Your search keyword '"Chu, Henry K."' showing total 3 results

1. Characterization of biomechanical properties of cells through dielectrophoresis-based cell stretching and actin cytoskeleton modeling.

Author

Bai G, Li Y, Chu HK, Wang K, Tan Q, Xiong J, and Sun D

Subjects

Biomechanical Phenomena, Cell Line, Tumor, Cost-Benefit Analysis, Electrophoresis economics, Electrophoresis instrumentation, Humans, Mechanotransduction, Cellular, Stress, Mechanical, Actin Cytoskeleton metabolism, Electrophoresis methods, Mechanical Phenomena, Models, Biological

Abstract

Background: Cytoskeleton is a highly dynamic network that helps to maintain the rigidity of a cell, and the mechanical properties of a cell are closely related to many cellular functions. This paper presents a new method to probe and characterize cell mechanical properties through dielectrophoresis (DEP)-based cell stretching manipulation and actin cytoskeleton modeling., Methods: Leukemia NB4 cells were used as cell line, and changes in their biological properties were examined after chemotherapy treatment with doxorubicin (DOX). DEP-integrated microfluidic chip was utilized as a low-cost and efficient tool to study the deformability of cells. DEP forces used in cell stretching were first evaluated through computer simulation, and the results were compared with modeling equations and with the results of optical stretching (OT) experiments. Structural parameters were then extracted by fitting the experimental data into the actin cytoskeleton model, and the underlying mechanical properties of the cells were subsequently characterized., Results: The DEP forces generated under different voltage inputs were calculated and the results from different approaches demonstrate good approximations to the force estimation. Both DEP and OT stretching experiments confirmed that DOX-treated NB4 cells were stiffer than the untreated cells. The structural parameters extracted from the model and the confocal images indicated significant change in actin network after DOX treatment., Conclusion: The proposed DEP method combined with actin cytoskeleton modeling is a simple engineering tool to characterize the mechanical properties of cells.

Published

2017

2. Characterization of a Honeycomb-Like Scaffold With Dielectrophoresis-Based Patterning for Tissue Engineering.

Author

Huan Z, Chu HK, Yang J, and Sun D

Subjects

Animals, Cell Differentiation physiology, Cell Line, Cell Separation instrumentation, Electrophoresis methods, Equipment Design, Equipment Failure Analysis, Humans, Mice, Osteoblasts physiology, Osteogenesis physiology, Porosity, Electrophoresis instrumentation, Micromanipulation instrumentation, Osteoblasts cytology, Printing, Three-Dimensional instrumentation, Tissue Engineering instrumentation, Tissue Scaffolds

Abstract

Objective: Seeding and patterning of cells with an engineered scaffold is a critical process in artificial tissue construction and regeneration. To date, many engineered scaffolds exhibit simple intrinsic designs, which fail to mimic the geometrical complexity of native tissues. In this study, a novel scaffold that can automatically seed cells into multilayer honeycomb patterns for bone tissue engineering application was designed and examined., Methods: The scaffold incorporated dielectrophoresis for noncontact manipulation of cells and intrinsic honeycomb architectures were integrated in each scaffold layer. When a voltage was supplied to the stacked scaffold layers, three-dimensional electric fields were generated, thereby manipulating cells to form into honeycomb-like cellular patterns for subsequent culture., Results: The biocompatibility of the scaffold material was confirmed through the cell viability test. Experiments were conducted to evaluate the cell viability during DEP patterning at different voltage amplitudes, frequencies, and manipulating time. Three different mammalian cells were examined and the effects of the cell size and the cell concentration on the resultant cellular patterns were evaluated., Conclusion: Results showed that the proposed scaffold structure was able to construct multilayer honeycomb cellular patterns in a manner similar to the natural tissue., Significance: This honeycomb-like scaffold and the dielectrophoresis-based patterning technique examined in this study could provide the field with a promising tool to enhance seeding and patterning of a wide range of cells for the development of high-quality artificial tissues.

Published

2017

3. Characterization of biomechanical properties of cells through dielectrophoresis-based cell stretching and actin cytoskeleton modeling.

Author

Guohua Bai, Ying Li, Chu, Henry K., Kaiqun Wang, Qiulin Tan, Jijun Xiong, Dong Sun, Bai, Guohua, Li, Ying, Wang, Kaiqun, Tan, Qiulin, Xiong, Jijun, and Sun, Dong

Subjects

CELLULAR mechanics, DIELECTROPHORESIS, CYTOSKELETON, DOXORUBICIN, LEUKEMIA, ELECTROPHORESIS equipment, BIOLOGICAL models, CELL lines, CELLULAR signal transduction, COST effectiveness, CYTOPLASM, ELECTROPHORESIS, KINEMATICS, MECHANICS (Physics), PHYSIOLOGIC strain

Abstract

Background: Cytoskeleton is a highly dynamic network that helps to maintain the rigidity of a cell, and the mechanical properties of a cell are closely related to many cellular functions. This paper presents a new method to probe and characterize cell mechanical properties through dielectrophoresis (DEP)-based cell stretching manipulation and actin cytoskeleton modeling.Methods: Leukemia NB4 cells were used as cell line, and changes in their biological properties were examined after chemotherapy treatment with doxorubicin (DOX). DEP-integrated microfluidic chip was utilized as a low-cost and efficient tool to study the deformability of cells. DEP forces used in cell stretching were first evaluated through computer simulation, and the results were compared with modeling equations and with the results of optical stretching (OT) experiments. Structural parameters were then extracted by fitting the experimental data into the actin cytoskeleton model, and the underlying mechanical properties of the cells were subsequently characterized.Results: The DEP forces generated under different voltage inputs were calculated and the results from different approaches demonstrate good approximations to the force estimation. Both DEP and OT stretching experiments confirmed that DOX-treated NB4 cells were stiffer than the untreated cells. The structural parameters extracted from the model and the confocal images indicated significant change in actin network after DOX treatment.Conclusion: The proposed DEP method combined with actin cytoskeleton modeling is a simple engineering tool to characterize the mechanical properties of cells. [ABSTRACT FROM AUTHOR]

Published

2017