Toward
Chemotactic Supramolecular Nanoparticles: From
Autonomous Surface Motion Following Specific Chemical Gradients to
Multivalency-Controlled Disassembly
posted on 2021-09-22, 16:10authored byChiara Lionello, Andrea Gardin, Annalisa Cardellini, Davide Bochicchio, Manisha Shivrayan, Ann Fernandez, S. Thayumanavan, Giovanni M. Pavan
Nature designs chemotactic
supramolecular structures that can selectively
bind specific groups present on surfaces, autonomously scan them moving
along density gradients, and react once a critical concentration is
encountered. Since such properties are key in many biological functions,
these also offer inspirations for designing artificial systems capable
of similar bioinspired autonomous behaviors. One approach is to use
soft molecular units that self-assemble in an aqueous solution generating
nanoparticles (NPs) that display specific chemical groups on their
surface, enabling multivalent interactions with complementarily functionalized
surfaces. However, a first challenge is to explore the behavior of
these assemblies at sufficiently high-resolution to gain insights
on the molecular factors controlling their behaviors. Here, by coupling
coarse-grained molecular models and advanced simulation approaches,
we show that it is possible to study the (autonomous or driven) motion
of self-assembled NPs on a receptor-grafted surface at submolecular
resolution. As an example, we focus on self-assembled NPs composed
of facially amphiphilic oligomers. We observe how tuning the multivalent
interactions between the NP and the surface allows to control of the
NP binding, its diffusion along chemical surface gradients, and ultimately,
the NP reactivity at determined surface group densities. In
silico experiments provide physical–chemical insights
on key molecular features in the self-assembling units which determine
the dynamic behavior and fate of the NPs on the surface: from adhesion,
to diffusion, and disassembly. This offers a privileged point of view
into the chemotactic properties of supramolecular assemblies, improving
our knowledge on how to design new types of materials with bioinspired
autonomous behaviors.