Physics of Self-Assembly and Morpho-Topological Changes of Klebsiella Pneumoniae in Desiccating Sessile Droplets

Abstract

We have investigated the flow and desiccation-driven self-assembly of Klebsiella Pneumoniae in the naturally evaporating sessile droplets. Klebsiella Pneumoniae exhibits extensive changes in its morphology and forms unique patterns as the droplet dries, revealing hitherto unexplored rich physics governing its survival and infection strategies. Self-assembly of bacteria at the droplet contact line is characterized by order-to-disorder packing transitions with high packing densities and excessive deformations (bacteria deforms nearly twice its original length scales). In contrast, thin-film instability-led hole formation at the center of the droplet engenders spatial packing of bacteria analogous to honeycomb weathering. The varying physical forces acting on bacteria based on their respective spatial location inside the droplet cause an assorted magnitude of physical stress. Self-assembly favors the bacteria at the rim of the droplet, leading to enhanced viability and pathogenesis on the famously known “coffee ring” of the droplet compared to the bacteria present at the center of the droplet residue. Mechanistic insights gained via our study can have far-reaching implications for bacterial infection through droplets, e.g., through open wounds.