Life science research and drug discovery typically favor in vitro assays for cost-efficient screening and in vivo assays for data with higher physiological context. Recent innovations in live-cell imaging have begun to close this gap by offering the convenience, control, and throughput of well-plate based assays that approach the clinical relevance of an animal model.
Fluxion Biosciences developed its well-plate microfluidics technology to emulate in vivo conditions in a well-plate assay format. The company’s BioFlux System incorporates this technology to offer live-cell imaging assays with controllable shear flow.
Numerous biological processes occur in the presence of shear flow, particularly in the vascular, immune, and respiratory systems. Many of these processes behave differently under flow versus static conditions. This severely limits the overall effectiveness of conventional static well-plate assays. The BioFlux platform enables simulation of physiological shear flow rates as well as other microenvironmental factors such as temperature, oxygen, and carbon dioxide concentrations. This yields a high-content, live-cell imaging assay that can be performed in a well-plate format. Some of the key applications will be discussed in this article, including cell adhesion and microbiology.
The BioFlux System comprises a benchtop instrument and microfluidic well-plate consumable (Figure 1). Each BioFlux well plate contains up to 24 individual flow cells that are fully enclosed microfluidic channels for running flow-based experiments. The flow cells are arrayed on the bottom of an SBS-standard well plate with a conduit integrated from the well to the microfluidic path (Figure 2).
This enables the reagents to be introduced directly into the microfluidic path via the well, rather than through tubing or off-chip reservoir. Effective containment of the fluids within the plate obviates the cleaning and assembly steps required with other types of flow cells.
Some BioFlux plate configurations offer two input wells in each experimental channel. This feature provides a software-controlled exchange of compounds, media, or buffer in real time without interruption of flow. Once the reagents have been introduced into the wells, an air-tight interface is placed on the plate with a series of pneumatic connections to each of the wells.
Shear is initiated using a pneumatic controller that delivers bidirectional shear force within the physiological range, and rapidly (<200 ms) switches shear values on the fly. This enables complex flow protocols to be established, such as cyclical waveforms or rapid application of stress. The BioFlux controller can be supplied with ambient air or customized gas mixtures to effectively establish tissue culture, anaerobic, or hypoxic microenvironments.
Principal benefits of the system include higher throughput and experimental flexibility. Microfluidic parallelization enables up to 24 unique assays on a single plate, which can be multiplexed up to 96 simultaneous assays using multiple device interfaces.
BioFlux software supports automated shear control and integrated imaging with select CCD and CMOS cameras. This allows the user to concurrently control flow protocols and imaging in an automated sequence. For example, if images are captured during a step-wise shear ramp, the software can be set to acquire in concert with the shear switching. The software integrates analysis modules to quantitate common assays such as cell rolling velocity, cell counts and adhesion, migration, and fluorescence intensity.