DNA-bare Gold Affinity Interactions: Mechanism and Applications in Biosensing
Author(s)
Koo, Kevin M
Sina, Abu AI
Carrascosa, Laura G
Shiddiky, Muhammad JA
Trau, Matt
Griffith University Author(s)
Year published
2015
Metadata
Show full item recordAbstract
The adsorption of DNA onto gold due to affinity interactions is highly desirable for developing low-cost, convenient and sensitive biosensors. To date, DNA–gold adsorption phenomenon has been demonstrated as one of the most promising physical mechanisms for achieving precise control over unmodified gold nanoparticles (AuNPs) aggregation, and DNA monolayer formation on gold surfaces. The adsorption phenomenon is exquisitely controlled by many factors including intermolecular forces, along with DNA composition and sequence. The understanding and manipulation of these factors have allowed broad biosensing applications and ...
View more >The adsorption of DNA onto gold due to affinity interactions is highly desirable for developing low-cost, convenient and sensitive biosensors. To date, DNA–gold adsorption phenomenon has been demonstrated as one of the most promising physical mechanisms for achieving precise control over unmodified gold nanoparticles (AuNPs) aggregation, and DNA monolayer formation on gold surfaces. The adsorption phenomenon is exquisitely controlled by many factors including intermolecular forces, along with DNA composition and sequence. The understanding and manipulation of these factors have allowed broad biosensing applications and notably, sequence-dependent DNA–gold adsorption which may be highly relevant for DNA methylation detection in cancer. Herein, we review the underlying principles governing DNA–gold adsorption as well as recent biosensing strategies based on differential ssDNA/dsDNA–AuNPs adsorption and sequence-dependent DNA–gold adsorption. Finally, we have also contributed insights regarding the future trend of DNA–gold adsorption-based biosensors.
View less >
View more >The adsorption of DNA onto gold due to affinity interactions is highly desirable for developing low-cost, convenient and sensitive biosensors. To date, DNA–gold adsorption phenomenon has been demonstrated as one of the most promising physical mechanisms for achieving precise control over unmodified gold nanoparticles (AuNPs) aggregation, and DNA monolayer formation on gold surfaces. The adsorption phenomenon is exquisitely controlled by many factors including intermolecular forces, along with DNA composition and sequence. The understanding and manipulation of these factors have allowed broad biosensing applications and notably, sequence-dependent DNA–gold adsorption which may be highly relevant for DNA methylation detection in cancer. Herein, we review the underlying principles governing DNA–gold adsorption as well as recent biosensing strategies based on differential ssDNA/dsDNA–AuNPs adsorption and sequence-dependent DNA–gold adsorption. Finally, we have also contributed insights regarding the future trend of DNA–gold adsorption-based biosensors.
View less >
Journal Title
Analytical Methods
Volume
7
Issue
17
Subject
Analytical chemistry
Analytical chemistry not elsewhere classified
Other chemical sciences