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{{Infobox technology
== DNA Nanotechnology ==
| name = DNA Nanotechnology
| image = File:DNA_tetrahedron_white.png
| caption = A DNA tetrahedron, a basic structure in DNA nanotechnology.
}}


'''DNA nanotechnology''' is a branch of [[nanotechnology]] that uses the unique molecular recognition properties of [[DNA]] and other nucleic acids to create self-assembling structures with a variety of uses. This field exploits the predictable base pairing rules of DNA to design and construct complex, nanoscale architectures.
'''DNA nanotechnology''' is a branch of [[nanotechnology]] that uses the unique molecular recognition properties of [[DNA]] and other [[nucleic acids]] to create self-assembling [[nanostructures]]. This field exploits the predictable base pairing rules of DNA to design and construct complex structures at the nanoscale.


==History==
=== History ===
The concept of DNA nanotechnology was first proposed by [[Nadrian Seeman]] in the early 1980s. Seeman envisioned using DNA to create a lattice that could organize other molecules in a predictable manner. His pioneering work laid the foundation for the development of this field.
The concept of DNA nanotechnology was first introduced by [[Nadrian Seeman]] in the early 1980s. Seeman proposed using DNA to create a lattice for organizing other molecules, which laid the foundation for the development of this field.


==Principles==
=== Principles ===
DNA nanotechnology relies on the specific base pairing of DNA strands, where [[adenine]] pairs with [[thymine]] and [[cytosine]] pairs with [[guanine]]. By designing sequences of DNA, researchers can create strands that will self-assemble into desired structures. These structures can be two-dimensional or three-dimensional, and they can be static or dynamic.
DNA nanotechnology relies on the specific base pairing interactions between [[adenine]] (A) and [[thymine]] (T), and between [[cytosine]] (C) and [[guanine]] (G). These interactions allow for the precise design of DNA strands that can self-assemble into predetermined structures.


===Structural DNA Nanotechnology===
=== Applications ===
Structural DNA nanotechnology focuses on creating stable, static structures. These include:
DNA nanotechnology has a wide range of applications, including:


* '''DNA Lattices''': Arrays of DNA that form a repeating pattern, useful for organizing other molecules.
* **Molecular Computing**: DNA can be used to perform computations by encoding information in the sequence of bases.
* '''DNA Polyhedra''': Three-dimensional shapes such as tetrahedra, cubes, and more complex polyhedra.
* **Drug Delivery**: DNA nanostructures can be designed to carry and release therapeutic agents in a controlled manner.
* **Biosensing**: DNA-based sensors can detect specific molecules or changes in the environment.
* **Structural Biology**: DNA nanostructures can be used to organize proteins and other biomolecules for structural studies.


[[File:Escher_Depth.jpg|thumb|DNA nanostructures can be as intricate as Escher's art.]]
=== Techniques ===
Some of the key techniques used in DNA nanotechnology include:


===Dynamic DNA Nanotechnology===
* **DNA Origami**: A method where a long single strand of DNA is folded into a specific shape with the help of short "staple" strands.
Dynamic DNA nanotechnology involves structures that can change in response to stimuli. This includes:
* **Tile-based Assembly**: Uses small DNA tiles that can self-assemble into larger structures.
* **Hybridization Chain Reaction**: A technique where DNA strands undergo a chain reaction of hybridization to form long chains.


* '''DNA Walkers''': Molecular machines that "walk" along a DNA track.
=== Challenges ===
* '''DNA Origami''': Folding a long single strand of DNA into a desired shape with the help of short "staple" strands.
 
==Applications==
DNA nanotechnology has a wide range of potential applications, including:
 
* '''Medicine''': Targeted drug delivery systems and biosensors.
* '''Materials Science''': Creating new materials with unique properties.
* '''Computing''': DNA-based computation and data storage.
 
==Challenges==
Despite its potential, DNA nanotechnology faces several challenges, such as:
Despite its potential, DNA nanotechnology faces several challenges, such as:


* '''Stability''': Ensuring that DNA structures remain stable under physiological conditions.
* **Stability**: DNA structures can be sensitive to environmental conditions such as temperature and pH.
* '''Scalability''': Producing DNA nanostructures on a large scale.
* **Scalability**: Creating large and complex structures can be difficult and resource-intensive.
* **Cost**: The synthesis of custom DNA sequences can be expensive.


==Also see==
=== Future Directions ===
* [[Nanotechnology]]
Research in DNA nanotechnology is ongoing, with efforts focused on improving the stability and scalability of DNA structures, as well as expanding their applications in medicine and materials science.
* [[Molecular self-assembly]]
* [[DNA computing]]
* [[Synthetic biology]]


==References==
== References ==
* Seeman, N. C. (1982). "Nucleic acid junctions and lattices." Journal of Theoretical Biology, 99(2), 237-247.
<references/>
* Rothemund, P. W. K. (2006). "Folding DNA to create nanoscale shapes and patterns." Nature, 440(7082), 297-302.


==External links==
== External Links ==
* [https://www.dna-nanotech.org DNA Nanotechnology Research]
* [DNA Nanotechnology at Wikipedia](https://en.wikipedia.org/wiki/DNA_nanotechnology)
* [Nadrian Seeman's Research Group](http://seemanlab4.chem.nyu.edu/)


{{Nanotechnology}}
{{Nanotechnology}}
{{Molecular biology}}
{{Molecular Biology}}


[[Category:Nanotechnology]]
[[Category:Nanotechnology]]
[[Category:Molecular biology]]
[[Category:Molecular Biology]]
[[Category:DNA]]
[[Category:DNA]]
[[Category:Emerging Technologies]]
<gallery>
File:DNA tetrahedron white.png|DNA tetrahedron white
File:Escher Depth.jpg|Escher Depth
File:Неподвижная структура Холлидея (англ.).svg|Неподвижная структура Холлидея (англ.)
File:Holliday junction coloured.png|Holliday junction coloured
File:Mao-DX-schematic-2.svg|Mao-DX schematic 2
File:Mao-DXarray-schematic-small.gif|Mao-DXarray schematic small
File:DX DNA array.png|DX DNA array
File:DNA nanostructures.png|DNA nanostructures
File:SierpinskiTriangle.svg|Sierpinski Triangle
File:Rothemund-DNA-SierpinskiGasket.jpg|Rothemund DNA Sierpinski Gasket
</gallery>

Latest revision as of 06:15, 3 March 2025

DNA Nanotechnology[edit]

DNA nanotechnology is a branch of nanotechnology that uses the unique molecular recognition properties of DNA and other nucleic acids to create self-assembling nanostructures. This field exploits the predictable base pairing rules of DNA to design and construct complex structures at the nanoscale.

History[edit]

The concept of DNA nanotechnology was first introduced by Nadrian Seeman in the early 1980s. Seeman proposed using DNA to create a lattice for organizing other molecules, which laid the foundation for the development of this field.

Principles[edit]

DNA nanotechnology relies on the specific base pairing interactions between adenine (A) and thymine (T), and between cytosine (C) and guanine (G). These interactions allow for the precise design of DNA strands that can self-assemble into predetermined structures.

Applications[edit]

DNA nanotechnology has a wide range of applications, including:

  • **Molecular Computing**: DNA can be used to perform computations by encoding information in the sequence of bases.
  • **Drug Delivery**: DNA nanostructures can be designed to carry and release therapeutic agents in a controlled manner.
  • **Biosensing**: DNA-based sensors can detect specific molecules or changes in the environment.
  • **Structural Biology**: DNA nanostructures can be used to organize proteins and other biomolecules for structural studies.

Techniques[edit]

Some of the key techniques used in DNA nanotechnology include:

  • **DNA Origami**: A method where a long single strand of DNA is folded into a specific shape with the help of short "staple" strands.
  • **Tile-based Assembly**: Uses small DNA tiles that can self-assemble into larger structures.
  • **Hybridization Chain Reaction**: A technique where DNA strands undergo a chain reaction of hybridization to form long chains.

Challenges[edit]

Despite its potential, DNA nanotechnology faces several challenges, such as:

  • **Stability**: DNA structures can be sensitive to environmental conditions such as temperature and pH.
  • **Scalability**: Creating large and complex structures can be difficult and resource-intensive.
  • **Cost**: The synthesis of custom DNA sequences can be expensive.

Future Directions[edit]

Research in DNA nanotechnology is ongoing, with efforts focused on improving the stability and scalability of DNA structures, as well as expanding their applications in medicine and materials science.

References[edit]

<references/>

External Links[edit]

Molecular biology
Overview
Engineering
  • DNA tetrahedron white
    DNA tetrahedron white
  • Escher Depth
    Escher Depth
  • Неподвижная структура Холлидея (англ.)
    Неподвижная структура Холлидея (англ.)
  • Holliday junction coloured
    Holliday junction coloured
  • Mao-DX schematic 2
    Mao-DX schematic 2
  • Mao-DXarray schematic small
    Mao-DXarray schematic small
  • DX DNA array
    DX DNA array
  • DNA nanostructures
    DNA nanostructures
  • Sierpinski Triangle
    Sierpinski Triangle
  • Rothemund DNA Sierpinski Gasket
    Rothemund DNA Sierpinski Gasket
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