Your search keyword '"Ulri N. Lee"' showing total 4 results

1. CandyCollect: at-home saliva sampling for capture of respiratory pathogens

Author

Ulri N. Lee, Xiaojing Su, Damielle L. Hieber, Wan-chen Tu, Anika M. McManamen, Meg G. Takezawa, Grant W. Hassan, Tung Ching Chan, Karen N. Adams, Ellen R. Wald, Gregory P. DeMuri, Erwin Berthier, Ashleigh B. Theberge, and Sanitta Thongpang

Subjects

Adult, Streptococcus pyogenes, Streptococcal Infections, Biomedical Engineering, Humans, Bioengineering, Pharyngitis, General Chemistry, Child, Saliva, Biochemistry, Polymerase Chain Reaction

Abstract

This paper presents a new sample collection platform for a common bacterial infection, group A streptococcal (GAS) pharyngitis, also known as strep throat, caused by Streptococcus pyogenes.

Published

2022

2. An open microfluidic coculture model of fibroblasts and eosinophils to investigate mechanisms of airway inflammation

Author

Yuting Zeng, Xiaojing Su, Meg G. Takezawa, Paul S. Fichtinger, Ulri N. Lee, Jeffery W. Pippin, Stuart J. Shankland, Fang Yun Lim, Loren C. Denlinger, Nizar N. Jarjour, Sameer K. Mathur, Nathan Sandbo, Erwin Berthier, Stephane Esnault, Ksenija Bernau, and Ashleigh B. Theberge

Subjects

Histology, Biomedical Engineering, Bioengineering, Biotechnology

Abstract

Interactions between fibroblasts and immune cells play an important role in tissue inflammation. Previous studies have found that eosinophils activated with interleukin-3 (IL-3) degranulate on aggregated immunoglobulin G (IgG) and release mediators that activate fibroblasts in the lung. However, these studies were done with eosinophil-conditioned media that have the capacity to investigate only one-way signaling from eosinophils to fibroblasts. Here, we demonstrate a coculture model of primary normal human lung fibroblasts (HLFs) and human blood eosinophils from patients with allergy and asthma using an open microfluidic coculture device. In our device, the two types of cells can communicate via two-way soluble factor signaling in the shared media while being physically separated by a half wall. Initially, we assessed the level of eosinophil degranulation by their release of eosinophil-derived neurotoxin (EDN). Next, we analyzed the inflammation-associated genes and soluble factors using reverse transcription quantitative polymerase chain reaction (RT-qPCR) and multiplex immunoassays, respectively. Our results suggest an induction of a proinflammatory fibroblast phenotype of HLFs following the coculture with degranulating eosinophils, validating our previous findings. Additionally, we present a new result that indicate potential impacts of activated HLFs back on eosinophils. This open microfluidic coculture platform provides unique opportunities to investigate the intercellular signaling between the two cell types and their roles in airway inflammation and remodeling.

Published

2022

3. Fundamentals of rapid injection molding for microfluidic cell-based assays

Author

Xiaojing Su, Erwin Berthier, Ashleigh B. Theberge, Ashley M. Dostie, Ulri N. Lee, David J. Guckenberger, and Tianzi Zhang

Subjects

Materials science, Fabrication, Phase contrast microscopy, Microfluidics, Cell Culture Techniques, Biomedical Engineering, Bioengineering, Nanotechnology, 02 engineering and technology, Molding (process), 01 natural sciences, Biochemistry, Article, Cell Line, law.invention, law, Animals, Microscale chemistry, 010401 analytical chemistry, technology, industry, and agriculture, Equipment Design, General Chemistry, Microfluidic Analytical Techniques, 021001 nanoscience & nanotechnology, Key features, Cell based assays, Channel geometry, 0104 chemical sciences, Microscopy, Fluorescence, Computer-Aided Design, Cattle, 0210 nano-technology

Abstract

Microscale cell-based assays have demonstrated unique capabilities in reproducing important cellular behaviors for diagnostics and basic biological research. As these assays move beyond the prototyping stage and into biological and clinical research environments, there is a need to produce microscale culture platforms more rapidly, cost-effectively, and reproducibly. ‘Rapid’ injection molding is poised to meet this need as it enables some of the benefits of traditional high volume injection molding at a fraction of the cost. However, rapid injection molding has limitations due to the material and methods used for mold fabrication. Here, we characterize advantages and limitations of rapid injection molding for microfluidic device fabrication through measurement of key features for cell culture applications including channel geometry, feature consistency, floor thickness, and surface polishing. We demonstrate phase contrast and fluorescence imaging of cells grown in rapid injection molded devices and provide design recommendations to successfully utilize rapid injection molding methods for microscale cell-based assay development in academic laboratory settings.

Published

2018

4. Layer-by-Layer Fabrication of 3D Hydrogel Structures Using Open Microfluidics

Author

Ross C. Bretherton, Ulri N. Lee, Ashleigh B. Theberge, John H. Day, Wenbo Lu, Cole A. DeForest, Amanda J. Haack, and Erwin Berthier

Subjects

Materials science, Fabrication, Capillary action, Microfluidics, Biomedical Engineering, Bioengineering, Nanotechnology, 02 engineering and technology, Biochemistry, Article, Polyethylene Glycols, 03 medical and health sciences, Lab-On-A-Chip Devices, Humans, Lithography, Cells, Cultured, 030304 developmental biology, 0303 health sciences, Layer by layer, Hydrogels, General Chemistry, Microfluidic Analytical Techniques, 021001 nanoscience & nanotechnology, Casting, Self-healing hydrogels, 0210 nano-technology, Layer (electronics), Hydrophobic and Hydrophilic Interactions

Abstract

Patterned deposition and 3D fabrication techniques have enabled the use of hydrogels for a number of applications including microfluidics, sensors, separations, and tissue engineering in which form fits function. Devices such as reconfigurable microvalves or implantable tissues have been created using lithography or casting techniques. Here, we present a novel open-microfluidic patterning method that utilizes surface tension forces to form hydrogel layers on top of each other, into a patterned 3D structure. We use a patterning device to form a temporary open microfluidic channel on an existing gel layer, allowing the controlled flow of unpolymerized gel in device-regions. After layer gelation and device removal, the process can be repeated iteratively to create multi-layered 3D structures. The use of open-microfluidic and surface tension-based methods to define the shape of each individual layer enables patterning to be performed with a simple pipette and with minimal dead-volume. Our method is compatible with unmodified (native) biological hydrogels, and other non-biological materials with precursor fluid properties compatible with capillary flow. With our open-microfluidic layer-by-layer fabrication method, we demonstrate the capability to build agarose, type I collagen, and polymer-peptide 3D structures featuring asymmetric designs, multiple components, overhanging features, and cell-laden regions.

Published

2020