Lithographic Microneedle-Motors from Multimodal Microfluidics for Cargo Delivery

Micromotors have led to an unprecedented revolution in the field of cargo delivery. Attempts in this area trend toward enriching their structures and improving their functions to promote their further applications. Herein, novel microneedle-motors (MNMs) for active drug delivery through a flexible multimodal microfluidic lithographic approach are presented. The multimodal microfluidics is composed of a co-flow geometry-derived droplet fluid and an active cargo mixed laminar flow in a triangular microchannel. The MNMs with sharp tips and spherical fuel-loading cavities are obtained continuously from microfluidics with the assistance of flow lithography. The structural parameters of the MNMs could be precisely tailored by simply choosing the flow speed or the shape of the photomask. As the actives are mixed into the phase solution during the generation, the resultant MNMs are loaded with cargoes for direct applications without any extra complex operation. Based on these features, it is demonstrated that with sharp tips and autonomous movement, the MNMs can efficiently penetrate the tissue-like substrates, indicating the potential in overcoming physiological barriers for cargo release. These results indicate that the proposed multimodal microfluidic lithographic MNMs are valuable for practical active cargo delivery in biomedical and other relative areas.

Automated summary

Microneedle-motors (MNMs) for active drug delivery are developed using a flexible multimodal microfluidic lithographic approach. The MNMs, with sharp tips and spherical fuel-loading cavities, are continuously obtained from microfluidics with the assistance of flow lithography. The structural parameters of the MNMs can be precisely tailored by adjusting the flow speed or the shape of the photomask. These MNMs demonstrate efficient penetration of tissue-like substrates, indicating their potential in overcoming physiological barriers for cargo release. These findings highlight the value of multimodal microfluidic lithographic MNMs in biomedical and other relevant areas.