Gravity-Oriented Microfluidic Device for Biocompatible End-to-End Fabrication of Cell-Laden Microgels.

Droplet microfluidics are extensively utilized to generate monodisperse cell-laden microgels in biomedical applications. However, maintaining cell viability is still challenging due to overexposure to harsh conditions in subsequent procedures that recover the microgels from the oil phase. Here, a gravity-oriented microfluidic device for end-to-end fabrication of cell-laden microgels is reported, which integrates dispersion, gelation, and extraction into a continuous workflow. This innovative on-chip extraction, driven by native buoyancy and kinetically facilitated by pseudosurfactant, exhibits 100% retrieval efficiency for microgels with a wide range of sizes and stiffnesses. The viability of encapsulated cells is perfectly maintained at ≈98% with minimal variations within and between batches. The end-to-end fabrication remarkably enhances the biocompatibility and practicality of microfluidics-based cell encapsulation and is promising to be compatible with various applications ranging from single-cell analysis to clinical therapy.

Portable Biosensor with Bimetallic Metal-Organic Frameworks for Visual Detection and Elimination of Bacteria.

A multifunctional platform that meets the demands of both bacterial detection and elimination is urgently needed because of their harm to human health. Herein, a "sense-and-treat" biosensor was developed by using immunomagnetic beads (IMBs) and AgPt nanoparticle-decorated PCN-223-Fe (AgPt/PCN-223-Fe, PCN stands for porous coordination network) metal-organic frameworks (MOFs). The synthesized AgPt/PCN-223-Fe not only exhibited excellent peroxidase-like activity but also could efficiently kill bacteria under near infrared (NIR) irradiation. This biosensor enabled the colorimetric detection of E. coli O157:H7 in the range of 103-108 CFU/mL with a limit of detection of 276 CFU/mL, accompanied with high selectivity, good reproducibility, and wide applicability in diverse real samples. Furthermore, the biosensor possessed a highly effective antibacterial rate of 99.94% against E. coli O157:H7 under 808 nm light irradiation for 20 min. This strategy can provide a reference for the design of novel versatile biosensors for bacterial discrimination and antibacterial applications.

Effect of Tryptophan Metabolites on Cell Damage Revealed by Bacteria-Cell Interactions in Hydrogel Microspheres.

This work presented an alternative approach for studying bacteria-cell interactions in three-dimensional (3D) hydrogel microspheres formed by the cross-linking reaction of alginate and calcium-ethylenediaminetetraacetic acid (EDTA-Ca) produced in a microfluidic chip. During the co-culture process of hepatocytes (HepG2) and Escherichia coli (E. coli) 25922, we concluded that the content change of tryptophan metabolites detected via ultra-performance liquid chromatography-tandem mass spectrometry (UPLC-MS/MS) was related to the cell damage level and the change of interleukin (IL-22) detected by matrix-assisted laser desorption/ionization-time of flight mass spectrometry (MALDI-TOF-MS) was related to the ways of co-cultivation. Compared to the two-dimensional (2D) adherent cell culture process in a Petri dish (2D), the co-culture process of HepG2 and E. coli 25922 in hydrogel microspheres indicated more information about metabolism such as the appearance of indole-3-propionic acid (IPA) and possibly IL-22. The method provides a new perspective to investigate the bacteria-cell interaction and it could be a promising tool in the study of gut microbiota and human health.

Multiplexed detection of foodborne pathogens using one-pot CRISPR/Cas12a combined with recombinase aided amplification on a finger-actuated microfluidic biosensor.

Foodborne pathogens have raised significant concerns in human public health. Rapid, high-sensitive, low-cost, and easy-to-use testing methods for food safety are needed. In this study, we developed a finger-actuated microfluidic biosensor (FA-MB) for multiplexed detection of Bacillus cereus and other six common foodborne pathogens based on one-pot CRISPR/Cas12a combined with recombinase aided amplification (RAA). Wells for RAA and CRISPR/Cas12a were isolated to avoid interference, while finger-actuated one-way control valves were incorporated to fulfill the unidirectional flow of RAA products to the CRISPR/Cas12a reaction wells, realizing one-pot RAA-CRISPR/Cas12a assay. The final fluorescent signal was acquired and processed by a smartphone. Under selected experimental conditions, seven pathogenic bacteria could be tested in about 1 h with the limits of detection (LODs) below 500 CFU/mL. Recoveries ranged from 90% to 116% of the spiked samples were readily achieved. The proposed FA-MB is highly integrated and easy-to-use, and could be used for rapid, high-sensitive point of care (POC) testing without the external driving device, suitable for resource-constrained settings.

Microfluidic Aqueous Two-Phase Focusing of Chemical Species for In Situ Subcellular Stimulation.

Confinement of chemical species in a controllable micrometer-level (several to a dozen micrometers) space in an aqueous environment is essential for precisely manipulating chemical events in subcellular regions. However, rapid diffusion and hard-to-control micrometer-level fluids make it a tough challenge. Here, a versatile open microfluidic method based on an aqueous two-phase system (ATPS) is developed to restrict species inside an open space with micron-level width. Unequal standard chemical potentials of the chemical species in two phases and space-time correspondence in the microfluidic system prevent outward diffusion across the phase interface, retaining the target species inside its preferred phase flow and creating a sharp boundary with a dramatic concentration change. Then, the chemical flow (the preferred phase with target chemical species) is precisely manipulated by a microfluidic probe, which can be compressed to a micron-level width and aimed at an arbitrary position of the sample. As a demonstration of the feasibility and versatility of the strategy, chemical flow is successfully applied to subcellular regions of various kinds of living single cells. Subcellular regions are successfully labeled (cytomembrane and mitochondria) and damaged. Healing-regeneration behaviors of living single cells are triggered by subcellular damage and analyzed. The method is relatively general regarding the species of chemicals and biosamples, which could promote deeper cell research.