Your search keyword '"He Xiaoming"' showing total 13 results

1. Methods of Generating Dielectrophoretic Force for Microfluidic Manipulation of Bioparticles.

Author

Kwizera EA, Sun M, White AM, Li J, and He X

Subjects

Cell Separation, Electrophoresis, Lab-On-A-Chip Devices, Microfluidic Analytical Techniques, Microfluidics

Abstract

Manipulation of microscale bioparticles including living cells is of great significance to the broad bioengineering and biotechnology fields. Dielectrophoresis (DEP), which is defined as the interactions between dielectric particles and the electric field, is one of the most widely used techniques for the manipulation of bioparticles including cell separation, sorting, and trapping. Bioparticles experience a DEP force if they have a different polarization from the surrounding media in an electric field that is nonuniform in terms of the intensity and/or phase of the electric field. A comprehensive literature survey shows that the DEP-based microfluidic devices for manipulating bioparticles can be categorized according to the methods of creating the nonuniformity via patterned microchannels, electrodes, and media to generate the DEP force. These methods together with the theory of DEP force generation are described in this review, to provide a summary of the methods and materials that have been used to manipulate various bioparticles for various specific biological outcomes. Further developments of DEP-based technologies include identifying materials that better integrate with electrodes than current popular materials (silicone/glass) and improving the performance of DEP manipulation of bioparticles by combining it with other methods of handling bioparticles. Collectively, DEP-based microfluidic manipulation of bioparticles holds great potential for various biomedical applications.

Published

2021

2. Label-Free On-Chip Selective Extraction of Cell-Aggregate-Laden Microcapsules from Oil into Aqueous Solution with Optical Sensor and Dielectrophoresis.

Author

Sun M, Durkin P, Li J, Toth TL, and He X

Subjects

Biotechnology instrumentation, Capsules, Cell Aggregation, Cell Culture Techniques, Cells, Cultured, Electrophoresis, Emulsions, Humans, Lab-On-A-Chip Devices, MCF-7 Cells, Microfluidics instrumentation, Oils chemistry, Optical Devices, Water chemistry, Biotechnology methods, Cells, Immobilized cytology, Microfluidics methods

Abstract

Microfluidic encapsulation of cells or tissues in biocompatible solidlike hydrogels has wide biomedical applications. However, the microfluidically encapsulated cells/tissues are usually suspended in oil and need to be extracted into aqueous solution for further culture or use. Current extracting techniques are either nonselective for the cell/tissue-laden hydrogel microcapsules or rely on fluorescence labeling of the cells/tissues, which may be undesired for their further culture or use. Here we developed a microelectromechanical system (MEMS) to achieve label-free on-chip selective extraction of cell-aggregate-laden hydrogel microcapsules from oil into aqueous solution. The system includes a microfluidic device, an optical sensor, a dielectrophoretic (DEP) actuator, and microcontrollers. The microfluidic device is for encapsulating cell aggregates in hydrogel microcapsules using the flow-focusing function with microchannels for extracting microcapsules. The optical sensor is to detect the cell aggregates, based on the difference of the optical properties between the cell aggregates and surrounding solution before their encapsulation in hydrogel microcapsules. This strategy is used because the difference in optical property between the cell-aggregate-laden hydrogel microcapsules and empty microcapsules is too small to tell them apart with a commonly used optical sensor. The DEP actuator, which is controlled by the sensor and microcontrollers, is for selectively extracting the targeted hydrogel microcapsules by DEP force. The results indicate this system can achieve selective extraction of cell-aggregate-laden hydrogel microcapsules with ∼100% efficiency without compromising the cell viability, and can improve the purity of the cell-aggregate-laden microcapsules by more than 75 times compared with nonselective extraction.

Published

2018

3. Fluid displacement during droplet formation at microfluidic flow-focusing junctions.

Author

Huang H and He X

Subjects

Microfluidics instrumentation, Microspheres, Models, Theoretical, Oils, Water, Hydrodynamics, Microfluidics methods

Abstract

Microdroplets and microcapsules have been widely produced using microfluidic flow-focusing junctions for biomedical and chemical applications. However, the multiphase microfluidic flow at the flow-focusing junction has not been well investigated. In this study, the displacement of two (core and shell) aqueous fluids that disperse into droplets altogether in a carrier oil emulsion was investigated both numerically and experimentally. It was found that extensive displacement of the two aqueous fluids within the droplet during its formation could occur as a result of the shear effect of the carrier fluid and the capillary effect of interfacial tension. We further identified that the two mechanisms of fluid displacement can be evaluated by two dimensionless parameters. The quantitative relationship between the degree of fluid displacement and these two dimensionless parameters was determined experimentally. Finally, we demonstrated that the degree of fluid displacement could be controlled to generate hydrogel microparticles of different morphologies using planar or nonplanar flow-focusing junctions. These findings should provide useful guidance to the microfluidic production of microscale droplets or capsules for various biomedical and chemical applications.

Published

2015

4. Oxidation and RGD Modification Affect the Early Neural Differentiation of Murine Embryonic Stem Cells Cultured in Core-Shell Alginate Hydrogel Microcapsules.

Author

Dumbleton, Jenna, Shamul, James G., Jiang, Bin, Agarwal, Pranay, Huang, Haishui, Jia, Xiaofeng, and He, Xiaoming

Subjects

STEM cell culture, EMBRYONIC stem cells, ALGINIC acid, HYDROGELS, CELL populations, STEM cells, CELL culture

Abstract

Directed neural differentiation of embryonic stem cells (ESCs) has been studied extensively to improve the treatment of neurodegenerative disorders. This can be done through stromal-cell derived inducing activity (SDIA), by culturing ESCs directly on top of a layer of feeder stromal cells. However, the stem cells usually become mixed with the feeder cells during the differentiation process, making it difficult to obtain a pure population of the differentiated cells for further use. To address this issue, a non-planar microfluidic device is used here to encapsulate murine ESCs (mESCs) in the 3D liquid core of microcapsules with an alginate hydrogel shell of different sizes for early neural differentiation through SDIA, by culturing mESC-laden microcapsules over a feeder layer of PA6 cells. Furthermore, the alginate hydrogel shell of the microcapsules is modified via oxidation or RGD peptide conjugation to examine the mechanical and chemical effects on neural differentiation of the encapsulated mESC aggregates. A higher expression of Nestin is observed in the aggregates encapsulated in small (∼300 μm) microcapsules and cultured over the PA6 cell feeder layer. Furthermore, the modification of the alginate with RGD facilitates early neurite extension within the microcapsules. This study demonstrates that the presence of the RGD peptide, the SDIA effect of the PA6 cells, and the absence of leukemia inhibition factor from the medium can lead to the early differentiation of mESCs with extensive neurites within the 3D microenvironment of the small microcapsules. This is the first study to investigate the effects of cell adhesion and degradation of the encapsulation materials for directed neural differentiation of mESCs. The simple modifications (i.e., oxidation and RGD incorporation) of the miniaturized 3D environment for improved early neural differentiation of mESCs may potentially enhance further downstream differentiation of the mESCs into more specialized neurons for therapeutic use and drug screening. [ABSTRACT FROM AUTHOR]

Published

2022

5. Bioinspired One Cell Culture Isolates Highly Tumorigenic and Metastatic Cancer Stem Cells Capable of Multilineage Differentiation.

Author

Wang, Hai, Agarwal, Pranay, Jiang, Bin, Stewart, Samantha, Liu, Xuanyou, Liang, Yutong, Hancioglu, Baris, Webb, Amy, Fisher, John P., Liu, Zhenguo, Lu, Xiongbin, Tkaczuk, Katherine H. R., and He, Xiaoming

Subjects

METASTASIS, CANCER stem cells, CELL culture, DEVELOPMENTAL biology, CANCER cells, CANCER relapse

Abstract

Cancer stem cells (CSCs) are rare cancer cells that are postulated to be responsible for cancer relapse and metastasis. However, CSCs are difficult to isolate and poorly understood. Here, a bioinspired approach for label‐free isolation and culture of CSCs, by microencapsulating one cancer cell in the nanoliter‐scale hydrogel core of each prehatching embryo‐like core–shell microcapsule, is reported. Only a small percentage of the individually microencapsulated cancer cells can proliferate into a cell colony. Gene and protein expression analyses indicate high stemness of the cells in the colonies. Importantly, the colony cells are capable of cross‐tissue multilineage (e.g., endothelial, cardiac, neural, and osteogenic) differentiation, which is not observed for "CSCs" isolated using other contemporary approaches. Further studies demonstrate the colony cells are highly tumorigenic, metastatic, and drug resistant. These data show the colony cells obtained with the bioinspired one‐cell‐culture approach are truly CSCs. Significantly, multiple pathways are identified to upregulate in the CSCs and enrichment of genes related to the pathways is correlated with significantly decreased survival of breast cancer patients. Collectively, this study may provide a valuable method for isolating and culturing CSCs, to facilitate the understanding of cancer biology and etiology and the development of effective CSC‐targeted cancer therapies. [ABSTRACT FROM AUTHOR]

Published

2020

6. Fabrication and verification of a glass–silicon–glass micro-/nanofluidic model for investigating multi-phase flow in shale-like unconventional dual-porosity tight porous media.

Author

Zhang, Yandong, Zhou, Chuanle, Qu, Chuang, Wei, Mingzhen, He, Xiaoming, and Bai, Baojun

Subjects

MULTIPHASE flow, POROUS materials, NANOFLUIDICS, NONAQUEOUS phase liquids, SHALE oils, MICROFLUIDICS, FLUID flow, GAS reservoirs

Abstract

Unconventional shale or tight oil/gas reservoirs that have micro-/nano-sized dual-scale matrix pore throats with micro-fractures may result in different fluid flow mechanisms compared with conventional oil/gas reservoirs. Microfluidic models, as a potential powerful tool, have been used for decades for investigating fluid flow at the pore-scale in the energy field. However, almost all microfluidic models were fabricated by using etching methods and very few had dual-scale micro-/nanofluidic channels. Herein, we developed a lab-based, quick-processing and cost-effective fabrication method using a lift-off process combined with the anodic bonding method, which avoids the use of any etching methods. A dual-porosity matrix/micro-fracture pattern, which can mimic the topology of shale with random irregular grain shapes, was designed with the Voronoi algorithm. The pore channel width range is 3 μm to 10 μm for matrices and 100–200 μm for micro-fractures. Silicon is used as the material evaporated and deposited onto a glass wafer and then bonded with another glass wafer. The channel depth is the same (250 nm) as the deposited silicon thickness. By using an advanced confocal laser scanning microscopy (CLSM) system, we directly visualized the pore level flow within micro/nano dual-scale channels with fluorescent-dyed water and oil phases. We found a serious fingering phenomenon when water displaced oil in the conduits even if water has higher viscosity and the residual oil was distributed as different forms in the matrices, micro-fractures and conduits. We demonstrated that different matrix/micro-fracture/macro-fracture geometries would cause different flow patterns that affect the oil recovery consequently. Taking advantage of such a micro/nano dual-scale 'shale-like' microfluidic model fabricated by a much simpler and lower-cost method, studies on complex fluid flow behavior within shale or other tight heterogeneous porous media would be significantly beneficial. [ABSTRACT FROM AUTHOR]

Published

2019

7. Three dimensional phase-field investigation of droplet formation in microfluidic flow focusing devices with experimental validation.

Author

Bai, Feng, He, Xiaoming, Yang, Xiaofeng, Zhou, Ran, and Wang, Cheng

Subjects

*DROPLETS, *MICROFLUIDICS, *CAPILLARY flow, *NAVIER-Stokes equations, *CAHN-Hilliard-Cook equation, *MULTIPHASE flow

Abstract

In this paper, the droplet formation process at a low capillary number in a flow focusing micro-channel is studied by performing a three-dimensional phase field benchmark based on the Cahn–Hilliard Navier–Stokes equations and the finite element method. Dynamic moving contact line and wetting condition are considered, and generalized Navier boundary condition (GNBC) is utilized to demonstrate the dynamic motion of the interface on wall surface. It is found that the mobility parameter plays a very critical role in the squeezing and breakup process to control the shape and size of droplets. We define the characteristic mobility M c to represent the correct relaxation time of the interface. We also demonstrate that the characteristic mobility is associated with the physical process and should be kept as a constant as the product of the mobility tuning parameter χ and the square of interfacial thickness ε 2 . This criterion is applied for different interfacial thicknesses to correctly capture the physical process of droplet formation. Moreover, the size of the droplet, the velocity of the droplet along the downstream, and the period of droplet formation are compared between the numerical and experimental results which agree with each other both qualitatively and quantitatively. The presented model and criterion can be used to predict the dynamic behavior and movement of multiphase flows. [ABSTRACT FROM AUTHOR]

Published

2017

8. Generation and manipulation of hydrogel microcapsules by droplet-based microfluidics for mammalian cell culture.

Author

Huang, Haishui, Yu, Yin, Hu, Yong, He, Xiaoming, Berk Usta, O., and Yarmush, Martin L.

Subjects

MOLECULAR capsules, HYDROGELS, CELL culture, MICROFLUIDICS, FLUID dynamics

Abstract

Hydrogel microcapsules provide miniaturized and biocompatible niches for three-dimensional (3D) in vitro cell culture. They can be easily generated by droplet-based microfluidics with tunable size, morphology, and biochemical properties. Therefore, microfluidic generation and manipulation of cell-laden microcapsules can be used for 3D cell culture to mimic the in vivo environment towards applications in tissue engineering and high throughput drug screening. In this review of recent advances mainly since 2010, we will first introduce general characteristics of droplet-based microfluidic devices for cell encapsulation with an emphasis on the fluid dynamics of droplet breakup and internal mixing as they directly influence microcapsule's size and structure. We will then discuss two on-chip manipulation strategies: sorting and extraction from oil into aqueous phase, which can be integrated into droplet-based microfluidics and significantly improve the qualities of cell-laden hydrogel microcapsules. Finally, we will review various applications of hydrogel microencapsulation for 3D in vitro culture on cell growth and proliferation, stem cell differentiation, tissue development, and co-culture of different types of cells. [ABSTRACT FROM AUTHOR]

Published

2017

9. In vitro culture of ovarian follicles from Peromyscus.

Author

He, Xiaoming and Toth, Thomas L.

Subjects

*PEROMYSCUS, *OVARIAN follicle, *OVULATION, *LABORATORY mice, *IN vitro studies, *REPRODUCTION

Abstract

The ovarian follicle is the fundamental functional tissue unit of mammalian ovary. Each ovarian follicle contains one single oocyte. Isolation and in vitro culture of ovarian follicles to obtain fertilizable oocytes have been regarded as a promising strategy for women to combat infertility. The follicles from Peromyscus are considered as a better model than that from inbred mice for studying follicle culture. This is because Peromyscus mice are outbred (as with humans) with an increased life span. In this article, we reviewed studies on this subject conducted using Peromyscus follicles. These studies show that the conventional 2D micro-drop and 3D hanging-drop approaches established for in vitro culture of early preantral follicles from inbred mice are not directly applicable for cultivating the follicles from Peromyscus. However, the efficiency could be significantly improved by culturing multiple early preantral follicles in one hanging drop of Peromyscus ovarian cell-conditioned medium. It is further revealed that the mechanical heterogeneity in the extracellular matrix of ovary is crucial for developing early preantral follicles to the antral stage and for the subsequent ovulation to release cumulus-oocyte complex. These findings may provide valuable guidance for furthering the technology of in vitro follicle culture to restore fertility in the clinic. [ABSTRACT FROM AUTHOR]

Published

2017

10. Interfacial tension based on-chip extraction of microparticles confined in microfluidic Stokes flows.

Author

Huang, Haishui and He, Xiaoming

Subjects

*INTERFACIAL tension, *MICROFLUIDICS, *STOKES flow, *REYNOLDS number, *EXTRACTION techniques

Abstract

Microfluidics involving two immiscible fluids (oil and water) has been increasingly used to produce hydrogel microparticles with wide applications. However, it is difficult to extract the microparticles out of the microfluidic Stokes flows of oil that have a Reynolds number (the ratio of inertia to viscous force) much less than one, where the dominant viscous force tends to drive the microparticles to move together with the surrounding oil. Here, we present a passive method for extracting hydrogel microparticles in microfluidic Stokes flow from oil into aqueous extracting solution on-chip by utilizing the intrinsic interfacial tension between oil and the microparticles. We further reveal that the thickness of an "extended confining layer" of oil next to the interface between oil and aqueous extracting solution must be smaller than the radius of microparticles for effective extraction. This method uses a simple planar merging microchannel design that can be readily fabricated and further integrated into a fluidic system to extract microparticles for wide applications. [ABSTRACT FROM AUTHOR]

Published

2014

11. Quantifying genetically inserted fluorescent protein in single iPS cells to monitor Nanog expression using electroactive microchamber arrays.

Author

Kim, Soo Hyeon, He, Xiaoming, Kaneda, Shohei, Kawada, Jiro, Fourmy, Dominique, Noji, Hiroyuki, and Fujii, Teruo

Subjects

*INDUCED pluripotent stem cells, *FLUORESCENT proteins, *MICROFLUIDIC analytical techniques, *MICROFLUIDIC devices, *MICROFLUIDICS, *NANOFLUIDICS, *BIOLOGICAL transport

Abstract

Interest in the gene expression levels of pluripotent stem cells has increased in order to precisely understand cellular differentiation. Here, we propose a method utilizing a large number of arrayed microchambers to quantitatively measure an intracellular fluorescence protein that is genetically inserted to monitor a pluripotency marker protein, Nanog, in pluripotent stem cells. Individual cells are isolated and lysed by inducing an electric potential on the cell membrane within the tightly enclosed microchambers. The microchambers have a size that is comparable to the target cells, making it possible to trap single cells and restrict the dilution of the cell lysate. The amount of intracellular fluorescence proteins in a single cell is precisely quantified inside the well-defined volume of each microchamber. Our method will be a useful tool for high-throughput and parallelized read-outs of gene expression levels in individual cells in a large population of cells. [ABSTRACT FROM AUTHOR]

Published

2014

12. Creating a capture zone in microfluidic flow greatly enhances the throughput and efficiency of cancer detection.

Author

Sun, Mingrui, Xu, Jiangsheng, Shamul, James G., Lu, Xiongbin, Husain, Syed, and He, Xiaoming

Subjects

*CANCER diagnosis, *CIRCULATING tumor DNA, *CANCER treatment, *MICROFLUIDICS, *BLOOD testing

Abstract

Abstract Efficient capture of rare circulating tumor cells (CTCs) from blood samples is valuable for early cancer detection to improve the management of cancer. In this work, we developed a highly efficient microfluidics-based method for detecting CTCs in human blood. This is achieved by creating separate capture and flow zones in the microfluidic device (ZonesChip) and using patterned dielectrophoretic force to direct cells from the flow zone into the capture zone. This separation of the capture and flow zones minimizes the negative impact of high flow speed (and thus high throughput) and force in the flow zone on the capture efficiency, overcoming a major bottleneck of contemporary microfluidic approaches using overlapping flow and capture zones for CTC detection. When the flow speed is high (≥0.58 mm/s) in the flow zone, the separation of capture and flow zones in our ZonesChip could improve the capture efficiency from ∼0% (for conventional device without separating the two zones) to ∼100%. Our ZonesChip shows great promise as an effective platform for the detection of CTCs in blood from patients with early/localized-stage colorectal tumors. [ABSTRACT FROM AUTHOR]

Published

2019

13. The crucial role of mechanical heterogeneity in regulating follicle development and ovulation with engineered ovarian microtissue.

Author

Choi, Jung Kyu, Agarwal, Pranay, Huang, Haishui, Zhao, Shuting, and He, Xiaoming

Subjects

*OVARIAN physiology, *TISSUE engineering, *MICROFLUIDICS, *BIOMIMETIC chemicals, *EPIDERMAL growth factor, *LUTEINIZING hormone

Abstract

Abstract: Contemporary systems for in vitro culture of ovarian follicles do not recapitulate the mechanical heterogeneity in mammalian ovary. Here we report microfluidic generation of biomimetic ovarian microtissue for miniaturized three-dimensional (3D) culture of early secondary preantral follicles by using alginate (harder) and collagen (softer) to fabricate the ovarian cortical and medullary tissues, respectively. This biomimetic configuration greatly facilitates follicle development to antral stage. Moreover, it enables in vitro ovulation of cumulus–oocyte complex (COC) from the antral follicles in the absence of luteinizing hormone (LH) and epidermal growth factor (EGF) that are well accepted to be responsible for ovulation in contemporary literature. These data reveal the crucial role of mechanical heterogeneity in the mammalian ovary in regulating follicle development and ovulation. The biomimetic ovarian microtissue and the microfluidic technology developed in this study are valuable for improving in vitro culture of follicles to preserve fertility and for understanding the mechanism of follicle development and ovulation to facilitate the search of cures to infertility due to ovarian disorders. [Copyright &y& Elsevier]

Published

2014