4 results found
    1. Physics of Living Systems

    Developmental adaptations of trypanosome motility to the tsetse fly host environments unravel a multifaceted in vivo microswimmer system

    Sarah Schuster et al.
    Trypanosome development within the transmitting tsetse fly reveals essential adaptations of microbial motility to diverse physical microenvironments.
    1. Physics of Living Systems

    High-speed motility originates from cooperatively pushing and pulling flagella bundles in bilophotrichous bacteria

    Klaas Bente et al.
    Bacteria reach swimming speeds of several hundred body lengths per second and change direction in less than 5 ms by using coordinated flagella bundle agitation.
    1. Physics of Living Systems

    Confinement discerns swarmers from planktonic bacteria

    Weijie Chen et al.
    For the same bacterial strain, the swarming phenotype can be biophysically discerned from swimming phenotype based on the motion pattern under circular confinement on a soft agar.
    1. Physics of Living Systems

    Swarming bacteria undergo localized dynamic phase transition to form stress-induced biofilms

    Iago Grobas et al.
    Collective stress response via localized dynamic phase transition turns swarming Bacillus subtilis into biofilms.

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