Rigid matrix supports osteogenic differentiation of stem cells from human exfoliated deciduous teeth (SHED)

Stem cell fate can be induced by the grade of stiffness of the extracellular matrix, depending on the developed tissue or complex tissues. For example, a rigid extracellular matrix induces the osteogenic differentiation in bone marrow derived mesenchymal stem cells (MSCs), while a softer surface induces the osteogenic differentiation in dental follicle cells (DFCs). To determine whether differentiation of ectomesenchymal dental precursor cells is supported by similar grades of extracellular matrices (ECMs) stiffness, we examined the influence of the surface stiffness on the proliferation and osteogenic differentiation of stem cells from human exfoliated deciduous teeth (SHED). Cell proliferation of SHED was significantly decreased on cell culture surfaces with a muscle-like stiffness. A dexamethasone-based differentiation medium induced the osteogenic differentiation of SHED on substrates of varying mechanical stiffness. Here, the hardest surface improved the induction of osteogenic differentiation in comparison to that with the softest stiffness. In conclusion, our study showed that the osteogenic differentiation of ectomesenchymal dental precursor cells SHED and DFCs are not supported by similar grades of ECM stiffness.     

Utilization of newly developed immobilized enzyme reactors for preparation and study of immunoglobulin G fragments

The newly developed immobilized enzyme reactors (IMERs) with proteolytic enzymes chymotrypsin, trypsin or papain were used for specific fragmentation of high molecular-mass and heterogeneous glycoproteins immunoglobulin G (IgG) and crystallizable fragment of IgG (Fc). The efficiency of splitting or digestion were controlled by RP-HPLC. The specificity of digestion by trypsin reactor was controlled by MS. IMERs (trypsin immobilized on magnetic microparticles focused in a channel of magnetically active microfluidic device) was used for digestion of the whole IgG molecule. The sufficient conditions for IgG digestion in microfluidic device (flow rate, ratio S:E, pH, temperature) were optimized. It was confirmed that the combination of IMERs with microfluidic device enables efficient digestion of highly heterogeneous glycoproteins such as IgG in extremely short time and minimal reaction volume.     

Amphiphilic hydrolyzable polydimethylsiloxane-b-poly(ethyleneglycol methacrylate-co-trialkylsilyl methacrylate) block copolymers for marine coatings. II. Antifouling laboratory tests and field trials

Abstract

Poly(dimethylsiloxane) (PDMS) elastomer coatings containing an amphiphilic hydrolyzable diblock copolymer additive were prepared and their potential as marine antifouling and antiadhesion materials was tested. The block copolymer additive consisted of a PDMS first block and a random poly(trialkylsilyl methacrylate (TRSiMA, R?=?butyl, isopropyl)-co-poly(ethyleneglycol) methacrylate (PEGMA) copolymer second block. PDMS-b-TRSiMA block copolymer additives without PEGMA units were also used as additives. The amphiphilic character of the coating surface was assessed in water using the captive air bubble technique for measurements of static and dynamic contact angles. The attachment of macro- and microorganisms on the coatings was evaluated by field tests and by performing adhesion tests to the barnacle Amphibalanus amphitrite and the green alga Ulva rigida. All the additive-based PDMS coatings showed better antiadhesion properties to A. amphitrite larvae than to U. rigida spores. Field tests provided meaningful information on the antifouling and fouling release activity of coatings over an immersion period of 23?months.     

条形码微流控芯片在分泌蛋白检测方面的应用

微流控芯片具有液体流动可控、消耗试样少、分析速度快等特点,它可以在几分钟甚至更短的时间内进行上百个样品的同时分析,并且可以实现在线样品的预处理及分析全过程。一种条形码微流控芯片能够以高密度的单链DNA为模板,从而克服了传统蛋白质微流控芯片固定在固体表面容易变性的缺点,既解决了稳定性的要求,又满足芯片平行处理大量数据的要求,可以用来大量的、快速的定量检测细胞的分泌蛋白。条形码微流控芯片因其对样品要求简单、低耗高效、高通量等特点正在成为分泌蛋白检测的最具吸引力的分析工具,在样品分析与检测以及临床检测研究等领域得到了广泛的应用。     

A microfluidic lung-on-a-chip based on biomimetic hydrogel membrane

Lung-on-chips have showed great promise as a tool to recapitulate the respiratory system for investigation of lung diseases in the past decade. However, the commonly applied artificial elastic membrane (e.g., polydimethylsiloxane, PDMS) in the chip failed to mimic the alveolar basal membrane in the composition and mechanical properties. Here we replaced the PDMS film by a thin, biocompatible, soft, and stretchable membrane based on F127-DA hydrogel that well approached to the composition and stiffness of extracellular matrix in human alveoli for construction of lung-on-a-chip. This chip well reconstructed the mechanical microenvironments in alveoli so that the epithelial/endothelial functions were highly expressed with a well established alveolar-capillary barrier. In opposite to the unexpectedly accelerated fibrotic process on the PDMS-based lung-on-a-chip, HPAEpiCs on hydrogel-based chip only presented fibrosis under nonphysiologically high strain, well reflecting the features of pulmonary fibrosis in vivo. This physiologically relevant lung-on-a-chip would be an ideal model in investigation of lung diseases and for development of antifibrosis drugs.     

All-atom and coarse-grained force fields for polydimethylsiloxane

By combining the bottom-up and top-down approaches, we have developed a new all-atom (AA) force field from quantum mechanics and experimental data and a new coarse grained (CG) force field from AA simulation and experimental data, for polydimethylsiloxane (PDMS). The AA force field is developed based on the TEAM force field database. The CG force field uses a mapping rule that splits the connecting oxygen into neighbouring CG beads to maintain the charge neutrality of the beads, analytical functional forms including anharmonic terms in the valence terms, and the temperature-dependent free-energy functional form to describe the inter-bead interactions. Broad range of thermodynamic properties of PDMS including density, surface tension, solubility parameter, radius of gyration and glass transition temperature are calculated to validate the force fields, and good agreements with the experimental data are obtained.     

Lipid-gel and poly(dimethylsiloxane) film to mimic bioaccumulation in adipocytes

Bioaccumulation is an increasingly important consideration in validation studies of the safety and efficacy of potential drugs. Although an "adipocyte" cell line model has been proven successful to mimic the accumulation of naphthalene in adipocytes, the prolonged incubation time limits its use in high-throughput studies and reduces reproducibility. In this investigation, naphthalene and naphthol accumulation and uptake kinetics of thin poly(dimethylsiloxane) (PDMS) film and lipid nanospheres suspended in a crosslinked gelatin gel (lipid-gel) were compared with those of adipocytes. Unlike the PDMS film, the lipid-gel can mimic the kinetics and extent of naphthalene accumulation in the adipocytes reasonably well. However, the lipid-gel accumulated about twice as much naphthol as the adipocytes, suggesting that hydrophobicity/hydrophilicity of the metabolite may be an important factor in the accuracy of accumulation studies with the lipid-gel. Nonetheless, the lipid-gel system shows promise as an inexpensive, convenient, and reproducible fat mimic for bioaccumulation studies.     

Procedure for the Development of Multi-depth Circular Cross-sectional Endothelialized Microchannels-on-a-chip

Efforts have been focused on developing in vitro assays for the study of microvessels because in vivo animal studies are more time-consuming, expensive, and observation and quantification are very challenging. However, conventional in vitro microvessel assays have limitations when representing in vivo microvessels with respect to three-dimensional (3D) geometry and providing continuous fluid flow. Using a combination of photolithographic reflowable photoresist technique, soft lithography, and microfluidics, we have developed a multi-depth circular cross-sectional endothelialized microchannels-on-a-chip, which mimics the 3D geometry of in vivo microvessels and runs under controlled continuous perfusion flow. A positive reflowable photoresist was used to fabricate a master mold with a semicircular cross-sectional microchannel network. By the alignment and bonding of the two polydimethylsiloxane (PDMS) microchannels replicated from the master mold, a cylindrical microchannel network was created. The diameters of the microchannels can be well controlled. In addition, primary human umbilical vein endothelial cells (HUVECs) seeded inside the chip showed that the cells lined the inner surface of the microchannels under controlled perfusion lasting for a time period between 4 days to 2 weeks.     

微流控技术在细胞生物学中的应用

微流控技术是在尺度为几个或上百微米的通道中操纵纳升或纳升以下流体的技术,作为一种全新的领域,它给化学合成、生物分析、光学和信息学带来了重大的影响。本文将综述微流控技术在细胞学等领域的应用,并对其发展前景进行展望。