Precise building of multifunctional nano/microarchitectures
holds
exciting prospects in various biomedical applications such as drug
delivery, biosensing, and disease diagnosis. However, the reported
architectures still face great challenges when implemented in vivo
due to insufficient biocompatibility, inevitable invasiveness, low
stability, and difficulty for reconfiguration. Here, we report an
optically reconfigurable platelet architecture through an organic
integration of programmable optical manipulation and intravital platelets,
functioning as highly skilled mason and endogenous biological blocks,
respectively. By programming the optical force landscape in real time,
multiple platelets can be stably trapped and then precisely arranged
into a designed pattern, followed by spontaneous binding through the
robust interaction between membrane protein and ligands, thus achieving
a stable biological architecture with a high navigation flexibility.
More importantly, they can be sculptured in a dynamically reconfigurable
manner, with the aim to execute multifunctional biomedical tasks,
including the active circumventions across the obstacles, precise
vessel labeling, blood flow switching, and targeted cargo delivery.
The reported platelet architecture might serve as a smart biomedical
platform for constructing multifunctional cellular micromachines,
with great promises for the desired biomanufacturing, targeted drug
delivery, and immune therapy.