We report that a cell-sized water droplet (CWD) with a diameter of several tens of microns can serve as a micro-biochemical reactor. Since the droplet inner surface is covered by a phospholipid layer, it provides an environment similar to that in living cells. The CWD is manipulated with laser tweezers and we monitor the time-development of biochemical reactions in a single CWD by fusing two droplets which contain a substrate and an enzyme, respectively. As actual examples of enzymatic reactions, we present results on the reaction of calcein with esterase and on the expression reaction of green fluorescent protein
This paper describes the utilization of giant unilamellar vesicles (GUVs) as a platform for handling...
Water-in-oil (w/o) emulsions are used as a cellular model because of their unique cell-like architec...
The young field of microfluidics has been growing due to its utility in chemical and biological appl...
Exploring and understanding how the smallest scale features of a cell affect biochemical reactions h...
In the last two decades, the integration of life science and micro-engineering has developed systems...
Compartmentalization represents a key step in the design and synthesis of artificial cell-like struc...
SummaryWe demonstrate the utility of a microfluidic platform in which water-in-oil droplet compartme...
A simple, rapid, and highly controlled platform to prepare life-inspired subcellular scale compartme...
Natural evolution has chosen the localization of biomolecular processes into crowded sub-cellular fe...
In this study, we introduce an optofluidic method for the rapid construction of large-area cell-size...
Living cells harvest energy from their environments to drive the chemical processes that enable life...
This work proposes the use of charged droplets driven by the Coulombic force as solution-phase react...
Over recent years, there has been a growing interest in the field of artificial cell development, as...
In the field of bottom-up synthetic biology, lipid membranes are the scaffold to create minimal cell...
The formation of lipid-membrane compartments is one of the distinguishing features of eukaryotic cel...
This paper describes the utilization of giant unilamellar vesicles (GUVs) as a platform for handling...
Water-in-oil (w/o) emulsions are used as a cellular model because of their unique cell-like architec...
The young field of microfluidics has been growing due to its utility in chemical and biological appl...
Exploring and understanding how the smallest scale features of a cell affect biochemical reactions h...
In the last two decades, the integration of life science and micro-engineering has developed systems...
Compartmentalization represents a key step in the design and synthesis of artificial cell-like struc...
SummaryWe demonstrate the utility of a microfluidic platform in which water-in-oil droplet compartme...
A simple, rapid, and highly controlled platform to prepare life-inspired subcellular scale compartme...
Natural evolution has chosen the localization of biomolecular processes into crowded sub-cellular fe...
In this study, we introduce an optofluidic method for the rapid construction of large-area cell-size...
Living cells harvest energy from their environments to drive the chemical processes that enable life...
This work proposes the use of charged droplets driven by the Coulombic force as solution-phase react...
Over recent years, there has been a growing interest in the field of artificial cell development, as...
In the field of bottom-up synthetic biology, lipid membranes are the scaffold to create minimal cell...
The formation of lipid-membrane compartments is one of the distinguishing features of eukaryotic cel...
This paper describes the utilization of giant unilamellar vesicles (GUVs) as a platform for handling...
Water-in-oil (w/o) emulsions are used as a cellular model because of their unique cell-like architec...
The young field of microfluidics has been growing due to its utility in chemical and biological appl...
Add to ORKG