Multicenter evaluation of the GenomEra SARS-CoV-2 assay kit.

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) first emerged in late 2019, and quickly spread to every continent causing the global coronavirus disease 2019 (COVID-19) pandemic. Fast propagation of the disease presented numerous challenges to the health care industry in general and especially placed enormous pressure on laboratory testing. Throughout the pandemic, reverse transcription-PCR (RT-PCR)-based nucleic acid amplification tests have been the primary technique to identify acute infections caused by SARS-CoV-2. Since the start of the pandemic, there has been a constantly growing need for accurate and fast tests to enable timely protective and isolation means, as well as rapid therapeutic interventions. Here we present an evaluation of the GenomEra test for SARS-CoV-2. Analytical and clinical performance was evaluated in a multicenter setting with specimens analyzed using standard-of-care (SOC) techniques. Analytical sensitivity was assessed from spiked respiratory swab samples collected into different viral transport media, and in the best performer eSwab, the limit of detection was found to be 239 IU/mL in a heat processed sample. The GenomEra SARS-CoV-2 Assay Kit did not show specificity/cross-reactivity issues with common micro-organisms or other substances commonly found in respiratory specimens when analyzed both in vitro and in silico. Finally, the clinical performance was assessed in comparison to SOC techniques used at four institutions. Based on the analysis of 274 clinical specimens, the positive agreement of the GenomEra SARS-CoV-2 Assay Kit was 90.7%, and the negative agreement was 100%. The GenomEra SARS-CoV-2 Assay Kit provided accurate detection of SARS-CoV-2 with a short turnaround time in under 90 min.

A 365 nm UV LED-excitable antenna ligand for switchable lanthanide luminescence.

The time-resolved luminescence of lanthanide complexes is a highly sensitive and widely used bioassay technology for clinical diagnostics. With the time-resolved luminescence detection the naturally occurring autofluorescence of biological matrices, solid supports and plastics can be avoided. A major drawback of the current technique is that the luminescent lanthanide labels require ultraviolet (UV) excitation, typically shorter than 360 nm, which is strongly absorbed and can damage living biological systems. The lack of cost-efficient high power solid state excitation light sources for UV excitation further limits the development of low-cost and more compact measurement instruments for time-resolved luminescence and the potential use of lanthanide luminescence in different applications. Switchable lanthanide luminescence is a binary probe technology that inherently enables a high signal modulation in a separation-free detection of targets. The intrinsically luminescent lanthanide chelate is split into two nonluminescent moieties, a lanthanide ion carrier chelate and a light harvesting antenna ligand, each of which can be attached to a separate molecular probe. A luminescent lanthanide complex is formed only when the two probes bind adjacently to the target molecule. Herein we describe a new 365 nm excitable antenna ligand (AL360) for switchable lanthanide luminescence of europium(iii) (EuIII) that would enable the use of 365 nm light emitting diodes (LEDs) as an excitation light source for time-resolved fluorescence imaging and detection. With the acquired subpicomolar assay sensitivity it would be applicable for solution or surface arrays and UV LED microscopy.

Spectrally and Spatially Multiplexed Serological Array-in-Well Assay Utilizing Two-Color Upconversion Luminescence Imaging.

We demonstrate a simple dual-mode multiplexed array-in-well immunoassay for simultaneous classification and detection of serum IgG and IgM antibodies against influenza A and human adenoviruses based on the color and position of the upconversion luminescence on the array. Biotinylated influenza A/H1N1 and A/H5N1 as well as adenovirus serotype 2 and 5 hexon antigens along with positive and negative controls were printed in an array format onto the bottom of streptavidin-coated microtiter wells. The anti-influenza A and antiadenovirus antibodies present in the sample were captured to the array and detected with antihuman antibody-coated upconverting nanophosphors (UCNPs). The green emitting UCNPs (NaYF4:Yb(3+),Er(3+)) coated with antihuman IgG and blue emitting UCNPs (NaYF4:Yb(3+),Tm(3+)) coated with antihuman IgM were used to detect human IgG and IgM antibodies, respectively. The emission of the bound UCNPs was imaged free of autofluorescence with anti-Stokes photoluminescence microwell imager. No spectral cross-talk was observed between green and blue emitting UCNPs. Also the cross-reactivities between UCNP-conjugates and immobilized human IgG and IgM antibodies were negligible. Position of the signal on the array defined the antigen specificity and the antibody class was defined by the color of the upconversion luminescence. This technology could be used for differentiation between acute infection from past infection and immunity. Additionally, the class of the antibody response can be used for the differentiation between primary and secondary infections, hence, facilitating epidemiological seroprevalence studies.