As a kind of nanomachine that has great potential for applications in nanoscale sensing and manipulation, nanovehicles with unique shapes and functions have received extensive attention in recent years. Different from the existing common method of using synthetic chemistry to design and manufacture a nanovehicle, here we theoretically report a molecularly assembled DNA-tracked nanovehicle that can move on a solid-state surface using molecular dynamics simulations. A graphene membrane with four nanopores acts as the chassis of the nanoscale vehicle, and two circular ssDNAs across the nanopores serve as the wheels. The electroosmotic flows induced by independently charged nanopores with different surface charge densities under external electric fields were found to be the main power to actuate the controlled rotary motion of circular ssDNAs across every two nanopores. By tuning the rotary speed of each circular ssDNA, the linear and turning movements of the designed nanovehicle were realized. The designed nanovehicle makes it possible to have access to almost everywhere in the human body, which would lead to significant breakthroughs in the fields of nanoscale surgery, drug delivery and so on. The research not only enriches the family of nanorobots, but also opens another way for designing nanovehicles.
Keyphrases
- solid state
- molecular dynamics simulations
- single molecule
- atomic force microscopy
- drug delivery
- endothelial cells
- molecular docking
- coronary artery bypass
- circulating tumor
- acute coronary syndrome
- coronary artery disease
- risk assessment
- induced pluripotent stem cells
- atrial fibrillation
- high resolution
- percutaneous coronary intervention
- surgical site infection
- carbon nanotubes
- pluripotent stem cells
- walled carbon nanotubes