Moving perfusion culture and live-cell imaging from lab to disc: proof of concept toxicity assay with AI-based image analysis.

In vitro, cell-based assays are essential in diagnostics and drug development. There are ongoing efforts to establish new technologies that enable real-time detection of cell-drug interaction during culture under flow conditions. Our compact (10 × 10 × 8.5 cm) cell culture and microscope on disc (CMoD) platform aims to decrease the application barriers of existing lab-on-a-chip (LoC) approaches. For the first time in a centrifugal device, (i) cells were cultured for up to six days while a spindle motor facilitated culture medium perfusion, and (ii) an onboard microscope enabled live bright-field imaging of cells while the data wirelessly transmitted to a computer. The quantification of cells from the acquired images was done using artificial intelligence (AI) software. After optimization, the obtained cell viability data from the AI-based image analysis proved to correlate well with data collected from commonly used image analysis software. The CMoD was also suitable for conducting a proof-of-concept toxicity assay with HeLa cells under continuous flow. The half-maximal inhibitory time (IT50) for various concentrations of doxorubicin (DOX) in the case of HeLa cells in flow, was shown to be lower than the IT50 obtained from a static cytotoxicity assay, indicating a faster onset of cell death in flow. The CMoD proved to be easy to handle, enabled cell culture and monitoring without assistance, and is a promising tool for examining the dynamic processes of cells in real-time assays.

An Ingestible Self-Polymerizing System for Targeted Sampling of Gut Microbiota and Biomarkers.

A proof-of-concept for the fabrication of a self-polymerizing system for sampling of gut microbiome in the upper gastrointestinal (GI) tract is presented. An orally ingestible microdevice is loaded with the self-polymerizing reaction mixture to entrap gut microbiota and biomarkers. This polymerization reaction is activated in the aqueous environment, like fluids in the intestinal lumen, and causes site-specific microsampling in the gastrointestinal tract. The sampled microbiota and protein biomarkers can be isolated and analyzed via high-throughput multiomic analyses. The study utilizes a hollow microdevice (Su-8, ca. 250 µm), loaded with an on-board reaction mixture (iron chloride, ascorbic acid, and poly(ethylene glycol) diacrylate monomers) for diacrylate polymerization in the gut of an animal model. An enteric-coated rat capsule was used to orally gavage these microdevices in a rat model, thereby, protecting the microdevices in the stomach (pH 2), but releasing them in the intestine (pH 6.6). Upon capsule disintegration, the microdevices were released in the presence of luminal fluids (in the small intestine region), where iron chloride reacts with ascorbic acid, to initiate poly(ethylene glycol) diacrylate polymerization via a free radical mechanism. Upon retrieval of the microdevices, gut microbiota was found to be entrapped in the polymerized hydrogel matrix, and genomic content was analyzed via 16s rRNA amplicon sequencing. Herein, the results show that the bacterial composition recovered from the microdevices closely resemble the bacterial composition of the gut microenvironment to which the microdevice is exposed. Further, histological assessment showed no signs of local tissue inflammation or toxicity. This study lays a strong foundation for the development of untethered, non-invasive microsampling technologies in the gut and advances our understanding of host-gut microbiome interactions, leading to a better understanding of their commensal behavior and associated GI disease progression in the near future.