Fully Programmable Collective Behavior of Light-Powered Chemical Microrobotics: pH-Dependent Motion Behavior Switch and Controlled Cancer Cell Destruction

Fully Programmable Collective Behavior of Light-Powered Chemical Microrobotics: pH-Dependent Motion Behavior Switch and Controlled Cancer Cell Destruction

Článek WoS

The development of fuel-free light-powered multi stimuli-responsive microrobots is becoming a vital field in biomedical research. The challenge is to design biomedical robots with precise motion control and novel functionalities such that one day they will stand alongside medical staff as fully fledged partners in the delivery of advanced non-invasive therapeutic procedures. In this study, a simple one-step etching/polymerization procedure is used to fabricate crystalline metal-organic framework structures surface-coated with a conductive polypyrrole (PPy) layer and then enriched with Methylene Blue sensitizer molecules. Due to the PPy surface charge, the microrobots start to move when exposed to a visible light source, enabling the controllable accumulation of the microrobots at the focal point of the light beam. Furthermore, a self-regulated motion is achieved by the PPy surface charge also providing a pH-dependent switch capable of altering microrobot behavior. In vitro study is conducted to test microrobot efficiency against human cervix carcinoma HeLa cells. It is shown that the micromotors are able to penetrate and successfully destroy the cancer cells. The work provides proof-of-concept for a novel strategy in which such microrobots can be guided by an optical beam, can self-regulate movement toward or away from each other, and can perform therapeutic functions with great efficiency.

The development of fuel-free light-powered multi stimuli-responsive microrobots is becoming a vital field in biomedical research. The challenge is to design biomedical robots with precise motion control and novel functionalities such that one day they will stand alongside medical staff as fully fledged partners in the delivery of advanced non-invasive therapeutic procedures. In this study, a simple one-step etching/polymerization procedure is used to fabricate crystalline metal-organic framework structures surface-coated with a conductive polypyrrole (PPy) layer and then enriched with Methylene Blue sensitizer molecules. Due to the PPy surface charge, the microrobots start to move when exposed to a visible light source, enabling the controllable accumulation of the microrobots at the focal point of the light beam. Furthermore, a self-regulated motion is achieved by the PPy surface charge also providing a pH-dependent switch capable of altering microrobot behavior. In vitro study is conducted to test microrobot efficiency against human cervix carcinoma HeLa cells. It is shown that the micromotors are able to penetrate and successfully destroy the cancer cells. The work provides proof-of-concept for a novel strategy in which such microrobots can be guided by an optical beam, can self-regulate movement toward or away from each other, and can perform therapeutic functions with great efficiency.

cancer cells; collective behavior; conductive polymers; fuel-free; light-powered; microrobots; switchable properties

cancer cells; collective behavior; conductive polymers; fuel-free; light-powered; microrobots; switchable properties

DĚKANOVSKÝ, L.; YING, Y.; ZELENKA, J.; PLUTNAR, J.; MOHSEN BELADI, M.; KŘÍŽOVÁ, I.; NOVOTNÝ, F.; RUML, T.; PUMERA, M.

2023

01.09.2022

WILEY-V C H VERLAG GMBH

WEINHEIM

1616-301X

ADVANCED FUNCTIONAL MATERIALS

32

38

Spolková republika Německo

2205062-1

2205062-15

15

https://onlinelibrary.wiley.com/doi/10.1002/adfm.202205062