Solid-Phase Optical Sensing Techniques for Sensitive Virus Detection.

Viral infections can pose a major threat to public health by causing serious illness, leading to pandemics, and burdening healthcare systems. The global spread of such infections causes disruptions to every aspect of life including business, education, and social life. Fast and accurate diagnosis of viral infections has significant implications for saving lives, preventing the spread of the diseases, and minimizing social and economic damages. Polymerase chain reaction (PCR)-based techniques are commonly used to detect viruses in the clinic. However, PCR has several drawbacks, as highlighted during the recent COVID-19 pandemic, such as long processing times and the requirement for sophisticated laboratory instruments. Therefore, there is an urgent need for fast and accurate techniques for virus detection. For this purpose, a variety of biosensor systems are being developed to provide rapid, sensitive, and high-throughput viral diagnostic platforms, enabling quick diagnosis and efficient control of the virus's spread. Optical devices, in particular, are of great interest due to their advantages such as high sensitivity and direct readout. The current review discusses solid-phase optical sensing techniques for virus detection, including fluorescence-based sensors, surface plasmon resonance (SPR), surface-enhanced Raman scattering (SERS), optical resonators, and interferometry-based platforms. Then, we focus on an interferometric biosensor developed by our group, the single-particle interferometric reflectance imaging sensor (SP-IRIS), which has the capability to visualize single nanoparticles, to demonstrate its application for digital virus detection.

Biosensors for virus detection

Diseases caused by pathogenic viruses, such as Ebola, Zika, HIV, and SARS-CoV-2, have challenged the world in recent years leading to an urgent need for novel virus diagnostic technologies in medical, sanitation, and food applications. Unlike current technologies, biosensors present an enormous potential to address the demand for sensitive, robust, and cost-effective virus detection tools employing various recognition units such as antibodies, enzymes, peptides, nucleic acids, peptide nucleic acids, and molecularly imprinted polymers to specifically target viral protein, genetic material, or whole virus. These elements are often combined with quantum dots, nanocomposites, metallic nanoparticles, and graphene to enhance the sensing performance. In this chapter, while reviewing the current trends in virus diagnostics, we discuss the working principles of various virus biosensors by focusing on affinity materials, transducer properties, fabrication methods, and nanostructures involved to provide a deep understanding of virus targeting sensor platforms. © 2023 Elsevier Inc. All rights reserved.

Detection of SARS-CoV-2 in Human Breast Milk.

Certain viral pathogens can be shed into the human breast milk and cause infections in the infant upon breastfeeding. Thus, it is important to clarify whether viral RNA as well as infectious virus can be found in breast milk. The complexity of this body fluid poses several challenges for viral RNA isolation and detection of infectious virus. We here provide a protocol that allowed the identification of SARS-CoV-2 RNA in breast milk and the isolation of infectious virus after the virus has been artificially spiked into milk samples.

Optimal Insertion Depth for Nasal Mid-Turbinate and Nasopharyngeal Swabs.

Millions of people are tested for COVID-19 daily during the pandemic, and a lack of evidence to guide optimal nasal swab testing can increase the risk of false-negative test results. This study aimed to determine the optimal insertion depth for nasal mid-turbinate and nasopharyngeal swabs. The measurements were made with a flexible endoscope during the collection of clinical specimens with a nasopharyngeal swab at a public COVID-19 test center in Copenhagen, Denmark. Participants were volunteer adults undergoing a nasopharyngeal SARS-CoV-2 rapid antigen test. All 109 participants (100%) completed the endoscopic measurements; 52 (48%) women; 103 (94%) white; mean age 34.39 (SD, 13.2) years; and mean height 176.7 (SD, 9.29) cm. The mean swab length to the posterior nasopharyngeal wall was 9.40 (SD, 0.64) cm. The mean endoscopic distance to the anterior and posterior end of the inferior turbinate was 1.95 (SD, 0.61) cm and 6.39 (SD, 0.62) cm, respectively. The mean depth to nasal mid-turbinate was calculated as 4.17 (SD, 0.48) cm. The optimal depths of insertion for nasal mid-turbinate swabs are underestimated in current guidelines compared with our findings. This study provides clinical evidence to guide the performance of anatomically correct nasal and nasopharyngeal swab specimen collection for virus testing.

Perspective on Proteomics for Virus Detection in Clinical Samples.

One of the most widely used methods to detect an acute viral infection in clinical specimens is diagnostic real-time polymerase chain reaction. However, because of the COVID-19 pandemic, mass-spectrometry-based proteomics is currently being discussed as a potential diagnostic method for viral infections. Because proteomics is not yet applied in routine virus diagnostics, here we discuss its potential to detect viral infections. Apart from theoretical considerations, the current status and technical limitations are considered. Finally, the challenges that have to be overcome to establish proteomics in routine virus diagnostics are highlighted.