Hannebelle Lab – In-vivo-mimetic systems to study the physics of infection

Molecular and physical mechanisms of infection

Infectious disease is often understood through its molecular components: pathogens, host receptors, immune responses, drugs, and vaccines. But infection also depends on physical steps. Pathogens must swim or move, attach to surfaces, withstand flows and forces, cross barriers, and navigate complex tissues.

We study these overlooked physical mechanisms to identify bottlenecks in infection. By understanding how pathogens interact mechanically and dynamically with their environments, we aim to reveal new ways to interfere with infection processes.

In-vivo-mimetic systems

We build experimental systems that reproduce selected features of host environments in the laboratory. These include microfluidic devices, organs-on-a-chip, and tissue-like environments where physical parameters such as flow, confinement, adhesion, and mechanical resistance can be controlled.

These systems allow us to isolate and measure physical processes that are difficult to access in living hosts, while keeping the biological questions closely connected to infection.

Quantitative biophysics of pathogens

The lab uses microscopy, force measurements, modelling, and simulation to quantify how pathogens move and interact with their surroundings. We are interested in processes such as motility, adhesion, collective organization, tissue invasion, and barrier crossing.

Our long-term goal is to understand infection across scales, from the motion and mechanics of individual pathogens to their behavior in host-like environments.

Research vision

By treating infection as both a biological and physical process, we seek to complement existing molecular approaches to infectious disease. Our hope is that uncovering the physics of infection will point to new strategies for prevention, diagnosis, and intervention.

More details about the lab: sites.google.com/scilifelab.se/hannebelle-lab/