ライフサイエンスコーパス: filler

1 for grade 4 FLA (1 mL equals 1 syringe of HA filler).

2 taFlux gap-filler and 80.3 using a basic gap-filler.

3 ng pore size and porosity of the MOF used as filler.

4 containing 9.09, 23.08, or 33.33 mass% CaF2 filler.

5 y more uses than simply scaffolding or space filler.

6 ed PS when reinforced with fumed silica as a filler.

7 operons, transport systems, and pathway-hole fillers.

8 the injection of neuromodulators and dermal fillers.

9 in-based systems containing no ion-releasing fillers.

10 (89%) provided training with hyaluronic acid fillers.

11 operons, transport systems and pathway-hole fillers.

12 nt option is cosmetic surgery with synthetic fillers.

13 operons, transport systems and pathway-hole fillers.

14 m in the resin for substantial reinforcement fillers.

15 operons, transport systems, and pathway hole-fillers.

16 .51) or barium (refractive index 1.53) glass fillers.

17 o include predicted operons and pathway hole fillers.

18 were partially adherent, and 19% were excess fillers.

19 rtially adherent and were highest for excess fillers.

20 atrix, combined or not with nanogel-modified fillers.

21 networks are engaged during the utterance of fillers.

22 n additional innocuous particles are used as fillers.

23 ismatch observed in soft polymers with solid fillers.

24 (3) insulating polymers, and (4) conductive fillers.

25 r than what could be achieved with fullerene fillers.

26 enhanced flexibility versus zero-dimensional fillers.

27 Total costs for excess fillers (14,044 US dollars) were substantially higher th

28 A single treatment of hyaluronic acid (HA) filler, 20 mg/mL, may provide an immediate, natural-appe

29 s, with botulinum toxin (30 of 32 [94%]) and fillers (27 of 32 [84%]) most prevalent and with vascula

30 RECENT FINDINGS: When a filler agent is chosen, the aim is to provide some lift,

31 rs provide an objective parameter of how the filler agent will perform in a specific area.

32 or concurrently, botulinum toxin and dermal filler agents offer an affordable, minimally invasive ap

33 d and midface restoration/rejuvenation using filler agents.

34 Filler aggregation, the major bottleneck for the develop

35 All dermal fillers aim to achieve the same goal: long-lasting soft-

36 Sufficient mobility from these fillers allows the process to happen at a low temperatur

37 lyimide (PI)-modified aluminum nitride (AlN) fillers, AlN@PI.

38 se with wheat starch being the discontinuous filler, an outcome that is explored in the in vitro stud

39 ared to 91.0 using the previous MetaFlux gap-filler and 80.3 using a basic gap-filler.

40 t is useful in building and agriculture as a filler and insulating agent.

41 These particles are hybrids of filler and nanoscale additives because their lengths are

42 atically studied using CaCu3Ti4O12 (CCTO) as filler and P(VDF-TrFE) 55/45 mol.% copolymer as the matr

43 By designing the inorganic filler and polymer matrix, which are both relaxor ferroe

44 s that both the orientation of the nanoscale filler and the orientation of X-type covalent bonds at t

45 esin matrix and/or the interface between the filler and the resin matrix.

46 using a reduced scoring threshold to provide fillers and extensions between highly significant segmen

47 cts of (left) anterior negativity between wh-fillers and gaps in English and German, but with a right

48 including drug-delivery systems, bone-graft fillers and medical devices.

49 elusive because of incompatibilities between fillers and polymers that are further compounded by proc

50 dense packing of multiwalled carbon nanotube fillers and report strong viscoelastic behaviour with up

51 oiting both the high permittivity of ceramic fillers and the high breakdown strength of the polymer m

52 hanging the initiation system, monomers, and fillers and their coupling agents, and by developing nov

53 ves the thermal and dielectric properties of fillers and these can be used extensively for electronic

54 enhancement using facial neuromodulators and fillers and to present advanced techniques using facial

55 nd with 60 wt% fillers with nanogel-modified fillers and/or free nanogel additives at 15 wt% in the r

56 ncreases with the volume content of metallic filler, and anisotropy increases with alignment.

57 extractable monomer, reduced adhesion to the filler, and the potential for increased swelling.

58 he material investigated contained 23 wt% of filler, and the ratios of calcium fluoride to chlorhexid

59 Bio-Alcamid has many advantages over other fillers, and has become widely used.

60 secticides and fungicides), polymers, waxes, fillers, and pigments.

61 ion, or with specific alignment (the way the fillers are arranged in the matrix).

62 These fillers are composed of core-shell structures that exhib

63 Nanoparticle fillers are highly attractive for this purpose, because

64 Nanoscale carbon-based fillers are known to significantly alter the mechanical

65 Nonpermanent or semi-permanent fillers are most widely accepted by physicians mainly be

66 Cosmetic facial fillers are not approved for use in the forehead, but of

67 These fillers are used for electronic encapsulation in high pe

68 ds are usually non-specific, acting as space-fillers at the protein-DNA interface.

69 conductivity associated with the addition of filler atoms into the void site.

70 clude filler type, filler particle size, and filler-binder bonding.

71 tational optimization of the interfacial and filler bonds arising from its three-dimensional branched

72 as well as allografts may serve as biologic fillers, but do not apparently contribute to osteoinduct

73 e currently available, mainly as bone defect fillers, but it is still required a versatile processing

74 with amorphous calcium phosphate (ACP) as a filler can release supersaturating levels of calcium and

75 erials with different biotemplates/hosts and fillers can achieve even higher anisotropic ratios, allo

76 Botulinum toxin and dermal fillers can be used to diminish facial rhytides, restore

77 Dermal injection of cosmetic fillers can lead to irreversible blindness when injected

78 Soft-tissue augmentation with dermal fillers can successfully address these signs of aging by

79 s the interaction between storage medium and filler, cast doubt on the clinical relevance of in vitro

80 ly by weekly addition of irradiated, splenic filler cells and IL-2, with or without E.G7-OVA.

81 anufacturing would replace injectable defect fillers (cements) and allow personalized implants to be

82 th methacrylate monomers and silanized glass fillers (CHX or CHX@MSN + glass filler particle = 70 wt%

83 ency analysis revealed that the utterance of fillers, compared to that of ordinary words, was associa

84 Rubber-filler composites are a key component in the manufacture

85 r aim was to determine how matrix selection, filler composition, and filler silanization affect fille

86 of variance revealed that storage solution, filler composition, and total time in the storage soluti

87 By systematically varying filler concentration, morphology, and size, we identify

88 The filler concentrations were 9.1, 23.1, or 33.3 wt%, and t

89 ene) nanocomposites reinforced by nanocarbon fillers consisting of graphene flakes and fullerenes.

90 mechanical properties of particle- or fiber-filler-containing indirect dental resin composite materi

91 s containing CaF2 particles as a function of filler content and pH.

92 Increasing the filler content from 9.09 to 33.33 mass% increased the fl

93 rticle-deposited boron nitride nanosheets as fillers could effectively enhance the thermal conductivi

94 Injection of dermal filler, cross-linked hyaluronic acid, into the skin of i

95 cturers' information are included for dermal fillers currently approved for use by the US Food and Dr

96 e and tendon, aspiration biopsies and dermal fillers (DF).

97 r target sequences, although the addition of filler DNA and small duplications or deletions of genomi

98 ions displayed microhomologies and contained filler DNA from nearby sequences, suggesting an origin b

99 flanked by the same sequences that flank the filler DNA in the deletion.

100 repeats flanking the deletion junctions and filler DNA in the donor Ac.

101 pproximately half of the Ds elements contain filler DNA inserted at the deletion junction that is der

102 In the remaining two, extra sequences or filler DNA is inserted at the junction.

103 Filler DNA was found at some of the junctions.

104 , non-homologous exogenous DNA (also termed 'filler DNA') can be incorporated at the site of a DSB.

105 hromosomal duplications and the insertion of filler DNA.

106 nts of the delivered DNA flanked by genomic (filler) DNA that did not originate from the integration

107 plants, the recombination products contained filler-DNA or an inversion of an endogenous segment.

108 The filler DNAs are identical to sequences found close to th

109 Short filler DNAs were also present in several junctions.

110 Filler silanization was followed by a filler drying at 60 degrees C for 24 h.

111 resistance resulting from separation of the fillers during elongation.

112 en two apposed bilayers and as a lipid "hole-filler," effectively preventing defect holes from develo

113 hange occurring at the filler surfaces, more filler elements leach from composites stored in a salt s

114 Though dental composite materials leach filler elements when stored in distilled water, it is no

115 ugh the Web, it provides a more accurate gap filler for metabolic models; it supports development of

116 To evaluate the safety and efficacy of an HA filler for treatment of HIV-associated FLA during a 12-m

117 ety and efficacy and supports use of this HA filler for treatment of HIV-associated FLA with durable

118 safety, efficacy, and durability of this HA filler for treatment of HIV-associated FLA.

119 years, the use of botulinum toxin and dermal fillers for aesthetic purposes has risen sharply.

120 rafast saturable absorbers to gas sensors to fillers for composite reinforcement.

121 ent of nanomaterial enabled sensors, polymer fillers for electromagnetic radiation shields, and catal

122 When used as the fillers for isotropically electrically conductive compos

123 rder and chain upturns, thus they may act as fillers for the pore.

124 The hybrid filler formulations reported herein resulted in a synerg

125 epsins (CTPs) subsequent to application of a filler-free (Res.A) or an ion-releasing resin (Res.B) to

126 O4 (10%) and placed in direct contact with a filler-free (RESIN) or 2 experimental ion-releasing resi

127 neralized dentin specimens in contact with a filler-free or 2 ion-releasing resins containing microme

128 ations of these minor alkaloid levels in the filler from 50 popular cigarette brands were found to be

129 A whisker composite with 74% fillers had a wear depth of 77.7 +/- 6.9 mum, less than

130 ymer composites with electrically conductive fillers have been developed as mechanically flexible, ea

131 Neuromodulators and hyaluronic acid gel fillers have been shown to be well tolerated and efficac

132 Poly-L-lactic acid and dermal fillers have potential therapeutic applications in child

133 14 MPa.m(1/2) for whisker composite with 74% fillers, higher than 1.13 +/- 0.19 MPa.m(1/2) for a pros

134 d as a carrier of an active compound or as a filler in bioplastics.

135 can be applied upon activation as conductive filler in composite biomaterials.

136 infection in the presence of polyacrylamide filler in cosmetic surgery, possibly due to a biofilm mo

137 ctive glass incorporated as micrometer-sized filler in dental composites may offer greater beneficial

138 e and pozzolans in cements and concretes, as filler in paper, in the take-up of Cs and Sr from nuclea

139 lications associated with Bio-Alcamid facial filler in patients with HIV-related facial lipoatrophy (

140 s of central retinal artery occlusion due to fillers in 3 patients shortly after their cosmetic proce

141 One promising use of carbon nanotubes is as fillers in a composite material to improve mechanical be

142 The composite with 75% fillers in a NaCl solution (133 mmol/L, pH = 7.4, 37 deg

143 f nanotubes, particularly inorganic ones, as fillers in composite materials makes it essential to und

144 Polymer modified fillers in composites has attracted the attention of num

145 The glass fillers in composites provide only limited reinforcement

146 were detected in the presence of binders and fillers in intact formulations using LEMS.

147 xchange materials, fire retardants, and nano-fillers in polymer nanocomposites.

148 ategy demonstrates a freezing effect towards fillers in polymer, resulting in an extremely high-loadi

149 Magainin monomers play the role of fillers in the expansion region thereby stabilizing the

150 terials, as well as their use as nanocluster fillers, in nanocomposites, mouthwashes, medicines, and

151 n and transport mechanisms involved in solid-filler incorporated TFN membranes.

152 been no prior reports of blindness caused by filler injected into the forehead.

153 Filler injection for face augmentation is a common cosme

154 old women received a Calcium Hydroxylapatite filler injection to her nose bridge for the correction o

155 ery emboli following Calcium Hydroxylapatite filler injection to the nose bridge.

156 tituted by aluminum, (ii) neutral amine pore fillers instead of rigid and large quaternary amine SDAs

157 mposite materials, particularly at the resin-filler interface.

158 our observations in human skin, injection of filler into dermal equivalent cultures causes elongation

159 The addition of ceramic fillers into a ferroelectric polymer leads to augmentati

160 ynthesis and separation of high-aspect-ratio fillers is challenging, stiffness increases with the vol

161 nofillers with stable and strong reinforcing fillers is promising to yield a nanocomposite with both

162 useful screening tool to assess addition of filler juices and water to pomegranate juices.

163 al mixtures at different levels of water and filler juices.

164 composition, and filler silanization affect filler leachability of composites after storage in the s

165 It was further hypothesized that whisker filler level and heat-cure temperature and time signific

166 combat dental caries, and to investigate the filler level effects.

167 The whisker composite with 70% filler level had a flexural strength in MPa (mean +/- SD

168 Filler level had a significant effect on composite prope

169 es, and to investigate the effect of whisker filler level on composite properties.

170 properties of composite resins; the whisker filler level plays a key role in determining composite p

171 positional factors including degree of cure, filler level, and silanation directly affected the wear

172 ompositional factors such as degree of cure, filler level, and silanation level should be optimized.

173 st increased, then plateaued with increasing filler level.

174 us and hardness increased monotonically with filler level.

175 gree of conversion decreased with increasing filler level.

176 P) were incorporated into PE and PEHB at 40% filler level.

177 Greater wear was correlated with lower filler levels (r2 = 0.88; p < 0.05), significantly incre

178 PO(4), and F release can be achieved at low filler levels in the resin, because of the high surface

179 nanoparticles produced high F release at low filler levels, thereby making room in resin for reinforc

180 The higher level of filler loading reduced the degree of polymerization, lea

181 are complex and can be tuned via changes in filler loading, that is, the character of polymer bridge

182 At 40 wt% of filler loading, the highest thermal conductivity of AlN@

183 The whisker composite with a filler mass fraction of 55% had a flexural strength (mea

184 The whisker filler mass fraction was varied from 0% to 79%, the heat

185 rsion were measured as a function of whisker filler mass fraction, which ranged from 0% to 70%.

186 nitride whiskers at a 1:1 ratio were used at filler mass fractions of 0-75%.

187 ngineering, and also as protein mimics and a filler material for nanocomposites.

188 bone mineral (BBM) is extensively used as a filler material in periodontal reconstructive surgery of

189 investigations glia, once considered passive filler material in the brain, have emerged as active pla

190 This rather simple twist to the filler material of a fusion weld could be generally appl

191 he composites are fabricated from an organic filler material possessing very high dielectric constant

192 e been combined with the assumption that the filler material will help maintain the space necessary f

193 Given the wide variety of filler materials available, clinicians and surgeons must

194 ron microscopy was used to investigate three filler materials for packing fungus biofilm.

195 om which the films were cast was varied, and filler materials such as hydrophobic, amorphous silica o

196 g and densification of polymer chains at the filler-matrix interface, thereby providing insights into

197 onal design and molecular engineering of the filler-matrix interfaces of electroactive polymer nanoco

198 ical models suggest the decisive role of the filler-matrix interfaces on the dielectric, piezoelectri

199 hereas a higher viscosity filler or a harder filler may be better indicated for structure and support

200 wn strength of the polymer composites on the filler morphology is revealed experimentally and is furt

201 a metal-organic framework (MOF) material as fillers, namely, the Zr-fum-fcu-MOF possessing an optima

202 etic enhancement procedures involving facial fillers need to be aware of this potential complication

203 Simulations of filler network formation using attractive, repulsive and

204 on the bulk mechanical properties and of the filler network structure (both imaging and by simulation

205 substantially improved by reinforcement with fillers of ceramic whiskers fused with silica glass part

206 rheological elastomer comprising a hybrid of fillers of liquid metal microdroplets and metallic magne

207 is proposed to quickly screening some common fillers of pomegranate juice that could decrease the ant

208 Evaluation of the new gap-filler on randomly degraded variants of the EcoCyc metab

209 ization of the impact of molecular and ionic fillers on PVA blends' triboelectric performance is pres

210 y being used for commercial purposes such as fillers, opacifiers, catalysts, semiconductors, cosmetic

211 o their use in catalyst, adsorption, polymer filler, optical devices, bio-imaging, drug delivery, and

212 ness is required, whereas a higher viscosity filler or a harder filler may be better indicated for st

213 se nanocomposites with either combination of fillers or polymer matrix help in further improving the

214 GDMA (5:3:2, with 25 wt% silanated inorganic fillers) or to one commercial composite cement (Relyx Ul

215 anized glass fillers (CHX or CHX@MSN + glass filler particle = 70 wt%).

216 ant material parameters include filler type, filler particle size, and filler-binder bonding.

217 tly does not exist any work directly linking filler particle spacing and mechanical properties.

218 It was shown that the smallest studied filler particles (500 nm) have the potential to aid the

219 rve how the presence of monodispersed silica filler particles in a methacrylate based resin reduces l

220 sin matrix reactive group conversion between filler particles is not fully understood.

221 in the linear elasticity) by the addition of filler particles is phenomenologically understood, consi

222 Filler particles of various sizes were added at differen

223 The presence of the filler particles resulted in electric field distortions

224 Either silica or barium glass filler particles were incorporated into these matrices.

225 as to functionalize the surface of inorganic filler particles with thiouretanes and evaluate the impa

226 likely arises from interactions between the filler particles, mediated by the rubber matrix.

227 tive to the orientation of high aspect ratio filler particles.

228 People occasionally use filler phrases or pauses, such as "uh", "um", or "y'know

229 nd fill silent moments between ordinary (non-filler) phrases.

230 erfacial coupling between dipoles across the filler/polymer interfaces.

231 nipple, areola, or flap; malfunction of the filler port of a tissue expander; and wound dehiscence.

232 predicted operons and predicted pathway hole fillers-predictions of which enzymes may catalyze pathwa

233 Each dermal filler preparation available for patient use has unique

234 re also observed, presumably from zinc oxide fillers present in the stoppers.

235 The filler presumably enters the central retinal artery via

236 rocedures, including energy, neurotoxin, and filler procedures, are safe when performed by experience

237 The filler provides mechanical reinforcement and additional

238 vely combined with a limited nanogel content filler-resin interphase to lower volumetric shrinkage an

239 A novel filler-resin matrix interphase structure was developed a

240 Optimizing filler/resin refractive index mismatch provides increase

241 ure depths related to monomer reactivity and filler/resin refractive index mismatch with significant

242 pth are influenced by monomer reactivity and filler/resin refractive index mismatch.

243 conducting linkages eliminates the need for fillers, resulting in a material which achieves 99.9% ac

244 Joints welded with an AA7075 filler rod containing TiC nanoparticles not only exhibit

245 on the fiber surfaces enhancing the ceramic filler's interconnection, which may be the reason for th

246 t the breakpoint was contiguous with a 35 bp filler sequence followed by a satellite III DNA-containi

247 binary vector sequences, and other unknown "filler" sequences.

248 modulus of such composites as a function of filler shape.

249 filled with thiourethane-silanized inorganic fillers showed up to 35% lower stress while doubling mec

250 Nanogel-modified fillers significantly reduced the polymerization stress

251 ow matrix selection, filler composition, and filler silanization affect filler leachability of compos

252 Filler silanization was followed by a filler drying at 6

253 surimi were kept constant by adding an inert filler, silicon dioxide in inverse concentrations to the

254 +/- 39) at 0% fillers to (114 +/- 23) at 75% fillers, similar to (112 +/- 22) of a non-releasing comp

255 h is further enhanced with a decrease of the filler size, has been identified experimentally and veri

256 A new tobacco filler Standard Reference Material (SRM) has been issued

257 mer matrix is blended with nanoparticles (or fillers)-strengthen under sufficiently large strains.

258 Then, nanocomposites of conductive fillers such as carbon nanotubes, graphene and inorganic

259 The tests can detect binders and fillers such as chalk, talc, and starch not revealed by

260 olatile solutions having carbon materials as fillers such as graphene oxide (GO), carbon nanotubes (C

261 el additives were chemically attached to the filler surface to use this created interphase as a poten

262 When the nanogel-modified filler surface treatment and resin-dispersed nanogel str

263 ith decreasing interparticle spacing for two filler surface treatments are quantitatively equivalent

264 as that due to ion exchange occurring at the filler surfaces, more filler elements leach from composi

265 most of the development concentrating on the filler technology.

266 ducting oxides are considered better ceramic fillers than Li(+) -insulating oxides for improving Li(+

267 h tunable cross-link density and anisotropic filler that enable precise control of their elastic modu

268 ubes (SWCNTs) have recently been utilized as fillers that reduce the flammability and enhance the str

269 her improvements have been achieved by using fillers (the conductive component) with increased aspect

270 lymer films that do not contain carbon black filler to relate the QCM frequency change and the ellips

271 er composites ranged from (106 +/- 39) at 0% fillers to (114 +/- 23) at 75% fillers, similar to (112

272 s relies on adding high thermal-conductivity fillers to improve the thermal-diffusion-based charging

273 ental sizes (~0.1-1 mum), we expect graphene fillers to provide substantial reinforcement, which also

274 o use ceramic single-crystalline whiskers as fillers to reinforce composites, and to investigate the

275 A novel filler transition route was introduced (Ti6Al4V --> V --

276 In series III (D, J-M), the portion of fillers treated with a silane coupler (MPS) was 100, 80,

277 The important material parameters include filler type, filler particle size, and filler-binder bon

278 which describes ideal behavior of flake-like fillers uniformly imbedded in a polymer.

279 In the past, the filler used in dental composites mainly consisted of gla

280 ogy of long-lasting adverse reactions to gel fillers used in cosmetic surgery is not known.

281 ugh an addition of high thermally conductive fillers usually cannot provide an expected value, especi

282 reliminary results raise the hypothesis that filler utterance would often occur when large-scale netw

283 enrichment of low-abundance yeast cells when filler volume fractions approximately 1 x 10(-5) v/v are

284 +/- 2.08 W m(-1) K(-1) for EGaInSn at a 40% filler volume mixing ratio) and liquid-to-paste transiti

285 t% group, due to the dilution of the overall filler volume, which also led to decreased stress.

286 precise coating thickness or the presence of fillers was identified as the source of error for partit

287 ed linearly as the percent of silane-treated fillers was reduced (r2 = 0.99; p < 0.05).

288 Through addition of fiber-based fillers, we demonstrate printing of electrically conduct

289 Fillers were mixed (70 wt%) with 4 bisphenol-A diglycidy

290 Glass fillers were treated with trimethoxyvinylsilane and furt

291 ryloxypropyltrimethoxysilane-surface treated fillers were used as a control.

292 d of SU-8 polymer added with graphite carbon filler which enables patterning of conductive thin films

293 Fillers with different shapes have been found to cause s

294 d with BisGMA/TEGDMA resin blend with 60 wt% fillers with nanogel-modified fillers and/or free nanoge

295 fective pathway that modifies the surface of fillers with polymer coating.

296 es consisting of readily prepared Al(2) O(3) fillers with systematically varied morphologies includin

297 osite contained NACP and reinforcement glass fillers, with QADM in the resin.

298 osites are typically a mixture of conductive fillers within elastomeric substrates.

299 copolymers can accommodate a high loading of fillers without a significant loss of mechanical strengt

300 othesis that combining nano-CaF(2) and glass fillers would yield nanocomposites with high mechanical