ライフサイエンスコーパス: adhesives

1 design approach can be applied to synthetic adhesives.

2 nd implications for large-scale bio-inspired adhesives.

3 cure is a popular mode of curing for dental adhesives.

4 of geckos has inspired hundreds of synthetic adhesives.

5 n specimens prepared from the commercialized adhesives.

6 ion stage usually mediated by polysaccharide adhesives.

7 ve in a way not easily achieved by synthetic adhesives.

8 rformance and explaining differences between adhesives.

9 s in printable materials, cargo carriers and adhesives.

10 in bonds and compared it with 2 other dental adhesives.

11 FG are mechanically the weakest adhesives.

12 ol (PEG) adhesives, and 3 albumin-based (AB) adhesives.

13 e contact for chronic use without sutures or adhesives.

14 ical, or mechanical insulators, bearings, or adhesives.

15 r developing effective artificial underwater adhesives.

16 thin the primers of 3 commercially available adhesives.

17 -dentin interfaces created by etch-and-rinse adhesives.

18 th poor mechanical durability in these model adhesives.

19 microdevices and keratoprostheses, or tissue adhesives.

20 s the strongest ever measured for biological adhesives.

21 e was no difference in bond strength between adhesives.

22 lead-free alloys and electrically conductive adhesives.

23 s such as the specificities of intercellular adhesives.

24 esin-dentin interfaces of one-step self-etch adhesives.

25 e is also a long-standing problem in polymer adhesives.

26 to distinguish among high-performing dentin adhesives.

27 discriminating among high-performing dentin adhesives.

28 ies of synthetic catechol-based polymers and adhesives.

29 mber of products ranging from emulsifiers to adhesives.

30 re currently being prepared and evaluated as adhesives.

31 oic acid was used to formulate the versatile adhesives.

32 t T110-2007 and was comparable to commercial adhesives.

33 CP, increased the strength of the biopolymer adhesives.

34 heep, horse) was occasionally found in mixed adhesives.

35 ed SOR, SOL and CYTO properties of unaltered adhesives.

36 esives and biomimetic chemically synthetized adhesives.

37 cretion resemble those of pressure-sensitive adhesives.

38 s and have inspired novel types of synthetic adhesives.

39 lopment of a new class of stimuli-responsive adhesives.

40 able block polyesters are pressure-sensitive adhesives.

41 of proteins and sugars gives rise to strong adhesives.

42 exocytosis in the secretion of the permanent adhesives.

43 surfaces as compared with those of existing adhesives.

44 eneral principles underlying diverse botanic adhesives.

45 yzae(1), powerful glycoprotein-rich mucilage adhesives(2) cement melanized and pressurized dome-shape

46 We applied 2 self-etch adhesives-Adper Prompt L-Pop (APLP, pH ~ 0.8) and Adper

47 rm mechanical properties, we evaluated model adhesives after 3 months of aqueous storage.

48 manufacture self-cleaning, re-attachable dry adhesives, although problems related to their durability

49 cluding genetically engineered protein-based adhesives and biomimetic chemically synthetized adhesive

50 se proteins have been created to function as adhesives and coatings for a wide range of applications.

51 s offers guidance for the engineering of wet adhesives and coatings.

52 including theranostics, biosensors, optics, adhesives and coatings.

53 pired versatile new synthetic strategies for adhesives and coatings.

54 ctions, ranging from orb web construction to adhesives and cocoons.

55 , dental composites and light curing, dental adhesives and dental cements, ceramics, and new function

56 ole of chemical interaction/reaction between adhesives and dentin.

57 devices, adaptive optical devices, smart dry adhesives and fasteners.

58 e two representative examples, protein-based adhesives and fibers have attracted tremendous attention

59 plorations and applications of protein-based adhesives and fibers in wound healing, tissue regenerati

60 iple interfaces will open up a new design of adhesives and hybrid materials.

61 o many biological processes and to synthetic adhesives and manufactured coatings and composites.

62 This study investigated the influence of adhesives and marginal sealing on demineralization progr

63 The production of adhesives and multicomponent tools is considered complex

64 throughput chemical screens to identify anti-adhesives and our findings provide insight into the targ

65 e grafts (CTG) between cyanoacrylates tissue adhesives and polytetrafluoroethylene (PTFE) sutures.

66 were bonded with etch-and-rinse or self-etch adhesives and prepared for microtensile bond testing and

67 ious implications for the fabrication of dry adhesives and robotic systems inspired by the gecko's lo

68 ssue scaffolds, therapeutic delivery, tissue adhesives and sealants, as well as the formation of inte

69 ing at the margins of restorations depend on adhesives and significantly contribute to the progress o

70 ed the antimicrobial activity of synthesized adhesives and the DOX-containing eluates against Strepto

71 nship between nanophase separation in dentin adhesives and their long-term mechanical properties, we

72 a wide spectrum of applications in plastics, adhesives and thermal papers.

73 ltifunctional, biomimetic pressure-sensitive adhesives and varnishes.

74 When adhesives and/or composites are bonded to the tooth, wat

75 brin glues (FG), 3 polyethylene glycol (PEG) adhesives, and 3 albumin-based (AB) adhesives.

76 eins share no homology with any other marine adhesives, and a common sequence-basis that defines how

77 approved by FDA as surgery sealants, tissue adhesives, and are now being investigated as a vitreous

78 to synthetic materials systems for coatings, adhesives, and encapsulants.

79 ials sciences by offering advanced coatings, adhesives, and glues.

80 for designing physical barriers, biomimetic adhesives, and targeted delivery systems that go beyond

81 Biopolymer adhesives are an attractive alternative because of lower

82 Adhesives are commonly used in the manufacture of multil

83 Existing adhesives are cytotoxic, adhere weakly to tissues, or ca

84 Adhesives are important in creating multilayer products,

85 Biodendrimer-based adhesives are of potential use for repairing corneal wou

86 Commercial adhesives are petroleum-based thermoset networks or nonb

87 ngths approaching those of permanent bonding adhesives are possible as feature size is scaled down.

88 these marine organisms, two main biological adhesives are presented, including genetically engineere

89 Current dentin adhesives are sensitive to moisture, as evidenced by nan

90 Additive-free LCE-based adhesives are shown to overcome these challenges due to

91 CA adhesives are the strongest and most homogenous group in

92 Pressure sensitive adhesives are ubiquitous in commodity products such as t

93 Newer, improved tissue adhesives are under development and may replace and surp

94 Dental adhesives are vital for the success of dental restoratio

95 ducts of future materials, including polymer adhesives, are within the context of a healthy ecosystem

96 utility of compounds with such structures as adhesives arises in part because their isocyanate functi

97 igh loads of goethite ochre to make compound adhesives at the type-site of the Mousterian, Le Moustie

98 Current smart adhesives based on elastomers have limited adhesion tuna

99 This problem may soon be addressed by adhesives based on vertically aligned carbon nanotubes,

100 Current adhesives bond to dentin via a micro-interlocking mechan

101 oth biologically and for design of synthetic adhesives, but the findings may be relevant to the chara

102 adding to clinical steps in the placement of adhesives, but their incorporation within dental adhesiv

103 e successful encapsulation of DOX within the adhesives-but, more important, to support the hypothesis

104 0 cm water pressure with experimental BisGMA adhesives by ethanol wet-bonding exhibited tensile stren

105 sue adhesives were included: 4 cyanoacrylate adhesives (CA), 2 fibrin glues (FG), 3 polyethylene glyc

106 The mimetic adhesives can be alternatively binding-on and lifting-of

107 We tested the hypothesis that resin-based adhesives can be used for such fabrication without compr

108 Fibrin-based adhesives carry the disadvantages of prolonged preparati

109 proteins underlie the elasticity of natural adhesives, cell adhesion proteins, and muscle proteins.

110 -dentin interfaces created by commercialized adhesives challenges its clinical effectiveness as a mec

111 ed strongly with mechanical strength for all adhesives combined.

112 increasing curing time between the modified adhesives compared to SBMP.

113 Reversible adhesives composed of renewable materials are presented

114 These simple, non-tacky adhesives consist of natural rubber impregnated into sti

115 descended to ~50% in enamel, whereas TPO+4E adhesives consistently scored ~80% DC across the enamel-

116 We report a bioinspired design for adhesives consisting of two layers: an adhesive surface

117 vestigate the antibacterial effect of dental adhesives containing dimethylaminododecyl methacrylate (

118 In conclusion, the adhesives containing DMADDM had remarkable antimicrobial

119 SOL) and cytotoxicity (CYTO) of experimental adhesives containing nitrogen-doped titanium dioxide nan

120 Mussel-inspired adhesives containing paired catechol and cationic functi

121 However, both TEG-DVBE-containing adhesives developed more and deeper resin tags in dentin

122 s known on the mechanical strength of tissue adhesives directly after application.

123 Because such electrostatic adhesives do not require mechanical detachment, they are

124 rinted thermoplastic electrically conductive adhesives (ECA), which takes the advantage of the capill

125 None of the adhesives eluates were cytotoxic to the human dental pul

126 These adhesives exhibit highly desirable properties for dynami

127 le bond strength was enhanced for 2 types of adhesives following the addition of both inhibitors.

128 s of environmentally-responsible, reversible adhesives for a wide variety of applications.

129 This work should guide the design of new adhesives for binding to charged surfaces in saline envi

130 comonomer in the formulation of hydrophobic adhesives for ethanol wet-bonding is a concern, due to i

131 cture can help in designing better synthetic adhesives for humid environments.

132 velopment of medicine-containing patches and adhesives for intraoral use have led to a new approach f

133 on depolymerization and high performances as adhesives for lignocellulosic bioplastics were achieved.

134 Developing strong, thermally resistant adhesives for load-bearing applications remains challeng

135 Translation of existing gecko-inspired adhesives for medical applications is complex, as multip

136 Common adhesives for nonstructural applications are manufacture

137 ous devices to be integrated with large-area adhesives for packaging.

138 ve mechanisms and in the design of synthetic adhesives for soft substrates (including for biomedical

139 s obtained by top-down microfabrication (dry adhesives, friction driven), and represent a unique flui

140 set of well-dated and chemically identified adhesives from Middle Paleolithic/Middle Stone Age conte

141 Homo sapiens is known to have made compound adhesives from naturally sticky substances and ochre, a

142 rfaces in aqueous environments in which most adhesives function poorly.

143 The hybrid TEG-DVBE-containing dental adhesives generated equivalent shear bond strength and u

144 When applied to enamel, TPO-only adhesives had ~80% DC in resin, which gradually descende

145 Many natural underwater adhesives harness hierarchically assembled amyloid nanos

146 sives, but their incorporation within dental adhesives has not been fully explored.

147 For instance, cyanoacrylate adhesives have been shown to cause foreign-body sensatio

148 However, both of these adhesives have certain limitations.

149 Consequently, polymeric hydrogel adhesives have emerged as essential materials for wound

150 Fibrillar, or "hairy," adhesives have evolved multiple times independently with

151 Artificial dry adhesives have exhibited great potential in the field of

152 Antibacterial adhesives have favorable prospects to inhibit biofilms a

153 Although tissue adhesives have potential advantages over suturing or sta

154 Tissue adhesives have recently been investigated as alternate m

155 Their adhesives have unique attributes that define them as tar

156 Synthetic adhesives have yet to overcome this fundamental challeng

157 Bioadhesives such as tissue adhesives, hemostatic agents, and tissue sealants have p

158 Dental adhesives hydrolyze in the mouth.

159 and to compare the interfacial integrity of adhesives in cavities through 3-dimensional (3D) image a

160 yond gaining control on the use of ultrathin adhesives in cutting-edge technologies such as stretchab

161 EMA-based commercial and experimental dental adhesives in terms of shear bond strength and microtensi

162 es has very often been missing in biomimetic adhesives; in turn, their performance is significantly l

163 vival studies of resin composites and dental adhesives indicate, secondary caries is the foremost rea

164 ive and non-drug release antibacterial resin adhesives ingeniously overcome the defect of the present

165 n of the biobased materials makes salamander adhesives interesting for practical applications in the

166 Developing future high performance adhesives is predicated upon achieving properties includ

167 rom experiments and other Middle Paleolithic adhesives, it demonstrates that Neandertals mastered com

168 responsible for the performance of fibrillar adhesives, it will be important to take advantage of the

169 s implications for the strength of polymeric adhesives; it also suggests a method for patterning thin

170 These adhesives kill both Gram-negative and Gram-positive bact

171 lved one of the most versatile and effective adhesives known.

172 This family of adhesives may be useful in many areas of application, in

173 substantially outperform previous biomimetic adhesives obtained by top-down microfabrication (dry adh

174 eport strong and multi-functional underwater adhesives obtained from fusing mussel foot proteins (Mfp

175 We have found that the temporary adhesives of cyprid are produced by the clustered tempor

176 revealed when comparing oyster cement to the adhesives of other marine organisms.

177 Whereas currently available adhesives offer an alternative to sutures, other novel b

178 The adhesive characteristics of fibrillar adhesives on a soft deformable membrane are reported.

179 lymerization efficacies of the two self-etch adhesives on dentin were apparently different.

180 ration (OR, 1.40; 95% CI, 1.06-1.84), use of adhesives on patients (OR, 1.65; 95% CI, 1.22-2.24), and

181 biointerfaces with hydrophobic methacrylate adhesives on wet surfaces.

182 ligosaccharides (MSOs) that function as anti-adhesives once provided to the neonate.

183 Synthesis of the permanent adhesives only occurs during the early cyprid stage, and

184 livery to tissues and cultures, and serve as adhesives or barriers between tissue and material surfac

185 c constituents of the filter matrix, such as adhesives or binders was likely the main formaldehyde so

186 properties compare favorably with commercial adhesives or bio-based polyester formulations but withou

187 pment of bio-inspired devices such as tissue adhesives or needles, trocars, and vascular tunnelers wh

188 covalent bonding, as in reactive structural adhesives, or through noncovalent interactions, which ar

189 SP), Adper Scotchbond (ASB) and experimental adhesives (OSP + 25% or 30% of N_TiO(2)) were fabricated

190 Significantly, these adhesives outperformed the controls after being challeng

191 es both natural and synthetic gecko-inspired adhesives, over 14 orders of magnitude in adhesive force

192 mm x 4 mm), among the strongest pure CNT dry adhesives, over a temperature range from -196 to 1,000 d

193 orobenzene for insecticides, D4-siloxane for adhesives, para-chlorobenzotrifluoride (PCBTF) for solve

194 Several different appendages, adhesins and adhesives play roles during attachment, and foster the t

195 te the recent progress in and demand for wet adhesives, practical underwater adhesion remains limited

196 The results confirmed that stiffer adhesives provide higher resistance to failure.

197 Dental adhesives provide retention to composite fillings in den

198 Experimental BisGMA adhesives provide the proof of concept that relatively h

199 techol synergy, polymeric pressure-sensitive adhesives (PSAs) have now been synthesized by copolymeri

200 Results showed that TPO+4E adhesives reached DC similar to TPO-only counterparts up

201 es are attractive, but requirements for skin adhesives remain.

202 Thus, designing biomimetic amyloid-based adhesives remains challenging.

203 that defines how nanostructures function as adhesives remains undiscovered.

204 red and bio-derived protein-based underwater adhesives reported thus far.

205 Polymeric dental adhesives require the formation of densely crosslinked n

206 Chemical-based adhesives require tissue-specific reactive chemistry, ty

207 Developing adhesives requires addressing design issues including fi

208 l benefits; however, the development of anti-adhesives requires an in-depth knowledge of adhesion-ass

209 ment and use of polymeric hydrogels as wound adhesives, sealants, and hemostats, their design require

210 ent design elements of both gecko and mussel adhesives, should be useful for reversible attachment to

211 Conventional adhesives show a decrease in the adhesion force with inc

212 or to the development of novel self-cleaning adhesives, smart surfaces, microelectromechanical system

213 erences were greatest for cleaning products, adhesives/solvents, and gases/vapors.

214 tics for instrument cleaning and exposure to adhesives/solvents.

215 rogress was slower in the fluoride-releasing adhesives SP and BF and significantly different from SB,

216 their numerous current applications, tissue adhesives still face several limitations and unresolved

217 d in a wide range of applications, including adhesives, structural and electrical laminates.

218 y, the introduction of cyanoacrylate tissues adhesives such as Histoacryl Blue (Trihawk International

219 ing(5,6), existing liquid or hydrogel tissue adhesives suffer from several limitations: weak bonding,

220 life cycle assessment demonstrates that the adhesives synthesized via this approach outcompete the s

221 s study provides new insight into the larval adhesives system of thoracican barnacles.

222 we report tertiary amine (TA)-modified resin adhesives (TA@RAs) with pH-responsive antibacterial effe

223 platform in the future for discovery of anti-adhesives targeted for strain and species specificity.

224 merous applications in reinforcing polymers, adhesives, textiles, medical devices, metallic alloys, a

225 The relatively hydrophobic adhesives that achieved equivalent/enhanced bonding perf

226 s study is to make strong and durable dental adhesives that are free from 2 symbolic methacrylate-bas

227 medical need for tough biodegradable polymer adhesives that can adapt to or recover from various mech

228 Developing underwater adhesives that can rapidly and reversibly switch the adh

229 ported in resin-dentin interfaces created by adhesives that contain 10-methacryloyloxydecyl dihydroge

230 ew model system for the design of smart soft adhesives that dynamically respond to their environment

231 Self-etch adhesives that etch and prime simultaneously are becomin

232 Developing versatile, tough, and sustainable adhesives that function effectively in both wet and dry

233 Marine mussels secrete strong underwater adhesives that have been mimicked in synthetic systems.

234 inhibitors into the synthesis of therapeutic adhesives that may enhance the longevity of hybrid layer

235 Adhesives that selectively debond from a surface by stim

236 itive behaviour of carbon nanotube (CNT) dry adhesives that show a temperature-enhanced adhesion stre

237 top, we have created gecko-foot-mimetic dry adhesives that show macroscopic adhesive forces of appro

238 Smart adhesives that undergo reversible detachment in response

239 observations suggest that polymerization of adhesives that underwent insufficient light cure is salv

240 if such self-cure phenomenon takes place in adhesives that underwent prior inadequate light cure and

241 als for a range of applications, such as dry adhesives, tissue engineering, biointegrated electronics

242 al groups have become commonplace in medical adhesives, tissue scaffolds, and advanced smart polymers

243 cycle, many marine organisms rely on natural adhesives to attach to wet surfaces for movement and sel

244 b-weaving spiders have evolved well-designed adhesives to capture preys.

245 ed 10-MDP-containing self-etch and universal adhesives to human dentin.

246 by integration of film-terminated fibrillar adhesives to hybrid nematic liquid crystal network (LCN)

247 for many biomedical applications, designing adhesives to perform in the presence of body fluids prov

248 te rapid deterioration of the ability of the adhesives to stick to dentine, clinical studies show tha

249 the morphology of 81 species with fibrillar adhesives to test the hypothesis that packing density of

250 -coloured plastic dental fillings secured by adhesives to tooth structures are widely used to fix dec

251 Commercial adhesives typically fall into two categories: structural

252 Adhesives typically fall into two categories: those that

253 rrently available and investigational tissue adhesives used for corneal incisions.

254 Ancient adhesives used in multicomponent tools may be among our

255 ood contact chemicals from printing inks and adhesives used on plastic food contact materials was dev

256 literature on the use of a variety of tissue adhesives used to seal corneal incisions in cataract sur

257 formulated, prepared, and evaluated 2 dental adhesives using mixtures of a hydrolytically stable ethe

258 ly, the mechanical properties of these model adhesives varied from 'minimal change' to 'significant d

259 egree of conversion (DC) of HAp-incorporated adhesives was monitored by infrared spectroscopy during

260 the chemical interaction between dentin and adhesives was responsible for the observations.

261 lp facilitate the next generation of aqueous adhesives, we performed a combination of surface forces

262 Selected adhesives were allowed to etch and extract HAp from enam

263 (pizza and pastry) produced with 5 different adhesives were analysed by GC-O-MS.

264 These biodendrimer-based adhesives were applied directly to a 4.1-mm linear centr

265 Dentin adhesives were applied to the surface of sound dentin di

266 6.0 mm, t = 0.5 mm) of OPTB and experimental adhesives were characterized using Time-of-Flight Second

267 These adhesives were composed of equimolar ester-/ether-based

268 Biodendrimer-based hydrogel adhesives were derived from biocompatible building block

269 A total of 25 different compounds from adhesives were detected in these laminates.

270 Seven commercialized adhesives were examined: Adhese Universal (Ivoclar-Vivad

271 Model self-etch adhesives were formulated with various components, inclu

272 Twelve surgical tissue adhesives were included: 4 cyanoacrylate adhesives (CA),

273 Chemical studies have shown that these adhesives were made from a local conifer of the Podocarp

274 Experimental adhesives were manually synthesized by incorporating 20%

275 Model methacrylate-based adhesives were mixed with different amounts of water to

276 easurements suggested that the hybrid dental adhesives were relatively more hydrophobic than the Bis-

277 CA adhesives were stronger than AB (T: P = 0.017; S: P = 0.

278 Two adhesives were tested, one a commercial epoxy resin and

279 Commercial adhesives were used to bond the paint to various substra

280 leaking pressures were determined for these adhesives when used to seal 4.1-mm central lacerations a

281 s provides an analogy to mussel and barnacle adhesives whereas the high inorganic content is exclusiv

282 The typical protein adhesives, which are secreted by mussels, sandcastle wor

283 ectrodes with conductive gels and aggressive adhesives, while requiring precise positioning to ensure

284 Ideally, replacement adhesives will be made from benign, cheap, and renewable

285 Advances in tissue adhesives will open new avenues for wound care and poten

286 s)-into synthetic, cost-effective underwater adhesives with adjustable nano- and macroscale character

287 non-covalent interactions for the design of adhesives with advanced functionalities such as stimuli

288 on polymerization effectiveness of self-etch adhesives with different pHs has rarely been studied.

289 rfaces, and a broad range of animal secreted adhesives with environment-dependent properties.

290 luorometric assay and zymography showed that adhesives with MMP inhibitors had high affinity toward b

291 pplied to the development of various dry CNT adhesives with novel features.

292 ion of high-performance thermoset resins and adhesives with potential utility in transportation and a

293 d rheology of a comprehensive list of tissue adhesives with regard to colorectal adhesiveness.

294 Hand-sized gecko-inspired adhesives with reversible force capacities as high as 29

295 Developing tough adhesives with superior strength and ductility is challe

296 re we show a series of sustainable polymeric adhesives, with an eco-design, that perform in both dry

297 identified a number of EWs as potential anti-adhesives, with some as strain- or species-specific.

298 itu zymography within the HLs of both tested adhesives, with XPB higher than CSE ( P < 0.05).

299 Ideally these adhesives would also have the ability to deliver drugs o

300 many areas of application, including tissue adhesives, wound dressings, and tissue repair.