled sponges. Indeed, cells are constituted of a sponge-like porous elastic matrix (comprising the cytoskeleton, organelles, and macromolecules) bathed in an interstitial fluid (the cytosol).

In this analogy, the rate at which the fluid-filled sponge can be deformed is limited by how fast internal water can redistribute within the sponge in response to deformation. This rate is dictated by three parameters: the stiffness of the sponge matrix, the size of the pores within the sponge matrix, and the viscosity of the interstitial fluid.

To study cellular responses, LCN scientists used cell-sized levers to apply rapid well-controlled deformations on the cell surface and monitored the temporal response of cells to these deformations. Close examination of the experimental results revealed that the rate of cellular deformation was limited by how rapidly water could redistribute within the cell interior. Experimental measurements indicated that this sponge-like behaviour of cells likely occurs during normal function of organs such as the lungs and the cardiovascular system.

Emad Moeendarbary, lead author of the paper from the LCN said: "In the cardiovascular system, some tissues encounter extreme mechanical conditions. Heart valves can typically withstand 7-fold increases in their length in less than one second. The poroelastic nature of cells may allow them to behave similarly to shock absorbers when exposed to these extreme mechanical conditions."

To experimentally verify the fluid-filled sponge model, researchers manipulated the size of the cellular pores using chemical and genetic tools and showed that the rate of cellular deformation was affected by the pore size, as suggested by the theory of poroelasticity.

Guillaume Charras, senior co-author of the paper from the LCN said: "Cells can detect the mechanical forces they are subjected to and modify their behaviour accordingly. How changes in the mechanical environment are converted into biochemical information that the cell can interpret remains unknown. A better understanding of the physics of the cellular material is a first step towards formulating possible mechanisms through which this could occur."

###

Notes for Editors

1. For more information, please contact Emad Moeendarbary on tel: +44 (0)20 7679 2923 or +44 (0)1223333762, mobile: +44 07723599221, e-mail: e.moeendarbary@ucl.ac.uk.

2. Alternatively, please contact Clare Ryan in the UCL Media Relations Office on tel: +44 (0)20 3108 3846, mobile: +44 07747 556 056, out of hours +44 (0)7917 271 364, e-mail: clare.ryan@ucl.ac.uk

3. 'They cytoplasm of living cells behaves as a poroelastic model' is published in the journal Nature Materials on 6 January and is embargoed to 18:00 (London time) Journalists can obtain copies of the paper by contacting UCL Media Relations.

4. An image illustrating the experiment can be obtained from the UCL Media Relations Office.

About UCL (University College London)

Founded in 1826, UCL was the first English university established after Oxford and Cambridge, the first to admit students regardless of race, class, religion or gender and the first to provide systematic teaching of law, architecture and medicine.

We are among the world's top universities, as reflected by our performance in a range of international rankings and tables. According to the Thomson Scientific Citation Index, UCL is the second most highly cited European university and the 15th most highly cited in the world.

UCL has nearly 25,000 students from 150 countries and more than 9,000 employees, of whom one third are from outside the UK. The university is based in Bloomsbury in the heart of London, but also has two international campuses UCL Australia and UCL Qatar. Our annual income is more than 800 million.

www.ucl.ac.uk | Follow us on Twitter @uclnews | Watch our YouTube channel YouTube.com/UCLTV


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AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert! system.


Living cells behave like fluid-filled sponges [ Back to EurekAlert! ] Public release date: 6-Jan-2013
[ | E-mail | Share Share ]

Contact: Clare Ryan
clare.ryan@ucl.ac.uk
44-077-475-65056
University College London

Animal cells behave like fluid-filled sponges in response to being mechanically deformed according to new research published today in Nature Materials.

Scientists from the London Centre for Nanotechnology (LCN) at UCL have shown that animal cells behave according to the theory of 'poroelasticity' when mechanically stimulated in a way similar to that experienced in organs within the body. The results indicate that the rate of cell deformation in response to mechanical stress is limited by how quickly water can redistribute within the cell interior.

Poroelasticity was originally formulated to describe the behaviour of water-saturated soils and has important applications in the fields of rock engineering and petro-physics. It is commonly used in the petroleum industry. Poroelastic models describe cells as being analogous to fluid-filled sponges. Indeed, cells are constituted of a sponge-like porous elastic matrix (comprising the cytoskeleton, organelles, and macromolecules) bathed in an interstitial fluid (the cytosol).

In this analogy, the rate at which the fluid-filled sponge can be deformed is limited by how fast internal water can redistribute within the sponge in response to deformation. This rate is dictated by three parameters: the stiffness of the sponge matrix, the size of the pores within the sponge matrix, and the viscosity of the interstitial fluid.

To study cellular responses, LCN scientists used cell-sized levers to apply rapid well-controlled deformations on the cell surface and monitored the temporal response of cells to these deformations. Close examination of the experimental results revealed that the rate of cellular deformation was limited by how rapidly water could redistribute within the cell interior. Experimental measurements indicated that this sponge-like behaviour of cells likely occurs during normal function of organs such as the lungs and the cardiovascular system.

Emad Moeendarbary, lead author of the paper from the LCN said: "In the cardiovascular system, some tissues encounter extreme mechanical conditions. Heart valves can typically withstand 7-fold increases in their length in less than one second. The poroelastic nature of cells may allow them to behave similarly to shock absorbers when exposed to these extreme mechanical conditions."

To experimentally verify the fluid-filled sponge model, researchers manipulated the size of the cellular pores using chemical and genetic tools and showed that the rate of cellular deformation was affected by the pore size, as suggested by the theory of poroelasticity.

Guillaume Charras, senior co-author of the paper from the LCN said: "Cells can detect the mechanical forces they are subjected to and modify their behaviour accordingly. How changes in the mechanical environment are converted into biochemical information that the cell can interpret remains unknown. A better understanding of the physics of the cellular material is a first step towards formulating possible mechanisms through which this could occur."

###

Notes for Editors

1. For more information, please contact Emad Moeendarbary on tel: +44 (0)20 7679 2923 or +44 (0)1223333762, mobile: +44 07723599221, e-mail: e.moeendarbary@ucl.ac.uk.

2. Alternatively, please contact Clare Ryan in the UCL Media Relations Office on tel: +44 (0)20 3108 3846, mobile: +44 07747 556 056, out of hours +44 (0)7917 271 364, e-mail: clare.ryan@ucl.ac.uk

3. 'They cytoplasm of living cells behaves as a poroelastic model' is published in the journal Nature Materials on 6 January and is embargoed to 18:00 (London time) Journalists can obtain copies of the paper by contacting UCL Media Relations.

4. An image illustrating the experiment can be obtained from the UCL Media Relations Office.

About UCL (University College London)

Founded in 1826, UCL was the first English university established after Oxford and Cambridge, the first to admit students regardless of race, class, religion or gender and the first to provide systematic teaching of law, architecture and medicine.

We are among the world's top universities, as reflected by our performance in a range of international rankings and tables. According to the Thomson Scientific Citation Index, UCL is the second most highly cited European university and the 15th most highly cited in the world.

UCL has nearly 25,000 students from 150 countries and more than 9,000 employees, of whom one third are from outside the UK. The university is based in Bloomsbury in the heart of London, but also has two international campuses UCL Australia and UCL Qatar. Our annual income is more than 800 million.

www.ucl.ac.uk | Follow us on Twitter @uclnews | Watch our YouTube channel YouTube.com/UCLTV


[ Back to EurekAlert! ] [ | E-mail | Share Share ]

?


AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert! system.


Source: http://www.eurekalert.org/pub_releases/2013-01/ucl-lcb010513.php

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