ライフサイエンスコーパス: cement

1 il simulant, which may be viewed as a "lunar cement".

2 han the positive control (zinc oxide-eugenol cement).

3 surface dissolution zone in the CO2-attacked cement.

4 a porous-coated implant (uncemented) or with cement.

5 to the carbon dioxide reaction front on the cement.

6 -treated lithium disilicate ceramic to resin cement.

7 the processes involved in the carbonation of cement.

8 the nano-hydrates during the preparation of cement.

9 nse mixture of tungsten powder and temporary cement.

10 oreign bodies found were titanium and dental cement.

11 ertebral body, followed by injection of PMMA cement.

12 thin coatings of dripstone beach-rock silica cement.

13 ase Hg from storing and processing BFD-added cement.

14 ormed via the hydration of ordinary portland cement.

15 , including exchangeable sites and carbonate cement.

16 cs and osteoblastic biocompatibility of bone cement.

17 ck copolymers to commercially available bone cement.

18 the majority cementitious phase in Portland cement.

19 rvival rates when inserted with conventional cements.

20 ibility for further research in these dental cements.

21 cation of bismuth oxide-containing hydraulic cements.

22 to assess the hydrogen mobility within these cements.

23 ration and leaching profile of the prototype cements.

24 initial bimodal distribution of pores in the cement, 1-2 and 10-20 nm, is affected differently during

25 These results cement a growing understanding that pigments are essenti

26 rbonates represent a promising class of bone cement additives that can be used to enhance the antibac

27 bridge formation, superior to glass-ionomer cement alone in vivo, in a rat molar pulpotomy model aft

28 h 0.01%, 0.02%, and 0.03%, CNTs by weight of cement, along with a control mix without CNTs.

29 nically available biomaterials, such as bone cement and ceramic particles, this strategy is designed

30 Strength and other mechanical properties of cement and concrete rely upon the formation of calcium-s

31 reatments on the bond strength between resin cement and disilicate ceramic.

32 in the rational design of the properties of cement and related materials.

33 were microbiologically contaminated for both cemented and screw-retained superstructures.

34 microflora of healthy implants restored with cemented and screwed superstructures.

35 ing would replace injectable defect fillers (cements) and allow personalized implants to be rapidly p

36 ement (OPC) and calcium sulfoaluminate (CSA) cement, and (ii) promotes environmental benefits in term

37 Therefore, cement appears as a suitable waste form for (90)Sr stora

38 ustrial commodities such as iron, glass, and cement are carbon-intensive, accounting for 23% of globa

39 ate, and oxysalt (both chloride and sulfate) cements are all assessed.

40 o their good biocompatibility, glass ionomer cements are an interesting restorative option.

41 Many such cements are ideally suited to specialist applications in

42 The majority of MgO-based cements are more costly to produce than Portland cement

43 efits, particularly for young patients, over cemented artificial joints.

44 eleton and bioglass-magnesium phosphate bone cement as the osteoconductive matrix.

45 Our observations help us understand how cement attains its unique strength and may help in the r

46 treatment that involves the use of inorganic cements based on calcium or silicon-based mineral aggreg

47 ainable reinforcing nano-material for use in cement-based formulations.

48 s the primary barrier very often consists of cement-based materials, two distinct aspects are essenti

49 calcium carbonate precipitation (MICP) over cement-based sealants is that the solutions used to prom

50 The boiler ash and cement-based waste pretreatments also produced high meth

51 Antibiotic loaded cement beads are commonly used for the treatment of biof

52 nts are more costly to produce than Portland cement because of the relatively high cost of reactive s

53 xtensive carbonation of wellbore cement, the cement becomes less permeable because of carbonate miner

54 ardness tests on hardened samples of class G cement before and after CO2 exposure.

55 assess the effectiveness of calcium silicate cement (Biodentine) versus glass ionomer cement (GIC; co

56 use in combination with mineralised CO(2) in cement-bound construction products.

57 tones fill cavities formed within previously cemented breccias and therefore do not form a stratigrap

58 ction-induced mechanical failure of wellbore cement by coupling sensitivity analysis and mechanical p

59 longstanding economic and social inequality, cemented by an economic framework that predicted that ec

60 e early hominin atlas yet found, having been cemented by breccia in its displaced and flipped over po

61 h a focus on the dissolution of its dolomite cement, Ca(1.05)Mg(0.75)Fe(0.2)(CO(3))(2).

62 wever, chemical and mechanical alteration of cement can reduce the permeability of leakage pathways.

63 While utilization of alternative cements can be environmentally beneficial, similar reduc

64 the structure and hydration process of these cements can bring the necessary understanding to further

65 ro computed tomography (mu-CT) study of well cement carbonation at realistic reservoir stress, pore-p

66 were combined with raw biomass and Portland Cement, CEM 1 and exposed to CO(2).

67 nd light curing, dental adhesives and dental cements, ceramics, and new functional repair materials.

68 cellulose paper, pervious pavement, Portland cement concrete, and an activated carbon cloth, respecti

69 Novel rechargeable orthodontic cement containing ACP was developed with a high bracket-

70 ess the chemical and structural stability of cement containing radioactive species.

71 Despite use of blended cements containing significant amounts of aluminum for o

72 commercially available gentamicin-containing cement control; whilst in vitro gentamicin release was i

73 The recharged orthodontic cement could release CaP ions continuously for four week

74 The role of this sponge effect along the cement cycle (including production, use, and demolition)

75 t CO(2) emissions reduction along the global cement cycle will require both radical technology advanc

76 d make real-time microscopic observations of cement degradation experimentally challenging.

77 , and sheds light on how interactions, which cement dependencies within communities of microorganisms

78 Wellbore cement deterioration is critical for wellbore integrity

79 ACP incorporation into the novel orthodontic cement did not adversely affect the bracket-enamel bond

80 The model includes well casing, wellbore cement, drilling mud, processing equipment, gas compress

81 ers within the polymerizing/hardening of the cement during application.

82 with composite resins or self-adhesive resin cements, especially for implant-supported restorations.

83 erstand how the mechanical properties of the cement evolves with CO2 exposure time.

84 P solutions have low viscosities compared to cement, facilitating fluid transport into the formation.

85 ngs suggest that US surgeons should consider cemented fixation in the hemiarthroplasty treatment of d

86 s and systematic reviews have suggested that cemented fixation is more effective than uncemented fixa

87 nted fixation and 6449 (51.6%) had undergone cemented fixation, and the median length of follow-up wa

88 e system, uncemented fixation, compared with cemented fixation, was associated with a statistically s

89 ty (1.7% for uncemented fixation vs 2.0% for cemented fixation; HR, 0.94 [95% CI, 0.73-1.21]; P = .61

90 : 20.0% for uncemented fixation vs 22.8% for cemented fixation; HR, 0.95 [95% CI, 0.90-1.01]; P = .08

91 that households with improved sanitation and cement floors in the kitchen area had reduced fecal cont

92 , open eaves blocked with bricks and mortar, cement floors repaired or constructed, and rain gutters

93 vestigating the clinical application of bone cements for infection management.

94 mulations to study a coarse-grained model of cement formation, and investigate the equilibrium and ar

95 e physicochemical environment evolves during cement formation, making it difficult to disentangle wha

96 In this study, a series of bone cement formulations with enhanced antibacterial performa

97 This precludes MgO-based cements from providing a large-scale replacement for Por

98 ate cement (Biodentine) versus glass ionomer cement (GIC; control group) as indirect pulp capping mat

99 Bioactive glass ionomer cements (GICs) have been in widespread use for approxima

100 Glass-ionomer cements (GICs) have been widely used for over forty year

101 ian pronephros and to the development of the cement gland and oral cavity.

102 s reports of the temporary (antennulary) and cement glands in thoracican barnacles.

103 rly cyprid stage, and is terminated once the cement glands reach maximum size.

104 dence of the epithelial invaginations on the cement glands supports the involvement of exocytosis in

105 Cement glands undergo a morphological transition as the

106 from the ionic solution upon dissolution of cement grains in water.

107 In ice-cemented ground (permafrost), the lag of soil particles

108 nt ways in which abstractness contributes to cement group cohesion.

109 onsisted of 18 patients (55 implants) in the cemented group and 22 patients (46 implants) in the scre

110 the two methods of prosthetic retention: the cemented group presented significantly higher bacterial

111 higher permeability to most microbes in the cemented group.

112 icantly higher at peri-implant sulci for the cemented group; at the inner portion of connections, val

113 coloration-resistant calcium aluminosilicate cement has been formulated to overcome the timely proble

114 The resorption of brushite-based bone cements has been shown to be highly unpredictable, with

115 However, these cements have limited mechanical strength to survive in t

116 the Korteweg liquid stress field around each cement hydrate particle provided the capillary forces at

117 imize the nanoscale mechanical properties of cement hydrate.

118 Unraveling such links in cement hydrates can be groundbreaking and controlling th

119 ether with a realistic nanogranular model of cement hydrates.

120 f calcium-silicate-hydrate take place during cement hydration.

121 ing, glass alteration, zeolite syntheses and cement hydration.

122 of calcium-silicate-hydrates (C-S-H) during cement hydration.

123 cessed pachytene piRNAs at intermitochodrial cement (IMC).

124 with a lower risk of RTT when compared with cemented implants (OR, 0.69; 95% CI, 0.54-0.88; P = .002

125 ds due to structural integrity impairment of cement in gas wells.

126 oducers should replace 30 to 40% of portland cement in high-strength concrete to minimize the regiona

127 scenes are more memorable than others: they cement in minds with consistencies across observers and

128 tional role: for example, when they serve as cement in the extracellular matrix of biofilms.

129 iding a large-scale replacement for Portland cement in the production of steel-reinforced concretes f

130 the progress of reaction fronts in Portland cement, including density changes, sample deformation, a

131 nd re-release from the novel ACP orthodontic cement indicated favorable release and re-release patter

132 It is used in the cement industry and plays a crucial role in the global c

133 level (TRL) scale for carbon capture in the cement industry is developed.

134 including the metallurgical industry and the cement industry, was proposed for the first time in the

135 chnologies have been proposed for use in the cement industry.

136 Bone cement injected under pressure not only fills the areas

137 ergoes multiple structural rearrangements to cement interactions with the nucleosome and with ubiquit

138 Longer cemented intervals can seal large fractures; however, th

139 ew vertebral body height by introducing bone cement into fractured vertebrae.

140 2) gas at 50% RH for 24 h, during which they cemented into hardened monolithic products.

141 missions produced as a reaction byproduct of cement, iron and steel, glass, and oil production.

142 icant unidentified portion of acorn barnacle cement is comprised of low complexity proteins; they are

143 t, when appropriate selection and removal of cement is performed, cement retention is not a risk indi

144 e it is inexpensive and easy to manufacture, cement is the material of choice to store large volumes

145 (Ca3SiO5), the main constituent of Portland cement, is amongst the most reactive silicates in water.

146 tallography, with corresponding DFT studies, cement its assignment as the ring-protonated isomer, [Fe

147 may be used as a component of oxyfuel in the cement kiln to improve efficiency and lower CO(2) emissi

148 es suggest that the heterogeneity of reacted cement leads to a wide range of brittle strength values

149 veloped to relate fracture aperture with the cemented length required for self-sealing.

150 Overall, chalk is useful for a cementing lifestyle because it enables morphological pla

151 ich was significantly higher (P = 0.04) than cement-lined cast-iron mains (n = 6; geometric mean = 2.

152 itted as a result of fossil fuel burning and cement manufacture.

153 study in Pennsylvania, which shows steel and cement manufacturing paired to suitable sinks as having

154 from a background area to the vicinity of a cement manufacturing plant that uses alternative fuel an

155 Deep decarbonization of cement manufacturing will require remediation of both th

156 n 2007 to eight in 2013, and the society has cemented many lasting alliances with regional societies

157 rful glycoprotein-rich mucilage adhesives(2) cement melanized and pressurized dome-shaped infection c

158 The cement mesoscale structure was relaxed under the action

159 porations in agriculture, forestry, seafood, cement, minerals and fossil energy cause environmental i

160 Adding magnetic and/or metallic particles to cement mixes changes the properties of the concrete, whi

161 Local irreversible deformations of the cement nanograins assembly were identified due to liquid

162 coloration-resistant calcium aluminosilicate cement on osteogenesis by differentiated hDPSCs is more

163 tigate the influence of antimicrobial-loaded cement on sonicate fluid culture positivity for the diag

164 in the production of both ordinary Portland cement (OPC) and calcium sulfoaluminate (CSA) cement, an

165 ur understanding of the flow of powders like cement or flour is sparse compared to the flow of coarse

166 nts with two to three implants restored with cemented or screwed restorations and 5 years of follow-u

167 Advances in the past decade have cemented our understanding of DC subsets, functions, hem

168 challenges remain, these can be overcome by cementing our resolve, raising advocacy, bolstering glob

169 The influence of nanocellulose on oil well cement (OWC) properties is not known in detail, despite

170 Continuing recalcitrance to therapy cements pancreatic cancer (PC) as the most lethal malign

171 1) a complete sorption isotherm of hydrated cement paste (including the capillary range), 2) pore si

172 Particularly for a cement paste enhanced with micro-sized iron (III) oxide

173 rticles, the S21 curve was improved over the cement paste only sample by as much as 10 dB.

174 Results show that compared to cement paste only sample, cement paste with micro-sized

175 on tests find different porosity of C-S-H in cement paste specimens prepared at varied water-to-cemen

176 te the consequences of its beta-decay on the cement paste structure.

177 Specifically, enhancing a cement paste with iron-based magnetic particles improves

178 w that compared to cement paste only sample, cement paste with micro-sized iron-based magnetic partic

179 ons of nanoporous materials such as hydrated cement paste, shale, coal, and some other rocks and soil

180 scale poromechanics framework was applied to cement paste, which is the most common building material

181 t the mechanical performance of the hardened cement paste.

182 resonator antenna array embedded in enhanced cement pastes.

183 these measures, the substitution of portland cement (PC) clinker with alternative materials is arguab

184 ield and the microstructure of the carbonate-cementing phase was distinct and related to the particul

185 Initial dissolution of cement phases occurs in the 10-20 nm pores and leads to

186 The important attributes that a cement plant must have to be "carbon-capture ready" for

187 e of the sites with highest influence of the cement plant were the ones with the highest concentratio

188 the tops of mountains whose slopes faced the cement plant.

189 atched the profile of the emissions from the cement plant.

190 The similar durations of cement-plant renovation and capture-plant construction s

191 For application at cement plants, partial oxy-fuel combustion, amine scrubb

192 lenges facing their retrofitting to existing cement plants.

193 Cement plays a dual role in the global carbon cycle like

194 f the flow history on CO(2) leakage risk for cement plugging.

195 r polymers adsorbed on the surface of MgO in cement pore solution are simulated by molecular dynamics

196 ons but also crystallizes in simulated young cement pore water, a pH 13 aqueous solution mainly conta

197 ation-exchange properties in simulated young cement pore water.

198 ight into the interactions between CO(2) and cement, potentially helping in assessing the risks of CO

199 e high-temperature kiln, the electrochemical cement process could be powered solely by renewable elec

200 mate Change, and that emissions from China's cement production are 45 per cent less than recent estim

201 issions from the burning of fossil fuels and cement production between 2010 and 2012 occurred in Chin

202 2) emissions from fossil-fuel combustion and cement production in the United States based directly on

203 O2 emissions from fossil fuel combustion and cement production is 2.49 gigatonnes of carbon (2 standa

204 Cement production is among the most difficult industrial

205 Cement production is currently the largest single indust

206 18) in subjects with an antimicrobial-loaded cemented prosthesis and 58.3% (21 of 36) in subjects wit

207 Protein VI, an internal capsid cement protein and substrate for AVP, is cleaved at two

208 vectors by deleting the gene for IIIa capsid cement protein of lower-seroprevalence adenovirus seroty

209 apsid for genome packaging, thus acting as a cementing protein similar to those found in many bacteri

210 Barnacles adhere by producing a mixture of cement proteins (CPs) that organize into a permanently b

211 have determined the structures of all of the cement proteins (IIIa, VI, VIII, and IX) and their organ

212 conflicting atomic models for the important cement proteins IIIa, VIII, and IX from conventional/fil

213 type 5 and confirmed our previous models of cement proteins IIIa, VIII, and IX, thus clarifying the

214 repancies exist concerning the assignment of cement proteins IIIa, VIII, and IX.

215 Inspired by the chemical features of the cement proteins of the sandcastle worm, here we report a

216 These cement proteins share no homology with any other marine

217 cial to maintain stability in the absence of cementing proteins or cross-linking, as occur in other b

218 Low complexity regions found throughout the cement proteome, as well as multiple lysyl oxidases and

219 ped and testing of targeted therapeutics has cemented psoriasis as IL-23/TH17 polarized.

220 dy examined the effects of this experimental cement (Quick-Set2) on the viability and proliferation o

221 th with chemical stabilizing agents, such as cement, raises environmental concerns.

222 es could mineralise CO(2) gas and be used to cement 'raw' biomass in solid carbonated monolithic comp

223 anic fillers) or to one commercial composite cement (Relyx Ultimate, 3M Espe).

224 Such cements remain in the tooth and fail to degrade and thus

225 luation, presence of adjacent natural teeth, cemented restorations and two-piece implants were protec

226 nders derived from most of these alternative cements result in lower greenhouse gas (GHG) emissions a

227 e lower mechanical strength in glass ionomer cements results not only from the presence of pores, but

228 on, single restorations (versus multi-unit), cement-retained restorations, and presence of occlusal w

229 mine the association between retention type (cement-retained versus screw-retained restorations) and

230 election and removal of cement is performed, cement retention is not a risk indicator for peri-implan

231 The carbonate-cemented sandy layers served as nucleus for subsequent c

232 to perform percutaneous fixation by internal cemented screw (FICS).

233 n of pathologic pelvis fractures by internal cemented screw is a safe and effective approach that can

234 ng factors, i.e., platform switching design, cement-/screw-retained restoration, and flapped/flapless

235 T-guided percutaneous fixation with internal cemented screws (FICS) for impending pathologic fracture

236 nclusion Percutaneous fixation with internal cemented screws as performed by the interventional radio

237 The work herein further cements SECCM as a premier technique for structure-funct

238 Carbonation of the bulk cement, self-healing of the leakage path in the cement s

239 To predict the behavior of the cement sheath after CO2 injection and the potential for

240 H(4)(+) can be successfully removed from bio-cemented soils, acceptable limits for NH(4)(+) aqueous c

241 was to define the role of antibiotics in the cement spacer in relation to reimplantation cultures and

242 cedure for PJI, adding a glycopeptide to the cement spacer reduces the rate of positive cultures duri

243 Overall, a glycopeptide in the cement spacer was not associated with a lower failure ra

244 on culture of antimicrobial agent-containing cement spacers (ACSs) collected during second stages of

245 cultures during reimplantation was 9.5% for cement spacers containing a glycopeptide (27/284) (with

246 Sonication culture of cement spacers identifies a similar proportion of patien

247 ng reimplantation, and cases without data on cement spacers were excluded.

248 ent, self-healing of the leakage path in the cement specimen, and leaching of CaCO3 were thus directl

249 te goals would be imperiled if the growth of cement stocks continues.

250 processes are crucial for the development of cement strength, and for the long-term evolution of conc

251 CH-depleted zone and the dissolution of the cement surfaces utilizing a reduced-dimension (1D) react

252 f the most commonly investigated alternative cement systems.

253 transition them away from other lineages and cement T cell identity.

254 tment produces higher bond strength to resin cement than other surface treatment protocols.

255 times more frequent at peri-implant sulci of cemented than screw-retained prostheses.

256 a reduced dimension model for CO2 attack on cement that captures the important nanoscale mechanisms

257 mall/wide angle scattering study of wellbore cement that has been exposed to carbon dioxide for three

258 ite) in microbial mats forming framework and cement that may be analogous to the micritic microstruct

259 rpes simplex virus 1 (HSV-1)-infected cells, cement the contribution of host STAT3 to persistence of

260 p53 DNA-binding and tetramerization domains cement the importance of these domains in tumor suppress

261 arch using standardized methods is needed to cement the scientific evidence on MP contamination and h

262 earch and more than 75,000 publications have cemented the foundational role of integrins as major con

263 ology correlates with the differences in AD, cementing the idea that conformational strains of oligom

264 ned dysmature and disorganised EEG patterns, cementing the link between early maturational trajectori

265 f tumors with BRCA mutations and HR defects, cementing the pathogenicity of L35P.

266 Our phylogeny cements the early branching in complex thalloids.

267 e implicit psychological infrastructure that cements the mismatch between today's workplace and today

268 Structurally, protein VI cements the outer capsid shell and links it to the viral

269 hat during extensive carbonation of wellbore cement, the cement becomes less permeable because of car

270 and experimental depletion of microglia have cemented their importance.

271 s peripheral contacts and the central ligand cements this ternary interaction.

272 e cemented THR, 3.8%; antibiotic-impregnated cemented THR, 21.4%; CoC, 40.9%; MoP, 33.9%; CoP, 20.8%;

273 6.6%; uncemented THR, 74.8%; antibiotic-free cemented THR, 3.8%; antibiotic-impregnated cemented THR,

274 Antibiotic-free cemented THRs and antibiotic-impregnated cemented THRs w

275 Antibiotic-impregnated cemented THRs had a better prognosis than uncemented THR

276 prosthetic revision: antibiotic-impregnated cemented THRs have a better prognosis and MoM THRs a wor

277 ree cemented THRs and antibiotic-impregnated cemented THRs were compared with uncemented THRs.

278 ctivity of bioglass-magnesium phosphate bone cement, thus providing support for load-bearing bone def

279 hether the wells can be suitably sealed with cement to hinder the escape of CO(2).

280 eries; antibiotics are usually added to bone cement to prevent infection offset.

281 ate-hydrate) in order to test the ability of cement to trap and hold this radioactive fission product

282 re they rapidly became lodged in crevices or cemented to the benthos by encrusting organisms.

283 7 [95% CI 0.6-0.8], RR for patellofemoral vs cemented total knee replacement 0.3 [0.2-0.5], and RR fo

284 ent 0.3 [0.2-0.5], and RR for unicondylar vs cemented total knee replacement 0.5 [0.5-0.6]) were asso

285 dylar knee replacement (RR for uncemented vs cemented total knee replacement 0.7 [95% CI 0.6-0.8], RR

286 e THR survivorship was assessed according to cement type and bearing surface in univariate and multiv

287 d understanding of the behavior of fractured cement under realistic subsurface conditions including e

288 i-implantitis and peri-implant mucositis for cement- versus screw-retained restorations were 1.43 (0.

289 paste specimens prepared at varied water-to-cement (w/c) ratios.

290 The cement was exposed to CO2-rich fluid for one to six mont

291 as a possible healing mechanism of fractured cement, was found to be enhanced in confined regions hav

292 conditions of CO(2)-saturated water through cement, we were able to delineate regimes dominated by c

293 Experimental orthodontic cements were developed using pyromellitic glycerol dimet

294 e cytotoxicity profiles of the two hydraulic cements were not significantly different and were much l

295 ce the antibacterial performance of the bone cement whilst maintaining mechanical strength and cellul

296 with commercially available calcium silicate cement (white mineral trioxide aggregate; WMTA) after di

297 ural changes upon exposure of cured Portland cement with an artificially engineered leakage path (cav

298 nanoporosities will reduce the reactivity of cement with CO2 due to reactive surface area loss.

299 ivize concrete producers to replace portland cement with industrial byproducts to reduce their greenh

300 work worldwide on magnesium-based inorganic cements, with a focus on both scientific and patent lite