Your search keyword '"Huh D"' showing total 6 results

1. High performance inkjet printed embedded electrochemical sensors for monitoring hypoxia in a gut bilayer microfluidic chip.

Author

Khalid MAU, Kim KH, Chethikkattuveli Salih AR, Hyun K, Park SH, Kang B, Soomro AM, Ali M, Jun Y, Huh D, Cho H, and Choi KH

Subjects

Drug Evaluation, Preclinical, Humans, Oxygen, Reactive Oxygen Species, Hypoxia, Microfluidics

Abstract

Sensing devices have shown tremendous potential for monitoring state-of-the-art organ chip devices. However, challenges like miniaturization while maintaining higher performance, longer operating times for continuous monitoring, and fabrication complexities limit their use. Herein simple, low-cost, and solution-processible inkjet dispenser printing of embedded electrochemical sensors for dissolved oxygen (DO) and reactive oxygen species (ROS) is proposed for monitoring developmental (initially normoxia) and induced hypoxia in a custom-developed gut bilayer microfluidic chip platform for 6 days. The DO sensors showed a high sensitivity of 31.1 nA L mg -1 with a limit of detection (LOD) of 0.67 mg L -1 within the 0-9 mg L -1 range, whereas the ROS sensor had a higher sensitivity of 1.44 nA μm -1 with a limit of detection of 1.7 μm within the 0-300 μm range. The dynamics of the barrier tight junctions are quantified with the help of an in-house developed trans -epithelial-endothelial electrical impedance (TEEI) sensor. Immunofluorescence staining was used to evaluate the expressions of HIF-1α and tight junction protein (TJP) ZO-1. This platform can also be used to enhance bioavailability assays, drug transport studies under an oxygen-controlled environment, and even other barrier organ models, as well as for various applications like toxicity testing, disease modeling and drug screening.

Published

2022

2. A microengineered model of RBC transfusion-induced pulmonary vascular injury.

Author

Seo J, Conegliano D, Farrell M, Cho M, Ding X, Seykora T, Qing D, Mangalmurti NS, and Huh D

Subjects

Cells, Cultured, Endothelium, Vascular injuries, Hemodynamics, Humans, Lung Injury pathology, Pulmonary Circulation, Endothelium, Vascular cytology, Erythrocyte Transfusion adverse effects, Lung Injury etiology, Microfluidics methods, Stress, Mechanical

Abstract

Red blood cell (RBC) transfusion poses significant risks to critically ill patients by increasing their susceptibility to acute respiratory distress syndrome. While the underlying mechanisms of this life-threatening syndrome remain elusive, studies suggest that RBC-induced microvascular injury in the distal lung plays a central role in the development of lung injury following blood transfusion. Here we present a novel microengineering strategy to model and investigate this key disease process. Specifically, we created a microdevice for culturing primary human lung endothelial cells under physiological flow conditions to recapitulate the morphology and hemodynamic environment of the pulmonary microvascular endothelium in vivo. Perfusion of the microengineered vessel with human RBCs resulted in abnormal cytoskeletal rearrangement and release of intracellular molecules associated with regulated necrotic cell death, replicating the characteristics of acute endothelial injury in transfused lungs in vivo. Our data also revealed the significant effect of hemodynamic shear stress on RBC-induced microvascular injury. Furthermore, we integrated the microfluidic endothelium with a computer-controlled mechanical stretching system to show that breathing-induced physiological deformation of the pulmonary microvasculature may exacerbate vascular injury during RBC transfusion. Our biomimetic microsystem provides an enabling platform to mechanistically study transfusion-associated pulmonary vascular complications in susceptible patient populations.

Published

2017

3. Acoustically detectable cellular-level lung injury induced by fluid mechanical stresses in microfluidic airway systems.

Author

Huh D, Fujioka H, Tung YC, Futai N, Paine R 3rd, Grotberg JB, and Takayama S

Subjects

Acoustics instrumentation, Air, Basement Membrane physiology, Cell Differentiation, Cell Division, Cell Survival, Cells, Cultured physiology, Epithelial Cells physiology, Epithelium physiopathology, Equipment Design, Humans, Lung Diseases physiopathology, Microfluidic Analytical Techniques, Perfusion, Pulmonary Surfactants, Shear Strength, Tissue Engineering instrumentation, Epithelium injuries, Lung Diseases etiology, Microfluidics, Stress, Mechanical

Abstract

We describe a microfabricated airway system integrated with computerized air-liquid two-phase microfluidics that enables on-chip engineering of human airway epithelia and precise reproduction of physiologic or pathologic liquid plug flows found in the respiratory system. Using this device, we demonstrate cellular-level lung injury under flow conditions that cause symptoms characteristic of a wide range of pulmonary diseases. Specifically, propagation and rupture of liquid plugs that simulate surfactant-deficient reopening of closed airways lead to significant injury of small airway epithelial cells by generating deleterious fluid mechanical stresses. We also show that the explosive pressure waves produced by plug rupture enable detection of the mechanical cellular injury as crackling sounds.

Published

2007

4. Gravity-driven microfluidic particle sorting device with hydrodynamic separation amplification.

Author

Huh D, Bahng JH, Ling Y, Wei HH, Kripfgans OD, Fowlkes JB, Grotberg JB, and Takayama S

Subjects

Dimethylpolysiloxanes chemistry, Particle Size, Silicones chemistry, Water chemistry, Gravitation, Microfluidics instrumentation, Microfluidics methods

Abstract

This paper describes a simple microfluidic sorting system that can perform size profiling and continuous mass-dependent separation of particles through combined use of gravity (1 g) and hydrodynamic flows capable of rapidly amplifying sedimentation-based separation between particles. Operation of the device relies on two microfluidic transport processes: (i) initial hydrodynamic focusing of particles in a microchannel oriented parallel to gravity and (ii) subsequent sample separation where positional difference between particles with different mass generated by sedimentation is further amplified by hydrodynamic flows whose streamlines gradually widen out due to the geometry of a widening microchannel oriented perpendicular to gravity. The microfluidic sorting device was fabricated in poly(dimethylsiloxane), and hydrodynamic flows in microchannels were driven by gravity without using external pumps. We conducted theoretical and experimental studies on fluid dynamic characteristics of laminar flows in widening microchannels and hydrodynamic amplification of particle separation. Direct trajectory monitoring, collection, and post-analysis of separated particles were performed using polystyrene microbeads with different sizes to demonstrate rapid (<1 min) and high-purity (>99.9%) separation. Finally, we demonstrated biomedical applications of our system by isolating small-sized (diameter <6 microm) perfluorocarbon liquid droplets from polydisperse droplet emulsions, which is crucial in preparing contrast agents for safe, reliable ultrasound medical imaging, tracers for magnetic resonance imaging, or transpulmonary droplets used in ultrasound-based occlusion therapy for cancer treatment. Our method enables straightforward, rapid, real-time size monitoring and continuous separation of particles in simple stand-alone microfabricated devices without the need for bulky and complex external power sources. We believe that this system will provide a useful tool to separate colloids and particles for various analytical and preparative applications and may hold potential for separation of cells or development of diagnostic tools requiring point-of-care sample preparation or testing.

Published

2007

5. Microfluidics for flow cytometric analysis of cells and particles.

Author

Huh D, Gu W, Kamotani Y, Grotberg JB, and Takayama S

Subjects

Animals, Biopolymers analysis, Biopolymers chemistry, Biopolymers metabolism, Cell Physiological Phenomena, Equipment Design, Flow Injection Analysis instrumentation, Flow Injection Analysis methods, Humans, Cell Culture Techniques instrumentation, Cell Culture Techniques methods, Flow Cytometry instrumentation, Flow Cytometry methods, Microfluidics instrumentation, Microfluidics methods

Abstract

This review describes recent developments in microfabricated flow cytometers and related microfluidic devices that can detect, analyze, and sort cells or particles. The high-speed analytical capabilities of flow cytometry depend on the cooperative use of microfluidics, optics and electronics. Along with the improvement of other components, replacement of conventional glass capillary-based fluidics with microfluidic sample handling systems operating in microfabricated structures enables volume- and power-efficient, inexpensive and flexible analysis of particulate samples. In this review, we present various efforts that take advantage of novel microscale flow phenomena and microfabrication techniques to build microfluidic cell analysis systems.

Published

2005

6. Reversible switching of high-speed air-liquid two-phase flows using electrowetting-assisted flow-pattern change.

Author

Huh D, Tkaczyk AH, Bahng JH, Chang Y, Wei HH, Grotberg JB, Kim CJ, Kurabayashi K, and Takayama S

Subjects

Air, Electrochemistry, Microfluidics instrumentation, Surface Properties, Water chemistry, Microfluidics methods

Abstract

This work is the first demonstration of electrical modulation of surface energy to reversibly switch dynamic high-speed gas-liquid two-phase microfluidic flow patterns. Manipulation of dynamic two-phase systems with continuous high-speed flows is complex and interesting due to the multiple types of forces that need to be considered. Here, distinct stable flow patterns are formed through a multipronged approach: both surface tension forces generated by surface chemistry modulation as well as viscous and inertial forces produced by fluid flows are employed. The novel fluidic actuation mechanism provides insights into better understanding microscale two-phase flow dynamics and offers new opportunities for the development of two-phase biochemical microsystems that are mechanically simple and operational at high speeds.

Published

2003