Solid-binding peptides: smart tools for nanobiotechnology

Trends in Biotechnology
Andrew CareAnwar Sunna

Abstract

Over the past decade, solid-binding peptides (SBPs) have been used increasingly as molecular building blocks in nanobiotechnology. These peptides show selectivity and bind with high affinity to the surfaces of a diverse range of solid materials including metals, metal oxides, metal compounds, magnetic materials, semiconductors, carbon materials, polymers, and minerals. They can direct the assembly and functionalisation of materials, and have the ability to mediate the synthesis and construction of nanoparticles and complex nanostructures. As the availability of newly synthesised nanomaterials expands rapidly, so too do the potential applications for SBPs.

References

Sep 15, 1992·Proceedings of the National Academy of Sciences of the United States of America·S Brown
Jan 1, 1984·Regulatory Peptides·R W Steigerwalt, J A Williams
Nov 4, 2000·Clinical and Diagnostic Laboratory Immunology·Q HeS J Bell
Mar 6, 2003·Nature Materials·Rajesh R NaikMorley O Stone
Jun 5, 2003·Proceedings of the National Academy of Sciences of the United States of America·Chuanbin MaoAngela M Belcher
Aug 12, 2003·Journal of Nanoscience and Nanotechnology·Rajesh R NaikMorley O Stone
Sep 3, 2003·Nature Materials·Mehmet SarikayaFrançois Baneyx
Nov 20, 2003·Journal of the American Chemical Society·Ken-Ichi Sano, Kiyotaka Shiba
Oct 14, 2004·Journal of the American Chemical Society·Ryan M KramerRajesh R Naik
Apr 14, 2005·Chemical Reviews·J Christopher LoveGeorge M Whitesides
Nov 1, 2005·Biomolecular Engineering·Edward EtesholaStephen Craig Lee
Feb 2, 2006·Journal of the American Chemical Society·Ken-Ichi SanoKiyotaka Shiba
Jun 15, 2006·Nano Letters·Arnaud MagrezLaszló Forró
Jun 21, 2007·Langmuir : the ACS Journal of Surfaces and Colloids·Urartu Ozgur Safak SekerMehmet Sarikaya
Jul 10, 2007·Current Opinion in Biotechnology·François Baneyx, Daniel T Schwartz
Sep 19, 2007·Bioinformatics·Ersin Emre OrenRam Samudrala
Jan 16, 2008·Langmuir : the ACS Journal of Surfaces and Colloids·Atanu SenguptaFrançois Baneyx
Sep 11, 2008·Langmuir : the ACS Journal of Surfaces and Colloids·Chang-Ying XueKun-Lin Yang
Sep 23, 2008·Trends in Biotechnology·Jungbae KimPing Wang
Oct 9, 2008·Langmuir : the ACS Journal of Surfaces and Colloids·Marketa HnilovaMehmet Sarikaya
Oct 29, 2008·The Journal of Biological Chemistry·Hideki WatanabeIzumi Kumagai
Feb 26, 2009·Dalton Transactions : an International Journal of Inorganic Chemistry·Ruimin XingZijian Guo
May 9, 2009·ACS Nano·Dennis B PacardoMarc R Knecht
Jun 16, 2009·Nature Materials·Andre E NelMike Thompson
Dec 17, 2009·Nanotechnology·B ZhengY Uraoka
Jan 22, 2010·Biopolymers·Candan TamerlerMehmet Sarikaya
Jan 26, 2010·Expert Opinion on Drug Delivery·Ndidi NgwulukaDinesh Naidoo
Feb 18, 2010·Chemical Communications : Chem Comm·Shailendra SinghWilfred Chen
Mar 11, 2010·Nanotechnology·Ravit NochomovitzNurit Ashkenasy
Mar 12, 2010·Journal of the American Chemical Society·Weibin ZhouFrançois Baneyx
Jul 6, 2010·Acta Biomaterialia·Dmitriy KhatayevichMehmet Sarikaya
Oct 15, 2010·Nano Letters·Yue CuiMichael C McAlpine
Feb 5, 2011·Langmuir : the ACS Journal of Surfaces and Colloids·Woo-Jae ChungSeung-Wuk Lee
Mar 15, 2011·Trends in Biotechnology·Ying WangYuehe Lin

❮ Previous
Next ❯

Citations

Sep 4, 2015·Analytical and Bioanalytical Chemistry·Ju-Hwan OhJae-Seung Lee
Apr 28, 2016·ACS Applied Materials & Interfaces·Liuen LiangAndrei V Zvyagin
Aug 10, 2016·ACS Central Science·Dominic J Glover, Douglas S Clark
Jun 30, 2016·ACS Applied Materials & Interfaces·Anas M SultanTiffany R Walsh
Jul 19, 2016·ACS Applied Materials & Interfaces·Elaheh Zare-EelanjeghGreta Faccio
May 18, 2016·Experimental Biology and Medicine·Julie N Renner, Shelley D Minteer
Mar 7, 2017·Journal of the American Chemical Society·Brian J F SwiftFrançois Baneyx
May 12, 2017·Nano Convergence·Teruyuki Nagamune
Mar 22, 2016·Chemical Communications : Chem Comm·Seigo SuzukiTakeshi Serizawa
May 14, 2016·Physical Chemistry Chemical Physics : PCCP·Seong-Oh KimNam-Joon Cho
Oct 24, 2018·Chemistry : a European Journal·Mona BauerChristian Limberg
Jul 31, 2019·Macromolecular Bioscience·Lina ApitiusUlrich Schwaneberg
Dec 11, 2019·Biomolecules·Dmitry PolikarpovEvgenii Guryev
Jan 2, 2020·International Journal of Molecular Sciences·Krištof Bozovičar, Tomaž Bratkovič
Apr 8, 2020·Biotechnology and Bioengineering·Adam A CaparcoJulie A Champion
Jul 22, 2015·ChemMedChem·Alberto Bianco, Sylviane Muller
Sep 12, 2019·Scientific Reports·Anna Jancik ProchazkovaAlexander Kovalenko
May 18, 2016·Advanced Materials·Jessica Soto-RodríguezFrançois Baneyx
Jan 1, 2016·Nanomaterials·Jose M Palomo, Marco Filice
Nov 8, 2017·Macromolecular Rapid Communications·Niels Ten BrummelhuisHans G Börner
Apr 11, 2019·Polymers·Kristin RübsamUlrich Schwaneberg
Jun 7, 2016·Journal of Materials Chemistry. B, Materials for Biology and Medicine·Kazutoshi IijimaMineo Hashizume
Oct 25, 2017·Biotechnology and Bioengineering·Kristin RübsamUlrich Schwaneberg
May 21, 2019·Biomimetics·Nora SchönbergerKatrin Pollmann
Dec 24, 2019·Analytical Sciences : the International Journal of the Japan Society for Analytical Chemistry·Yuki TogoSatoru Kawasaki
Apr 14, 2020·Materials Science & Engineering. C, Materials for Biological Applications·Libo ZhangQian Wang
Jan 7, 2021·Biotechnology and Bioengineering·Maximilian NöthUlrich Schwaneberg
Jan 11, 2021·Biochemical and Biophysical Research Communications·Yibing WangPing Wang
Jan 15, 2021·Molecules : a Journal of Synthetic Chemistry and Natural Product Chemistry·Yanan Huang, Alfonso E Garcia-Bennett
May 16, 2020·ACS Chemical Neuroscience·Sameera IqbalNicolle H Packer
Apr 20, 2021·Biomacromolecules·Nicolò AlvisiRenko de Vries
May 1, 2021·Nanoscale·Tyler D JorgensonRené M Overney
May 12, 2021·Bioprocess and Biosystems Engineering·Kasun GodigamuwaSatoru Kawasaki
Jun 13, 2021·The Science of the Total Environment·Zhen FangMattheos A G Koffas
Jul 25, 2021·International Journal of Molecular Sciences·Fabio VianelloMassimiliano Magro

❮ Previous
Next ❯

Related Concepts

Related Feeds

Biosensors for Cancer Detection

Biosensors are devices that are designed to detect a specific biological analyte by essentially converting a biological entity (ie, protein, DNA, RNA) into an electrical signal that can be detected and analyzed. The use of biosensors in cancer detection and monitoring holds vast potential. Biosensors can be designed to detect emerging cancer biomarkers and to determine drug effectiveness at various target sites. Biosensor technology has the potential to provide fast and accurate detection, reliable imaging of cancer cells, and monitoring of angiogenesis and cancer metastasis, and the ability to determine the effectiveness of anticancer chemotherapy agents.