ライフサイエンスコーパス: thermoplastic

1 ybutyrate that are a source of biodegradable thermoplastic.

2 al in-plane nanopore sensor, fabricated in a thermoplastic.

3 those of PCHC, showing potential as a future thermoplastic.

4 ing and dehydration forms fibers as stiff as thermoplastics.

5 promising method for fabricating recyclable thermoplastics.

6 mechanochemical stability compared to other thermoplastics.

7 e to prepare conventional petrochemical-free thermoplastics.

8 processes, which are historically limited to thermoplastics.

9 ucture and mechanical strength of 3D printed thermoplastics.

10 g the design and construction of sustainable thermoplastics.

11 rmosets and malleability/reprocessability of thermoplastics.

12 ndent devices benefits from prototyping with thermoplastics.

13 ide range of amorphous and low crystallinity thermoplastics.

14 chieving quality prints from semicrystalline thermoplastics.

15 one that provides fully cured thermosets and thermoplastics.

16 important chemical building blocks for a.o. thermoplastics.

17 es from biodegradable cellulose acetate (CA) thermoplastics.

18 rs, combining the benefits of thermosets and thermoplastics.

19 M from thermal decomposition of nano-enabled thermoplastics.

20 ng of epoxy thermosets that do not exist for thermoplastics.

21 ymers and the processability/adaptibility of thermoplastics.

22 e Rheometer (OSR), constructed entirely from thermoplastic 3D printed components and off-the-shelf el

23 er, 4-acryloylmorpholine (ACMO), printing of thermoplastic 3D scaffolds is demonstrated, which can be

24 ar model epitomized by upcycling a prominent thermoplastic, acrylonitrile butadiene styrene (ABS) int

25 structures are assembled using wax as both a thermoplastic adhesive layer between two glass substrate

26 orporation of nanoparticles into engineering thermoplastics affords engineers an opportunity to synth

27 The flax mucilage conjugate exhibited thermoplastic and elastic properties; revealing Young's

28 acterization of microfluidic devices made of thermoplastic and elastomeric polymers.

29 e/butylene-styrene (SEBS) copolymers combine thermoplastic and elastomeric properties to provide micr

30 aterials with properties similar to those of thermoplastics and are an environmentally friendly alter

31 exhibit comparable performance to commercial thermoplastics and can be depolymerized to the original

32 ces with the advantageous properties of hard thermoplastics and ease of fabrication similar to PDMS.

33 The synthesis and processing of most thermoplastics and thermoset polymeric materials rely on

34 assical division of polymeric materials into thermoplastics and thermosets based on covalent network

35 applications have been largely restricted to thermoplastics and thermosets.

36 tworks (CANs) has obscured the line between "thermoplastic" and "thermoset" and erected a conceptual

37 However, thermoplastics are also known to exhibit autofluorescenc

38 hough glass could be used as an alternative, thermoplastics are better from a cost and fabrication pe

39 ting of polymers is accomplished easily with thermoplastics as the extruded hot melt solidifies rapid

40 cross-linked thermosets to non-cross-linked thermoplastics as well as degradable and nondegradable m

41 such as elastomers (MED: 61.2%; PAC: 3.4%), thermoplastics (ATL: 36.8%: MED: 20.7% PAC: 27.7%) and s

42 s to robust, machinable formats that exhibit thermoplastic behavior consenting material reshaping at

43 Unfortunately, biopolymers exhibiting thermoplastic behaviour and which preserve their mechani

44 The thermoplastic binder enables the electrodes to be hot em

45 th inexpensive materials (i.e., graphite and thermoplastic binder).

46 t composite graphite electrodes containing a thermoplastic binder.

47 al cancellous chips uniformly dispersed in a thermoplastic biologic carrier.

48 and cuttlefish are one notable exception of thermoplastic biopolymers.

49 mmercially available paraffin wax-polyolefin thermoplastic blend (elastomer matrix binder) with bulk-

50 g interest in low-cost, facile and versatile thermoplastic bonding for microfluidic applications that

51 robot while their arm was held in place by a thermoplastic brace.

52 Linear polymers for thermoplastics, branched polymers for thermosets and oth

53 oduced by passing CO(2) gas through a porous thermoplastic bubbler immersed in an aqueous solution of

54 thylene (POM) is a commonly used engineering thermoplastic, but its recycling by conventional means,

55 nd make the case that nanofiller presence in thermoplastics can significantly affect the physicochemi

56 Traditional thermoplastics cannot match soft tissue mechanics, while

57 in complex manufacturing processes, such as thermoplastic carbon fibre manufacturing.

58 (LT) PGA/TMC membrane and an allograft in a thermoplastic carrier.

59 etic beads-based sample preparation within a thermoplastic cartridge and a portable droplet magnetofl

60 e duplex test was integrated into a low-cost thermoplastic cartridge with automated processing of pen

61 mized modification conditions, a 3-electrode thermoplastic chip was integrated with paper-based analy

62 a circular piece of paper to the 3-electrode thermoplastic chip, enclosing the system with a PMMA cov

63 lectrochromatography of model peptides using thermoplastic columns with surfaces engineered to identi

64 s and yields more affordable cost than other thermoplastics commonly used for microfluidic applicatio

65 n-selective electrode combines a carbon-mesh/thermoplastic composite as the ion-to-electron transduce

66 d to be considered when manufacturing carbon thermoplastic composite electrochemical sensors when usi

67 iable approach for the manufacture of carbon thermoplastic composite electrochemical sensors.

68 e present formulation of a simple conductive thermoplastic composite we term 'carbomorph' and demonst

69 A series of flattened-nanotube reinforced thermoplastic composites are sizably fabricated as a fun

70 processing an extensive range of materials (thermoplastics, composites, biobased materials, etc.).

71 nalized target products, such as thermosets, thermoplastics, composites, cellulose nanocrystals, and

72 This cube, made of thermoplastic, contains reservoirs and channels for liqu

73 Bilayers from thermoplastic corn starch (TPS) and PLA were obtained, i

74 ng carbon dioxide (CO(2)) to make recyclable thermoplastics could reduce greenhouse gas emissions ass

75 ) from thermal decomposition of nano-enabled thermoplastics, critical questions about the effect of n

76 osed of 3 functional modules including (i) a thermoplastic CTC selection module composed of high aspe

77 xymethylene-a highly crystalline engineering thermoplastic (Delrin(R))-into its repolymerizable monom

78 Hot-embossed thermoplastic devices allow for high-throughput analysis

79 se a rapid prototyping protocol to fabricate thermoplastic devices from a stereolithography (SLA) 3D

80 as observed in PDMS devices compared to both thermoplastic devices.

81 present flexible X-ray detectors prepared by thermoplastic dispersal of a semiconductive MOF (SCU-13)

82 oughput, it is common to mold devices out of thermoplastics due to low per-unit costs at high volumes

83 ene propylene diene monomer rubber (EPDM) or thermoplastic elastomer (TPE) eluates, reflect the stron

84 of this triblock copolymer showed a typical thermoplastic elastomer behavior with a steady rubbery p

85 We demonstrate the use of thermoplastic elastomer gels as advanced substrates for

86 r (P(MMA-b-MA-b-MMA), M(n) = 564 kg mol(-1)) thermoplastic elastomer showed exceptional strain (>1600

87 of the MOP nanocomposites, a MOP-composited thermoplastic elastomer was obtained, providing practica

88 ersion of 1-5 vol.% of carbon nanotubes in a thermoplastic elastomer yields nanocomposites that can s

89 ials through direct pyrolysis of crosslinked thermoplastic elastomer-based block copolymers.

90 We demonstrate that a thermoplastic elastomer-poly(vinyl alcohol) (PVA) compos

91 rain at break) were prepared, along with SPU thermoplastic elastomers (578 % strain at break) which a

92 The resulting thermoplastic elastomers (TPEs) exhibit microphase separ

93 d in recent years, technologically important thermoplastic elastomers (TPEs) that are not only bio-ba

94 ghly performant functional polymers, such as thermoplastic elastomers and adhesives, among others.

95 es the advantageous mechanical properties of thermoplastic elastomers and the dynamic self-healing fe

96 Thermoplastic elastomers based on polyesters/carbonates

97 This diene copolymerization resulted in thermoplastic elastomers displaying nanophase separation

98 t for traditional petroleum-derived styrenic thermoplastic elastomers due to the high glass temperatu

99 Following mechanical damage, these thermoplastic elastomers show excellent self-healing abi

100 ving frustrated Lewis pairs (FLPs)-which are thermoplastic elastomers showing much superior mechanica

101 e show a design of multiphase supramolecular thermoplastic elastomers that combine high modulus and t

102 gmented multi-block polyurethanes (SPUs) and thermoplastic elastomers that incorporate an appreciable

103 nds of boronic ester into commodity triblock thermoplastic elastomers that reversibly bind with vario

104 rethanes that can be either strong amorphous thermoplastic elastomers with properties that exceed mos

105 rentially reinforce the hard microdomains of thermoplastic elastomers with smectic clay of similar ch

106 n effort to synthesize chemically recyclable thermoplastic elastomers, a redox-switchable catalytic s

107 sis of the most ubiquitous materials such as thermoplastic elastomers, bridge interphases in polymer

108 properties of bio-derived ABA-block polymer thermoplastic elastomers, but the general fingerprinting

109 nd thermomechanical properties that resemble thermoplastic elastomers, including a rubbery plateau in

110 -cost carbon fibers, engineered plastics and thermoplastic elastomers, polymeric foams, fungible fuel

111 so provide potential alternatives to current thermoplastic elastomers, rubber-modified plastics, and

112 m rigid to flexible thermoplastics, to tough thermoplastic elastomers, to a pressure-sensitive adhesi

113 Uses as thermoplastic elastomers, toughened plastics, adhesives,

114 k copolymers, with potential applications as thermoplastic elastomers, were synthesized by combining

115 ical performance, unlike commercial styrenic thermoplastic elastomers.

116 temperatures, show significant potential as thermoplastic elastomers.

117 bon nanotube electrical components and tough thermoplastic elastomers.

118 ircuit substrate in combination with printed thermoplastic electrically conductive adhesives (ECA), w

119 Herein we describe incorporation of thermoplastic electrode (TPE) arrays into flow ePADs.

120 Thermoplastic electrodes (TPEs) are carbon composite ele

121 Thermoplastic electrodes (TPEs) were modified with these

122 The electrodes, which are termed thermoplastic electrodes (TPEs), are easy to fabricate a

123 rs on the electrochemical activity of carbon thermoplastic electrodes but limited is known about the

124 luation of LCPM for the case of polyurethane thermoplastic enabled with carbon nanotubes (PU-CNT).

125 ood processes such as fermentation, malting, thermoplastic extrusion or enzymatic, alkaline and acid

126 nd SOX9) genes within networks of 3D printed thermoplastic fibers to produce mechanically reinforced,

127 tal associations in particles unique to each thermoplastic filament type.

128 In this technique, a transparent thermoplastic film (ethylene vinyl acetate polymer) is a

129 Thermoplastic films (50-75 microm thickness) are coated

130 identified the composition with the highest thermoplastic formability in the glass-forming system Mg

131 ricated simultaneously and characterized for thermoplastic formability through parallel blow forming.

132 erature) is narrow, resulting in very little thermoplastic formability, which limits their practical

133 to traditional metal processing techniques, thermoplastic forming (TPF)-based microfabrication metho

134 llization of BMG formers has uncovered novel thermoplastic forming (TPF)-based processing opportuniti

135 ttlement of amorphous alloys associated with thermoplastic forming and yields new insight the forming

136 ce rivalling advanced engineering alloys and thermoplastic forming capabilities analogous to conventi

137 ctural homogeneity and isotropy, and ease of thermoplastic forming exhibited by these materials.

138 Rapid thermoplastic forming of the undercooled liquid into com

139 als that offer the unique ability to perform thermoplastic forming operations at low thermal budget w

140 arsh environments can readily be obtained by thermoplastic forming(14).

141 hile a large number of chemically recyclable thermoplastics have been developed in recent years, tech

142 based thermoset networks or nonbiodegradable thermoplastic hot melts, making them ideal targets for r

143 nctionalization upcycled the material from a thermoplastic into a tough elastomer with the tensile pr

144 Extending DLP to thermoplastics is highly desirable, but is challenging d

145 e synthesis and characterization of a strong thermoplastic made from 2,3-dihydrofuran (DHF), a monome

146 effective electric resistivity of conductive thermoplastics manufactured by filament extrusion method

147 s array as part of a microfluidic chamber in thermoplastic material and performed multiplexed SP-PCR

148 These findings highlight that any conductive thermoplastic material can be fabricated into a microele

149 cyclic olefin copolymer (COC), a widely used thermoplastic material known for its excellent chemical

150 xolane) (UHMW pDXL), a chemically recyclable thermoplastic material with excellent physical propertie

151 g a solid or liquid, and use potentially any thermoplastic material without processing additives.

152 describes a microfluidic device composed of thermoplastic material, poly (methyl methacrylate) (PMMA

153 inting technique based on the extrusion of a thermoplastic material.

154 Although thermoplastic materials are mostly derived from petro-ch

155 The use of thermoplastic materials may pave the way for inexpensive

156 ene co-methacrylic acid) ionomers (EMAA) are thermoplastic materials that when punctured, cut, shot o

157 er)s (PAEs) are a family of high-performance thermoplastic materials with high glass-transition tempe

158 A variety of ceramic substrates, thermoplastic materials, and metals can be used; e.g., i

159 by embossing features from a hard mould onto thermoplastic materials, typically polymers with low gla

160 ant to the processing and to applications of thermoplastic materials.

161 ew entry point for researchers interested in thermoplastic microchips and can accelerate the developm

162 The thermoplastic microfluidic device comprises five tailor-

163 addition, owing to the surge in the usage of thermoplastic microfluidics and its adverse effect on th

164 iscuss the development and clinical use of a thermoplastic modular microsystem for the high-throughpu

165 An inexpensive, magnetic thermoplastic nanomaterial is developed utilizing a hier

166 The thermoplastic nature also enables excellent mechanical s

167 r equipped with multiple extruders, we blend thermoplastics of varying Shore hardness into monolithic

168 By 3D printing a mendable thermoplastic onto woven glass/carbon fiber reinforcemen

169 The crosslinked matrix can be thermoplastic or thermoset, depending on the extent of c

170 del and relevant assays in a high-throughput thermoplastic organ-on-chip platform, PREDICT96.

171 e-metal Fe particles make up over 50% of the thermoplastic particle population.

172 Thermoplastic parts manufactured via fused filament fabr

173 ices with low adsorption properties from the thermoplastics poly(methyl methacrylate) (PMMA), polysty

174 Partially biobased engineering thermoplastic, poly(trimethylene terephthalate) (PTT), w

175 rmance, all-aromatic, insoluble, engineering thermoplastic polyimides, such as pyromellitic dianhydri

176 f water to selectively remove the insulating thermoplastic (polylactic acid) via saponification.

177 posite electrodes consisting of graphite and thermoplastic polymer binder.

178 essels are constructed from injection-molded thermoplastic polymer components.

179 nt of superparamagnetic nanoparticles into a thermoplastic polymer enables the repair of regions dama

180 due to the presence of a high percentage of thermoplastic polymer in the conductive filaments.

181 Polyvinylpyrrolidone (PVP), a thermoplastic polymer is sprayed below its glass transit

182 lability of composite materials containing a thermoplastic polymer matrix and dispersed silica partic

183 , which are involved in the synthesis of the thermoplastic polymer polyhydroxybutyric acid.

184 te (PET) material as a substrate, which is a thermoplastic polymer resin from the polyester family.

185 r and transformation of polyamide-6 (PA6), a thermoplastic polymer widely used in industry during sim

186 Polystyrene (PS) is a widely used thermoplastic polymer, but its very low recycling rate h

187 Thermoplastic polymers (plastics) allow easy surface tre

188 ere, a successful attempt at DLP printing of thermoplastic polymers is reported, realized by controll

189 Driven by the need to make high temperature thermoplastic polymers more processable and expand the r

190 us-shaped devices, generally fabricated from thermoplastic polymers or silicone elastomers, used to a

191 ity of combining three-dimensionally printed thermoplastic polymers with polymeric foam to replicate

192 Thermoplastic polymers, despite their reprocessibility t

193 mal analysis indicated the presence of eight thermoplastic polymers, originating from diffuse sources

194 , including metals, ceramics, thermoset, and thermoplastic polymers.

195 the non-biodegradable silicone elastomer or thermoplastic polymers.

196 wrinkles were created by chemically treating thermoplastic polystyrene sheets to form a thin skin lay

197 non-solvent liquids, porous carbon nanofiber/thermoplastic polyurethane (CNF/TPU) nanocomposites were

198 um rosin as a biocompatible agent within the thermoplastic polyurethane (TPU) elastomer to form the T

199 butyral (PVB), ethylene vinyl acetate (EVA), thermoplastic polyurethane (TPU), and the ionomer Sentry

200 wo orders of magnitude longer than that of a thermoplastic polyurethane (TPU).

201 Thermoplastic Polyurethane (TPU)/Carbon Nanotubes (CNTs)

202 ic particles from a bio-based, biodegradable thermoplastic polyurethane (TPU-FC1) and demonstrated th

203 Ester- and ether-based thermoplastic polyurethane (TPU_Ester and TPU_Ether) mic

204 The strain-induced softening of thermoplastic polyurethane elastomers (TPUs), known as t

205 Thermoplastic polyurethane elastomers enjoy an exception

206 Here we produced SWCNT ropes wrapped in thermoplastic polyurethane elastomers, and demonstrated

207 eport the development of mechanically robust thermoplastic polyurethane fibers and films capable of a

208 tal particles (LMPs) within a functionalized thermoplastic polyurethane matrix.

209 idene fluoride (PVDF) and PVDF embedded with thermoplastic polyurethane nanofibers are synthesized as

210 r-degrading bacteria are incorporated into a thermoplastic polyurethane using high-temperature melt e

211 ak) which are comparable values to classical thermoplastic polyurethanes (TPUs).

212 e overall tensile properties of spore-filled thermoplastic polyurethanes are substantially improved,

213 another, which is verified by the 3D-printed Thermoplastic Polyurethanes prototypes.

214 onstrate its applicability for polyamide and thermoplastic polyurethanes.

215 of these monomers to prepare fully renewable thermoplastic polyurethanes.

216 Currently available (thermoplastic) polyurethanes [(T)PU] are not biodegradab

217 riendly, step-by-step guide for converting a thermoplastic printer into a bioprinter using components

218 This affordable thermoplastic probe makes high spatial resolution nano-D

219 us properties of cross-linked materials with thermoplastic processability.

220 r results provide guidance for the design of thermoplastic processing methods and methods for verifyi

221 Here we describe thermoplastic processing of squid SRT via hot extrusion

222 duced PHA suggest that they are suitable for thermoplastic processing.

223 hydroxyalkanoates) are natural polymers with thermoplastic properties.

224 tion (HDA) to amplify the DNA in a low-cost, thermoplastic reaction chip heated with a pair of commer

225 es because of the high content of insulating thermoplastic required for FFF printers.

226 ricated by plasma treatment of a prestressed thermoplastic shrink film to create tunable multiscaled

227 We found that nanofiller presence in thermoplastics significantly enhances not only the total

228 device consists of electrospun medical-grade thermoplastic silicone-polycarbonate-urethane and is sof

229 res occurs spontaneously when a metal-coated thermoplastic stamp is compressed against a ceramic subs

230 ures on ceramic surfaces using metal-coated, thermoplastic stamps.

231 Improved miscibility between thermoplastic starch (TPS) and polybutylene adipate-co-t

232 ional bioplastic packaging was produced from thermoplastic starch (TPS) with nitrite (1-5%) and polyb

233 ith poly(butylene adipate terephthalate) and thermoplastic starch blends (PBAT/TPS) by blown-film ext

234 polybutylene adipate terephthalate and 60 % thermoplastic starch) were produced via extrusion for fi

235 ign of biomimetic protein- and peptide-based thermoplastic structural biopolymers with potential biom

236 tes are underinvestigated, and the resulting thermoplastic structure-property relationships, processi

237 While this has been observed in thermoplastics, studies on how stereochemistry affects t

238 provide benefits over traditionally employed thermoplastic substrates and enable 3D device integratio

239 Thin-film pH electrodes on thermoplastic substrates can be subjected to gamma-radia

240 These values are similar to those of thermoplastics such as polyethylene, yet unlike thermopl

241 Thermoplastics such as polystyrene (PS) and cyclo-olefin

242 opolymers with backbones derived from common thermoplastics, such as poly(dimethylsiloxane), hydrogen

243 tly improved by the effective removal of the thermoplastic support polylactic acid (PLA) as well as t

244 rosslinking between the bulk photoresist and thermoplastic surface is achieved during polymerization.

245 Thermoplastic surfaces were oxidized using UV-generated

246 bonds between 3D photoresist structures and thermoplastic surfaces.

247 Here, we combine large-scale thermoplastic tensile deformation of collections of Pt-b

248 icient polymerization method affords a tough thermoplastic that can undergo selective depolymerizatio

249 ded (XPS) is a rigid, lightweight insulating thermoplastic that has a variety of uses in the consumer

250 PSUs are high-performance engineering thermoplastics that are commonly used for reverse osmosi

251 ractions of ODO yields tough and transparent thermoplastics that have over 12x elongation at break co

252 rmoplastics such as polyethylene, yet unlike thermoplastics, the glassy gels can be deformed up to 67

253 The range of polymers used in AM encompasses thermoplastics, thermosets, elastomers, hydrogels, funct

254 CANs span the divide between thermosets and thermoplastics, thus offering unprecedented possibilitie

255 rate of depolymerization of the sacrificial thermoplastic to match the kinetics of FP has the potent

256 range of mechanical properties, encompassing thermoplastics to plastomers to elastomers.

257 ono-materials ranging from rigid to flexible thermoplastics, to tough thermoplastic elastomers, to a

258 s nanocellulose (CNF) into rice starch-based thermoplastic (TPS) films, evaluating the effects of fou

259 ce conditions and easy reprocessability like thermoplastics under certain external stimuli.

260 rmally assisted solvent based bonding of the thermoplastics was accomplished in a domestic microwave

261 Micromilling of thermoplastics was used to fabricate these microstructur

262 properties of the other four Cp-incorporated thermoplastics were also examined.

263 structures of discontinuous fiber reinforced thermoplastics, while also allowing scientists and engin

264 erties, spanning elastomers to plastomers to thermoplastics, while integrating a high melting transit

265 as investigated as a potential high-strength thermoplastic with greater susceptibility toward degrada

266 identified as a new class of semicrystalline thermoplastics with a valuable combination of mechanical

267 ously inaccessible multiblock thermosets and thermoplastics with full recyclability, and may be gener

268 ss-linked rubbers or robust, semicrystalline thermoplastics with properties comparable to commercial

269 All these materials are amorphous thermoplastics, with high glass transition temperatures