The overarching goal of the Reichhardt Lab is to discover the fundamental biophysical principles of biofilm assembly. Within biofilms, aggregates of microbes are encased in a mesh-like, biopolymer-rich matrix that promotes microbial cell-cell interactions, adherence to host tissues, and protection from antimicrobials. These properties contribute to biofilms causing difficult-to-treat chronic infections.

Despite the importance of the biofilm matrix, we still do not understand how individual matrix components are assembled into a functional architecture. Since this problem spans several scales—multicellular to atomic—new multidisciplinary approaches are required. Therefore, we are developing approaches that integrate microbiological methods with physical chemistry tools including microscopy and solid-state nuclear magnetic resonance (NMR). Overall, our research program aims to provide critical understanding of biofilm assembly, with broader impact on bacterial physiology, materials science, and treatment for chronic infections.


Transmission electron micrograph of a biofilm

Biofilm matrix dynamics

Biological materials—including the biofilm matrix—are dynamic, with properties and functions that change in response to environmental cues. We are applying solid-state NMR and microscopy to explore how biofilm matrix interactions change over the course of the biofilm lifecycle.


Neutrophil extracellular traps (NETs). Photo credit: NIAMS Systemic Autoimmunity Branch, Mariana J. Kaplan

Integration of host material into biofilms

An incredibly important feature of biofilm infections is the host environment. However, in general, only self-produced biofilm matrix has been characterized. We are developing solid-state NMR and microscopy approaches to examine total infection-relevant biofilm composition.


Biofilms in CF lung infections

Material from CF lung infections can be analyzed by solid-state NMR

People with cystic fibrosis (CF) have recurrent lung infections that are thought to be biofilm-involved infections. We are using innovative interdisciplinary approaches to provide critical understanding of biofilm assembly in CF lung infections.