Infectious diseases caused by bacterial pathogens remain one of the most common causes of morbidity and mortality worldwide. Rapid microbiological analysis is required for prompt treatment of bacterial infections and to facilitate antibiotic stewardship. This study reports an adaptable microfluidic system for rapid pathogen classification and antimicrobial susceptibility testing (AST) at the single-cell level. By incorporating tunable microfluidic valves along with real-time optical detection, bacteria can be trapped and classified according to their physical shape and size for pathogen classification. By monitoring their growth in the presence of antibiotics at the single-cell level, antimicrobial susceptibility of the bacteria can be determined in as little as 30 minutes compared with days required for standard procedures. The microfluidic system is able to detect bacterial pathogens in urine, blood cultures, and whole blood and can analyze polymicrobial samples. We pilot a study of 25 clinical urine samples to demonstrate the clinical applicability of the microfluidic system. The platform demonstrated a sensitivity of 100% and specificity of 83.33% for pathogen classification and achieved 100% concordance for AST.
Collective
cell migration plays a pivotal role in development, wound healing,
and metastasis, but little is known about the mechanisms and coordination
of cell migration in 3D microenvironments. Here, we demonstrate a
3D wound healing assay by photothermal ablation for investigating
collective cell migration in epithelial tissue structures. The nanoparticle-mediated
photothermal technique creates local hyperthermia for selective cell
ablation and induces collective cell migration of 3D tissue structures.
By incorporating dynamic single cell gene expression analysis, live
cell actin staining, and particle image velocimetry, we show that
the wound healing response consists of 3D vortex motion moving toward
the wound followed by the formation of multicellular actin bundles
and leader cells with active actin-based protrusions. Inhibition of
ROCK signaling disrupts the multicellular actin bundle and enhances
the formation of leader cells at the leading edge. Furthermore, single
cell gene expression analysis, pharmacological perturbation, and RNA
interference reveal that Notch1-Dll4 signaling negatively regulates
the formation of multicellular actin bundles and leader cells. Taken
together, our study demonstrates a platform for investigating 3D collective
cell migration and underscores the essential roles of ROCK and Notch1-Dll4
signaling in regulating 3D epithelial wound healing.
A nanotube assisted microwave electroporation (NAME) technique is demonstrated for delivering molecular biosensors into viable bacteria for multiplex single cell pathogen identification to advance rapid diagnostics in clinical microbiology. Due to the small volume of a bacterial cell (~femtoliter), the intracellular concentration of the target molecule is high, which results in a strong signal for single cell detection without amplification. The NAME procedure can be completed in as little as 30 minutes and can achieve over 90% transformation efficiency. We demonstrate the feasibility of NAME for identifying clinical isolates of bloodborne and uropathogenic pathogens and detecting bacterial pathogens directly from patient's samples. In conjunction with a microfluidic single cell trapping technique, NAME allows single cell pathogen identification and antimicrobial susceptibility testing concurrently. Using this approach, the time for microbiological analysis reduces from days to hours, which will have a significant impact on the clinical management of bacterial infections.
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