Interplay Between High-Affinity DNA and Carbon Nanotubes

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Interplay Between High-Affinity DNA and Carbon Nanotubes

Context:

  • In a new study, researchers from Pusan National University employed high-throughput screening methods to explore the relationship between DNA sequences and their binding affinity to carbon nanotubes
  • They focused on optimising the binding affinity and stability of these constructs through advanced sequence design and molecular dynamics simulations.

 

Interplay Between High-Affinity DNA and Carbon Nanotubes

 

Single-walled carbon nanotubes (SWCNTs) 

  • They have garnered attention for their exceptional physical and chemical properties, making them promising candidates for applications in biotechnology and nanoelectronics
  • Challenges such as insolubility and toxicity have hindered their widespread use.
  • To address these issues, researchers delved into the interplay between high-affinity DNA and SWCNTs.

 

 

Key Highlights:

  • The researchers focused on improving the stability and safety of SWCNTs by functionalising them with optimal single-stranded DNA (ssDNA) sequences. 
  • They used molecular simulation to validate the binding affinity and machine-learning models to predict how ssDNA interacts with SWCNTs.
  • The rigorous methodology involved iterative rounds of screening a diverse random 30-nucleotide ssDNA library to identify high-affinity sequences. 
  • Computational modelling, particularly molecular dynamics simulations, provided insights into the structural dynamics of the ssDNA-SWCNT complexes
  • The researchers developed a freely accessible online service that predicts the binding affinity of ssDNA sequences to SWCNTs.

 

Study Findings

  • High-affinity 30-nt ssDNA sequences, rich in adenine and cytosine, showed superior binding strength.
  • Stable intramolecular hydrogen bonds formed near the SWCNT surface, enhancing structural integrity.
  • Machine-learning models accurately predicted binding affinities.
  • Improved resistance to enzymatic degradation compared to free ssDNA.

 

 

Applications and Impact:

  • High-affinity ssDNA-SWCNT constructs are suitable for long-term biological applications.
  • Potential applications include cell or tissue-specific drug delivery systems and high-performance nano-electronic devices.

 

Future Prospects:

  • The study advances the understanding of ssDNA and SWCNT interactions and offers practical applications in advanced technologies. 
  • Developing nanomaterials and devices with enhanced stability can drive innovation in nanoelectronics and biotechnology.

 

About Carbon Nanotubes:

 

Interplay Between High-Affinity DNA and Carbon Nanotubes

 

Interplay Between High-Affinity DNA and Carbon Nanotubes

 

  • They are allotropic forms of elemental carbon, consisting of hexagonal sheets of single-layer hybridised carbon atoms rolled up in cylindrical form.
  • A carbon nanotube has a diameter of a few nanometres and a length of several micrometres.
  • Types of Carbon Nanotubes:
    1. Single-Walled Carbon Nanotubes (SWCNTs): They are composed of a single graphene layer rolled into a hollow cylinder. Often referred to as graphene nanotubes (GNTs).
    2. Multi-Walled Carbon Nanotubes (MWCNTs): They consist of multiple layers of graphene rolled into concentric tubes.
  • Properties: High electrical conductivity, Mechanical strength, Stability, Chemical resistance, Thermal conductivity, and Load-bearing capacity.

 

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