RESUMO
Microfluidic paper-based analytical devices (µPADs) allow user-friendly and portable chemical determinations, although they provide limited applicability due to insufficient sensitivity. Several approaches have been proposed to address poor sensitivity in µPADs, but they frequently require bulky equipment for power and/or read-outs. Universal serial buses (USB) are an attractive alternative to less portable power sources and are currently available in many common electronic devices. Here, USB-powered µPADs (USB µPADs) are proposed as a fusion of both technologies to improve performance without adding instrumental complexity. Two ITP USB µPADs were developed, both powered by a 5 V potential provided through standard USB ports. The first device was fabricated using the origami approach. Its operation was analyzed experimentally and numerically, yielding a two-order-of-magnitude sample focusing in 15 min. The second ITP USB µPAD is a novel design, which was numerically prototyped with the aim of handling larger sample volumes. The reservoirs were moved away from the ITP channel and capillary action was used to drive the sample and electrolytes to the separation zone, predicting 25-fold sample focusing in 10 min. USB µPADs are expected to be adopted by minimally-trained personnel in sensitive areas like resource-limited settings, the point-of-care and in emergencies.
Assuntos
Isotacoforese/instrumentação , Técnicas Analíticas Microfluídicas/instrumentação , Papel , Fontes de Energia Elétrica , Eletrólitos/química , Desenho de EquipamentoRESUMO
Detecting bacteria is important in the fields of human health, environmental monitoring, and food safety. Foodborne pathogens alone are estimated to cause 420â¯000 deaths annually, with low-income regions affected most. Despite improvements in bacterial detection, fast, disposable, low-cost, sensitive, and user-friendly methods are still needed. Traditional methods for detecting bacteria rely primarily on cell culturing or polymerase chain reaction (PCR), which require highly trained personnel and a central laboratory and take several hours or even days to deliver results. Low-cost methods like lateral flow immunoassays exist but frequently suffer from poor sensitivity and/or lack quantitative results. Here, a rapid method for detecting bacteria at very low concentrations is presented using two sequential preconcentration steps. In the first preconcentration step, the sample is mixed with antibody-modified magnetic particles and free antibodies conjugated to ß-galactosidase (ß-gal). The target bacteria are isolated and concentrated using immunomagnetic separation. The isolated bacteria are then incubated with chlorophenol red-ß-d-galactopyranoside (CPRG), which reacts with ß-gal to produce chlorophenol red (CPR) in a bacteria concentration-dependent manner. In the second step, CPR and CPRG are separated and focused using an isotachophoretic microfluidic paper-based analytical device, significantly improving the final detection limit relative to paper-based devices lacking the focusing mechanism. Moreover, CPR and CPRG form two visible color bands that act as test and control bands, respectively, improving assay robustness. The method was tested with E. coli DH5-α and successfully detected concentrations as low as 9.2 CFU/mL in laboratory samples and 920 CFU/mL in apple juice samples in â¼90 min.