Bacteria occupy heterogeneous environments, attaching and growing within pores in materials, living hosts, and matrices like soil. Systems that permit high-resolution visualization of dynamic bacterial processes within the physical confines of a realistic and tractable porous media environment are rare. Here we use microfluidics to replicate the grain shape and packing density of natural sands in a 2D platform to study the flow-induced spatial evolution of bacterial biofilms underground. We discover that initial bacterial dispersal and grain attachment is influenced by bacterial transport across pore space velocity gradients, a phenomenon otherwise known as rheotaxis. We find that gravity-driven flow conditions activate different bacterial ...
Bacterial communities attached to surfaces under fluid flow represent a widespread lifestyle of the ...
Bacteria colonize environments that contain networks of moving fluids, including digestive pathways,...
Biofilms are microbial collectives that occupy a diverse array of surfaces. It is well known that th...
Bacteria in porous media, such as soils, aquifers, and filters, often form surface-attached communit...
International audienceMicrobes often live in dense communities called biofilms, where competition be...
Microbes often live in dense communities called biofilms where competition between strains and speci...
Microbial life in porous systems dominates the functioning of numerous ecosystems, ranging from stre...
Bacteria often live in biofilms, which are microbial communities surrounded by a secreted extracellu...
The majority of bacteria in nature live in biofilms, where they are encased by extracellular polymer...
© 2019 American Physical Society. Bacterial biofilms represent a major form of microbial life on Ear...
Microorganisms navigate and divide on surfaces to form multicellular structures called biofilms, the...
Biofilms are antibiotic-resistant, sessile bacterial communities that occupy most moist surfaces on ...
When bacteria attach to a surface and start growing into assemblies, they excrete a slimy layer know...
Biofilms are antibiotic-resistant, sessile bacterial communities that occupy most moist surfaces on ...
International audienceBacterial communities attached to surfaces under fluid flow represent a widesp...
Bacterial communities attached to surfaces under fluid flow represent a widespread lifestyle of the ...
Bacteria colonize environments that contain networks of moving fluids, including digestive pathways,...
Biofilms are microbial collectives that occupy a diverse array of surfaces. It is well known that th...
Bacteria in porous media, such as soils, aquifers, and filters, often form surface-attached communit...
International audienceMicrobes often live in dense communities called biofilms, where competition be...
Microbes often live in dense communities called biofilms where competition between strains and speci...
Microbial life in porous systems dominates the functioning of numerous ecosystems, ranging from stre...
Bacteria often live in biofilms, which are microbial communities surrounded by a secreted extracellu...
The majority of bacteria in nature live in biofilms, where they are encased by extracellular polymer...
© 2019 American Physical Society. Bacterial biofilms represent a major form of microbial life on Ear...
Microorganisms navigate and divide on surfaces to form multicellular structures called biofilms, the...
Biofilms are antibiotic-resistant, sessile bacterial communities that occupy most moist surfaces on ...
When bacteria attach to a surface and start growing into assemblies, they excrete a slimy layer know...
Biofilms are antibiotic-resistant, sessile bacterial communities that occupy most moist surfaces on ...
International audienceBacterial communities attached to surfaces under fluid flow represent a widesp...
Bacterial communities attached to surfaces under fluid flow represent a widespread lifestyle of the ...
Bacteria colonize environments that contain networks of moving fluids, including digestive pathways,...
Biofilms are microbial collectives that occupy a diverse array of surfaces. It is well known that th...