Tamsyn Stanborough1, Fiona M Given1, Barbara Koch2, Campbell R Sheen2, André Buzas Stowers-Hull3, Mark R Waterland3, Deborah L Crittenden1. 1. Biomolecular Interaction Centre and School of Physical and Chemical Sciences, University of Canterbury, Christchurch 8140, New Zealand. 2. Protein Science and Engineering, Callaghan Innovation, Christchurch 8140, New Zealand. 3. MacDiarmid Institute for Advanced Materials and Nanotechnology, Massey University, Palmerston North 4442, New Zealand.
Abstract
The emergence of a new strain of coronavirus in late 2019, SARS-CoV-2, led to a global pandemic in 2020. This may have been preventable if large scale, rapid diagnosis of active cases had been possible, and this has highlighted the need for more effective and efficient ways of detecting and managing viral infections. In this work, we investigate three different optical techniques for quantifying the binding of recombinant SARS-CoV-2 spike protein to surface-immobilized oligonucleotide aptamers. Biolayer interferometry is a relatively cheap, robust, and rapid method that only requires very small sample volumes. However, its detection limit of 250 nM means that it is not sensitive enough to detect antigen proteins at physiologically relevant levels (sub-pM). Surface plasmon resonance is a more sensitive technique but requires larger sample volumes, takes longer, requires more expensive instrumentation, and only reduces the detection limit to 5 nM. Surface-enhanced Raman spectroscopy is far more sensitive, enabling detection of spike protein to sub-picomolar concentrations. Control experiments performed using scrambled aptamers and using bovine serum albumin as an analyte show that this apta-sensing approach is both sensitive and selective, with no appreciable response observed for any controls. Overall, these proof-of-principle results demonstrate that SERS-based aptasensors hold great promise for development into rapid, point-of-use antigen detection systems, enabling mass testing without any need for reagents or laboratory expertise and equipment.
The emergence of a nen class="Chemical">w strain of coronavirus in late 2019, SARS-CoV-2, led to a global pandemic in 2020. This may have been preventable if large scale, rapid diagnosis of active cases had been possible, and this has highlighted the need for more effective and efficient ways of detecting and managing viral infections. In this work, we investigate three different optical techniques for quantifying the binding of recombinant SARS-CoV-2spike protein to surface-immobilized oligonucleotide aptamers. Biolayer interferometry is a relatively cheap, robust, and rapid method that only requires very small sample volumes. However, its detection limit of 250 nMmeans that it is not sensitive enough to detect antigen proteins at physiologically relevant levels (sub-pM). Surface plasmon resonance is a more sensitive technique but requires larger sample volumes, takes longer, requires more expensive instrumentation, and only reduces the detection limit to 5 nM. Surface-enhanced Raman spectroscopy is far more sensitive, enabling detection of spike protein to sub-picomolar concentrations. Control experiments performed using scrambled aptamers and using bovine serum albumin as an analyte show that this apta-sensing approach is both sensitive and selective, with no appreciable response observed for any controls. Overall, these proof-of-principle results demonstrate that SERS-based aptasensors hold great promise for development into rapid, point-of-use antigen detection systems, enabling mass testing without any need for reagents or laboratory expertise and equipment.
Authors: Amber M Paul; Zhen Fan; Sudarson S Sinha; Yongliang Shi; Linda Le; Fengwei Bai; Paresh C Ray Journal: J Phys Chem C Nanomater Interfaces Date: 2015-09-22 Impact factor: 4.126
Authors: Zunlong Ke; Joaquin Oton; Kun Qu; Mirko Cortese; Vojtech Zila; Lesley McKeane; Takanori Nakane; Jasenko Zivanov; Christopher J Neufeldt; Berati Cerikan; John M Lu; Julia Peukes; Xiaoli Xiong; Hans-Georg Kräusslich; Sjors H W Scheres; Ralf Bartenschlager; John A G Briggs Journal: Nature Date: 2020-08-17 Impact factor: 49.962
Authors: Nicholas C Grassly; Margarita Pons-Salort; Edward P K Parker; Peter J White; Neil M Ferguson Journal: Lancet Infect Dis Date: 2020-08-18 Impact factor: 25.071
Authors: Ioanna Smyrlaki; Martin Ekman; Antonio Lentini; Nuno Rufino de Sousa; Natali Papanicolaou; Martin Vondracek; Johan Aarum; Hamzah Safari; Shaman Muradrasoli; Antonio Gigliotti Rothfuchs; Jan Albert; Björn Högberg; Björn Reinius Journal: Nat Commun Date: 2020-09-23 Impact factor: 14.919
Authors: Emilio Gomez-Gonzalez; Alejandro Barriga-Rivera; Beatriz Fernandez-Muñoz; Jose Manuel Navas-Garcia; Isabel Fernandez-Lizaranzu; Francisco Javier Munoz-Gonzalez; Ruben Parrilla-Giraldez; Desiree Requena-Lancharro; Pedro Gil-Gamboa; Cristina Rosell-Valle; Carmen Gomez-Gonzalez; Maria Jose Mayorga-Buiza; Maria Martin-Lopez; Olga Muñoz; Juan Carlos Gomez-Martin; Maria Isabel Relimpio-Lopez; Jesus Aceituno-Castro; Manuel A Perales-Esteve; Antonio Puppo-Moreno; Francisco Jose Garcia-Cozar; Lucia Olvera-Collantes; Raquel Gomez-Diaz; Silvia de Los Santos-Trigo; Monserrat Huguet-Carrasco; Manuel Rey; Emilia Gomez; Rosario Sanchez-Pernaute; Javier Padillo-Ruiz; Javier Marquez-Rivas Journal: Sci Rep Date: 2022-02-18 Impact factor: 4.996
Authors: Elena Zavyalova; Oganes Ambartsumyan; Gleb Zhdanov; Dmitry Gribanyov; Vladimir Gushchin; Artem Tkachuk; Elena Rudakova; Maria Nikiforova; Nadezhda Kuznetsova; Liubov Popova; Bakhtiyar Verdiev; Artem Alatyrev; Elena Burtseva; Anna Ignatieva; Anna Iliukhina; Inna Dolzhikova; Alexander Arutyunyan; Alexandra Gambaryan; Vladimir Kukushkin Journal: Nanomaterials (Basel) Date: 2021-05-25 Impact factor: 5.076
Authors: Nunzio Cennamo; Laura Pasquardini; Francesco Arcadio; Lorenzo Lunelli; Lia Vanzetti; Vincenzo Carafa; Lucia Altucci; Luigi Zeni Journal: Talanta Date: 2021-05-20 Impact factor: 6.057