Add to ORKGMicrobes self-organize in microcolonies while transitioning to a sessile form within a protective biofilm matrix. To enable the detailed study of microbial dynamics within these microcolonies, new sessile culture systems are needed that sequester cells and mimic their complex growth conditions and interactions. We present a new nanoliter-scale sessile culture system that is easily implemented via microfluidics-enabled fabrication. Hundreds of thousands of these nanocultures can be easily generated and imaged using conventional or confocal microscopy. Each nanoculture begins as a several nanoliter droplet of suspended cells, encapsulated by a polydimethylsiloxane (PDMS) membrane. The PDMS shell provides long-lasting mechanical support, enabl...
Traditionally regarded as single cell organisms, bacteria naturally and preferentially build multice...
How microbial cell walls are spatially organized and how they interact with their environment are im...
Burmeister A, Grünberger A. Microfluidic cultivation and analysis tools for interaction studies of m...
While new techniques and platforms have advanced rapidly to enhance our understanding of complex mic...
Interspecies interactions inside microbial communities bear a tremendous diversity of complex chemic...
Bacteria have evolved as intelligent microorganisms that can colonize and form highly structured and...
Controlled patterning of microorganisms into defined spatial arrangements offers unique possibilitie...
Nanofabricated structures and microfluidic technologies are increasingly being used to study bacteri...
The human microbiome comprises a plethora of interacting bacteria. The composition of the microbiome...
Microfluidics has significantly contributed to the expansion of the frontiers of microbial ecology o...
Biofilms are arguably the most important mode of growth of bacteria, but how antibiotic resistance e...
Bacteria have evolved as intelligent microorganisms that can colonize and form highly structured and...
Nutrient limitation is one of the most common triggers of antibiotic tolerance and persistence. Here...
Microfluidic technologies have allowed modern microbiologists the opportunity to explore biological ...
We describe a novel microfluldic perfusion system for high-resolution microscopes. Its modular desig...
Traditionally regarded as single cell organisms, bacteria naturally and preferentially build multice...
How microbial cell walls are spatially organized and how they interact with their environment are im...
Burmeister A, Grünberger A. Microfluidic cultivation and analysis tools for interaction studies of m...
While new techniques and platforms have advanced rapidly to enhance our understanding of complex mic...
Interspecies interactions inside microbial communities bear a tremendous diversity of complex chemic...
Bacteria have evolved as intelligent microorganisms that can colonize and form highly structured and...
Controlled patterning of microorganisms into defined spatial arrangements offers unique possibilitie...
Nanofabricated structures and microfluidic technologies are increasingly being used to study bacteri...
The human microbiome comprises a plethora of interacting bacteria. The composition of the microbiome...
Microfluidics has significantly contributed to the expansion of the frontiers of microbial ecology o...
Biofilms are arguably the most important mode of growth of bacteria, but how antibiotic resistance e...
Bacteria have evolved as intelligent microorganisms that can colonize and form highly structured and...
Nutrient limitation is one of the most common triggers of antibiotic tolerance and persistence. Here...
Microfluidic technologies have allowed modern microbiologists the opportunity to explore biological ...
We describe a novel microfluldic perfusion system for high-resolution microscopes. Its modular desig...
Traditionally regarded as single cell organisms, bacteria naturally and preferentially build multice...
How microbial cell walls are spatially organized and how they interact with their environment are im...
Burmeister A, Grünberger A. Microfluidic cultivation and analysis tools for interaction studies of m...