ライフサイエンスコーパス: stainless

1 The first comprised gold-plated stainless 316L beads coated with a self-assembled monola

2 ve to conventional stain-based protocols for stainless, all-digital pathology.

3 ately 4% of lung cancer cases, to which both stainless and mild steel welding contributed equally.

4 A 308 L stainless core is surrounded by a mild steel casing, inc

5 imaging has been widely tested as a tool for stainless digital histology of biomedical specimens, inc

6 n and generation of computationally stained (stainless) images is possible, resolving morphological f

7 nce to chemical corrosion, 2707 hyper duplex stainless steel (2707 HDSS) has been used in the marine

8 horse material for marine applications, 316L stainless steel (316L SS) is known to balance resistance

9 Lubricity between stainless steel (SS) and diamond-like carbon (DLC) is ex

10 sium (Mg) or a Mg alloy as the anode and 316 stainless steel (SS) as the cathode placed in a bench-sc

11 Stainless steel (SS) can be an attractive material to cr

12 ployed a BiOx-TiO2 semiconductor anode and a stainless steel (SS) cathode in the presence of sodium c

13 abricate micromilled microneedles (uMMNs) of stainless steel (SS) for precise delivery of agrochemica

14 We anchored titanium (Ti) and stainless steel (SS) implants into biomimetic scaffolds,

15 nificantly reduced biofilm cell densities on stainless steel (SS) materials for E. coli O157, S. ente

16 Stainless steel (SS) particles were demonstrated as a no

17 sized, which strongly adsorbs to Ti and 316L stainless steel (SS) substrates, providing an anchor for

18 Mechanical abrasion of stainless steel (SS) surfaces is demonstrated as an effe

19 In this work, stainless steel (SS) was used as a substrate to fabricat

20 rcuits, the use of iron or etched and sanded stainless steel (ss) wire, instead of platinum wire, sup

21 This work demonstrated that 317L-Cu stainless steel (SS), created by adding copper through a

22 g accompanied by precipitation in austenitic stainless steel (SS).

23 periments at the interface between CuAl5 and stainless steel 304 alloys.

24 c CuAl5 and (Mg0.75Fe0.25)2SiO4 olivine in a stainless steel 304 chamber, intended to replicate a nat

25 lloys were stacked together and shocked in a stainless steel 304 recovery chamber.

26 Earlier we reported a nanoporous stainless steel acupuncture needle with enhanced therape

27 stance, including a 2.3-fold improvement for stainless steel and a 13.9-fold improvement for Inconel

28 A flange converter produced from stainless steel and a hub lock produced from plastic or

29 lite MFI membranes are synthesized on porous stainless steel and alpha-alumina supports using a seede

30 c, iron(II), and iodide are measured by bare stainless steel and by stainless steel modified by eithe

31 In nonirradiated metals (e.g., stainless steel and copper), it was found that significa

32 ular injury created by slotted-tube geometry stainless steel and nitinol coronary stents in a rabbit

33 promising alternative to traditional medical stainless steel and polymer for the clinical application

34 rating the advantages of traditional medical stainless steel and polymer.

35 explain the entrainment phenomenon for 316 L stainless steel and Ti-6Al-4V powder layers.

36 ed from two operationally relevant surfaces: stainless steel and vinyl tile.

37 ing benefits over traditional materials like stainless steel and zirconia in terms of preferable comp

38 ire), and final alignment (0.019 x 0.025-in. stainless steel arch wire).

39 ing technique has been developed using a 316 stainless steel as an exemplar material to experimentall

40 hesis of bare gold nanoparticles mediated by stainless steel as reducing agent was monitored via infr

41 th stearate indicator, Ag-AgCl reference and stainless steel auxiliary microelectrodes.

42 The interface is based on a rotating stainless steel ball that transports samples from atmosp

43 For field-scale composting, stainless steel beads coated with PrP(263K) were exposed

44 omium sirolimus-eluting Orsiro stent and the stainless steel biolimus-eluting Nobori stent in an all-

45 exible, hard-piped equipment including large stainless steel bioreactors and tanks to hold product in

46 a device consisting of two rapidly spinning stainless steel blades that were pneumatically driven th

47 The normal stainless steel bore-through union serving as the upstre

48 Here we show that martensitic structures in stainless steel can be removed by appropriate electroche

49 e samples were collected in electro-polished stainless steel canisters from two aircraft while flying

50 ampling techniques within this area, namely, stainless steel canisters, cryotrapping, and solid adsor

51 continuous atmospheric inlet consisting of a stainless steel capillary and DC ion optics was designed

52 he column was an uncoated fused-silica-lined stainless steel capillary column.

53 The technique employs tandem stainless steel capillary columns, each coated with a pH

54 sting of a 10 cm x 127 microm inner diameter stainless steel capillary tube which was used to introdu

55 doped TiO2 (BiOx/TiO2) anode coupled with a stainless steel cathode at applied anodic potentials (Ea

56 eration by electron transfer from a low-cost stainless steel cathode.

57 ctive bismuth-doped TiO2 functionalities and stainless steel cathodes.

58 using mixed-metal oxide anodes coupled with stainless steel cathodes.

59 The adsorption isotherm of DEHP on the stainless steel chamber surfaces was explicitly measured

60 ics and adsorption isotherm of phthalates on stainless steel chamber surfaces were determined experim

61 5, (Mg0.75Fe(2+) 0.25)2SiO4 olivine, and the stainless steel chamber walls, the recovered specimen co

62 m reduction of Fe(2+) in olivine or from the stainless steel chamber.

63 floorings was measured in specially designed stainless steel chambers.

64 ring (VF) was measured in specially designed stainless steel chambers.

65 s evolved was actively transferred through a stainless steel channel to the capture chamber containin

66 porous hydrophobic material is packed into a stainless steel chromatographic column, and water is flu

67 ns in shear stress were created by placing a stainless steel clip over a 12-mm region of the rat abdo

68 mostly employing detachable or nondetachable stainless steel coils.

69 by inserting a fused silica capillary into a stainless steel column enclosed in a glass tube.

70 n gas flowing between the glass tube and the stainless steel column.

71 ng effects have been assessed for PEEK-lined stainless steel columns operated at 70 MPa, and effects

72 he well-known 'season cracking' of brass and stainless steel components in nuclear power generating s

73 d due to the low thermal conductivity of the stainless steel components.

74 ighly correlated for endospore recovery from stainless steel coupons inoculated with range of 1,000 e

75 Stainless steel coupons were cooled to generate a therma

76 mulated saliva or culture media and dried on stainless steel coupons.

77 It consists of a four-way stainless steel cross, plus the following components con

78 ique (HT; no caries removal, sealing in with stainless steel crowns), and nonrestorative caries treat

79 ely 3-log(10) inoculum of M. tuberculosis on stainless steel discs and a 6-log(10) inoculum of Geobac

80 , the biolimus A9-coated BioFreedom stent, a stainless steel drug-coated stent free from polymer, has

81 higher mass compared to the reference 316 H stainless steel due to the dissolution of Mn into the mo

82 as a function of grain orientations, in 316 stainless steel during high-cycle fatigue.

83 Experiments on porous 316L stainless steel during tensile process show that the ava

84 nts were made utilizing a specially designed stainless steel electrochemical cell that easily maintai

85 Moreover, the stainless steel electrode was modified simultaneously by

86 Stainless steel electrodes are found to corrode when cyc

87 Stainless steel electrodes were fabricated by 3D printin

88 the nucleus accumbens shell through bipolar stainless steel electrodes.

89 onto the increasingly popular pipe material stainless steel EN1.4307.

90 The on-line EC cell configuration with a stainless steel ES needle as the working electrode produ

91 oated silica particles were immobilized onto stainless steel fibers and subsequently used for headspa

92 was 5 times better than that obtained using stainless steel for a 85mer.

93 ofabrication techniques to create very small stainless steel fountain pens that were installed in pla

94 entane are filtered under pressure through a stainless steel funnel attached to an EPR tube fitted wi

95 lar response in porcine coronary arteries to stainless steel gold-coated NIR stents (7-cell, Medinol,

96 curred with only the Vena-Tech (VT) and 12-F stainless steel Greenfield (12SSG) filters and the 1.5-J

97 e (n=6, 1 failure), Simon-Nitinol (n=1), 12F Stainless Steel Greenfield (n=4), and Titanium Greenfiel

98 ctive heating of a sealed glass vessel via a stainless steel heating jacket and implements both onlin

99 4V, poly(L-lactide-co-D,L,-lactide), and 303 stainless steel implants with surface characteristics co

100 nd Cr3+) released from acid corrosion of the stainless steel inlet frit greatly accelerate the hydrol

101 We show that removing the stainless steel inlet frit, or use of a titanium frit, g

102 tudy, Tenax beads (TA) encapsulated within a stainless steel insert were used as an adsorption sink t

103 Joining titanium alloy and stainless steel is becoming an urgent need since their o

104 When austenitic stainless steel is heavily plastically deformed by grind

105 of peptides desalted and washed on uncoated stainless steel MALDI plates were consistently inferior

106 roteolytic fragments, while analysis using a stainless steel MALDI sample probe gives only 11 detecta

107 wn through a volume of sensitized austenitic stainless steel mapped with DCT and observed in situ by

108 n aliquot from this mixture was spotted on a stainless steel mass spectrometry grid and analyzed usin

109 eveloped using exclusively glass, Teflon and stainless steel materials.

110 The stainless steel mesh anode with graphite coating was use

111 ion media and it was noticed that WO3 coated stainless steel mesh showed high separation efficiency (

112 AAV2-eGFP vectors immobilized reversibly on stainless steel mesh surfaces through the protein G/anti

113 acile spray coating of nanostructured WO3 on stainless steel meshes and compared its performance in o

114 We prepared polydimethylsiloxane-coated stainless steel meshes for extraction and preconcentrati

115 r, onto glass, Tegaderm, Listerine tabs, and stainless steel microneedles.

116 of the active pharmaceutical ingredient on a stainless steel MN array consisting of thirty 500 mum pr

117 are measured by bare stainless steel and by stainless steel modified by either Pt or Au NPs.

118 taxel-coated ACHIEVE stent compared with the stainless steel Multi-Link (ML) PENTA stent.

119 A stainless steel needle deposited with saturated alkali c

120 an (TSQ 7000), were modified with a 35-gauge stainless steel needle.

121 )(3)-were coated on poly(dopamine) precoated stainless steel needles and used to rapidly preconcentra

122 -index (GRIN) lenses that were housed in two stainless steel needles, respectively.

123 , the metallic filter was made with either a stainless steel or a platinum grid separated from the se

124 pumps attached to bilateral cannulas made of stainless steel or microfluidic polymer fibers.

125 e observed chamber concentrations in gas and stainless steel phases.

126 achining by passing the laser beam through a stainless steel pinhole.

127 Stainless steel pins were placed at the mid-apical and c

128 th scale in the metamaterial fabricated in a stainless steel plate.

129 o those obtained with commercially available stainless steel plates when no organic matrix is used.

130 es (PCP), Teflon-based AnchorChip plates, or stainless steel plates, before analysis by matrix-assist

131 MALDI on PCP, AnchorChip plates, or uncoated stainless steel plates.

132 owth was induced by embolization of a hollow stainless steel plug into the left anterior descending c

133 An array of five stainless steel pocketed microneedles was shown to posse

134 rface of a microliter droplet deposited on a stainless steel post.

135 ociated prion protein from whole blood using stainless steel powder.

136 Here, stainless steel reactors are used to simulate the downho

137 This improved concurrently the stainless steel response (CV and potentiometry) toward t

138 sly, the new instruments were connected to a stainless steel riser tube that was installed in an obse

139 springs that accurately hold 0.5 mm diameter stainless steel rods in the required geometry.

140 an ex-service nuclear steam header Type 316 stainless steel sample is investigated through a multisc

141 Both stages house a Silonite-coated stainless steel sample loop; the second stage loop is fi

142 orption from liquid samples deposited onto a stainless steel sample target biased at a high potential

143 for custom 340-nL, 10-microL, and 110-microL stainless steel sample vials have been investigated usin

144 er at 355 nm was used to ablate a high-alloy stainless steel sample.

145 cribe a novel sampling device which utilizes stainless steel screens coated with a sticky polydimethy

146 of spores) from test surfaces (a bed rail, a stainless steel sheet, or a polypropylene work surface).

147 harvester by depositing P(VDF-TrFE) films on stainless steel springs using EPD process.

148 The Multi-Link stent is a balloon-expandable stainless steel stent with an interconnected ring struct

149 Stainless steel stents at 4 days contained more thrombus

150 ery was accomplished with balloon-expandable stainless steel stents coated with a cross-linked biodeg

151 ting blood flow was reduced in arteries with stainless steel stents compared with 4- and 14-day nitin

152 Stainless steel stents of 3 different configurations wer

153 Stainless steel stents of identical design with (GS) and

154 Stainless steel stents were expanded in normal or previo

155 Stainless steel stents were implanted for 4 days while n

156 Stainless steel stents were implanted in the iliac arter

157 Stainless steel stents were less uniformly expanded, had

158 Stainless steel stents were more often occluded by throm

159 Slotted-tube stainless steel stents were more thrombogenic and create

160 Here, we present an in-house designed stainless steel sublimator in which the parameters that

161 d diffusion is observed with either glass or stainless steel substrate.

162 trifluoroethylene (P(VDF-TrFE)) particles on stainless steel substrates during the electrophoretic de

163 phene-oxide (GO) that can be deposited on to stainless steel substrates using a simple spray-coating

164 ium oxide coatings using reactive landing on stainless steel support of gas-phase positive ions produ

165 n film of polymer on a tubular, macroporous, stainless steel support.

166 dy the effect of the surface coverage of the stainless steel surface by NPs on the electrochemical re

167 eral weeks for the sorption of DEHP onto the stainless steel surface to reach equilibrium.

168 The strong partitioning of DEHP onto the stainless steel surface was found to follow a simple lin

169 of vinyl flooring and decreasing that of the stainless steel surface within the chamber, the time to

170 g bi-functional surfaces, compared to a bare stainless steel surface.

171 rich surfaces, thin liquid films (TLF), and stainless steel surfaces (SS).

172 almonella enterica, and Listeria innocua, on stainless steel surfaces and on organic tomatoes, was as

173 the microelectrode was observed on type 304 stainless steel surfaces at active pitting corrosion sit

174 genic strain exhibited prolonged survival on stainless steel surfaces compared with the other E. coli

175 ffective MALDI of peptides and proteins from stainless steel surfaces, obviating the need for laborio

176 r adhesion and binding of S. aureus cells to stainless steel surfaces.

177 rinse recovery efficiency of endospores from stainless steel surfaces.

178 a simplified extraction line consisting of a stainless steel syringe needle and a glass cold trap.

179 intervention step carried one bag containing stainless steel tableware as meal boxes and used them fo

180 ater containing salt and organic matter in a stainless steel tank were sampled for size distribution,

181 onal (wooden barrel) and alternative system (stainless steel tank with dipped staves and micro-oxygen

182 the influence of new technologies of ageing (stainless steel tanks with wood staves or wood tablets o

183 acity ranged from 28% (raw amphorae) to 43% (stainless steel tanks).

184 The effect of MLF-container (stainless steel tanks, barrels) and barrel toasting (T1,

185 approximately 22% in glazed amphorae and in stainless steel tanks.

186 in raw, glazed, and engobe amphorae, and in stainless steel tanks.

187 amphorae, 23% in engobe amphorae, and 59% in stainless steel tanks.

188 in two 1.2-m long x 1.2-m high x 5.4 cm wide stainless steel tanks; each with a high-permeability san

189 including density of organism spotting on a stainless steel target plate and the direct overlay of o

190 A thin film of the matrix was deposited on a stainless steel target using the dried droplet method an

191 s compared with a PU target and a commercial stainless steel target.

192 on with the unmodified PU and the commercial stainless steel targets.

193 blem, here we examine an AISI 304 austenitic stainless steel that has a strain/microstructure-gradien

194 a 10 000 class clean room built entirely in stainless steel to avoid contamination.

195 The interface consists of a stainless steel tube in which the CE capillary is placed

196 of the device described above, in which the stainless steel tube is replaced with Hydroguard fused s

197 The device consists of a long stainless steel tube that is prefilled with calibrated g

198 age d(p) approximately 1.7 microm) and their stainless steel tubes (o.d. 4.53 and 6.35 mm).

199 constructed from an array of seven thin-wall stainless steel tubes soldered into a central hole of a

200 rous hydrophobic membrane tube with terminal stainless steel tubes that function as conductance-sensi

201 The oxygen-free gas was routed through stainless steel tubing directly into the sample compartm

202 itu polymerization in PEEK, fused silica, or stainless steel tubing having an inner diameter of 75 or

203 nvestigated, allowing performance similar to stainless steel tubing in the transport of ions from the

204 Flexible tubing, coupled to the stainless steel tubing, was run through the septum of a

205 emitter systems that utilize the more common stainless steel tubular electrodes.

206 ntergranular residual stresses in an AM 316L stainless steel under uniaxial tension.

207 arbon steel by cladding it with super duplex stainless steel using laser powder bed fusion process.

208 to a ring-down cell fashioned from standard stainless steel vacuum components.

209 hollow nanorods (HR) were directly grown on stainless steel via a sacrificial template accelerated h

210 e ATR unit taking immediate advantage of the stainless steel walls of the ATR cell.

211 Allergy to stainless steel was identified in 13.7%.

212 Initially, tensile specimens of a Co-added stainless steel were heat treated by quenching and parti

213 Here we show that conventional tungsten and stainless steel wire electrodes can be coated with carbo

214 this method the polymer mat is attached to a stainless steel wire without the need of a binder.

215 e 96-well screen filter plate consists of 96 stainless steel wire-mesh screen tubes connected to the

216 ions in brain homogenates and those bound to stainless steel wires was evaluated by using bioassays i

217 consenting patients, tissue and/or extracted stainless steel wires were collected during the debridem

218 aving for 15 min, human sCJD prions bound to stainless steel wires were eliminated.

219 g platinum, gold-coated stainless steel, and stainless steel wires, were tested.

220 ted effect on prions bound to the surface of stainless steel wires.

221 The modulator tube is silica-lined stainless steel with an internal film of dimethylpolysil

222 er-scale particles made of aluminum oxide or stainless steel with micron-scale projections designed t

223 I) species present in the milling equipment (stainless steel) as well as the mechanical impact of the

224 nce electrodes (QREs), we propose metal (Pt, stainless steel) coated with partially oxidized polypyrr

225 zation of latent fingerprints on a metallic (stainless steel) surface is described by means of spatia

226 tic, wood, poly(tetrafluoroethylene) (PTFE), stainless steel, and biological tissues, even without an

227 objects formerly covered with plastic, wood, stainless steel, and other materials found in the patien

228 d strength and work hardening for as-printed stainless steel, and show they are associated with back

229 e materials, including platinum, gold-coated stainless steel, and stainless steel wires, were tested.

230 entional sample plates, commonly formed from stainless steel, but provide additional capacity for cap

231 yethylene and polypropylene surfaces than on stainless steel, C8, or C18 surfaces.

232 ere found at the interface between CuAl5 and stainless steel, demonstrating nucleation of quasicrysta

233 zation coating serves as an inert shield for stainless steel, effectively resisting sulfide adsorptio

234 -resource settings: four nonporous surfaces (stainless steel, glass, plastic, and latex) and two poro

235 te) for disinfection of three surface types (stainless steel, heavy-duty tarp, and nitrile) with and

236 The balloon-expandable, stainless steel, hourglass-shaped, coronary-sinus reduci

237 ed using infectivity, SARS-CoV-2 survived on stainless steel, plastic, and nitrile for half-life 2.3-

238 um and its alloys, aluminium, cobalt-alloys, stainless steel, poly-ethylene, polyurethanes, polyglyco

239 ent of bimodal grain structure in austenitic stainless steel, SS316L.

240 nsfer between the sulfides and the silanized stainless steel, suggesting dissociative chemical adsorp

241 ts were subjected to ultrasonic scaling with stainless steel, titanium, and PEEK plastic tips.

242 hich is one of the most widely used types of stainless steel, we show that a strength gradient substa

243 he linear quadrupole rods from para-magnetic stainless steel, which works as a magnetic shield.

244 Regular use of stainless steel-made meals boxes can mitigate melamine e

245 hy and chemistry of veiled corrosion pits in stainless steel.

246 eactions), for ozone/D-limonene reactions on stainless steel.

247 copper alloy surfaces that did not occur on stainless steel.

248 ectra than observed in samples desorbed from stainless steel.

249 thylene and polypropylene surfaces than from stainless steel.

250 tion than observed for samples desorbed from stainless steel.

251 dual stresses and mechanical behaviour of AM stainless steel.

252 sistance to rolled and annealed super duplex stainless steel.

253 contributions in joining titanium alloy and stainless steel.

254 Here, in combination with the stainless steel/polyester fiber blended yarn, the polydi

255 icle compositions, we demonstrate that metal stainless-steel aerosols are released during the printin

256 er (AEL) coupling the proposed cathode and a stainless-steel anode can stably operate in both continu

257 ace areas of anodes, dominant performance of stainless-steel based anode materials, and the emerging

258 In some animals, a stainless-steel cannula was also implanted in the corpus

259 A stainless-steel cannula was inserted into the right late

260 4.5 in. long, 0.042 in. inner diameter (ID) stainless-steel capillary, was thus introduced.

261 ting Ebola virus-Makona strain (EBOV/Mak) on stainless-steel carriers per ASTM E2197-11.

262 ntains the highest nickel content, and for a stainless-steel cathode with a high surface area.

263 (E(EO)) values were lowest for the 304-grade stainless-steel cathode, which contains the highest nick

264 Experiments performed in a stainless-steel chamber interfaced to an FTIR were used

265 e-imprinted polyurethane layers deposited on stainless-steel chips.

266 tial experiments demonstrate that the planar stainless-steel column with proper interfacing can be a

267 The stent-grafts were made of self-expanding stainless-steel covered with woven polyester or polytetr

268 At an applied potential of +0.020 V, the stainless-steel electrode produced (*)OH with a yield th

269 oying a flow-through electrode consisting of stainless-steel fibers, the two processes could be opera

270 gdala and the rat was placed in a box with a stainless-steel grid floor through which a single footsh

271 ually placed at an air/liquid interface on a stainless-steel grid in cell culture wells containing a

272 a which had been cultured mucosal side up on stainless-steel grids.

273 Coaxial curved stainless-steel guide wires were used to obtain samples

274 lipid extraction directly on the surface of stainless-steel matrix-assisted laser desorption/ionizat

275 O(2) nanoribbons-carbon nanotubes) coated on stainless-steel mesh as photoanodes in a gas-phase chamb

276 ompatible device consisting of a cylindrical stainless-steel mesh.

277 first results of a robust, high-performance, stainless-steel microchip gas-chromatography (GC) column

278 for isoelectric focusing (IEF) utilizing the stainless-steel needle and plunger as electrodes.

279 meant to protect the portion of the uncoated stainless-steel of the blade that is normally exposed to

280 This work describes the use of mass-produced stainless-steel pins as low-cost electrodes to develop s

281 is work describes the use of mass-fabricated stainless-steel pins as new low-cost electrodes for a fl

282 printing tip life over the customary slotted stainless-steel pins.

283 ed, MFI zeolite films are prepared on seeded stainless-steel plates using organic template-free, seco

284 come this limitation, two custom-made 1.4404 stainless-steel prototype add-ons were developed for in-

285 o enhance the interaction between TiO(2) and stainless-steel skeletons for accelerated photogenerated

286 In this study, fine grained stainless-steel slag (SSS) is valorized to produce compa

287 s martensitic phase can also be generated in stainless-steel surfaces by cathodic charging, as a cons

288 ng of a back-pressure regulator, assembly of stainless-steel syringes, assembly of a continuous flow

289 re comparable to standard MBT BioTargets and stainless-steel targets and may be used for different MA

290 conditions using metallic silver foil and a stainless-steel vial and ball system.

291 d nitrogen (LN(2)) to top off the dewar of a stainless-steel water trap on a gaseous hydrogen-water p

292 xagonal boron nitride (hBN) nanocoating on a stainless-steel wire cloth (hBN-SSWC), and its applicati

293 (23 derivatives) has been developed through stainless-steel-driven decarboxylative acyl radical gene

294 Here we report that austenitic 316L stainless steels additively manufactured via a laser pow

295 Stainless steels are used in countless diverse applicati

296 l2O3-forming, high-creep strength austenitic stainless steels has been developed.

297 g process allows the hardness of cold-worked stainless steels to be maintained, while eliminating the

298 teristics of native oxide layers of type 304 stainless steels.

299 phs of different analyte concentrations on a stainless surface have been measured, together with the

300 es) followed by impacting the aerosol onto a stainless surface.