Correction: Zheng, N.; Wu, D.; Sun, P.; Liu, H.; Luo, B.; and Li, L., Mechanical Properties and Fire Resistance of Magnesium-Cemented Poplar Particleboard. Materials, 2019, 12, 3161

Zheng, Nihua; Wu, Danni; Sun, Peizhe; Liu, Hongguang; Luo, Bin; Li, Li

doi:10.3390/ma13010115

Cited by 16 publications

(16 citation statements)

References 1 publication

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“…we identified in DRGs from naive animals were also observed in all injury models and are 139 similar to those previously reported (Figure S1C-D) (Usoskin et al, 2015;Zeisel et al, 140 2018; Zheng et al, 2019). We also observed a neuronal cluster that expresses Fam19a4, 141 but very low levels of Th, which we termed putative-cLTMR2 (p_cLTMR2).…”

supporting

confidence: 88%

Transcriptional reprogramming of distinct peripheral sensory neuron subtypes after axonal injury

Renthal

Tochitsky

Yang

et al. 2019

Preprint

129

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24Primary somatosensory neurons are specialized to transmit specific types of sensory 25 information through differences in cell size, myelination, and the expression of distinct 26 receptors and ion channels, which together define their transcriptional and functional 27 identity. By transcriptionally profiling sensory ganglia at single-cell resolution, we find that 28 different somatosensory neuronal subtypes undergo a remarkably consistent and 29 dramatic transcriptional response to peripheral nerve injury that both promotes axonal 30 regeneration and suppresses cell identity. Successful axonal regeneration leads to a 31 restoration of neuronal cell identity and the deactivation of the growth program. This 32 injury-induced transcriptional reprogramming requires Atf3, a transcription factor which is 33 induced rapidly after injury and is necessary for axonal regeneration and functional 34 recovery. While Atf3 and other injury-induced transcription factors are known for their role 35 in reprogramming cell fate, their function in mature neurons is likely to facilitate major 36 adaptive changes in cell function in response to damaging environmental stimuli. 37 38

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supporting

confidence: 88%

Transcriptional reprogramming of distinct peripheral sensory neuron subtypes after axonal injury

Renthal

Tochitsky

Yang

et al. 2019

Preprint

129

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“…[1][2] Extensive efforts have been made in order to reduce the Pt loading (or to replace Pt by non-noble metal) and cost by sustaining (or even improving) the activity and durability of the catalyst under fuel cell operation conditions for prolonged durations. [3][4][5][6] Since, ORR is found to be very sensitive to the surface electronic structure and surface atomic arrangement of the Pt catalyst; engineering its surface properties is believed to be effective in achieving enhancement in the catalyst activity and durability. [7] Manipulation of the surface properties has been achieved by various ways such as: (i) synthesizing Pt nanocrystals with the most active exposed facets, [8] (ii) combining Pt with other non-precious metals in the form of alloy, core shell, and dendrimer nanostructures showing improved proper-ties due to synergistic effects of two different metals, [9][10][11][12][13] (iii) decorating the Pt surface with the foreign species like metal clusters, organic molecules, ions, organic or inorganic compounds [14][15][16] and (iv) selecting high corrosion resistant carbon or non-carbon support to enhance the durability by improving catalyst support interactions.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Oxygen Reduction Reaction by Pd‐Pt Alloy Catalyst with Stabilized Platinum Skin

et al. 2020

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Reducing the consumption of precious Platinum (Pt) metal by alloying with other transition metals or searching a new low cost, Pt‐free catalyst with the activity and durability higher than the state‐of‐the‐art Pt/C catalyst are the two possible approaches to accelerate the practical application of low temperature fuel cells. Herein we investigate the oxygen reduction reaction (ORR) electrocatalytic activity (1023 μA cm−2.Pt; 5 times higher than commercial Pt/C) and the corrosion stability of novel “Pt skin@PdPt” nanostructures in acidic media. An interesting trend of increment in the ORR activity with durability cycles has been found indicating a systematic surface rearrangement in “Pt skin@PdPt”. A systematic enhancement in the ORR activity from an initial value of 1023 μA cm−2.Pt to 1448 μA cm−2.Pt after 30,000 durability cycles has been observed indicating stable nature of low Pt content Pt skin@PdPt electrocatalyst. More than seven times (1448 μA cm−2.Pt) higher activity against the state‐of‐the‐art Pt/C catalyst has been seen with an electrochemical surface area (ECSA) of ∼97 m2 g−1.Pt, even after 30,000 potential cycles.

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“…These composite materials usually exhibit varying improvements in mechanical strength, thermal and electrical conductivity, stability, and biocompatibility, based on the combination of the excellent physical and chemical properties of graphene-family materials and the stable biomedical properties of SF. [54][55][56] Huang et al prepared composite films of GO and SF (15 wt%) with layered structures by modulating the pH of a solution of the two to around pH 10 and casting SF-GO hydrogels. [47] The resulting film showed a high tensile strength of 221.3 � 16.4 MPa, a high modulus of 17.2 � 1.9 GPa, and a failure strain of 1.8 � 0.4%, which values partially surpass those of natural nacre and similar nacre-like composites reported previously.…”

Section: Properties Of Composite Materialsmentioning

confidence: 99%

Combined Application of Graphene‐Family Materials and Silk Fibroin in Biomedicine

et al. 2019

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The main graphene‐family materials used in biomedicine include graphene, graphene oxide, and reduced graphene oxide. They have been well documented for their distinctive microstructure and excellent physicochemical properties. Although they also have some shortcomings, such as slow biodegradation and dose‐dependent biotoxicity, these problems can be solved by using them in conjunction with other biomaterials. Silk fibroin (SF), a natural polymer material with many advantageous properties, has been used widely in biomedicine. However, SF requires modification by other biomaterials to improve its mechanical properties and control its degradation rate for further use. In recent years, the combined application of graphene‐family materials and SF has increased gradually, and the effects of it on cell behavior have been preliminary investigated, such as promoting cell adhesion, proliferation, and differentiation. Further studies of the combined use have been conducted in biomedicine, including tissue engineering, biosensor, and other biomedical usage. In this paper, this combined application has been outlined and summarized, and some envisioned challenges and future perspectives have been mentioned. We hope that this review will provide some reference and inspiration for the combined application of graphene‐family materials and SF in biomedicine in the future.

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Correction: Zheng, N.; Wu, D.; Sun, P.; Liu, H.; Luo, B.; and Li, L., Mechanical Properties and Fire Resistance of Magnesium-Cemented Poplar Particleboard. Materials, 2019, 12, 3161

Abstract: The authors wish to revise the affiliation, due to the errors regarding affiliation in this published paper [...]

Cited by 16 publications

References 1 publication

Transcriptional reprogramming of distinct peripheral sensory neuron subtypes after axonal injury

Transcriptional reprogramming of distinct peripheral sensory neuron subtypes after axonal injury

Enhanced Oxygen Reduction Reaction by Pd‐Pt Alloy Catalyst with Stabilized Platinum Skin

Combined Application of Graphene‐Family Materials and Silk Fibroin in Biomedicine

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