Largemouth bass virus (LMBV) is a major viral pathogen in largemouth bass culture, usually causing high mortality and heavy economic losses. Accurate and early detection of LMBV is crucial for diagnosis and control of the diseases caused by LMBV. Previously, we selected the specific aptamers, LA38 and LA13, targeting LMBV by systematic evolution of ligands by exponential enrichment (SELEX). In this study, we further generated truncated LA38 and LA13 (named as LA38s and LA13s) with high specificity and affinities and developed an aptamer-based sandwich enzyme-linked apta-sorbent assay (ELASA) for LMBV diagnosis. The sandwich ELASA showed high specificity and sensitivity for the LMBV detection, without cross reaction with other viruses. The detection limit of the ELASA was as low as 1.25 × 102 LMBV-infected cells, and the incubation time of the lysate and biotin labeled aptamer was as short as 10 min. The ELASA could still detect LMBV infection in spleen lysates at dilutions of 1/25, with good consistency of qRT-PCR. For the fish samples collected from the field, the sensitivity of ELASA was 13.3% less than PCR, but the ELASA was much more convenient and less time consuming. The procedure of ELASA mainly requires washing and incubation, with completion in approximately 4 h. The sandwich ELASA offers a useful tool to rapidly detect LMBV rapidly, contributing to control and prevention of LMBV infection.

Exosomes have received increasingly significant attention and have shown great clinical value as biomarkers for a number of diseases. However, there is still a lack of a highly sensitive and visualized method for the detection of exosomes in numerous samples simultaneously. Here, we developed a high-throughput, colorimetric and simple method to detect colorectal cancer (CRC) exosomes based on terminal deoxynucleotidyl transferase (TdT)-aided ultraviolet signal amplification. Anti-A33, a CRC exosomal protein marker, was selected as a capture probe, and a facility-prepared EpCAM (CRC exosomal protein) aptamer-Au-primer complex was used as a signal probe. After the CRC exosomes were captured onto the surface of 96-well plates, the primer was extended to the poly(biotin-adenine) chains with the help of TdT, resulting in an increase in the binding amount of avidin-modified horseradish peroxidase (Av-HRP) for H2O2-mediated oxidation of 3,3\',5,5\'-tetramethyl benzidine (TMB) in enzyme-linked aptamer-sorbent assay (ELASA). The results showed that the incorporation of ploy(biotin-A) enabled approximately 10.4-fold signal amplification. This approach achieved a linear range of 9.75 × 103-1.95 × 106 particles/μL for CRC cell-derived exosomes. The feasibility of the developed assay was evaluated using clinical serum samples. CRC patients (n = 16) could be clearly and successfully distinguished from healthy individuals (n = 9). Furthermore, this proposed platform holds considerable potential for the detection of different targets, simply by changing the aptamer and antibody.

As the major opportunistic pathogen to both marine animals and humans, Vibrio alginolyticus (V. alginolyticus) has caused heavy economic losses to mariculture. ssDNA aptamer VA2 targeting live V. alginolyticus was generated by systematic evolution of ligands by exponential enrichment (SELEX) technology in our previous study. In this study, we first developed aptamer (VA2)-based enzyme-linked apta-sorbent assay (VA2-ELASA) for rapid detection of mariculture pathogen V. alginolyticus. The VA2-ELASA could achieve the rapid detection for V. alginolyticus infection with high specificity and sensitivity. The VA2-ELASA could specifically identify V. alginolyticus, but not other non-target bacterial strains. VA2-ELASA could detect V. alginolyticus at the concentration of 5 × 104 /ml, the incubation time short to 1 min and the incubation temperature as high as 45°C, which proved sensitivity and stability of the novel VA2-ELASA in this study. It took less than one hour to accomplish the detection process by VA2-ELASA. The characteristics of specificity, sensitivity and easy operation make VA2-ELASA a novel useful technology for the rapid diagnosis of pathogen V. alginolyticus in mariculture.