Difference between revisions of "Mechanical Properties of Xenopus Egg Cytoplasmic Extracts"

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In Progress...
 
In Progress...
 
[[Image:Xenopusfig1.png|thumb|300px| Figure 1, taken from [1].]]
 
[[Image:Xenopusfig1.png|thumb|300px| Figure 1, taken from [1].]]
[[Image:Xenopusfig2.png|thumb|300px| Figure 2, taken from [1].]]
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[[Image:Xenopusfig3.png|thumb|300px| Figure 2, taken from [1].]]
[[Image:Xenopusfig3.png|thumb|300px| Figure 3, taken from [1].]]
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[[Image:Xenopusfig4.png|thumb|300px| Figure 3, taken from [1].]]
[[Image:Xenopusfig4.png|thumb|300px| Figure 4, taken from [1].]]
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==General Information==
 
==General Information==
 
'''Authors''': M. T. Valentine, Z. E. Perlman, T. J. Mitchison, and D. A. Weitz
 
'''Authors''': M. T. Valentine, Z. E. Perlman, T. J. Mitchison, and D. A. Weitz
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==Summary==
 
==Summary==
 
This paper deals with the mechanical properties of cytoplasmic extracts from Xenopus laevis (African tree from). Xenopus extract is a common system because it's relatively easy to crush the eggs and extract the cytoplasm and each egg contains everything needed for ~30 divisions. Because of how well used this system is, it's interesting to consider the mechanical properties. This egg extract is used as an example system to try to study cytoplasm mechanics in general. In the paper, conventional macroscopic rheological measurements are made as well as microscopic microrheological measurements.  
 
This paper deals with the mechanical properties of cytoplasmic extracts from Xenopus laevis (African tree from). Xenopus extract is a common system because it's relatively easy to crush the eggs and extract the cytoplasm and each egg contains everything needed for ~30 divisions. Because of how well used this system is, it's interesting to consider the mechanical properties. This egg extract is used as an example system to try to study cytoplasm mechanics in general. In the paper, conventional macroscopic rheological measurements are made as well as microscopic microrheological measurements.  
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Figure 1 shows results for the time evolution of the elastic moduli (top panel) and the viscous moduli (lower panel) obtained using a conventional strain controlled rheometer. Each of the curves shown represents a separate measurement and it is evident that there is substantial variation. The common theme between all of the runs is that the extract forms a gel that acts like a soft solid (G''/G' ~ 0.3-0.5)
 
==Discussion==
 
==Discussion==
  
 
==References==
 
==References==
 
[1]Perlman et al. Mechanical properties of Xenopus egg cytoplasmic extracts. Biophysical journal (2005))
 
[1]Perlman et al. Mechanical properties of Xenopus egg cytoplasmic extracts. Biophysical journal (2005))

Revision as of 20:42, 25 November 2011

Original Entry: Peter Foster, AP 225, Fall 2011 In Progress...

Figure 1, taken from [1].
Figure 2, taken from [1].
Figure 3, taken from [1].

General Information

Authors: M. T. Valentine, Z. E. Perlman, T. J. Mitchison, and D. A. Weitz

Publication:Perlman et al. Mechanical properties of Xenopus egg cytoplasmic extracts. Biophysical journal (2005)

Summary

This paper deals with the mechanical properties of cytoplasmic extracts from Xenopus laevis (African tree from). Xenopus extract is a common system because it's relatively easy to crush the eggs and extract the cytoplasm and each egg contains everything needed for ~30 divisions. Because of how well used this system is, it's interesting to consider the mechanical properties. This egg extract is used as an example system to try to study cytoplasm mechanics in general. In the paper, conventional macroscopic rheological measurements are made as well as microscopic microrheological measurements.


Figure 1 shows results for the time evolution of the elastic moduli (top panel) and the viscous moduli (lower panel) obtained using a conventional strain controlled rheometer. Each of the curves shown represents a separate measurement and it is evident that there is substantial variation. The common theme between all of the runs is that the extract forms a gel that acts like a soft solid (G/G' ~ 0.3-0.5)

Discussion

References

[1]Perlman et al. Mechanical properties of Xenopus egg cytoplasmic extracts. Biophysical journal (2005))