As an ideal method to manipulate biological particles, the dielectrophoresis (DEP) technique has been widely used in clinical diagnosis, disease treatment, drug development, immunoassays, cell sorting, etc. This review summarizes the research in the field of bioparticle manipulation based on DEP techniques. Firstly, the basic principle of DEP and its classical theories are introduced in brief; Secondly, a detailed introduction on the DEP technique used for bioparticle manipulation is presented, in which the applications are classified into five fields: capturing bioparticles to specific regions, focusing bioparticles in the sample, characterizing biomolecular interaction and detecting microorganism, pairing cells for electrofusion and separating different kinds of bioparticles; Thirdly, the effect of DEP on bioparticle viability is analyzed; Finally, the DEP techniques are summarized and future trends in bioparticle manipulation are suggested.
Electrodes with three-dimensional (3D) nanostructure are expected to improve the energy and power densities per footprint area of lithium ion microbatteries. Herein, we report a large-scale synthesis of a SnO(2)/α-Fe(2)O(3) composite nanotube array on a stainless steel substrate via a ZnO nanowire array as an in situ sacrificial template without using any strong acid or alkali. Importantly, both SnO(2) and α-Fe(2)O(3) contribute to the lithium storage, and the hybridization of SnO(2) and α-Fe(2)O(3) into an integrated nanotube structure provides them with an elegant synergistic effect when participating in electrochemical reactions. Large areal capacities and good rate capability are demonstrated for such a composite nanotube array. Particularly noteworthy is that the areal capacities (e.g. 1.289 mAh cm(-2) at a current rate of 0.1 mA cm(-2)) are much larger than those of many previous thin-film/3D microbattery electrodes. Our work suggests the possibility of further improving the areal capacity/energy density of 3D microelectrodes by designing ordered hybrid nanostructure arrays.
This paper reports a kind of graphene superhydrophobic composite which shows robust resistance to extensive and cyclic stretching, oil contamination, knife-scratch, hand-rub, sandpaper abrasion, heat treatment and corrosive liquid attack. Moreover, this superhydrophobic composite is also a sensitive electromechanical sensor.
Globally, about 50% of all arable soils are classified as acidic. As crop and plant growth are significantly hampered under acidic soil conditions, many farmers, but increasingly as well forest managers, apply lime to raise the soil pH. Besides its direct effect on soil pH, liming also affects soil C and nutrient cycles and associated greenhouse gas (GHG) fluxes. In this meta-analysis, we reviewed 1570 observations reported in 121 field-based studies worldwide, to assess liming effects on soil GHG fluxes and plant productivity. We found that liming significantly increases crop yield by 36.3%. Also, soil organic C (SOC) stocks were found to increase by 4.51% annually, though soil respiration is stimulated too (7.57%). Moreover, liming was found to reduce soil N 2 O emission by 21.3%, yield-scaled N 2 O emission by 21.5%, and CH 4 emission and yieldscaled CH 4 emission from rice paddies by 19.0% and 12.4%, respectively. Assuming that all acid agricultural soils are limed periodically, liming results in a total GHG balance benefit of 633−749 Tg CO 2 -eq year −1 due to reductions in soil N 2 O emissions (0.60−0.67 Tg N 2 O-N year −1 ) and paddy soil CH 4 emissions (1.75−2.21 Tg CH 4 year −1 ) and increases in SOC stocks (65.7-110 Tg C year −1 ). However, this comes at the cost of an additional CO 2 release (c. 624-656 Tg CO 2 year −1 ) deriving from lime mining, transport and application, and lime dissolution, so that the overall GHG balance is likely neutral. Nevertheless, liming of acid agricultural soils will increase yields by at least 6.64 × 10 8 Mg year −1 , covering the food supply of 876 million people. Overall, our study shows for the first time that a general strategy of liming of acid agricultural soils is likely to result in an increasing sustainability of global agricultural production, indicating the potential benefit of liming acid soils for climate change mitigation and food security.
Silver
nanoparticles (AgNPs) have gained much attention in biomedical
research because of their antibacterial properties. However, they
have also exhibited cytotoxicity toward certain mammalian cells. In
order to improve therapeutic efficacy, the incorporation of gold (Au)
and Ag into bimetallic Ag–Au NPs is a promising strategy, as
it has the potential to increase biocompatibility and maintain antibacterial
activity. Toward this end, we prepared a series of bimetallic Ag–Au
NPs and studied them with X-ray absorption spectroscopy (XAS) in order
to elucidate the correlation of atomic structure to their bioactivities.
The addition of Au was found to drastically change the atomic structure
of the Ag NPs; namely, the Ag core of the NPs was gradually replaced
with Au, while Ag was found mostly on the surface. Next, NP antibacterial
activity toward S. aureus and cytotoxicity toward
NIH-3T3 fibroblast cells were assessed. It was found that the antibacterial
activity of the bimetallic NPs was lower than pure Ag NPs and dependent
on the Ag location within the NPs. On the other hand, the cytotoxicity
of bimetallic NPs was much lower than the pure Ag NPs and dependent
on the overall Au concentration. Using the structural information
garnered from XAS, we were able to rationalize the bioactivity results
of the NPs based on their atomic structure and provide guiding principles
to design Au–Ag NPs with balanced antibacterial and cytotoxic
activities. This work represents an important step toward engineering
the atomic structure of bimetallic Au–Ag NPs for biomedical
applications.
In this study, a flexible tactile sensing array based on a capacitive mechanism was designed, fabricated, and characterized for sensitive robot skin. A device with 8 × 8 sensing units was composed of top and bottom flexible polyethyleneterephthalate (PET) substrates with copper (Cu) electrodes, a polydimethylsiloxane (PDMS) dielectric layer, and a bump contact layer. Four types of microstructures (i.e., pyramids and V-shape grooves) atop a PDMS dielectric layer were well-designed and fabricated to enhance tactile sensitivity. The optimal sensing unit achieved a high sensitivity of 35.9%/N in a force range of 0–1 N. By incorporating a tactile feedback control system, the flexible sensing array as the sensitive skin of a robotic manipulator demonstrated a potential capability of robotic obstacle avoidance.
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