AbstractThrough self-assembly of branched junction molecules many different DNA structures (graphs) can be assembled. We show that every multigraph can be assembled by DNA such that there is a single strand that traces each edge in the graph at least once. This strand corresponds to a boundary component of a two-dimensional orientable surface that has the given graph as a deformation retract. This boundary component traverses every edge at least once, and it defines a circular path in the graph that “preserves the graph structure” and traverses each edge
DNA sequences can be analyzed using graph theory to improve efficiency in new fields such as biotech...
Designing self-assembling DNA nanostructures often requires the identification of a route for a scaf...
The predictability of DNA self-assembly is exploited in many nanotechnological approaches. Inspired ...
AbstractThrough self-assembly of branched junction molecules many different DNA structures (graphs) ...
Laboratory techniques have been developed using the Watson- Crick complementary properties of DNA st...
Application of graph theory to the well-known complementary properties of DNA strands has resulted i...
Emerging laboratory techniques have been developed using the Watson-Crick complementarity properties...
Motivated by the recent advancements in nanotechnology and the discovery of new laboratory technique...
DNA fragment assembly requirements have generated an important computational problem created by thei...
A number of exciting new laboratory techniques have been developed using the Watson-Crick complement...
We analyze a self-assembly model of flexible DNA tiles and develop a theoretical description of poss...
Motivated by genome rearrangements that take place in some species of ciliates we introduce a combin...
Self-assembly is the process of a collection of components combining to form an organized structure ...
Starting from a set of strands (or other types of building blocks) a variant of forbidding-enforcing...
The properties of DNA make it a useful tool for designing self-assembling nanostructures. Branched j...
DNA sequences can be analyzed using graph theory to improve efficiency in new fields such as biotech...
Designing self-assembling DNA nanostructures often requires the identification of a route for a scaf...
The predictability of DNA self-assembly is exploited in many nanotechnological approaches. Inspired ...
AbstractThrough self-assembly of branched junction molecules many different DNA structures (graphs) ...
Laboratory techniques have been developed using the Watson- Crick complementary properties of DNA st...
Application of graph theory to the well-known complementary properties of DNA strands has resulted i...
Emerging laboratory techniques have been developed using the Watson-Crick complementarity properties...
Motivated by the recent advancements in nanotechnology and the discovery of new laboratory technique...
DNA fragment assembly requirements have generated an important computational problem created by thei...
A number of exciting new laboratory techniques have been developed using the Watson-Crick complement...
We analyze a self-assembly model of flexible DNA tiles and develop a theoretical description of poss...
Motivated by genome rearrangements that take place in some species of ciliates we introduce a combin...
Self-assembly is the process of a collection of components combining to form an organized structure ...
Starting from a set of strands (or other types of building blocks) a variant of forbidding-enforcing...
The properties of DNA make it a useful tool for designing self-assembling nanostructures. Branched j...
DNA sequences can be analyzed using graph theory to improve efficiency in new fields such as biotech...
Designing self-assembling DNA nanostructures often requires the identification of a route for a scaf...
The predictability of DNA self-assembly is exploited in many nanotechnological approaches. Inspired ...