Kang Kug Lee scite author profile

As a result of increased water demand and water pollution, both surface water and groundwater quantity and quality are of major concern worldwide. In particular, the presence of nutrients and heavy metals in water is a serious threat to human health. The initial step for the effective management of surface waters and groundwater requires regular, continuous monitoring of water quality in terms of contaminant distribution and source identification. Because of this, there is a need for screening and monitoring measurements of these compounds at contaminated areas. However, traditional monitoring techniques are typically still based on laboratory analyses of representative field-collected samples; this necessitates considerable effort and expense, and the sample may change before analysis. Furthermore, currently available equipment is so large that it cannot usually be made portable. Alternatively, lab chip and electrochemical sensing-based portable monitoring systems appear well suited to complement standard analytical methods for a number of environmental monitoring applications. In addition, this type of portable system could save tremendous amounts of time, reagent, and sample if it is installed at contaminated sites such as Superfund sites (the USA's worst toxic waste sites) and Resource Conservation and Recovery Act (RCRA) facilities or in rivers and lakes. Accordingly, state-of-the-art monitoring equipment is necessary for accurate assessments of water quality. This article reviews details on our development of these lab-on-a-chip (LOC) sensors.

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Human stomach-on-a-chip with luminal flow and peristaltic-like motility

Lee

McCauley

Broda

et al. 2018

Lab Chip

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Current in vitro approaches and animal models have critical limitations for modeling human gastrointestinal diseases because they may not properly represent multicellular human primary tissues. Therefore, there is a need for model platforms that recapitulate human in vivo development, physiology, and disease processes to validate new therapeutics. One of the major steps toward this goal was the generation of three-dimensional (3D) human gastric organoids (hGOs) via the directed differentiation of human pluripotent stem cells (hPSCs). The normal functions and diseases of the stomach occur in the luminal epithelium, however accessing the epithelium on the inside of organoids is challenging. We sought to develop a bioengineered platform to introduce luminal flow through hGOs to better model in vivo gastric functions. Here, we report an innovative microfluidic imaging platform housing hGOs with peristaltic luminal flow in vitro. This human stomach-on-a-chip allows robust, long-term, 3D growth of hGOs with the capacity for luminal delivery via a peristaltic pump. Organoids were cannulated and medium containing fluorescent dextran was delivered through the lumen using a peristaltic pump. This system also allowed us to rhythmically introduce stretch and contraction to the organoid, reminiscent of gastric motility. Our platform has the potential for long-term delivery of nutrients or pharmacological agents into the gastric lumen in vitro for the study of human gastric physiology, disease modeling, and drug screening, among other possibilities.

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A new on-chip whole blood/plasma separator driven by asymmetric capillary forces

Lee

Ahn

2013

Lab Chip

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A new on-chip whole blood/plasma separator driven by asymmetric capillary forces, which are produced through a microchannel with sprayed nanobead multilayers, has been designed, fabricated and fully characterized. The silica nanobead multilayers revealing as superhydrophilic surfaces have been fabricated using a spray layer-by-layer (LbL) nano-assembly method. This new on-chip blood plasma separator has been targeted for a sample-to-answer (S-to-A) microfluidic lab-on-a-chip (LOC) toward point-of-care clinical testing (POCT). Effective plasma separation from undiluted whole blood was achieved through the microchannel which was composed of asymmetric superhydrophilic surfaces with a 10 mm hydrophobic patch. Blood cells were continuously accumulated over the hydrophobic patch while the blood plasma was able to flow over the patch. Therefore, the blood plasma was successfully separated from the whole blood throughout the accumulated blood cells which worked as a so-called 'self-built-in blood cell microfilter'. The separated plasma was approximately 102 nL from a single drop of 3 μL whole blood within 10 min, which is very suitable for single-use disposable POCT devices.

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A laminar-flow based microbial fuel cell array

Yang

Lee

Choi

2017

Sensors and Actuators B: Chemical

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Kang Kug Lee

State-of-the-art lab chip sensors for environmental water monitoring

Human stomach-on-a-chip with luminal flow and peristaltic-like motility

A new on-chip whole blood/plasma separator driven by asymmetric capillary forces

A laminar-flow based microbial fuel cell array

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