ライフサイエンスコーパス: plating

1 ving intramedullary nailing in comparison to plating.

2 kjet printing and subsequent chemical copper plating.

3 ional silver mirror reaction and electroless plating.

4 ta-glycerol phosphate to cells at 64 h after plating.

5 ng, in some cases nearly 2 years postinitial plating.

6 nced activation of ERK following fibronectin plating.

7 ed ERK activation in response to fibronectin plating.

8 s may be best treated with locked nailing or plating.

9 me, being wider on day 1 than on day 2 after plating.

10 as determined with calcein-AM 24 hours after plating.

11 cortical neurons (both sexes), silenced from plating.

12 ula: see text]) during days 2, 3 and 4 after plating.

13 e this problem by spatially confining the Li plating.

14 CC), enabling site-directed dendrite-free Li plating.

15 transport medium at room temperature before plating, 51% used Campy blood agar plate medium, 52% rea

16 e of cross-contamination was demonstrated by plating a total of 200 alternating inoculated and steril

17 tic conditions in the presence of particular plating additives (SPS, Imep, PEI, and PAG) used in the

18 To probe the trend of these plating additives toward inclusion into the deposit upon

19 PPy-chitosan plating also improved electric coupling between skeletal

20 Viral replication kinetics and efficiency-of-plating analysis performed at permissive and nonpermissi

21 at low temperature metal pastes, electroless plating and atomic layer deposition can all be used with

22 during charging, the device enables dense Li plating and avoids porosity and dendrites.

23 atients by selective and nonselective direct plating and broth enrichment.

24 were imaged within the first few hours after plating and colonies were accurately counted with result

25 limitations, including labor-intensive agar plating and colony selection methods associated with the

26 resenting four different periods: (i) manual plating and conventional biochemical identification (CON

27 during activating conditions, such as sparse plating and culturing on stiff 2D substrates.

28 lectrolytes enables ultrastable Li stripping/plating and essentially no polysulfide shuttle as well a

29 greement was 83.5% The time interval between plating and final organism identification was decreased

30 of detection of E. coli O157 by both direct plating and IMS was highly dependent upon the initial co

31 concentrations is very poor for both direct plating and IMS.

32 n sensory neurons and L7 begins by 3 h after plating and is accompanied by a rapid accumulation of a

33 ochemical identification (CONV), (ii) manual plating and MALDI-TOF MS identification (MALDI), (iii) M

34 hout the tissue extraction, serial dilution, plating and manual scoring involved in standard assays o

35 creased available surface for homogeneous Li plating and minimize volume fluctuation of Li electrodes

36 cells with two mutations, one formed before plating and one after.

37 technique to impose the exhaustive oxidative plating and re-reduction of halides on the silver elemen

38 Both the plating and replication efficiencies of ICP0- viruses we

39 The state of charge, metallic lithium plating and solid-electrolyte interface (SEI) formation

40 erlying cause of low Coulombic efficiency in plating and stripping (the charge and discharge processe

41 r, nonuniform Li-ion flux during repeated Li plating and stripping leads to continuous Li dendrite gr

42 We propose strategies for making lithium plating and stripping more efficient so that lithium met

43 As for crucial breakthroughs, reversible plating and stripping of calcium at the metal-anode inte

44 inactive or "dead lithium" formation during plating and stripping of lithium in a full-cell lithium

45 s of lithium buds and results in homogeneous plating and stripping of lithium metal anodes.

46 ells and half-cells achieve state-of-the-art plating and stripping performance.

47 anodes suffer from poor reversibility during plating and stripping processes due to their high reacti

48 ation of Li dendrites and inactive Li during plating and stripping processes, which can cause short c

49 overcome is the inferior reversibility of Li plating and stripping, typically thought to be related t

50 However, under repeated plating and stripping, zinc metal anodes undergo a well-

51 l as fast Li-ion diffusion for reversible Li plating and stripping.

52 nstrate the effects of two strategies, pulse plating and the use of electrolyte additives.

53 s 2.11 times higher in patients who received plating and this reached statistical significance (95% C

54 furthers the understanding of nonuniform Li plating and will inspire future studies to prolong the c

55 plating with the same instrument (replicate plating) and of the consensus agreement between the two

56 responses, discussing surface coating, cell plating, and fluorescence imaging in detail.

57 face activity, retarded cell spreading after plating, and led to the formation of immobile, tightly a

58 oast by plating on mCPC agar, enrichment and plating, and quantitative PCR (qPCR).

59 By using cell fractioning, plating, and single-cell fluorescent microscopy, we find

60 , coating the template by electroless nickel plating, and subsequently etching away the template.

61 development of safe and reversible Li metal plating, and the development of stable SEI.

62 aluated cross-contamination, the accuracy of plating, and the quality of the results.

63 brid In-Li anodes that use both alloying and plating approaches for charge storage.

64 It also enhances efficient hPSC plating as single cells.

65 Because of a possible wrapping mechanism, plating assays after post-exposure sonication were perfo

66 Re-plating assays of primary RB1(-/-) calvarial cells after

67 Plating assays show that as-received GO (ARGO) and TGO20

68 Clonogenic (single-cell plating) assays were used to define and quantify subpopu

69 text] preferred-oriented Au thin films by DC plating at 5 mA/cm(2).

70 etal, sustaining over 1000 h of Li stripping/plating at current densities up to 0.6 mA.cm(-2).

71 | Li cell during repeated lithium stripping/plating at room temperature, with a current density of 0

72 ersus Li(+)/Li, avoiding problematic lithium plating at the expense of reduced cell voltage.

73 ransiently, peaking within a few hours after plating, at which time the protein was in the form of pe

74 e in growth cone area already 24 hours after plating; axonal swellings, a hallmark of HSP pathology,

75 Plating battery electrodes typically deliver higher spec

76 his taxon confirms that echinoderms acquired plating before pentaradial symmetry and that their histo

77 position can significantly alter the lithium plating behavior, affording a promising route to suppres

78 ric cells, which exhibit stable Li stripping/plating behaviors with low overpotential of ~6 mV at 200

79 ene concede not only dendrite-free stripping/plating but also abundant open space accommodating volum

80 including surface functionalization and cell plating, can be completed in 10 h.

81 Now, a highly reversible iodine plating cathode is presented that operates on the redox

82 The iodine plating cathode with the theoretical capacity of 211 mAh

83 as TGF-beta2 production was not inhibited by plating cells on a synthetic nanofiber matrix with a thr

84 subcellular regions of cells is achieved by plating cells on an electrode array created by standard

85 In contrast, plating cells on collagen I triggered a TGFbetaRI kinase

86 CLANs were induced by plating cells on fibronectin (a beta1 integrin ligand) i

87 to take approximately 3 d (from the time of plating cells on imaging dishes).

88 This includes plating cells on six-well tissue culture plates or imagi

89 At 21 days post-plating, co-cultures were deformed to 0.50 shear strain

90 on potential of the fusion protein in serial plating colony assays.

91 Here we show a backside-plating configuration that enables long-term cycling of

92 a-Bertani (LB) medium, as well as a profound plating defect.

93 ntal conditions such as cell cycle phase and plating delay (correlation between modelled and observed

94 is integrated model to examine the effect of plating density on tissue growth via autocrine/paracrine

95 this localization pattern is insensitive to plating density.

96 junction communication level and fibronectin plating density.

97 s in ESwab tubes, the manual method and WASP plating each yielded 90 potential pathogens.

98 The plating efficiencies and shelf lives of locally made buf

99 Double dnaA seqA mutants exhibited plating efficiencies much superior to wild-type strains

100 Utilizing a difference in plating efficiencies, we were able to enrich the neuron

101 mined to investigate nonheritable changes in plating efficiency and burst size that depended on which

102 and NPC cells inhibited cell proliferation, plating efficiency and migration, and enhanced sensitivi

103 nstrate differences in cellular viability or plating efficiency but did exhibit a decreased replicati

104 We have found, however, that the enhanced plating efficiency did not occur when cells were synchro

105 Peak plating efficiency occurred as cells cycled out of G1 an

106 This lab reported previously that the plating efficiency of a herpes simplex virus type 1 ICP0

107 ine deprivation alone is able to enhance the plating efficiency of an ICP0(-) virus and that isoleuci

108 We now report that the plating efficiency of ICP0- viruses is not enhanced at a

109 d in five of eight plaques of T2294, and its plating efficiency under foscarnet was increased approxi

110 d into S phase, suggesting that the enhanced plating efficiency was due to cellular activities presen

111 PALB2-deficient cells, a severe reduction in plating efficiency was observed, with many abortive atte

112 east one year, with the post-thaw viability, plating efficiency, and full retention of pluripotent ph

113 (ES) cells lacking Cfp1 exhibit a decreased plating efficiency, decreased cytosine methylation, elev

114 yers prior to infection resulted in enhanced plating efficiency.

115 tions, mutations, micronuclei, and decreased plating efficiency.

116 rs is the primary determinant of ICP0- virus plating efficiency.

117 mu could not be attributed to variations in plating efficiency.

118 ion in the luminal cancer line LNCaP reduced plating efficiency.

119 a simple magnetic separation without a large plating effort.

120 However, a Nafion((R)) coated copper plating electrode shows a successful decrement of the in

121 However, reversible plating electrodes are rare for electronically insulatin

122 a pneumophila including cell cultivation and plating experiments for bacteria quantification.

123 ous starch compared to the spray dried HOSO, plating flavour oils on porous starch could be a suitabl

124 n donors were analyzed within 48 hours after plating for E-cadherin gene and protein expression (by R

125 it stable, low-overpotential Mg striping and plating for over 100 cycles at a current density of 0.05

126 dvantage over conventional direct blood agar plating for the diagnostic confirmation of bartonellosis

127 disaggregating the clumps, then diluting and plating for viable cell enumeration.

128 es by a conventional method that used direct plating from the transport/storage medium (50 specimens

129 ns that were negative by conventional direct plating from transport medium (range of numbers of posit

130 Here, we demonstrate that plating GI-101A human breast cancer cells on hard (0.9%)

131 Patients who received plating had a 2.19 times increased risk of treatment fai

132 ntramedullary nailing and submuscular bridge plating have also recently been reported to produce exce

133 Dissecting the hippocampus and plating hippocampal neurons takes 2-3 h.

134 Bacterial colonization was determined by plating homogenates onto MacConkey agar, and immunofluor

135 6,7) reduces the likelihood of lithium metal plating if proper charging controls are used, alleviatin

136 noelectrodes are prepared by electrochemical plating in a laser-pulled quartz nanopipette tip immerse

137 ion capacity compared to wt controls upon re-plating in methylcellulose supplemented with interleukin

138 However, plating, inoculating, and waiting for microbes to develo

139 st evaluation of a new microbiology specimen-plating instrument, the WASP, which offers opportunities

140 We observed that derivation from plating intact human blastocysts resulted predominantly

141 counteracted by the relative sluggishness of plating into the GB and the resulting back stress.

142 ith freshwater adaptation that controls bony plating is associated with changes in the ionome and nut

143 It is generally believed that Li plating is caused by the slow kinetics of graphite inter

144 Intramedullary fixation rather than plating is preferred, and allowing early protected weigh

145 direct laser writing and electroless silver plating, is comprised of four layers of conductively-cou

146 scopic fluorescent plaque in a Petri dish by plating it in a host bacterial medium.

147 This motility defect is rescued by plating knockdown cells on preformed laminin-332 matrix.

148 ed a modified culture protocol that included plating larger volumes of urine, incubation under varied

149 More than 110 h of lithium plating life is achieved in cell tests, which is among t

150 ations of 10(8)-10(9) cells grown without re-plating, longitudinal non-destructive monitoring of canc

151 ntegrity of LiF is easily compromised during plating, making it intrinsically unable to protect Li.

152 lent long-term functional outcomes; however, plating may lead to a higher risk of treatment failure a

153 Such a backside-plating method can be applied to not only zinc metal sys

154 g of the nerve fibers; (2) an adaptable drop-plating method for selective cell attachment, removal of

155 induced chondrogenesis, using a novel direct plating method in which intervening embryoid body format

156 (4.5 microm) is achieved via an electroless plating method involving initial reaction of the particl

157 Compared to the conventional agar plating method, the assay was rapid (1.5 h) and showed h

158 g-tolerant persisters were done by semisolid plating method.

159 SIA-SPR method together with the culturing (plating) method was able to detect C. jejuni in the real

160 these observations using standard bacterial plating methods.

161 Lastly, for the plating of 113 specimens in ESwab tubes, the manual meth

162 in which one polymer provides dendrite-free plating of a Li-metal anode and the other allows a Li(+)

163 ied electronic states for both dendrite-free plating of a lithium-metal anode and a Li(+) extraction

164 ptor for tetracycline detection; electroless plating of Au nanoparticles was applied on the Pt nanowi

165 dly phosphorylated on tyrosine residues upon plating of bone marrow-derived DCs (BMDCs) on integrin a

166 GDPD activity, adsorption, and efficiency of plating of Ca(2+) ions supports a role for GDPDLd17 acti

167 We previously reported that short-term (2 h) plating of cat atrial myocytes on the extracellular matr

168 Starting with the plating of digested tissue material, full-grown organoid

169 Direct plating of dilutions of bovine feces on SMACct can be us

170 mmunomagnetic separation (IMS) and to direct plating of dilutions of bovine feces onto sorbitol MacCo

171 The pores are fabricated by electroless plating of gold into the nanopores of an NCAM (Au-NCAM).

172 ished this by simplifying the production and plating of iNs and adapting them to a freezer-ready form

173 stribution within the battery can make local plating of Li above 0 V vs. Li(0)/Li(+) (room temperatur

174 The plating of lithium metal within the interior of the poro

175 Plating of metallic Li on graphite anodes is a critical

176 Here we report the defect-induced plating of metallic lithium within the interior of a por

177 which offers opportunities for the automated plating of microbiology specimens to an extent that has

178 Compared to PCR, direct plating of nasal swabs performed poorly, especially for

179 bla(KPC) from enrichment broth versus direct plating of rectal surveillance swabs on two selective cu

180 Direct plating of rectal swabs onto MacConkey agar containing 1

181 Therefore, direct plating of rectal swabs onto selective medium proved to

182 red cathodic deposition does not lead to the plating of reduced metals (Zn and Co).

183 e completed in approximately 8 h and include plating of serum-deprived VSM or ASM cell suspension on

184 r operates by the exhaustive electrochemical plating of the halides from the thin layer sample onto a

185 ]) in restrictive cells, we noticed that the plating of the ICP22 null (d22) and 3xstop mutants was r

186 Plating of urine specimens with the WASP was compared to

187 abbit corneal epithelial cells is reduced by plating on a basement membrane-like extracellular matrix

188 ved growth factor (PDGF) and prepolarized by plating on a fibronectin line substrate exhibit persiste

189 chment is not required for apoptosis because plating on bovine serum albumin-blocked poly-L-lysine (a

190 Plating on control surfaces with TGFbeta induced hypermo

191 ode interface, enables dendrite-free lithium plating on copper with outstanding coulombic efficiencie

192 of cortactin-KD cells were fully rescued by plating on increasing concentrations of exogenous ECM.

193 Plating on LN5' triggered smad nuclear translocation, an

194 which a 10-mug meropenem disk was placed and plating on MacConkey agar after overnight enrichment of

195 ter and oysters from Florida's Gulf Coast by plating on mCPC agar, enrichment and plating, and quanti

196 more convenient than traditional spontaneous plating on metallic discs, and similar yields were obtai

197 Among positive samples identified by direct plating on SMACct, the direct counts of E. coli O157:H7

198 igated by using three different methods: (i) plating on Thayer-Martin selective medium and testing by

199 V versus Li(+)/Li and can result in lithium plating on the graphite surface, raising safety concerns

200 motes actin-stress fiber formation following plating onto an integrin activating substrate whereas Fl

201 broth with 6.5% sodium chloride) followed by plating onto CHROMagar MRSA medium (broth-enriched CM cu

202 emoval of substrate interface by shadow mask-plating, or inhibition of Rho kinase or nonmuscle myosin

203 , human factors (lack of strict adherence to plating order, leading to only intermittent observation

204 The dissection and plating out of neurons takes 3-4 h and neurons can be ma

205 dishes and a further 3-4 h for isolation and plating out the cells.

206 her than that on SF at 24 and 72 hours after plating (P = 0.001 and 0.0005, respectively).

207 Axons grew up to 200 microm within 1 day of plating P19 embryoid bodies on laminin-1 (EHS laminin).

208 brid anode exhibits stable lithium stripping/plating performance over 1000 h with average overpotenti

209 asurement parameters, 0.1 M HCl electrolyte, plating potential of 0 mV, and staircase scan mode were

210 atteries (SIBs) (0.01 V), and well above the plating potential of metal.

211 Plating primary human keratinocytes on the gamma2 precur

212 n of the number of living cells through cell plating procedure after cultivations is known as time- a

213 s excellent guides in which the Li stripping/plating process can take place and effectively confine t

214 finite volume change during the Li stripping/plating process results in cracks and fractures of the s

215 Given the stochasticity of the plating process, we show that the number of atoms plated

216 ute to an in-depth understanding of the SnAg plating process.

217 plating solution, indicating a reproducible plating processes.

218 (90 mV at 3 mAcm(-2)), more-stable stripping/plating profiles, and better cycling performance ( appro

219 ults suggest that intramedullary nailing and plating provide equivalent long-term functional outcomes

220 fracture management strategies such as bone plating, providing physicians with quantitative informat

221 %, and 97% of samples respectively by direct plating, qPCR, and enrichment.

222 control of the arrival of ions and thus the plating rate on the Bi UME, to one ion every few seconds

223 The replicate plating results were comparable for both instruments, wh

224 yte on the pathogen killing was evaluated by plating Salmonella typhimurium on agar plates and showed

225 Plating SCN neurons at <100 cells/mm(2) eliminated synap

226 Finally, plating significantly prolonged operative duration by 20

227 Serial-dilution plating, single-cell fluorescence microscopy, and flow-c

228 e number of cells at the edge of colonies by plating small colonies can increase differentiation effi

229 edetermined composition of the metal mixture plating solution (and hence the nanowire composition).

230 e optimised design focused on increasing the plating solution flow to avoid sedimentation, and as a r

231 ll with the composition of the metal mixture plating solution, indicating a reproducible plating proc

232 g different types of template and by varying plating solvent composition.

233 ral assemblages often dominated by domed and plating species of the genera Agaricia, Porites and Side

234 ion of striped nanowires based on sequential plating steps from different metal solutions and leads t

235 the long term by repeated re-sorting and re-plating steps.

236 C/garnet/Li-C symmetric cell exhibits stable plating/striping performance with small voltage hysteres

237 that both reduce the current density during plating-stripping and serve as effective hosts that shie

238 d current collector will stabilize the metal plating-stripping behavior even with a conventional KPF(

239 m for achieving efficient and stable lithium plating-stripping cycles in a carbonate-based electrolyt

240 For instance, stable plating-stripping of Na is extremely difficult with conv

241 metallic Li through in situ monitoring of Li plating-stripping processes.

242 igh coulombic efficiency (ca. 97 %), deep Zn plating/stripping (10 mAh cm(-2) ), and long cycle life

243 ation, and stable cycling performance for Mg plating/stripping and Mg insertion/de-insertion in a mod

244 lyte enables a Li anode to achieve a high Li plating/stripping Coulombic efficiency of 99.55 % (1 mA

245 aller impedance and excellent stability upon plating/stripping cycles compared to cells using bare ga

246 , lithium symmetrical cells show outstanding plating/stripping cycles, and the full cell exhibits rem

247 rgoes continuous cracking/reformation during plating/stripping cycles.

248 ibutes toward the understanding of potassium plating/stripping electrochemistry and paves the way for

249 e of potassium enabling reversible potassium plating/stripping electrochemistry with high efficiency

250 1.2 mAh cm(-2) , a high CE of >99.2% for Li plating/stripping in FEC-based electrolyte is achieved w

251 Dendrite-free plating/stripping is achieved through improved electroly

252 Thus, dendrite formation due to uneven Li plating/stripping is suppressed.

253 -SO(3)Li allow reversible and stable lithium plating/stripping on lithium metal electrodes, demonstra

254 ncy of ~99% and ultralong-term reversible Li plating/stripping over 2500 h at a high current density

255 ng of this composite electrode with small Li plating/stripping overpotential (<90 mV) at a high curre

256 ghly ionic conductive Li(3) N reduces the Li plating/stripping overpotential, and LiF with high inter

257 node morphology ensures long-term reversible plating/stripping performance over 5000 h, a rate capabi

258 d electrolyte interphase (SEI) during the Li plating/stripping process lead to the growth of dendriti

259 ribute the Li-ion flux and lead to a uniform plating/stripping process.

260 nt density and homogeneous ionic flux during plating/stripping processes.

261 lombic efficiency and long cycle life during plating/stripping processes.

262 controlled lithium deposition during lithium plating/stripping results in low Coulombic efficiency an

263 of Ti-LLZTO layer, long-term stable lithium plating/stripping was reached in an areal capacity of 3.

264 which are generated during the cycling of Li plating/stripping, leading to safety issues.

265 m islands with further SEI coarsening during plating/stripping, possibly dead potassium metal on stri

266 Although plating studies showed that the yeast were still [PSI+],

267 genization over a considerably large lithium-plating surface.

268 separation of the lanthanides, the molecular plating technique was applied to prepare thin samples to

269 preparation of proper samples, by molecular plating technique, for alpha-spectrometry measurements.

270 ion, we compared broth enrichment and direct plating techniques by using brain heart infusion broth a

271 Electrochemical plating techniques were used to form quasi-reference and

272 lectrodes are modified using anodisation and plating techniques which do not require intricate and ex

273 constructed by picking colonies from primary platings that may contain single or multiple microorgani

274 By plating the bacterium on medium containing the CAMP nisi

275 terol-loaded macrophages with MbetaCD before plating the macrophages onto the SMCs.

276 lagenase XI, dispase and trypsin followed by plating the resultant muscle slurry on collagen type I-c

277 into an invertase-deficient yeast strain and plating the transformants on a medium containing sucrose

278 After subsequent plating, the hyaluronan-binding chondroitin sulfate prot

279 ompared to a broth preenrichment followed by plating to Baird-Parker agar.

280 Direct plating to CHROMagar (BD Diagnostics) was compared to a

281 containing 2 microg/ml imipenem followed by plating to MacConkey agar (MAC) (method 1) and (ii) stre

282 , and 12-month visits and cultured by direct plating to mannitol salt agar (MSA) and CHROMagar MRSA (

283 ally mapped after CM treatment or fibroblast plating to obtain conduction velocity and action potenti

284 rospheres (10-20 microm) through electroless plating to produce bulk (i.e., gram) quantities of nanop

285 structed tumor cell streaming in vitro by co-plating tumors cells, macrophages and endothelial cells

286 electrode sustains stable lithium stripping/plating under 30 mA cm(-2) and 5 mAh cm(-2) with a very

287 lithium alloy formation and enabling lithium plating underneath it.

288 nd antigen expression profile as compared to plating unfractionated CD34(+)/lin(-)-enriched bone marr

289 This study compared results from plating urine specimens with the BD InoqulA instrument u

290 ly by an atom-by-atom method in a controlled plating; we prepared an individual Pt deposit on Bi and

291 ed in more than 50 industries such as chrome plating, welding, wood processing and tanneries.

292 he sensitivities of ESwab and LS upon direct plating were 93.8% and 87.5%, respectively, and increase

293 Only 8% of typical colonies from direct plating were confirmed by PCR for vvhA; others yielded n

294 conditions, and flow cytometry and selective plating were used to quantify donor strain, EcoFJ1(pRP4-

295 c backbone enables uniform lithium stripping/plating, which successfully confines lithium within the

296 oltage is sufficiently high to avoid lithium plating while not significantly reducing cell potential.

297 Merwe) metal film growth at early stages of plating, while the tortuous 3D-Cu electrode reduces the

298 Electrochemical dual-pulse plating with sequential galvanostatic and potentiostatic

299 rine specimens with the WASP was compared to plating with the Dynacon Inoculab instrument.

300 The results of duplicate plating with the same instrument (replicate plating) and