Self-propelled catalytic micro- and nanomotors have been the subject of intense study over the past few years, but it remains a continuing challenge to build in an effective speed-regulation mechanism. Movement of these motors is generally fully dependent on the concentration of accessible fuel, with propulsive movement only ceasing when the fuel consumption is complete. Here we report a demonstration of control over the movement of self-assembled stomatocyte nanomotors via a molecularly built, stimulus-responsive regulatory mechanism. A temperature-sensitive polymer brush is chemically grown onto the nanomotor, whereby the opening of the stomatocytes is enlarged or narrowed on temperature change, which thus controls the access of hydrogen peroxide fuel and, in turn, regulates movement. To the best of our knowledge, this represents the first nanosized chemically driven motor for which motion can be reversibly controlled by a thermally responsive valve/brake. We envision that such artificial responsive nanosystems could have potential applications in controllable cargo transportation.
Inspired by highly efficient natural motors, synthetic micro/nanomotors are self-propelled machines capable of converting the supplied fuel into mechanical motion. A significant advance has been made in the construction of diverse motors over the last decade. These synthetic motor systems, with rapid transporting and efficient cargo towing abilities, are expected to open up new horizons for various applications. Utilizing emergent motor platforms for in vivo applications is one important aspect receiving growing interest as conventional therapeutic methodology still remains limited for cancer, heart, or vasculature diseases. In this review we will highlight the recent efforts towards realistic in vivo application of various motor systems. With ever booming research enthusiasm in this field and increasing multidisciplinary cooperation, micro/nanomotors with integrated multifunctionality and selectivity are on their way to revolutionize clinical practice.
We report the self-assembly
of a biodegradable platinum nanoparticle-loaded
stomatocyte nanomotor containing both PEG-b-PCL and
PEG-b-PS as a potential candidate for anticancer
drug delivery. Well-defined stomatocyte structures could be formed
even after incorporation of 50% PEG-b-PCL polymer.
Demixing of the two polymers was expected at high percentage of semicrystalline
poly(ε-caprolactone) (PCL), resulting in PCL domain formation
onto the membrane due to different properties of two polymers. The
biodegradable motor system was further shown to move directionally
with speeds up to 39 μm/s by converting chemical fuel, hydrogen
peroxide, into mechanical motion as well as rapidly delivering the
drug to the targeted cancer cell. Uptake by cancer cells and fast
doxorubicin drug release was demonstrated during the degradation of
the motor system. Such biodegradable nanomotors provide a convenient
and efficient platform for the delivery and controlled release of
therapeutic drugs.
Micro-and nano-motors are a class of miniaturized man-made machines that are able to convert chemical or external energy into mechanical motion. The past decade has witnessed significant progress in the design and fabrication of micro-and nano-motors as a future intelligent and comprehensive biomedical platform. In this review we will critically assess the challenges and limitations of micro-and nanomotors, their mechanism of propulsion and applications in the biomedical field. Important insights into the future development and direction of nano-motors for improved biocompatibility and design will be discussed.
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