Add to ORKGThe ubiquitous random motion of mesoscopic active particles, such as cells, can be "rectified" or directed by embedding the particles in systems containing local and periodic asymmetric cues. Incorporated on lab-on-a-chip devices, these microratchet-like structures can be used to self-propel fluids, transport particles, and direct cell motion in the absence of external power sources. In this Focus article we discuss recent advances in the use of ratchet-like geometries in microfluidics which could open new avenues in biomedicine for applications in diagnosis, cancer biology, and bioengineering
AbstractCell migration is a crucial event during development and in disease. Mechanical constraints ...
Ratchet devices allow turning an ac input signal into a dc output signal. A ratchet device is set by...
Living cells are a fascinating demonstration of nature’s most intricate and well-coordinated microme...
The ubiquitous random motion of mesoscopic active particles, such as cells, can be "rectified" or di...
Cell motility is a process deriving from the synchronized dynamics of the cytoskeleton. In several i...
The transport of objects in microfluidic arrays of obstacles is a surprisingly rich area of physics ...
We present a novel microfabricated concentrator for Escherichia coli that can be a stand-alone and s...
Thermal ratchets can extract useful work from random fluctuations. This is common in the molecular s...
Richard Feynman in his famous address “There’s plenty of room at the bottom” illuminated the potenti...
Resolving the heterogeneity of particle populations by size is important when the particle size is a...
Microfluidics, the manipulation of fluid samples on the order of nanoliters and picoliters, is rapid...
Microfluidic systems are attracting increasing interest for the high-throughput measurement of cellu...
Nanoscale machines which directly convert chemical energy into mechanical work are ubiquitous in nat...
To impart directionality to the motions of a molecular mechanism, one must overcome the random therm...
Cell migration is a crucial event during development and in disease. Mechanical constraints and chem...
AbstractCell migration is a crucial event during development and in disease. Mechanical constraints ...
Ratchet devices allow turning an ac input signal into a dc output signal. A ratchet device is set by...
Living cells are a fascinating demonstration of nature’s most intricate and well-coordinated microme...
The ubiquitous random motion of mesoscopic active particles, such as cells, can be "rectified" or di...
Cell motility is a process deriving from the synchronized dynamics of the cytoskeleton. In several i...
The transport of objects in microfluidic arrays of obstacles is a surprisingly rich area of physics ...
We present a novel microfabricated concentrator for Escherichia coli that can be a stand-alone and s...
Thermal ratchets can extract useful work from random fluctuations. This is common in the molecular s...
Richard Feynman in his famous address “There’s plenty of room at the bottom” illuminated the potenti...
Resolving the heterogeneity of particle populations by size is important when the particle size is a...
Microfluidics, the manipulation of fluid samples on the order of nanoliters and picoliters, is rapid...
Microfluidic systems are attracting increasing interest for the high-throughput measurement of cellu...
Nanoscale machines which directly convert chemical energy into mechanical work are ubiquitous in nat...
To impart directionality to the motions of a molecular mechanism, one must overcome the random therm...
Cell migration is a crucial event during development and in disease. Mechanical constraints and chem...
AbstractCell migration is a crucial event during development and in disease. Mechanical constraints ...
Ratchet devices allow turning an ac input signal into a dc output signal. A ratchet device is set by...
Living cells are a fascinating demonstration of nature’s most intricate and well-coordinated microme...