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Tumble-proof cargo transporter in biological cells

New model shows how collective transport by synthetic nanomotors along biopolymer filaments can be effectively directed

Date:
April 12, 2016
Source:
Springer
Summary:
Ever wondered how molecular nanomotors work when transporting material such as organelles in the cell? Typically, nanomotors move along biopolymer filaments to go about their duties in the cell. Researchers now show that synthetic motors can attach to polymeric filaments and move along without changing either their shape or the direction in which they set out to move.
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Ever wondered how a molecular nanomotor works when repairing DNA or transporting material such as organelles in the cell? Typically, nanomotors move along biopolymer filaments to go about their duties in the cell. To do so, they use the energy of chemical reactions derived from their surroundings to propel themselves. In a new study published in EPJ E, Mu-Jie Huang and Raymond Kapral from the University of Toronto in Ontario, Canada show that small synthetic motors can attach to polymeric filaments and -- unlike what previous studies showed -- move along without changing either their shape or the direction in which they set out to move. This makes it possible to effectively deliver the substances they transport, such as anti-cancer drugs or anti-pollutants.

The team has designed these nanomotors to move using the spatial variations of the concentrations of chemical species that they produce themselves by means of chemical reactions on their surfaces. The main improvement brought by this study's findings is that even very small synthetic motors -- possibly on the molecular scale of Angstroms, one ten-billionth of a meter -- can operate efficiently without suffering from rapid tumbling and loss of initial direction.

The authors studied the motions of these nanomotors on a filament surrounded by solvent by creating a coarse-grained level biomimetic model featuring all chemical species as particles -- namely, solvent molecules, the molecular building blocks of the filament and the motors themselves. The advantage: this approach accounts for disturbances stemming from the random motions of the solvent molecules and for macroscopic solvent fluid flows accompanying the motor motion.

They found that the local concentration of catalytic product helping fuel their movement leads to a reversal of the direction of the collective movement of nanomotors, provided that they are in high enough concentration. The work promises to stimulate further research on directed cargo transport.


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Journal Reference:

  1. Mu-Jie Huang, Raymond Kapral. Collective dynamics of diffusiophoretic motors on a filament. The European Physical Journal E, 2016; 39 (3) DOI: 10.1140/epje/i2016-16036-3

Cite This Page:

Springer. "Tumble-proof cargo transporter in biological cells: New model shows how collective transport by synthetic nanomotors along biopolymer filaments can be effectively directed." ScienceDaily. ScienceDaily, 12 April 2016. <www.sciencedaily.com/releases/2016/04/160412104812.htm>.
Springer. (2016, April 12). Tumble-proof cargo transporter in biological cells: New model shows how collective transport by synthetic nanomotors along biopolymer filaments can be effectively directed. ScienceDaily. Retrieved May 23, 2017 from www.sciencedaily.com/releases/2016/04/160412104812.htm
Springer. "Tumble-proof cargo transporter in biological cells: New model shows how collective transport by synthetic nanomotors along biopolymer filaments can be effectively directed." ScienceDaily. www.sciencedaily.com/releases/2016/04/160412104812.htm (accessed May 23, 2017).

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