Photo-Attachment of Biomolecules for Miniaturization on Wicking Si-Nanowire Platform
DownloadCheng-2015-Photo-attachment of.pdf (1.469Mb)
PUBLISHER_CC
Publisher with Creative Commons License
Creative Commons Attribution
Terms of use
Metadata
Show full item recordAbstract
We demonstrated the surface functionalization of a highly three-dimensional, superhydrophilic wicking substrate using light to immobilize functional biomolecules for sensor or microarray applications. We showed here that the three-dimensional substrate was compatible with photo-attachment and the performance of functionalization was greatly improved due to both increased surface capacity and reduced substrate reflectivity. In addition, photo-attachment circumvents the problems induced by wicking effect that was typically encountered on superhydrophilic three-dimensional substrates, thus reducing the difficulty of producing miniaturized sites on such substrate. We have investigated various aspects of photo-attachment process on the nanowire substrate, including the role of different buffers, the effect of wavelength as well as how changing probe structure may affect the functionalization process. We demonstrated that substrate fabrication and functionalization can be achieved with processes compatible with microelectronics processes, hence reducing the cost of array fabrication. Such functionalization method coupled with the high capacity surface makes the substrate an ideal candidate for sensor or microarray for sensitive detection of target analytes.
Date issued
2015-02Department
Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science; Massachusetts Institute of Technology. Department of Materials Science and EngineeringJournal
PLOS ONE
Publisher
Public Library of Science
Citation
Cheng, He, Han Zheng, Jia Xin Wu, Wei Xu, Lihan Zhou, Kam Chew Leong, Eugene Fitzgerald, Raj Rajagopalan, Heng Phon Too, and Wee Kiong Choi. “Photo-Attachment of Biomolecules for Miniaturization on Wicking Si-Nanowire Platform.” Edited by Michiya Matsusaki. PLOS ONE 10, no. 2 (February 17, 2015): e0116539.
Version: Final published version
ISSN
1932-6203