Selection of Brucella abortus mimetic epitopes for fast diagnostic purposes in cattle.

Bovine brucellosis is a disease that significantly impacts animal production and human health. Although many sensitive diagnostic tests are used, there is still no ideal fast serological test for all epidemiological situations. In this context, we developed peptides that mimic regions of antigenic proteins of Brucella abortus and can be used in serological diagnosis. RESULTS: From phage display technology, we randomly selected nine clones of phage displaying peptide binders to B. abortus. These clones were sequenced and translated. After molecular docking analysis, two peptides (Ba4 and Ba9) were selected, chemically synthesized, and verified for their potential diagnostic value. By enzyme-linked immunoassay (ELISA), Ba9 showed a sensitivity of up to 97.5% to detect antibodies circulating in animals with brucellosis. We incorporated the peptide Ba9 onto a bioelectrode (graphite modified with poly-3-hydroxyphenylacetic acid). Then, direct serum detection was demonstrated by differential pulse voltammetry, micrographs, and topographic analyses in addition to the average roughness coefficient (Ra) and the value of the mean squared deviation of the roughness (Rms). CONCLUSION: This work shows that the mimetic epitope of B. abortus can be useful for developing new platforms for diagnosing brucellosis. In addition, we propose a fast test based on an electrochemical sensor using graphite modified with poly-3-hydroxyphenylacetic acid.

Electrochemical Biosensor for Sensitive Detection of Hepatitis B in Human Plasma.

In this work, we report the construction of a novel electrochemical device for molecular diagnosis of hepatitis B virus in the blood plasma of infected patients, using graphite electrodes functionalized with poly(4-aminophenol) and sensitized with a specific DNA probe. The recognition of genomic DNA was evaluated by electrochemical techniques (DPV and EIS) and scanning electron microscopy. The genosensor was efficient in detecting genomic DNA with a linear range from 1.176 to 4.825 µg mL-1 and detection limit of 35.69 ng mL-1 (4.63 IU ml-1 or 25.93 copies.ml-1), which is better than the 10.00 IU ml-1 limit of reference method, real-time PCR, used in point of care. EIS analysis shows that the genosensor resistance increased exponentially with the concentration of the genomic DNA target. This novel platform has advantages to its applicability in real samples, such as good sensitivity, selectivity, low sample volume, and fast assay time (36 min), thus interesting for application in the diagnosis of hepatitis B virus in blood plasma. Also, the ease of synthesis of the low-cost polymer by electrosynthesis directly on the electrode surface allows the translation of the platform to portable devices.