Thermoset polyester as an alternative material for microchip electrophoresis/electrochemistry

Microchip CE coupled with electrochemical detection (MCE-EC) is a good method for the direct detection of many small molecule analytes because the technique is sensitive and readily miniaturized. Polymer materials are being increasingly used with MCE due to their affordability and ease of fabrication. While PDMS has become arguably the most widely used material in MCE-EC due to the simplicity of microelectrode incorporation, it suffers from a lack of separation efficiency, lower surface stability, and a tendency for analyte sorption. Other polymers, such as poly(methylmethacrylate) (PMMA) and poly(carbonate) (PC), have higher separation efficiencies but require more difficult fabrication techniques for electrode incorporation. In this report, thermoset polyester (TPE) was characterized as an alternative material for MCE-EC. TPE microchips were characterized in their native and plasma oxidized forms and after coating with polyelectrolyte multilayers (PEMs). TPE provides higher separation efficiencies when compared to PDMS microchips, while still using simple fabrication protocols. In this work, separation efficiencies as high as 295,000 N/m were seen when using TPE MCE-EC devices. Furthermore, the EOF was higher and more consistent as a function of pH for both native and plasma-treated TPE than PDMS. Finally, TPE is amenable to modification using simple PEM coatings as another way to control surface chemistry and surface charge.     

Hot embossing of electrophoresis microchannels in PMMA substrates using electric heating wires

A simple method based on electric heating wires has been developed for the rapid fabrication of poly(methyl methacrylate) (PMMA) electrophoresis microchips in ordinary laboratories without the need for microfabrication facilities. A piece of stretched electric heating wire placed across the length of a PMMA plate along its midline was sandwiched between two microscope slides under pressure. Subsequently, alternating current was allowed to pass through the wire to generate heat to emboss a separation microchannel on the PMMA separation channel plate at room temperature. The injection channel was fabricated using the same procedure on a PMMA sheet that was perpendicular to the separation channel. The complete microchip was obtained by bonding the separation channel plate to the injection channel sheet, sealing the channels inside. The electric heating wires used in this work not only generated heat; they also served as templates for embossing the microchannels. The prepared microfluidic microchips have been successfully employed in the electrophoresis separation and detection of ions in connection with contactless conductivity detection.     

一种可逆键合电泳微芯片的制作及在蛋白质分离中的应用

阐述了一种可逆键合电泳微芯片的制作方法, 以及电泳微芯片在蛋白质分离、临床尿蛋白检测方面的应用. 用标准光刻腐蚀技术在石英基片上腐蚀泳道, 清洗腐蚀好的基片和盖片后, 在真空条件下实现键合. 此种方法键合制作的电泳微芯片可重复键合使用, 制得的电泳微芯片成功地用于标准蛋白质分离以及临床尿蛋白分析.     

Morphology stability of lamellar composite magnetic materials

The aim of this study was to investigate the role of the copolymers and nanoparticles during elaboration of new stable composite materials. We have shown that the interactions between the mesophases that form the copolymers and nanoscopic particles can lead to highly organized hybrid materials. The morphology of such composites depends on the characteristics of both copolymers and nanoparticles. On one hand, diblock copolymers must form a strong segregation limit and have a higher mass. On the other hand, nanoparticles must show strong affinity for one of the two polymeric species of the copolymer and be as small as possible. In this case, a composite organic-inorganic material can be obtained with a periodic distribution of the particles in the polymeric matrix. This study can be applied to other copolymer-nanoparticle mixtures and used to design advanced composite architectures.     

芯片毛细管电泳及其在生命科学中的应用

芯片毛细管电泳 (Chip CE)技术在近几年已取得了很大的进展。本文着重介绍芯片毛细管区带电泳技术 ,对等电聚焦、等速电泳、自由溶液电泳及胶束电动色谱等其它芯片电泳模式也有所提及。讨论了芯片材料和制作技术、芯片的几何形状、样品的操作和衍生、检测及芯片毛细管电泳技术的应用 ,特别是在核酸和蛋白质的分离分析中的进展     

Cellulose-based hydrogels with excellent microstructural replication ability and cytocompatibility for microfluidic devices

In the face of challenges in the development of excellent biocompatible materials for microfluidic device fabrication, we demonstrated that cross-linked cellulose (RCC) hydrogel can be used as the bulk material for microchips. The cellulose hydrogel was prepared from cellulose solution dissolved in an 8 wt% LiOH/15 wt% urea aqueous system with cooling by crosslinking with epichlorohydrin. Collagen as a key extracellular matrix component for promoting cell cultivation was cross-linked in the cellulose hydrogel to obtain cellulose–collagen (RCC/C) hybrid hydrogels. The experimental results revealed that cellulose-based hydrogel microchips with well-defined 2D or 3D microstructures possessed excellent structural replication ability, good mechanical properties, and cytocompatibility for cell culture as well as excellent dimensional stability at elevated temperature. The hydrogel, as a transparent microchip material, had no effect on the fluorescence behaviors of FITC-dextran and rhodamine-dextran, leading to the good conjunction with fluorescent detection and imaging. Moreover, collagen could be immobilized in the RCC/C hydrogel scaffold for promoting cell growth and generating stable chemical concentration gradients, leading to superior cytocompatibility. This work provides new hydrogel materials for the microfluidic technology field and mimicks a 3D cell culture microenvironment for cell-based tissue engineering and drug screening.     

Fabrication of quartz microchips with optical slit and development of a linear imaging UV detector for microchip electrophoresis systems

We have developed quartz microchips for electrophoresis and a linear imaging UV detector along with the microchip. The microchips have an optical slit, which cut off the stray light in order to improve the sensitivity of UV absorption detection on the chip, at the bonding interface. They have been successfully fabricated on synthesized quartz glass substrates using the hydrofluoric acid (HF) solution bonding method. The signal level of UV absorption detection was effectively improved by applying microchips with the "on-chip" optical slit. It is also possible to improve the signal-to-noise ratio by repetitive scanning of linear photodiode array located along the separation channel, and signal averaging during elimination of the potential. Furthermore, the analysis may be performed until the separation of the target component is complete, because the real-time migration pattern of each component in the sample can be seen just as in a slab-gel electrophoresis, thus enabling a shorter analysis time.     

Simple and rapid methods for the fabrication of polymeric and glass chips for using in analytical chemistry

This paper describes simple and rapid methods for the fabrication of glass and polymeric chips for routine analytical applications. The methods are easily interfaced to the general laboratory environment and do not require special clean room facilities or expensive instruments. Glass microchips were fabricated by etching with HF solution. Microfluidic channels were designed with CAD program and transferred onto a sheet of commercial polymeric self-adhesive (PSA) film by a cutter plotter. The PSA film was used as a mask for etching process. The etching rate was about 7 μm min⁻¹. A cover glass plate was sealed on the top of etched substrate by using polycellulose (cellophane). Polymeric microchips were fabricated by sawing with a jigsaw. Commercial polycarbonate (PC) was used as a substrate and two iron sheets were used as leader masks. While this restricts us to the fabrication of straight channels, it is however, much faster and less complicated than the other methods. The chip comprised three polymeric plates and the channels were created in the middle plate. Thermal bonding was used to bond three layers of the microfluidic chip. With this method, we could achieve simple channels with the width of about 200 μm. The channel depth depends on the polymeric plate thickness. Fabricated channels were accurate without any sinuosity or sideshow.     

Electrophoresis microchips with sharp inlet tips, for contactless conductivity detection, fabricated by in-situ surface polymerization

A novel method based on in-situ surface polymerization of methyl methacrylate (MMA) has been developed for rapid fabrication of poly(methyl methacrylate) (PMMA) electrophoresis microchips with sharp inlet tips. Prepolymerized MMA containing an ultraviolet (UV) initiator was directly sandwiched between a nickel template and a PMMA plate. The image of the relief on the nickel template was precisely replicated in the synthesized PMMA layer on the surface of the commercially available PMMA plate during UV-initiated polymerization at room temperature. The chips were subsequently assembled by thermal bonding of channel plates and cover sheets. The sample was directly introduced into the separation channel through a sharp inlet tip, which was placed in the sample vial, without use of an injection cross. The attractive performance of the novel PMMA microchips has been demonstrated by using contactless conductivity detection for determination of several inorganic ions. Such rapid and simple sample introduction leads to highly reproducible signals with relative standard deviations of less than 5% for peak responses. These new approaches significantly simplify the process of fabricating PMMA devices and show great promise for high-speed microchip analysis.      

两亲性共聚物的分子设计与合成及其共混膜性能

从分子结构设计出发,采用自由基聚合、醚化、酯化、原子转移自由基聚合(ATRP)、可逆加成断裂链转移自由基聚合(RAFT)等方法合成了一系列具有不同分子结构(包括接枝、嵌段、交替、超支化等)和链形态(包括直链、梳状、哑铃状、链球状等)的两亲性共聚物,并对这些聚合物进行了谱学表征和性能测试.将这些两亲性共聚物与聚合物膜材料(包括聚偏氟乙烯、聚氯乙烯、聚砜、聚醚砜、聚醚砜酮等)进行溶液共混,通过相转化法制备共混膜,在成膜热力学和动力学分析的基础上,对共混膜的结构和性能进行调控.研究发现,两亲性共聚物在成膜过程中自发地向膜表面迁移富集,并进行自组装,在膜表面形成两亲性共聚物包膜,显著改善了聚合物多孔膜的亲水性和抗污染性能.此外,两亲性共聚物中的功能基团还可赋予共混膜某些功能特性,如生物相容性、环境响应性(pH、温度敏感性)、酶活性等.     

Preparation of high oxygen permeable transparent hybrid copolymers with silicone macro-monomers

In this study, high oxygen permeable transparent hybrid copolymers were prepared with hydrophilic monomer such as 2-hydroxyethylmethacrylate (HEMA) or N,N-dimethylacrylamide (DMAA) and mono- or difunctional silicone macro-monomer introduced methacryl groups. In HEMA-based hybrid copolymers, difunctional silicone macro-monomer and ethylene glycol dimethacrylate (EGDMA) as cross-linker were required in order to prepare transparent hybrid materials, while high transparent DMAA-based hybrid copolymers could be prepared without EGDMA cross-linker. The polymerization kinetics investigation revealed that this difference between HEMA and DMAA in preparation condition to transparent hybrid material originated to monomer reactivity in copolymerization and DMAA showed high reactivity compared with HEMA. Moreover, DMAA-based hybrid copolymers indicated high water content and high oxygen permeability as against HEMA-based hybrid copolymers because of its low cross-linking density.     

Chemical modification of polymeric microchip devices

Analytical polymeric microchips in both fluidic and array formats offer short analysis times, coupling of many sample processing and chemical reaction steps on one platform with minimal sample and reagent consumption, as well as low cost, minimal fabrication times and disposability. However, the invariable bulk properties of most commercial polymers have driven researchers to develop new modification strategies. This article critically reviews the scope and development of chemical modifications of such polymeric chips since 2003. Surface modifications were based on chemical derivatization or activation of surface layers with reagent solutions, reactive gases and irradiation. Bulk modification of polymer chips used newly incorporation of monomers with selective chemical functionalities throughout the bulk polymer material and integrated the chip modification and fabrication into a single step. Such modifications hold a great promise for establishing a true ‘lab-on-chip’ as can be seen from many novel applications for modulating electroosmosis, suppressing protein adsorption in microchip capillary electrophoretic separations, extraction of analytes and for zone-specific binding of enzymes and other biomolecules.     

Unusual Kinetics in Aqueous Heterophase Polymerizations

The heterogeneous nature of aqueous heterophase polymerizations is the base for an easy route to unique block copolymers, for the development of new and more effective polymerization strategies, and the abilities to unique studies of radical polymerization kinetics. Thermo-sensitive double hydrophilic block copolymers and micro- or nano-gel particles of poly(N-isopropyl acrylamide) as thermo-responsible block and charged or uncharged hydrophilic polymers can easily be prepared if the polymerization of N-isopropyl acrylamide is started with the corresponding polymeric radicals. The application of extremely fast microwave heating allows the development of highly effective pulsed thermal polymerization strategies and the production of polymers with desired molecular weight distributions over wide ranges. 2,2′-azobisisobutyronitrile simultaneously initiates the polymerization in both the monomer and the aqueous phase and leads, even under surfactant-free conditions, to stable latex particles.     

Poly(methylmethacrylate) and Topas capillary electrophoresis microchip performance with electrochemical detection

A capillary electrophoresis (CE) microchip made of a new and promising polymeric material: Topas (thermoplastic olefin polymer of amorphous structure), a cyclic olefin copolymer with high chemical resistance, has been tested for the first time with analytical purposes, employing an electrochemical detection. A simple end-channel platinum amperometric detector has been designed, checked, and optimized in a poly-(methylmethacrylate) (PMMA) CE microchip. The end-channel design is based on a platinum wire manually aligned at the exit of the separation channel. This is a simple and durable detection in which the working electrode is not pretreated. H(2)O(2) was employed as model analyte to study the performance of the PMMA microchip and the detector. Factors influencing migration and detection processes were examined and optimized. Separation of H(2)O(2) and L-ascorbic acid (AsA) was developed in order to evaluate the efficiency of microchips using different buffer systems. This detection has been checked for the first time with a microchip made of Topas, obtaining a good linear relationship for mixtures of H(2)O(2) and AsA in different buffers.     

Robust polymer microfluidic device fabrication via contact liquid photolithographic polymerization (CLiPP)

Microfluidic devices are commonly fabricated in silicon or glass using micromachining technology or elastomers using soft lithography methods; however, invariable bulk material properties, limited surface modification methods and difficulty in fabricating high aspect ratio devices prevent these materials from being utilized in numerous applications and/or lead to high fabrication costs. Contact Liquid Photolithographic Polymerization (CLiPP) was developed as an alternative microfabrication approach that uniquely exploits living radical photopolymerization chemistry to facilitate surface modification of device components, fabrication of high aspect ratio structures from many different materials with numerous covalently-adhered layers and facile construction of three-dimensional devices. This contribution describes CLiPP and demonstrates unique advantages of this new technology for microfabrication of polymeric microdevices. Specifically, the procedure for fabricating devices with CLiPP is presented, the living radical photopolymerization chemistry which enables this technology is described, and examples of devices made using CLiPP are shown.     

Fabrication of poly(methyl methacrylate) capillary electrophoresis microchips by in situ surface polymerization

A novel method based on in situ surface polymerization of methyl methacrylate (MMA) has been developed for the rapid fabrication of poly(methyl methacrylate) (PMMA) capillary electrophoresis (CE) microchips. MMA containing both thermal and ultraviolet (UV) initiators was allowed to prepolymerize in a water bath to form a fast curing molding solution that was subsequently sandwiched between a nickel template and a PMMA plate. The images of the raised microchannels on the nickel template were precisely replicated into the synthesized PMMA substrates during the UV-initiated polymerization of the molding solution within 30 min under ambient temperature. The attractive performances of the novel PMMA microchips have been demonstrated in connection with amperometric detection for the separation and detection of several model analytes. The new approach significantly simplifies the process for fabricating PMMA devices and could be applied to other materials that undergo light-initiated polymerization.     

Designing Gelatin Based Blood Compatible Materials with Hydrophilic and Hydrophobic Macromolecular Chains

Polymer matrices based on poly 2-hydroxyethyl methacrylate (PHEMA) have emerged as promising materials for developing applications in biomedical and tissue engineering fields. The major criteria of a material to be used as a support matrix in tissue engineering application rests on its biocompatible, hydrophilic, and mechanically strong nature. Although a great deal of research efforts have been put into designing such materials, achieving these properties together for such a material still remains a challenge. Thus, by a judicious combination of natural and synthetic polymers, such as gelatin and copolymers of PHEMA and PAN, respectively, it has been attempted to synthesize a polymer material by redox polymerization method. The prepared polymer matrix was characterized by FTIR, scanning electron microscopy (SEM), and differential scanning calorimetry (DSC) techniques. The prepared polymeric biomaterials were assessed for their water sorption potential under varying experimental conditions such as chemical composition, pH, and temperature of the swelling bath. The diffusion mechanism of transport of water molecules arising due to solvent–polymer interaction was analyzed to predict the behavior of continuously relaxing macromolecular chains. The in vitro blood compatibility of the prepared polymeric materials was determined by methods such as blood clot formation, platelet adhesion, percent hemolysis assay, and protein–adsorption on the surface of the prepared biomaterials.     

Surface modification of poly(dimethylsiloxane) microfluidic devices and its application in simultaneous analysis of uric acid and ascorbic acid in human urine

A novel and simple method based on layer-by-layer (LBL) technique has been developed for the modification of the channel in PDMS electrophoresis microchip to create a hydrophilic surface with a stable EOF. The functional surface was obtained by sequentially immobilizing chitosan and deoxyribonucleic acid (DNA) onto the microfluidic channel surface using the LBL assembly technique. Compared to the native PDMS microchips, the contact angle of the chitosan-DNA modified PDMS microchips decreased and the EOF increased. Experimental conditions were optimized in detail. The chitosan-DNA modified PDMS microchips exhibited good reproducibility and long-term stability. Separation of uric acid (UA) and ascorbic acid (AA) performed on the modified PDMS microchip generated 43,450 and 46,790 N/m theoretical plates compared with 4048 and 19,847 N/m with the native PDMS microchip. In addition, this method has been successfully applied to real human urine samples, without SPE, with recoveries of 97-105% for UA and AA.     

Synthesis and release profile analysis of thermo-sensitive albumin hydrogels

Novel thermo-responsive hydrophilic microspheres were prepared by free radical polymerization of methacrylate bovine serum albumin and N-isopropylacrylamide, as cross-linker and functional monomer, respectively. The incorporation of monomers in the network was confirmed by infrared spectroscopy, while the network density and shape of hydrogels strictly depend on concentration of monomers in the polymerization feed. The thermal analyses showed negative thermo-responsive behavior with pronounced water affinity of microspheres at temperature lower than lower critical solution temperature (LCST). The in vitro release studies of drug-loaded thermo-sensitive hydrogels were performed. Experimental data showed, for the copolymers with functional monomer/cross-linker ratio ≤ 1, a predominant drug release in the collapsed state, while the copolymers with functional monomer/cross-linker ratio > 1 showed prominent drug release in the swollen state. Below the hydrogel LCST, drug release through the swollen polymeric networks was observed, while a squeezing-out effect at temperature above the LCST was predominant.     

Aqueous Self‐Assembly of Purely Hydrophilic Block Copolymers into Giant Vesicles

Self‐assembly of macromolecules is fundamental to life itself, and historically, these systems have been primitively mimicked by the development of amphiphilic systems, driven by the hydrophobic effect. Herein, we demonstrate that self‐assembly of purely hydrophilic systems can be readily achieved with similar ease and success. We have synthesized double hydrophilic block copolymers from polysaccharides and poly(ethylene oxide) or poly(sarcosine) to yield high molar mass diblock copolymers through oxime chemistry. These hydrophilic materials can easily assemble into nanosized (<500 nm) and microsized (>5 μm) polymeric vesicles depending on concentration and diblock composition. Because of the solely hydrophilic nature of these materials, we expect them to be extraordinarily water permeable systems that would be well suited for use as cellular mimics.