Use of 3D printing and modular microfluidics to integrate cell culture, injections and electrochemical analysis

Munshi, Akash S.; Chen, Chengpeng; Townsend, Alexandra D.; Martin, R. Scott

doi:10.1039/c8ay00829a

Cited by 33 publications

(34 citation statements)

References 61 publications

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“…Further, the sample injection module for cell analysis permitted the injection of 195 nL of sample loaded in a groove formed on a rotor structure. 38 These injectors with multi-port valves permit simple procedures for switching load/injection but also repetitive injection of different samples. However, sample load/injection systems with an external multi-port valve still have a dead-volume problem related to the parts connecting the valve and the microchip.…”

Section: Introductionmentioning

confidence: 99%

Development of an on-chip sample injection system with a 6-port valve incorporated in a microchip

et al. 2020

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Section: Introductionmentioning

confidence: 99%

Development of an on-chip sample injection system with a 6-port valve incorporated in a microchip

et al. 2020

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“…Current dynamic endothelial models applied the cells on a 2D flat surface-either a wall of a microchannel, the bottom of a reservoir, or a sealed porous membrane. However, some recent studies have shown that the biophysical cues of an ECM can affect cellular activities 13,[29][30][31] . Therefore, we hypothesized that the aligned fibrous topography (Fig.…”

Section: Resultsmentioning

confidence: 99%

A 3D-Printed, Modular, and Parallelized Microfluidic System with Customizable ECM Integration to Investigate the Roles of Basement Membrane Topography on Endothelial Cells

Jones¹,

Huang²,

Chung³

et al. 2020

Preprint

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Because dysfunctions of endothelial cells are involved in many pathologies, in vitro endothelial cell models for pathophysiological and pharmaceutical studies have been a valuable research tool. Although numerous microfluidic-based endothelial models have been reported, they had the cells cultured on a flat surface without considering the possible 3D structure of the native ECM. Endothelial cells rest on the basement membrane in vivo, which contains an aligned microfibrous topography. To better understand and model the cells, it is necessary to know if and how the fibrous topography can affect endothelial functions. With conventional fully integrated microfluidic apparatus, it is difficult to include additional topographies in a microchannel. Therefore, we developed a modular microfluidic system by 3D-printing and electrospinning, which enabled easy integration and switching of desired ECM topographies. Also, with standardized designs, the system allowed for high flow rates up to 4000 µL/min, which covered the full shear stress range for endothelial studies. We found that the aligned fibrous topography on the ECM altered arginine metabolism in endothelial cells, and thus increased nitric oxide production. To the best of our knowledge, this is the most versatile endothelial model that has been reported, and the new knowledge generated thereby lays a groundwork for future endothelial research and modeling.

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“…Silk fibroin is a protein derived from raw silk, which has been widely used for biomedical applications due to its superior properties, including low immunogenicity, similarity to native ECMs, and ease of production [11,23]. Previous works showed that electrospun fibers from silk fibroin with submicron diameters are suitable substrates for 3D cell cul-tures [11,24]. Therefore, as shown in Figure 1A, we applied silk fibroin fibers with an average diameter of 0.8 ± 0.2 µm (mean of 200 fibers from 5 samples ± standard deviation) as the ECM for hepatocytes, with the control being a flat 2D substrate.…”

Section: The Fibrous Ecm and Basic Characterizations Of The Cellsmentioning

confidence: 99%

Electrospun Microfibers Modulate Intracellular Amino Acids in Liver Cells via Integrin β1

et al. 2021

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Although numerous recent studies have shown the importance of polymeric microfibrous extracellular matrices (ECMs) in maintaining cell behaviors and functions, the mechanistic nexus between ECMs and intracellular activities is largely unknown. Nevertheless, this knowledge will be critical in understanding and treating diseases with ECM remodeling. Therefore, we present our findings that ECM microstructures could regulate intracellular amino acid levels in liver cells mechanistically through integrin β1. Amino acids were studied because they are the fundamental blocks for protein synthesis and metabolism, two vital functions of liver cells. Two ECM conditions, flat and microfibrous, were prepared and studied. In addition to characterizing cell growth, albumin production, urea synthesis, and cytochrome p450 activity, we found that the microfibrous ECM generally upregulated the intracellular amino acid levels. Further explorations showed that cells on the flat substrate expressed more integrin β1 than cells on the microfibers. Moreover, after partially blocking integrin β1 in cells on the flat substrate, the intracellular amino acid levels were restored, strongly supporting integrin β1 as the linking mechanism. This is the first study to report that a non-biological polymer matrix could regulate intracellular amino acid patterns through integrin. The results will help with future therapy development for liver diseases with ECM changes (e.g., fibrosis).

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Use of 3D printing and modular microfluidics to integrate cell culture, injections and electrochemical analysis

Cited by 33 publications

References 61 publications

Development of an on-chip sample injection system with a 6-port valve incorporated in a microchip

Development of an on-chip sample injection system with a 6-port valve incorporated in a microchip

A 3D-Printed, Modular, and Parallelized Microfluidic System with Customizable ECM Integration to Investigate the Roles of Basement Membrane Topography on Endothelial Cells

Electrospun Microfibers Modulate Intracellular Amino Acids in Liver Cells via Integrin β1

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