Terry D Juang scite author profile

Dudley

et al. 2021

Nat Commun

The COVID-19 pandemic exposed difficulties in scaling current quantitative PCR (qPCR)-based diagnostic methodologies for large-scale infectious disease testing. Bottlenecks include lengthy multi-step processes for nucleic acid extraction followed by qPCR readouts, which require costly instrumentation and infrastructure, as well as reagent and plastic consumable shortages stemming from supply chain constraints. Here we report an Oil Immersed Lossless Total Analysis System (OIL-TAS), which integrates RNA extraction and detection onto a single device that is simple, rapid, cost effective, and requires minimal supplies and infrastructure to perform. We validated the performance of OIL-TAS using contrived SARS-CoV-2 viral particle samples and clinical nasopharyngeal swab samples. OIL-TAS showed a 93% positive predictive agreement (n = 57) and 100% negative predictive agreement (n = 10) with clinical SARS-CoV-2 qPCR assays in testing clinical samples, highlighting its potential to be a faster, cheaper, and easier-to-deploy alternative for infectious disease testing.

Confinement by liquid-liquid interface replicatesin vivoneutrophil deformations and elicits bleb based migration

Schrope

Horn

Farooqui

et al. 2023

Preprint

Cell migration plays an essential role in the immune response and is tightly regulated by both chemical and mechanical cues. After exiting circulation, immune cells navigate through tissues while mechanically confined by extracellular matrix components and tissue-resident cells. Common in vitro systems enable modeling of leukocyte migration through collagen-based hydrogels (individual fiber stiffness ~ 300 MPa) or in confined polymer-based microchannels (stiffness > MPa), however these existing systems fail to replicate the bidirectional mechanical interactions between migrating leukocytes and resident cells that typically exhibit a stiffness between 200-3000 Pa. Here, we utilize live-imaging of a dual-transgenic zebrafish to capture mechanical deformations of epidermal keratinocytes induced by interaction with migrating neutrophils. Subsequently, we engineer in vitro migration channels bound by a deformable liquid-liquid interface with tunable mechanical properties that replicate single cell keratinocyte deformations during neutrophil migration in vivo. We find that controlling the mechanical properties of the interface modulates neutrophil motility. This work introduces an in vitro controlled material interface that closely mimics the mechanical interactions between neutrophils and surrounding cells in vivo to provide a biologically relevant platform for exploring the influence of mechanical forces on cell migration.

A high-throughput nematode sensory assay reveals an inhibitory effect of ivermectin on parasite gustation

Nunn

Beebe

et al. 2023

Preprint

A high-throughput sensory assay for parasitic and free-living nematodes

Nunn

Beebe

et al. 2023

Sensory pathways first elucidated in Caenorhabditis elegans are conserved across free-living and parasitic nematodes, even though each species responds to a diverse array of compounds. Most nematode sensory assays are performed by tallying observations of worm behavior on two-dimensional planes using agarose plates. These assays have been successful in the study of volatile sensation but are poorly suited for investigation of water-soluble gustation or parasitic nematodes without a free-living stage. In contrast, gustatory assays tend to be tedious, often limited to the manipulation of a single individual at a time. We have designed a nematode sensory assay using a microfluidics device that allows for the study of gustation in a 96-well, three-dimensional environment. This device is suited for free-living worms and parasitic worms that spend their lives in an aqueous environment, and we have used it to show that ivermectin inhibits the gustatory ability of vector-borne parasitic nematodes. Insight box Nematodes are powerful model organisms for understanding the sensory biology of multicellular eukaryotes, and many parasitic species cause disease in humans. Simple sensory assays performed on agarose plates have been the bedrock for establishing the neuronal, genetic, and developmental foundations for many sensory modalities in nematodes. However, these classical assays are poorly suited for translational movement of many parasitic nematodes and the sensation of water-soluble molecules (gustation). We have designed a device for high-throughput nematode sensory assays in a gel matrix. This ‘gustatory microplate’ is amenable to several species and reveals novel responses by free-living and parasitic nematodes to cues and drugs.

Oil Immersed Lossless Total Analysis System (OIL-TAS): Integrated RNA Extraction and Detection for SARS-CoV-2 Testing

Dudley

et al. 2020

Preprint

The coronavirus disease 2019 (COVID-19) pandemic exposed difficulties in scaling current quantitative PCR (qPCR)-based diagnostic methodologies for large-scale infectious disease testing. Bottlenecks include the lengthy multi-step process of nucleic acid extraction followed by qPCR readouts, which require costly instrumentation and infrastructure, as well as reagent and plastic consumable shortages stemming from supply chain constraints. Here we report a novel Oil Immersed Lossless Total Analysis System (OIL-TAS), which integrates RNA extraction and detection onto a single device that is simple, rapid, cost effective, uses minimal supplies and requires reduced infrastructure to perform. We validated the performance of OIL-TAS using contrived samples containing inactivated SARS-CoV-2 viral particles, which show that the assay can reliably detect an input concentration of 10 copies/μL and sporadically detect down to 1 copy/μL. The OIL-TAS method can serve as a faster, cheaper, and easier-to-deploy alternative to current qPCR-based methods for infectious disease testing.