ライフサイエンスコーパス: print

1 s by additive manufacturing (for example, 3D printing).

2 e pore system has been extracted and nano-3D-printed.

3 h can be used as coating, but can also be 3D printed.

4 in the emerging fields of bio- and composite-printing.

5 y (EM) density maps, and export files for 3D printing.

6 insulating elastomers via multi-material 3D printing.

7 that can be performed with embedded droplet printing.

8 acilitate rapid holographic rendering and 3D printing.

9 g activities and ex situ analysis during ABS printing.

10 ol of polymer conversion and gelation during printing.

11 hrough microlithographic fabrication and 3-D printing.

12 is machine-woven and used as filament for 3D printing.

13 ew swabs for immediate mass production by 3D printing.

14 stomized scaffolds and surgical guides by 3D printing.

15 chanism essential to stereolithography-based printing.

16 fined features through selective single-cell printing.

17 [Epub ahead of print].

18 oxel-level dosimetry of a 3-dimensional (3D) printed 2-compartment kidney phantom was performed, and

19 [Epub ahead of print.] 32371401.

20 spherical and rectangular geometries of bio-printed 3D human colon cancer cell constructs.

21 ed organ-on-a-chip-like platforms along with printed 3D-cell structures.

22 3D printing (3DP) has transformed engineering, manufacturin

23 y, we used a multimaterial three-dimensional printing (3DP) technology and porous composite filaments

24 traditional antibody printing for ELISA that prints a capture antibody specific to a target of intere

25 A high-definition single-cell printing, a novel microfluidic technology, is presented

26 Here we introduce embedded droplet printing-a system and methods for the generation, trappi

27 ls, printed maxillofacial implants and other printed acellular devices have been used in patients.

28 in the integration of nanomaterials with 3D printing, achieved by leveraging mechanical, electrical,

29 e styrene (ABS) and polylactic acid (PLA) 3D printing activities and ex situ analysis during ABS prin

30 Therefore, precise prepatterning by 3D printing allows the construction of natural and unnatura

31 ctronics, it remains challenging to solution-print an array of NWs with precisely controlled position

32 ed through in vitro spray measurements in 3D-printed anatomic replicas using the gamma scintigraphy t

33 Based on its work, the SC publishes print and electronic standards and guidelines, including

34 lies on the use of biomaterial-based inks to print and stabilize deterministic patterns of biochemica

35 Here, we present the convergence of 3D printed and paper formats into hybrid devices that overc

36 Toward their success, advances in 3D printing and biofabrication technologies are needed with

37 of the key thrusts in three-dimensional (3D) printing and direct writing is to seamlessly vary compos

38 as demonstrated here in encryptable surface printing and stamping, direction- and track-programmable

39 nto the cellulose-based filter paper through printing and subjecting the paper to heat treatment to a

40 scientists to recognize the usefulness of 3D printing and to make an informed buying decision on thei

41 modelling, additive layer manufacturing (3D printing) and experimental testing are implemented to ju

42 trol over both the shape forming process (3D printing) and final mechanical properties.

43 approaches such as ink-jet printing, screen printing, and electron-beam lithography, whose limitatio

44 nclude spray draying, hot-melt extrusion, 3D printing, and electrospinning.

45 est-suited filament material for the cage 3D printing, and polycaprolactone fibers appeared the most

46 theses via automated noncontact scanning, 3D printing, and silicone casting.

47 F), jetting technologies including inkjet 3D printing, and vat photopolymerization techniques includi

48 d sensors and circuits, thinned silicon ICs, printed antennas, printed energy harvesting and storage

49 pment to expand the materials toolbox for 3D printing applications to meet the true potential of 3D p

50 ence electrodes were integrated by a stencil-printing approach, and the whole device was assembled by

51 eptides and the traditional capture antibody printing approach, with r(2) values of 0.99, 0.93, 0.99,

52 nnas and demonstrate that screen and stencil printing are both suitable for fabricating antennas; the

53 r variation of less than 10% across multiple printed arrays demonstrated the high sensitivity and rep

54 Ahead of Print article withdrawn by publisher.

55 reviously prepared HS oligosaccharides, were printed as a glycan microarray to examine the binding se

56 corresponding ganglio-oligosaccharides were printed as a microarray to examine binding specificities

57 In this Feature, we introduce 3D printing as a tool for use in research laboratories, bri

58 ry and internal architecture has situated 3D printing as an attractive fabrication technique for scaf

59 ion, from suspension polymerization to novel printing, as well as in a new family of polymerization t

60 3DP offers the advantage of being able to print at a variety of lengths scales; from a few microme

61 and photocaged oligonucleotides to serially print barcodes ('zipcodes') onto live cells in intact ti

62 Three-dimensionally (3D) printed bioceramic (BioCer) implants consisting of addit

63 system of cats, rats and zebrafish, that the printed bioelectronic interfaces allow for long-term int

64 Herein, a 3D printed bioinspired electrode of graphene reinforced wit

65 Here, we develop 3D printed bionic corals capable of growing microalgae with

66 Furthermore, fully-printed biosensors made with a tyrosinase-containing ink

67 ss spectrometry (MALDI-TOF MS) target plates printed by FDM technology using conductive plastic mater

68 3D printing can allow for the efficient manufacturing of el

69 ead applications in promoting the current 3D printing capacities for generating higher-resolution hyd

70 trochemical behaviour of skatole at a screen-printed carbon electrode (SPCE vs. Ag/AgCl).

71 sensor platform was constructed using screen-printed carbon electrode (SPCE) modified with graphene/t

72 the prepared NCs are deposited on the screen printed carbon electrode (SPCE) using chitosan as cross-

73 We describe a convenient assembly for screen printed carbon electrodes (SPCE) suitable for analyses i

74 amperometric detection at disposable screen-printed carbon electrodes (SPCEs) modified with a gold n

75 ence of H(2)O(2)/hydroquinone (HQ) at screen-printed carbon electrodes (SPCEs) upon surface capturing

76 printed electrochemical sensors using screen-printed carbon electrodes coated with carbon black inks

77 designed sensor, based on disposable screen-printed carbon electrodes modified with Au nanoparticles

78 linical applications, with a focus on how 3D-printed cartilage, bone and skin can be designed for ind

79 report a robust capillary-assisted solution printing (CASP) strategy to rapidly access aligned and h

80 f indoor microenvironments at six commercial printing centers in Singapore, the first such assessment

81 to these nanoparticles and work practices in printing centers.

82 lity of these powerful tools motivated us to print chemical sensing elements directly on the surface

83 The DT is constructed from a flexible printed circuit board (PCB), with a bespoke "dog-leg" tr

84 CSFET sensor array is combined with a custom-printed circuit board into a compact, fully integrated,

85 ensing units incorporated on the paper-based printed circuit boards (PCBs) absorbed bacteria-laden su

86 accomplish this by incorporating various 3D printed components and by modifying existing light pathw

87 Additionally, the printed composite film exhibits improved photoconductanc

88 In this work, we prepared 3D printed composite scaffolds comprising polycaprolactone

89 itable CPS type- and concentration-dependent printing conditions.

90 The 3D-printed conducting polymers can also be converted into h

91 Furthermore, the printed construct elicits minimal inflammatory responses

92 ocking by designing specific knobs in the 3D printed construct of the Cartilage Portion.

93 ning (85% reduced elastic modulus) of the 3D-printed constructs.

94 ary composition and functional properties in printed constructs.

95 It is forecast that the adoption of 3D printing could pave the way for a personalised health sy

96 erating large bone defects in sheep using 3D-printed customized calcium phosphate scaffolds with or w

97 tures using high-resolution visible light 3D printing, demonstrating the broad utility of these catal

98 A miniaturized 3D-printed device has been designed, manufactured and valid

99 This 3D printed device provides a unique high-throughput in vitr

100 Two types of 3D printed devices for simultaneous mixing of small volumes

101 s and that particles sampled during filtered prints did not have a high contribution (~4% vs ~10%) fr

102 The workflow of creating this novel nano-3D-printed digital rock 3D model is described in this paper

103 d energy harvesting and storage modules, and printed displays, are discussed.

104 spectrometry is implemented by coupling a 3D-printed drift tube ion mobility spectrometer, operated a

105 zation enables control over the curvature of printed droplets, as highlighted by high-throughput prin

106 promising features for its application in 3D printed drug products and nanofiber-based drug delivery

107 400.530.70) reduced the odds of distributing print education.

108 t discussions with patients, 17% distributed print educational resources, and 3% used intensive educa

109 Herein, we report the fabrication of fully-printed electrochemical sensors using screen-printed car

110 This is because the 3D-printed electrode has an open structure that ensures exc

111 A screen-printed electrode pair coated by a membrane impregnated

112 ded for the measurement, and office paper to print electrodes able to measure the butyrylcholinestera

113 nd seizures is presented by employing screen-printed electrodes (SPE).

114 using commercial graphene oxide-based screen-printed electrodes and varying enzyme producing strains,

115 de array (PBEA) constituted by eight stencil-printed electrodes on a flexible PET (polyethylene terep

116 Screen-printed electrodes were coated by the electropolymerizat

117 ols into a single platform by coating screen-printed electrodes with absorbing cotton padding.

118 ccase enzyme on carbon black modified screen-printed electrodes.

119 the design of next-generation of 'on-demand' printed electronic and electromechanical devices.

120 The performance of the printed electronics is demonstrated by using real-time c

121 It uses flexible and printed electronics where flexibility and scalability ar

122 All-printed electronics, incorporating machine learning, off

123 ilms, tubes, cones, unimorphs, bimorphs, and printed elements enables differentiated mechanical respo

124 Three-dimensional (3D) hydrogel printing enables production of volumetric architectures

125 Digital Light Processing (DLP) 3D printing enables the creation of hierarchical complex st

126 uits, thinned silicon ICs, printed antennas, printed energy harvesting and storage modules, and print

127 Since slot-die deposition enables printing enzymes without significant activity loss, the

128 hese tags could be used to form a network of printed, flexible, passive, interactive sensor tags.

129 haracterize two versions of flexible, screen printed folded dipoles and a meandered monopole operatin

130 soft biocompatible materials can be rapidly printed for the on-demand prototyping of customized elec

131 Unlike traditional antibody printing for ELISA that prints a capture antibody specif

132 may be scaled to large area by roll-to-roll printing for lightweight solar power systems.

133 A shift in emphasis from using 3D printing for prototyping, to mimic conventionally manufa

134 bioscanner imaging and manufactured using 3D printing for use with negative pressure wound therapy (N

135 de 1 cellulose chromatography paper with wax-printed four channels for wicking and capillary flow-bas

136 strain-energy dissipation compared to those printed from a commercially available photocurable elast

137 Three Japanese woodblock prints from the Edo period (1603-1868) underwent a scien

138 oved control over droplet packing, we can 3D-print functional synthetic tissues with single-droplet-w

139 vice assembled with SF-3D GA as anode and 3D-printed GA decorated with MnO(2) as cathode achieves a r

140 ntly improve the mechanical stability of the printed graphene films compared with those of convention

141 The printed graphene oxide microelectrodes were electrochemi

142 3D printing has become one of the most promising methods to

143 More recently, 3D printing has been introduced to fabricate molds for soft

144 Among methods for device fabrication, 3D printing has emerged as a potential approach for fabrica

145 Using a custom 3-dimenstional-printed heart simulator with porcine aortic roots (n=5),

146 ough the polylactic acid junctions in the 3D-printed heterostructure.

147 ported printing technique is developed to 3D print human cortical cells in the soft, biocompatible EC

148 eins and used this bioink to 3-dimensionally print human induced pluripotent stem cell-laden structur

149 Printed human neural stem cells (hNSCs) show high viabil

150 Our work demonstrates that the 3D-printed hydrogels with angiogenic cells hold great promi

151 gy distribution, demonstrating structures 3D printed in thiol-ene resin by means of tomographic volum

152 Inkjet-printing in particular is a compatible fabrication metho

153 despread usage of nano-enabled toners in the printing industry, as well as inadequate ENM-specific ex

154 cosmetics to direct write three-dimensional printing inks and filled rubbers.

155 er served as model for three 3-dimensionally printed inserts.

156 laboratories without access to the precision printing instrumentation and will be useful for antibody

157 ic functionalities, through the so-called 4D printing, introduces novel opportunities for the fabrica

158 Three-dimensional (3D) printing is transforming manufacturing paradigms within

159 Thus, we report 3D-printed labware designed to measure and handle solids in

160 l testing, the stress-strain responses of 3D-printed LCE lattice structures are shown to have 12 time

161 AME) as the filtering capacitor, wherein 3-D printed lines of varying wt% of PEDOT:PSS hydrogels were

162 sttest, P < 0.001), but did not affect their print-literacy skills.

163 The results indicate that 3D printed MALDI targets are comparable to standard MBT Bio

164 Moreover, the 3D printed MALDI targets are disposable, cheap, and easy to

165 The 3D printed MALDI targets were validated by analysis of diff

166 Advances in printing materials and techniques for flexible and hybri

167 The nature of the printing materials enhanced the analytical performance o

168 nted orthopaedic devices and surgical tools, printed maxillofacial implants and other printed acellul

169 ic regions onto nitrocellulose using the wax printing method and form one-dimensional sensor barcodes

170 DM prostate models are the most preferred 3D printing method by surgeons.

171 nd digital light projection (DLP) are the 3D printing methods most frequently adopted by the microflu

172 stablishing new models, predictive tools and printing methods that are deemed instrumental for the de

173 Many 3D printing methods were developed in short course after Ch

174 Designing 3D printed micro-architectures using electronic materials w

175 The miniaturization of SPE within a 3D printed microfluidic device further allows for fast and

176 ssfully achieved in the DAMR system using 3D-printed microfluidic device.

177 yl methacrylate-based monolith, formed in 3D printed microfluidic devices, which can selectively reta

178 tely from the excess fluorescent label in 3D printed microfluidic systems.

179 analysis on the use of hydrogel bioinks for printing microvascularized constructs within the framewo

180 The approach produced 3D printed mimics that performed similarly to ethylene-viny

181 nt of biomaterials suited for light-based 3D printing modalities with an emphasis on bioprinting appl

182 by enabling virtual surgical planning and 3D printed model generation.

183 In this work, we present a fully 3D-printed module for attenuated total reflection Fourier t

184 ssues in these PDMS devices produced from 3D printed molds and after proper device washing and condit

185 aged in patient-specific three-dimensionally printed molds by using 3-T MRI with DR-CSI and were then

186 In the present study, we investigated if 3D printed molds produced by stereolithography can leach co

187 leach components into PDMS, and compared 3D printed molds to their more conventional SU-8 counterpar

188 ndreds of picolitre-sized droplets within 3D-printed, multi-layer networks.

189 cluding spray drying, hot-melt extrusion, 3D printing, nanoprecipitation and electrospinning leading

190 We developed a 3D-printed nasopharyngeal (3DP) swab as a replacement of th

191 mperature or light radiation), adding to the printed object new interesting properties exploited afte

192 ghly biocompatible and elastic bioink for 3D printing of complex soft tissues is demonstrated.

193 tion of a pattern of MoS(2); the second, the printing of dielectric layers, contacts, and connections

194 Printing of electronics has been receiving increasing at

195 3D printing of graphene electrodes with high mechanical str

196 droplets, as highlighted by high-throughput printing of microlenses with tunable focal distance.

197 pai-pai stacking interaction, leading to the printing of multiple high-resolution patterns on various

198 aterial, less attention has been payed to 3D printing of nanoparticles with intrinsic porosity.

199 nsfer-printing, which enables patterning and printing of quantum dot arrays in omni-resolution scale;

200 trical stimulators, which are made via spray printing of silver nanowires on multiscale porous SEBS s

201 ese CBCT scans were used to print plastic 3D prints of the nasal cavities, which were also CBCT scann

202 Here, a new, yet general, approach to the "printing" of skyrmions with zero-field stability in arbi

203 s work describes the construction, by screen-printing, of a self-powered electrochromic device that c

204 ors of heterogeneous structures are directly printed on 2D flat and 3D spherical substrates, demonstr

205 When printed on polyimide, the PT sensor exhibited no variati

206 s to generate a COF ink that can be directly printed onto surfaces.

207 len extract, polyclonal anti-human IgE) were printed onto three different polymer-coated surfaces (al

208 to graphene ink that is suitable for screen printing onto paper substrates.

209 ctional imaging and ex vivo simulation using printed or virtual 3-dimensional models.

210 The first copy of every 3D-printed orbital prosthesis using this fabrication workfl

211 r, indicating a potential use as tunable 3-D printed organic electronic analog filtering elements for

212 ransducer materials in the emerging field of printed organic sensors and biosensors.

213 3D-printed orthopaedic devices and surgical tools, printed

214 oplanar 3 x 15 mm Prussian Blue, PB, cathode printed over a transparent poly(3,4-ethylenedioxythiophe

215 o involve complex hardware upgrades or other printing parameter alterations.

216 with a combination of three dimensional (3D)-printed parts and common hardware, which is amenable to

217 other type ("Mix-Bricks") consists of two 3D printed parts: an interlocking "brick" that contains a s

218 atterns on various substrates using a single printing pass.

219 ly reinforced and biologically compatible 3D printed PCL-rGO scaffolds are a promising platform for r

220 Intriguingly, the as-printed perovskite NWs array exhibit excellent optical a

221 reconstruction of large bone defects with 3D-printed personalized scaffolds.

222 ulations against in vitro measurements in 3D-printed phantoms representing the patient's vasculature.

223 Capturing the dynamic response of 3D printed phantoms, ex vivo biological tissue, and in vivo

224 -like housing consisting of two identical 3D printed pieces that were locked together by a magnetic s

225 These CBCT scans were used to print plastic 3D prints of the nasal cavities, which wer

226 erate reduced graphene oxide (rGO) within 3D-printed polylactic acid (PLA) electrodes and their poten

227 he same methodology to a ToF-SIMS image of a printed polymer microarray for the first time.

228 ration without layering defects, enabling 3D printed polymer parts with mechanical properties similar

229 The construction of HAPI consists of 3D printed polymer structures that enable a sufficiently lo

230 taking another step toward high-performance printed polymers.

231 e undergo significant deformation during the printing process, which may impair shape fidelity.

232 organize, or assemble nanomaterials in a 3D printing process.

233 Three-dimensional (3D) printed prostate cancer models are an emerging adjunct f

234 ToF-SIMs analysis was performed to assess printed protein stability and retention during washing s

235 3D printing proved to be a suitable and fast method for rep

236 This POCT with printed PT sensors has the potential to dramatically imp

237 Here, a post-3D printing recovery protocol is designed that eliminates t

238 We hereby review the peer-reviewed and pre-print reports pertaining to cardiovascular consideration

239 Unfiltered ABS prints resulted in particle mass size distributions with

240 This is not another 3D printing review but rather a guide which will help scien

241 Based on both applications, the 3D-printed rGO-PLA showed to be an excellent platform for s

242 ls enhanced the analytical performance of 3D-printed sample pretreatment devices.

243 d on conventional approaches such as ink-jet printing, screen printing, and electron-beam lithography

244 The 3D-printed sensor presented here is not only successful in

245 undamental building blocks of an FHE system, printed sensors and circuits, thinned silicon ICs, print

246 erent heterogeneity pattern were realized by printing separate compartments that could be filled with

247 d device was designed for each patient by 3D printing shape of a prism and a hollow base, taking into

248 ology, is presented here that can accurately print single cells from a mixture of multiple candidates

249 iscovery offers a practical means to keep 3D-printed single crystals from cracking due to unrelieved

250 We measured reading speed as a function of print size for three digital formats (laptop, tablet, an

251 on beam with a graphic pattern generator to "print" skyrmions is used, which is referred to as skyrmi

252 ted system that combines direct mask-less 3D printed strain gauges, flexible piezoelectric energy har

253 First, a robust meniscus-assisted solution-printing strategy is employed to facilitate the oriented

254 Here, a lithography-based 3D printing strategy is used to fabricate a novel miniaturi

255 chical porous structure is reported via a 3D printing strategy.

256 x, the rheological-parameters-guided DLS can print structures seven times tougher than those formed f

257 d electron-tunneling model for conductive 3D-printed structures with thermal expansion and external s

258 graphene oxide coatings (GOCs) by the screen-printed technique and further its implementation as a th

259 Each printing technique has merits toward the fabrication of

260 the present work, a lipid-bilayer-supported printing technique is developed to 3D print human cortic

261 ng advantage of the 3D conformal aerosol jet printing technique, a series of UV sensors of heterogene

262 However, commonly used printing techniques have limited resolution of micro- or

263 Here, a set of advanced and hybrid printing techniques is summarized, covering diverse aspe

264 Printing techniques using nanomaterials have emerged as

265 ing to the limitations of extrusion-based 3D printing techniques.

266 he changes in the colorants used in Japanese printing techniques.

267 Advanced imaging and printing technologies are not essential for successful o

268 rgistic integration of nanomaterials with 3D printing technologies can enable the creation of archite

269 rging organic actuator materials and digital printing technologies for fabricating haptic actuators i

270 pplications to meet the true potential of 3D printing technologies.

271 rough a heated nozzle, is the most common 3D printing technology for creation of objects.

272 3D printing technology has become a mature manufacturing te

273 We anticipate our shrinking printing technology to find widespread applications in p

274 A 3D printing technology was utilized with specially designed

275 ser powder bed fusion is a dominant metal 3D printing technology.

276 , bridging the gap between scientists and 3D printing technology.

277 are examined, spanning from high-throughput, printing-technology-compatible synthesis of nanocrystall

278 (PDMS) continuous phase and subsequently 3D printed the resulting emulsion into a variety of structu

279 feasibility of combining three-dimensionally printed thermoplastic polymers with polymeric foam to re

280 This study presents the first report of VAM-printed thiol-ene resins.

281 additive manufacturing, known commonly as 3D printing, this technology has revolutionized the biofabr

282 Herein, a screen-printed three-layered all-nanoparticle network was devel

283 The total printing time of the ATR module is 10.5 h, enabling over

284 cs simulations, evolutionary mapping, and 3D printing to gain a full proteome- and dynamicome-level u

285 esolution enhancement purely relying on post-printing treatment of hydrogel constructs.

286 ic to a target of interest, in this ELISA we printed unique "anchor" antibodies at the well surface,

287 ch to modulate extruded inks at the point of print, using droplet inclusions.

288 we report a nanoprinting technique that can print various functional colloidal nanoparticles into ar

289 These alloys are amenable to crack-free 3D printing via electron beam melting (EBM) with preheat as

290 The rheological parameters required to print viscoelastic nanoparticle suspensions toward tough

291 CT) scanning, enabling the creation of a 3-D printed vocal tract.

292 u analysis of particles collected during ABS printing was performed via TEM and electron energy loss

293 3D printing was used to develop an open access device capab

294 In this study, mathematical modeling and 3D printing were used to analyze the protective function of

295 show thermodynamic-driven immersion transfer-printing, which enables patterning and printing of quant

296 An alternative strategy is to print with human induced pluripotent stem cells, which c

297 One 3D print with PLA resulted in an aerosol mass size distribu

298 SWNTs) were deposited by quantitative inkjet printing with an optimal 3-dimensional semiconductor den

299 ential pathway to 3DP of textiles, dubbed as printing with fibers to create textile structures is pro

300 esthetic glove-are demonstrated to show that printing with organic materials is a versatile approach