A number of exciting new laboratory techniques have been developed using the Watson-Crick complementarity properties of DNA strands to achieve the self-assembly of graphical complexes. For all of these methods, an essential step in building the self-assembling nanostructure is designing the component molecular building blocks. These design strategy problems fall naturally into the realm of graph theory. We describe graph theoretical formalism for various construction methods, and then suggest several graph theory exercises to introduce this application into a standard undergraduate graph theory class. This application provides a natural framework for motivating central concepts such as degree sequence, Eulerian graphs, Fleury’s algorithm, t...
We analyze a self-assembly model of flexible DNA tiles and develop a theoretical description of poss...
DNA self-assembly technology has brought novel inspirations to the development of DNA computing Dive...
Abstract Self-assembly is the spontaneous self-ordering of substructures into superstructures driven...
Motivated by the recent advancements in nanotechnology and the discovery of new laboratory technique...
DNA sequences can be analyzed using graph theory to improve efficiency in new fields such as biotech...
Application of graph theory to the well-known complementary properties of DNA strands has resulted i...
The properties of DNA make it a useful tool for designing self-assembling nanostructures. Branched j...
Laboratory techniques have been developed using the Watson- Crick complementary properties of DNA st...
Deoxyribonucleic acids (DNA), Ribonucleic acids (RNA) and Proteins are the computational devices of ...
Self-assembly is the process of a collection of components combining to form an organized structure ...
Emerging laboratory techniques have been developed using the Watson-Crick complementarity properties...
This paper outlines a mathematics course centered around the interdisciplinary topic of modeling sel...
DNA fragment assembly requirements have generated an important computational problem created by thei...
This project deals with the graph theory topic of taking apart graphs and reassembling them. A graph...
Abstract. While the topic of Molecular Computation would have ap-peared even a half dozen years ago ...
We analyze a self-assembly model of flexible DNA tiles and develop a theoretical description of poss...
DNA self-assembly technology has brought novel inspirations to the development of DNA computing Dive...
Abstract Self-assembly is the spontaneous self-ordering of substructures into superstructures driven...
Motivated by the recent advancements in nanotechnology and the discovery of new laboratory technique...
DNA sequences can be analyzed using graph theory to improve efficiency in new fields such as biotech...
Application of graph theory to the well-known complementary properties of DNA strands has resulted i...
The properties of DNA make it a useful tool for designing self-assembling nanostructures. Branched j...
Laboratory techniques have been developed using the Watson- Crick complementary properties of DNA st...
Deoxyribonucleic acids (DNA), Ribonucleic acids (RNA) and Proteins are the computational devices of ...
Self-assembly is the process of a collection of components combining to form an organized structure ...
Emerging laboratory techniques have been developed using the Watson-Crick complementarity properties...
This paper outlines a mathematics course centered around the interdisciplinary topic of modeling sel...
DNA fragment assembly requirements have generated an important computational problem created by thei...
This project deals with the graph theory topic of taking apart graphs and reassembling them. A graph...
Abstract. While the topic of Molecular Computation would have ap-peared even a half dozen years ago ...
We analyze a self-assembly model of flexible DNA tiles and develop a theoretical description of poss...
DNA self-assembly technology has brought novel inspirations to the development of DNA computing Dive...
Abstract Self-assembly is the spontaneous self-ordering of substructures into superstructures driven...