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Proteins perform many mechanical functions in a cell. These proteins can be classified into two general categories- proteins that generate mechanical forces and proteins that are subjected to mechanical forces. Proteins providing mechanical support to the structure of the cell, such as keratin, are subjected to mechanical force, whereas proteins involved in cell movement and transport of molecules across cell membranes, such as an ion pump, are examples of generating mechanical force. 
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Cell Squeezing as a Robust, Microfluidic Intracellular Delivery Platform
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Mechanical Interaction between Cells Facilitates Molecular Transport.

David Gomez1, Sari Natan1, Yair Shokef1,2

  • 1School of Mechanical Engineering, Tel Aviv University, Tel Aviv, 69978, Israel.

Advanced Biosystems
|July 11, 2020
PubMed
Summary
This summary is machine-generated.

Cellular forces remodel the extracellular matrix (ECM), enhancing molecular transport. Increased fiber alignment and density transform 3D diffusion into faster 1D transport, revealing a mechano-biochemical feedback loop for cell communication.

Keywords:
cell-cell communicationfibrous extracellular matrixmean first passage timemolecular transporttransport through porous media

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Area of Science:

  • Cell Biology
  • Biophysics
  • Biochemistry

Background:

  • Eukaryotic cells exist within an extracellular matrix (ECM), a fibrous environment crucial for growth and development.
  • The ECM's anisotropic structure influences the diffusion of nanoscale molecules and biochemical signals.
  • Cellular mechanical interactions remodel the ECM, potentially linking biomechanical and biochemical cell communication.

Purpose of the Study:

  • To investigate how cell-induced forces on the ECM affect biochemical transport between distant cells.
  • To explore the impact of ECM remodeling on the speed and efficiency of molecular communication.

Main Methods:

  • Experimental observation of ECM remodeling by cells, noting increased fiber alignment and density.
  • Random walk simulations on a 3D lattice with obstacles mimicking fibrous ECM structures.
  • Measurement of tracer molecule diffusion and mean first-passage time for secreted molecules.

Main Results:

  • Cell-induced ECM remodeling significantly accelerates the transport of molecules between cells.
  • Increased fiber alignment and matrix density reduce transport dimensionality from 3D to 1D.
  • This dimensional reduction leads to a much faster molecular transport process.

Conclusions:

  • Cellular remodeling of the ECM provides a novel mechanism for regulating long-range cell-cell communication.
  • A mechano-biochemical feedback loop is suggested, where mechanical forces influence biochemical signaling.
  • ECM structure plays a critical role in the efficiency of intercellular communication.