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61.
Mark A. Hughes Paul M. Brennan Andrew S. Bunting Mike J. Shipston Alan F. Murray 《Journal of visualized experiments : JoVE》2014,(85)
Cell patterning platforms support broad research goals, such as construction of predefined in vitro neuronal networks and the exploration of certain central aspects of cellular physiology. To easily combine cell patterning with Multi-Electrode Arrays (MEAs) and silicon-based ‘lab on a chip’ technologies, a microfabrication-compatible protocol is required. We describe a method that utilizes deposition of the polymer parylene-C on SiO2 wafers. Photolithography enables accurate and reliable patterning of parylene-C at micron-level resolution. Subsequent activation by immersion in fetal bovine serum (or another specific activation solution) results in a substrate in which cultured cells adhere to, or are repulsed by, parylene or SiO2 regions respectively. This technique has allowed patterning of a broad range of cell types (including primary murine hippocampal cells, HEK 293 cell line, human neuron-like teratocarcinoma cell line, primary murine cerebellar granule cells, and primary human glioma-derived stem-like cells). Interestingly, however, the platform is not universal; reflecting the importance of cell-specific adhesion molecules. This cell patterning process is cost effective, reliable, and importantly can be incorporated into standard microfabrication (chip manufacturing) protocols, paving the way for integration of microelectronic technology. 相似文献
62.
EFFECTS OF SILICON DEFICIENCY ON LIPID COMPOSITION AND METABOLISM IN THE DIATOM CYCLOTELLA CRYPTICA1
Paul G. Roessler 《Journal of phycology》1988,24(3):394-400
The effects of silicon deficiency on the metabolism and composition of lipids in Cyclotella cryptica T13L Reimann, Lewin, and Guillard were examined. Silicon-deficient cells had higher levels of neutral lipids (primarily triacylglycerols) and higher proportions of saturated and monounsaturated fatty acids than silicon-replete cells. After 4 h of silicon deficiency, the percentage of newly assimilated NaH14CO3 partitioned into lipids increased from 27.6% to 54.1%, whereas the percentage partitioned into chrysolaminarin decreased from 21.6% to 10.6%. In addition, pulse-chase experiments with NaH14CO3 indicated that the amount of 14C in the total cellular lipid fraction increased by 32% after 12 h of silicon deficiency despite the absence of additional photoassimilable 14C. Therefore, the accumulation of lipids in response to silicon deficiency appears to be due to two distinct processes: (a) an increase in the proportion of newly assimilated carbon partioned into lipids, and (2) a slow conversion of previously assimilated carbon from non-lipid compounds into lipids 相似文献
63.
Whisker-mediated transformation of embryogenic callus of maize 总被引:4,自引:0,他引:4
The present study was designed to establish embryogenic callus as a target tissue for whisker-mediated transformation of
maize (Zea mays L.). Silicon carbide whiskers were used to deliver the bar and uidA (GUS) genes into embryogenic maize callus. Samples of osmotically-treated Type II callus were vigorously agitated in the
presence of whiskers and plasmid DNA using a standard laboratory vortex or a modified dental amalgamator. On average, three
transgenic callus lines were obtained per 100 samples treated. Plants were regenerated from several GUS-expressing callus
lines and DNA analyses confirmed stable integration and inheritance. As with other direct DNA delivery methods involving embryogenic
maize callus, integration patterns of the inserted DNA appeared to be complex. Although currently less efficient than microparticle
bombardment on a per target basis, whisker-mediated transformation of embryogenic callus represents a viable method for transgenic
maize production.
Received: 14 May 1999 / Revision received: 11 October 1999 / Accepted: 11 October 1999 相似文献
64.
Large scale electrophysiological recordings from neuronal ensembles offer the opportunity to investigate how the brain orchestrates the wide variety of behaviors from the spiking activity of its neurons. One of the most effective methods to monitor spiking activity from a large number of neurons in multiple local neuronal circuits simultaneously is by using silicon electrode arrays1-3.Action potentials produce large transmembrane voltage changes in the vicinity of cell somata. These output signals can be measured by placing a conductor in close proximity of a neuron. If there are many active (spiking) neurons in the vicinity of the tip, the electrode records combined signal from all of them, where contribution of a single neuron is weighted by its ''electrical distance''. Silicon probes are ideal recording electrodes to monitor multiple neurons because of a large number of recording sites (+64) and a small volume. Furthermore, multiple sites can be arranged over a distance of millimeters, thus allowing for the simultaneous recordings of neuronal activity in the various cortical layers or in multiple cortical columns (Fig. 1). Importantly, the geometrically precise distribution of the recording sites also allows for the determination of the spatial relationship of the isolated single neurons4. Here, we describe an acute, large-scale neuronal recording from the left and right forelimb somatosensory cortex simultaneously in an anesthetized rat with silicon probes (Fig. 2). 相似文献
65.
Seung?Jae?Oh Jong?Keun?Song Sung?June?KimEmail author 《Biotechnology and Bioprocess Engineering》2003,8(4):252-256
In this paper we describe the status of a silicon-based microelectrode for neural recording and an advanced neural interface.
We have developed a silicon neural probe, using a combination of plasma and wet etching techniques. This process enables the
probe thickness to be controlled precisely. To enhance the CMOS compatibility in the fabrication process, we investigated
the feasibility of the site material of the doped polycrystalline silicon with small grains of around 50 nm in size. This
silicon electrode demonstrated a favorable performance with respect to impedance spectra, surface topography and acute neural
recording. These results showed that the silicon neural probe can be used as an advanced microelectrode for neurological applications. 相似文献
66.
Novel ordered hierarchical mesoporous/microporous carbon (OHMMC) derived from mesoporous titanium‐carbide/carbon composites was prepared for the first time by synthesizing ordered mesoporous nanocrystalline titanium‐carbide/carbon composites, followed by chlorination of titanium carbides. The mesostructure and microstructure can be conveniently tuned by controlling the TiC contents of mesoporous TiC/C composite precursor, and chlorination temperature. By optimal condition, the OHMMC has a high surface area (1917 m2g?1), large pore volumes (1.24 cm3g?1), narrow mesopore‐size distributions (centered at about 3 nm), and micropore size of 0.69 and 1.25 nm, and shows a great potential as electrode for supercapacitor applications: it exhibits a high capacitance of 146 Fg?1 in noaqueous electrolyte and excellent rate capability. The ordered mesoporous channel pores are favorable for retention and immersion of the electrolyte, providing a more favorable path for electrolyte penetration and transportation to achieve promising rate capability performance. Meanwhile, the micropores drilled on the mesopore‐walls can increase the specific surface area to provide more sites for charge storage. 相似文献
67.
Salvatore Petralia Daniele Motta Sabrina Conoci 《Biotechnology and bioengineering》2019,116(8):2087-2094
In this paper, a miniaturized biosensor containing 96 silicon microchambers electroloaded with nano-volumes of liquid (EW-chip) is presented. The liquid electroloading is achieved by the appropriate modulation of interface properties. The surface chemistries have been studied to guarantee effective interface properties for both electrowetting on dielectric actuation and biocompatibility versus biochemical reactions. The silicon microchambers are 200 nl in volume and are connected to a specific system of electrodes able to deliver liquid sample on each well. The device also integrates temperature sensors and heaters to perform biochemical reactions. On that, the effectiveness of this device has been successfully proven towards the nucleic acids detection via real-time polymerase chain reaction amplification. Hepatitis B virus genome target has been used to assess the device performance. Results show very uniform amplification over the 96 microchambers without any cross-contamination process. These features make this system a very appealing potential solution for genetic point-of-care devices where a high level of parallelism of analysis is required. 相似文献
68.
Designing Active and Stable Silicon Photocathodes for Solar Hydrogen Production Using Molybdenum Sulfide Nanomaterials 下载免费PDF全文
Jesse D. Benck Sang Chul Lee Kara D. Fong Jakob Kibsgaard Robert Sinclair Thomas F. Jaramillo 《Liver Transplantation》2014,4(18)
Silicon is a promising photocathode for tandem photoelectrochemical water splitting devices, but efficient catalysis and long term stability remain key challenges. Here, it is demonstrated that with appropriately engineered interfaces, molybdenum sulfide nanomaterials can provide both corrosion protection and catalytic activity in silicon photocathodes. Using a thin MoS2 surface protecting layer, MoS2‐n+p Si electrodes that show no loss in performance after 100 h of operation are created. Transmission electron microscopy measurements show the atomic structure of the device surface and reveal the characteristics of the MoS2 layer that provide both catalytic activity and excellent stability. In spite of a low concentration of exposed catalytically active sites, these electrodes possess the best performance of any precious metal‐free silicon photocathodes with demonstrated long term stability to date. To further improve efficiency, a second molybdenum sulfide nanomaterial, highly catalytically active [Mo3S13]2? clusters, is incorporated. These photocathodes offer a promising pathway towards sustainable hydrogen production. 相似文献
69.
Kashish Sharma Annalisa Branca Andrea Illiberi Frans D. Tichelaar Mariadriana Creatore Mauritius C. M. van de Sanden 《Liver Transplantation》2011,1(3):401-406
In this paper the effect of the microstructure of remote plasma‐deposited amorphous silicon films on the grain size development in polycrystalline silicon upon solid‐phase crystallization is reported. The hydrogenated amorphous silicon films are deposited at different microstructure parameter values R* (which represents the distribution of SiHx bonds in amorphous silicon), at constant hydrogen content. Amorphous silicon films undergo a phase transformation during solid‐phase crystallization and the process results in fully (poly‐)crystallized films. An increase in amorphous film structural disorder (i.e., an increase in R*), leads to the development of larger grain sizes (in the range of 700–1100 nm). When the microstructure parameter is reduced, the grain size ranges between 100 and 450 nm. These results point to the microstructure parameter having a key role in controlling the grain size of the polycrystalline silicon films and thus the performance of polycrystalline silicon solar cells. 相似文献
70.
Matthias Weiling Christian Lechtenfeld Felix Pfeiffer Lars Frankenstein Diddo Diddens Jian-Fen Wang Sascha Nowak Masoud Baghernejad 《Liver Transplantation》2024,14(5):2303568
The implementation of silicon (Si)-containing negative electrodes is widely discussed as an approach to increase the specific capacity of lithium-ion batteries. However, challenges caused by severe volume changes and continuous (re-)formation of the solid-electrolyte interphase (SEI) on Si need to be overcome. The volume changes lead to electrolyte consumption and active lithium loss, decaying the cell performance and cycle life. Herein, the additive 2-sulfobenzoic acid anhydride (2-SBA) is utilized as an SEI-forming electrolyte additive for SiOx-containing anodes. The addition of 2-SBA to a state-of-the-art carbonate-based electrolyte in high-voltage LiNi0.8Mn0.1Co0.1O2, NMC811||artificial graphite +20% SiOx pouch cells leads to improved electrochemical performance, resulting in a doubled cell cycle life. The origin of the enhanced cell performance is mechanistically investigated by developing an advanced experimental technique based on operando attenuated total reflection Fourier-transform infrared (ATR-FTIR) spectroscopy. The operando ATR-FTIR spectroscopy results elucidate the degradation mechanism via anhydride ring-opening reactions after electrochemical reduction on the anode surface. Additionally, ion chromatography conductivity detection mass spectrometry, scanning electron microscopy, energy dispersive X-ray analysis, and quantum chemistry calculations are employed to further elucidate the working mechanisms of the additive and its degradation products. 相似文献