A stable physisorbed layer of packed capture antibodies for high-performance sensing applications

• Published in: Journal of materials chemistry. C, Materials for optical and electronic devices Vol. 11; no. 27; pp. 993 - 916
• Main Authors: Sarcina, Lucia, Scandurra, Cecilia, Di Franco, Cinzia, Caputo, Mariapia, Catacchio, Michele, Bollella, Paolo, Scamarcio, Gaetano, Macchia, Eleonora, Torsi, Luisa
• Format: Journal Article
• Language: English
• Published: England Royal Society of Chemistry 13.07.2023; The Royal Society of Chemistry
• Subjects: Antibodies; Bilayers; Biomedical materials; Biosensors; Chemical bonds; Chemistry; Gold; Homogeneity; Investigations; Ions; Proteins; Stability analysis; Surface plasmon resonance
• ISSN: 2050-7526; 2050-7534
• DOI: 10.1039/d3tc01123b

Antibody physisorption at a solid interface is a very interesting phenomenon that has important effects on applications such as the development of novel biomaterials and the rational design and fabrication of high-performance biosensors. The strategy selected to immobilize biorecognition elements can determine the performance level of a device and one of the simplest approaches is physical adsorption, which is cost-effective, fast, and compatible with printing techniques as well as with green-chemistry processes. Despite its huge advantages, physisorption is very seldom adopted, as there is an ingrained belief that it does not lead to high performance because of its lack of uniformity and long-term stability, which, however, have never been systematically investigated, particularly for bilayers of capture antibodies. Herein, the homogeneity and stability of an antibody layer against SARS-CoV-2-Spike1 (S1) protein physisorbed onto a gold surface have been investigated by means of multi-parametric surface plasmon resonance (MP-SPR). A surface coverage density of capture antibodies as high as (1.50 ± 0.06) × 10 12 molecules per cm −2 is measured, corresponding to a thickness of 12 ± 1 nm. This value is compatible with a single monolayer of homogeneously deposited antibodies. The effect of the ionic strength ( i s ) of the antibody solution in controlling physisorption of the protein was thoroughly investigated, demonstrating an enhancement in surface coverage at lower ionic strength. An atomic force microscopy (AFM) investigation shows a globular structure attributed to i s -related aggregations of antibodies. The long-term stability over two weeks of the physisorbed proteins was also assessed. High-performance sensing was proven by evaluating figures of merit, such as the limit of detection (2 nM) and the selectivity ratio between a negative control and the sensing experiment (0.04), which is the best reported performance for an SPR S1 protein assay. These figures of merit outmatch those measured with more sophisticated biofunctionalization procedures involving chemical bonding of the capture antibodies to the gold surface. The present study opens up interesting new pathways toward the achievement of a cost-effective and scalable biofunctionalization protocol, which could guarantee the prolonged stability of the biolayer and easy handling of the biosensing system. The uniformity and long-term stability of physisorbed antibodies against SARS-CoV-2-Spike1 at a solid interface are addressed. High-performance sensing is accomplished, outmatching the analytical performance achieved with the chemical bonding of capture antibodies.