ライフサイエンスコーパス: print

1 sional (3D) architectures by direct-write 3D printing.

2 by a water-assisted variant of microcontact printing.

3 uring the personalized titanium plates by 3D printing.

4 can be realized by standard machining or 3D printing.

5 at we could not produce using traditional 3D printing.

6 inding site was confirmed using DNase I foot-printing.

7 pered innovations and applications of DIW 3D printing.

8 ed electronic devices, for example by inkjet printing.

9 g dielectric permittivity manufactured by 3D printing.

10 ces via multimaterial three-dimensional (3D) printing.

11 Here we demonstrate fully inkjet-printed 2D-material active heterostructures with graphen

12 ere, we present the rational design of a wax-printed 3D-muPAD that enables more homogeneous permeatio

13 The two-step fabrication consists of printing a silver electrode followed by an electrochemic

14 wever, currently, there is no process for 3D printing (additive manufacturing) of nt-metals.

15 ace oxide, a novel approach is discovered to print and sinter Zn nanoparticle facilitated by evaporat

16 ore and a lipophilic pH indicator are inkjet-printed and adsorbed on paper and form a "dry" hydrophob

17 They could be 3D printed and cured both in air and under water.

18 previously established design rules, then 3D-printed and replicated into poly(dimethylsiloxane).

19 The printed and sintered ceramic foam honeycombs possess low

20 Silica inks are developed, which may be 3D printed and thermally processed to produce optically tra

21 nium nanoparticles and ferritin proteins for printing and forming 3D shapes and structures.

22 ing process combines soft silicone elastomer printing and liquid metal processing on a single high-pr

23 cted a small intestinal bioreactor using 3-D printing and polymeric scaffolds that mimic the 3-D topo

24 yzed tested positive with both immune tissue printing and qPCR; whereas 95% were positive with at lea

25 s by evaporation-condensation-mediated laser printing and sintering of Zn nanoparticle is reported.

26 are fabricated via three-dimensional ceramic printing and the bandgaps experimentally verified.

27 inks are the most important component for 3D printing, and are related to the materials, the printing

28 functional ovarian implant designed with 3D printing, and indicate that scaffold pore architecture i

29 nless steel electrodes were fabricated by 3D printing, and the surface was electroplated with gold.

30 herapeutic molecules) or as a 'bioink' in 3D-printing applications.

31 in the fabrication process is a print-pause-print approach for integrating membranes directly into t

32 material, multiscale, and multifunctional 3D printing approach is employed to fabricate 3D tactile se

33 as witnessed the rapid development of inkjet printing as an attractive bottom-up microfabrication tec

34 s investigated after these geometries are 3D printed at centimeter length scales based on molecular m

35 nd ovine mesenchymal stem cells (oMSCs) were printed at tissue-relevant densities (10(7) cells mL(-1)

36 The device consists of a printed base that hosts multiple windows containing a po

37 The device could operate for 10 min via a printed battery, and display the result for many hours o

38 robial fuel cell (pMFC) fabricated by screen-printing biodegradable carbon-based electrodes onto a si

39 pments in organo-functionalized graphene and printed biosensor technologies are comprehensively cover

40 We demonstrate printed black phosphorus as a passive switch for ultrafa

41 Following encapsulation, the printed black phosphorus is stable against long-term (>

42 y deposited on Ti6Al4V substrate by laser 3D printing, but the sample cracked in the printing process

43 n G wherein recombinant HDV delta antigen is printed by microarray on slides coated with a noncontinu

44 Easily scalable techniques such as 3D printing can be used for exploring mechanical behavior o

45 Microfabrication, inkjet- and screen-printing can be used for solid contact ion selective ele

46 ting is having a two-fold benefit: first, 3D printing can be used to validate the complex simulations

47 uous flow of the ink, thereby increasing the printing capacity of the system.

48 ypyrrole (PPy) nanocomposite onto the screen printed carbon electrode (SPCE) was investigated as a bi

49 conductive polymer (PEDOT: PSS) on a screen-printed carbon electrode (SPCE), followed by electrodepo

50 he piece of paper onto a conventional screen-printed carbon electrode (SPCE).

51 , which was previously deposited on a screen printed carbon electrode (SPE) to form the Co-salophen-I

52 oxide (rGO) to modify the surface of screen-printed carbon electrode (SPE).

53 ane microfluidic chip integrated with screen-printed carbon electrode for the electrochemical detecti

54 Ala96Leu mutant was immobilized on a screen-printed carbon electrode using glutaraldehyde cross-link

55 c detection of glucose by modifying a screen-printed carbon electrode with cobalt phthalocyanine, gra

56 Nano-Urchins for modification of the screen-printed carbon electrode, and also applying a specific D

57 Disposable screen-printed carbon electrodes (SPCEs) modified with a conduc

58 agnetic microparticles supported onto screen-printed carbon electrodes and covalent immobilization of

59 ectrode was carried out at disposable screen-printed carbon electrodes.

60 s negatively shifted to 0.64V vs. the screen-printed carbon pseudo-reference electrode.

61 Screen-printed carbon sensors coated with electrochemically red

62 Two versions of a 3D-printed cartridge for paper spray ionization (PSI) are d

63 rapid ink drying (< 10 s at < 60 degrees C), printing causes minimal oxidation.

64 The printed cells showed high viability (90% on average) and

65 any negative effect on the viability of the printed cells, and the self-folded hydrogel-based tubes

66 nge of applications for the cryogenically 3D printed CH structures, from soft tissue phantoms for sur

67 ment and viability on the collagen-coated 3D printed CH.

68 yer were compared with those obtained from a printed channeled layer.

69 munoSorbent Assay (eELISA), using a Lab-on-a-Printed Circuit Board (LoPCB) approach, for TB diagnosis

70 hese barcode sequences were immobilized on a printed circuit board (PCB) manufactured electrode array

71 rated with a lab-built low-cost miniaturized printed circuit board (PCB) to provide an electrical con

72 wing to S4s' compatibility with the standard printed circuit board assembly processes, a variety of c

73 res onto the working electrodes of polyimide printed circuit board platforms, resulting in the genera

74 By using a printed circuit board that carries an electric current a

75 mall amount of OM, whereas the combustion of printed circuit boards and copper-core cables emitted la

76 ales of polymer assembly and high-throughput printing/coating.

77 ercial 8-channel pipet using machined and 3D-printed components.

78 eproduction of patient anatomy was tested by printing computed tomographic (CT) images of a real pati

79 A 3D printed cradle held the smartphone integrated with optic

80 cesses, also known as three-dimensional (3D) printing, create 3D objects by the successive adding of

81 We show that these printed cyanobacteria are capable of generating a sustai

82 p process was employed to convert the inkjet-printed dense silver IDEs into their highly porous gold

83 ea/mass when optimizing drug release from 3D printed designs.

84 emains particularly challenging for solution-printed devices due to the complex crystallization kinet

85 is material as a functional ink platform for printed devices.Atomically thin black phosphorus shows p

86 ented in paper-based microfluidic and screen printing devices over the past decade as well as in the

87 hes such as drop casting, screen- and inkjet-printing, different strategies of graphene-based sensing

88 selected carbon nanotubes (CNT)-based inkjet-printed disposable electrodes for the direct ECL imaging

89 unction of crystal orientation in a laser 3D-printed DL125L Ni-based superalloy polycrystal is invest

90 Addressing this challenge, the use of screen-printed electrochemical sensor is reported.

91 The single-use device employed printed electrochemical sensors for hydrogen peroxide el

92 en peroxide electroreduction integrated with printed electrochromic display and battery.

93 notubes (MWCNT) was deposited on gold screen-printed electrode (AuSPE), and afterwards monoclonal ant

94 noparticles (AuNPs) modified graphite screen printed electrode (GSPE) surface for the selective, labe

95 sing a graphite-nanoparticle modified screen-printed electrode (SPCE-G-COOH).

96 researchers have focused on paper-based and printed electrode technologies as the material for fabri

97 aptamer was self-assembled on carbon screen printed electrode, which modified with electrodeposited

98 a multi-walled carbon nanotubes-based screen printed electrode.

99 a gold nanoparticles (AuNPs) modified screen-printed electrode.

100 model amphipathic viral peptide on a screen-printed electrode.

101 Thereby, PHA was immobilized on screen printed electrodes (SPE) through a blend formation with

102 thways (HMPs) demonstrates disposable screen-printed electrodes (SPEs) as an alternative to the tradi

103 ilt up on a surface of graphite-based screen-printed electrodes (SPEs) premodified with MnO2 nanopart

104 tentiostat is ensured with the use of screen-printed electrodes (SPEs).

105 Electrochemical biosensors based on screen-printed electrodes and peptides are promising alternativ

106 infarction (AMI) was carried out with screen-printed electrodes modified first with multi-walled carb

107 In this novel thin layer flow-cell screen-printed electrodes, the working electrode was modified w

108 ensing materials can be combined with screen-printed electrodes, which are successfully used for meas

109 ed materials provides low-cost inks enabling printed electronic devices, for example by inkjet printi

110 Printed electronics are a burgeoning area in electronics

111 Organic and printed electronics integration has the potential to rev

112 tions due to their diverse applications from printed electronics to biomedical devices.

113 In printed electronics, devices are built layer by layer an

114 ation of three-dimensional (3D) materials by printing engineered self-patterning bacteria on permeabl

115 emonstrated not only the potential of the 3D printing environment in planar chromatography but also o

116 Studies of carbon materials in 3D printing, especially GO-based materials, have been exten

117 As a result, the 3D-printed evaporator has a high solar steam efficiency of

118 3D printing, experimental tests, numerical simulation, and

119 We also provide the optimized designs for printing, facilitating further studies using 3D-muPADs.

120 The lamellar spacing of the printed features can be varied between approximately 100

121 It is shown that a single nozzle can print fibers with resolution much finer than the nozzle

122 coating and improving the reproducibility of printed films.

123 stive sensors were then fabricated by inkjet-printing fine-featured silver IDEs on top of the sensing

124 tive manufacturing process that produces all-printed flexible and stretchable electronics is demonstr

125 ) inks, and use them to fabricate all inkjet-printed flexible and washable field-effect transistors o

126 into polyrotaxane-based lattice cubes by 3D printing followed by post-printing polymerization are re

127 tallic structure was fabricated via laser 3D printing following the transition route.

128 nts: (1) word reading (Braille for blind and print for sighted participants), and (2) listening to sp

129 Here we propose multimaterial 3D printing for the fabrication of such devices in a single

130 CaLas from citrus tissues in a simple tissue printing format.

131 n, and Hounsfield units were investigated by printing geometric phantoms with gray scales ranging fro

132 Among most reports, only a few printed graphene-based biosensors including screen-print

133 Firstly, various methods for printing graphene-based fluids on different substrates a

134 3D printing has been developed for a variety of application

135 3D printing has been intensively explored to fabricate cust

136 Three-dimensional (3D) printing has emerged as a potential revolutionary techno

137 Three-dimensional (3D) printing has proven to be a versatile and useful technol

138 Three-dimensional (3D) printing has undergone an exponential growth in populari

139 ) technique, known as three-dimensional (3D) printing, has attracted much attention in industry and a

140 enabled simultaneous printing with multiple printing heads and, thus, multiplexed fabrication.

141 We show examples of all-inkjet-printed heterostructures, such as large-area arrays of p

142 We have developed a means of printing high performance thermoset carbon fiber composi

143 basis for a remarkably simple procedure for printing highly conductive (3 x 10(5) S m(-1) ) features

144 A custom 3D-printed holder was designed and built to facilitate the

145 As a stand-alone instrument, the 3D printed IMS is shown to achieve resolving powers of betw

146 For the latter, 40 channels were printed in parallel on a 10 cm x 10 cm format for the se

147 x and conductive electrode inks are directly printed in specific layouts.

148 chromatographic columns were designed and 3D printed in titanium as 2D serpentine, 3D spiral, and 3D

149 the versatility and broad perspective of 3D printing in optical detection.

150 However, the use of FDM 3D printing in tablet manufacturing requires a large portio

151 Here, we describe a 3D printed inexpensive open source and scalable motorized p

152 A lithium-chloride-containing hydrogel printing ink is developed and printed onto treated PDMS

153 t include plastics, paper, metal, glass, and printing inks.

154 at comparable residence time and, using a 3D-printed interface, be directly interfaceable with LC-MS.

155 Multimaterial 3D printing is a potentially new approach for the manufactu

156 nergy between large-scale simulations and 3D printing is having a two-fold benefit: first, 3D printin

157 mixing decreased (27% +/- 10%), but Polyjet printing is more suited for microfluidic applications wh

158 3D printing is shown to be a quick and cost-effective way t

159 ive manufacturing, or three-dimensional (3D) printing, is a potentially disruptive technology across

160 was subsequently adapted onto a low-cost 3D-printed isothermal device with real-time analysis capabi

161 ), and the rates varied over the course of a print job.

162 by manipulating the advancing angle between printed layers, affects the survival of ovarian follicle

163 fects, and without obvious interface between printed layers, which overall result in good mechanical

164 This work represents the first example of 3D printed light-guiding sensing platforms and demonstrates

165 The design of 3D-printed living materials is guided by quantitative model

166 Using a 3D printing low-cost technology we fabricated the smartphon

167 Our design is based on a 3D-printed mainframe, a Raspberry Pi computer, and high-def

168 The print material was characterized using gas chromatograph

169 was further validated by showing that the 3D printed material was well matched to the cast-moulded eq

170 imple, easy and provides a flexible route to print materials with preferred shapes, size and spatial

171 The resulting LRS and MRS 3D-printed materials exhibit similar, but distinct internal

172 this contribution we present a cryogenic 3D printing method able to produce stable 3D structures by

173 The immune tissue printing method also highlights the detail of the spatia

174 ted on a nitrocellulose membrane using a wax-printing method and then baked in an oven at 100 degrees

175 A hot melt 3D inkjet printing method with the potential to manufacture formul

176 nting, and are related to the materials, the printing method, and the structures of the final 3D-prin

177 re fabricated by an electrically assisted 3D-printing method.

178 the coarse resolution of conventional inkjet-printing methods.

179 imple protocol to manufacture disposable, 3D-printed microfluidic systems for sample preparation of p

180 rt the design, fabrication and testing of 3D printed microfluidics chips coupled with silicon photomu

181 3D printed micrometer-scale polymer mounts for single cryst

182 Here, we 3D print microporous hydrogel scaffolds to test how varying

183 ount for the responses of programed cells in printed microstructures of hydrogels.

184 A 3D printed mold was fabricated that could house 6 multiwall

185 transistors, require robust and reproducible printed multi-layer stacks consisting of active channel,

186 This 3D-printed muSPE device was applied to challenging matrices

187 Also, 3D-printed muSPE devices enabled fast emulsion breaking and

188 demonstrated by tuning the resonance of the printed nanocavities by the number of printer passes and

189 Owing to the screen-printed nature, such kind of biosensors have capability

190 The 3D printed nt-Cu is fully dense, with low to none impuritie

191 e present a low-cost process that employs 3D printing of aqueous droplets containing mammalian cells

192 Here, recent developments in 3D printing of emerging devices for energy-related applicat

193 The custom 3D printing of functional materials and devices opens new r

194 We subsequently suggest that 3D printing of graphene-based conductive filaments allows f

195 We report here 3D printing of high-quality, custom prisms by stereolithogr

196 l challenge of the current approaches is the printing of hollow tubular structures.

197 The L-PED process enables direct 3D printing of layer-by-layer and complex 3D microscale nt-

198 The demonstrated precise printing of medicines as films, without the use of solve

199 Microscale 3D printing of nt-Cu is demonstrated with high density of c

200 ically inducing defects through microcontact printing of patterned monolayers.

201 This study demonstrates the unprecedented 3D printing of PMDA-ODA using mask-projection stereolithogr

202 3D printing of polymers is accomplished easily with thermop

203 ices are further demonstrated, enabled by 3D printing of programed cells, including logic gates, spat

204 using ambient condition, extrusion-based 3D-printing of regolith simulant inks.

205 dvanced 4D biofabrication approach, based on printing of shape-morphing biopolymer hydrogels, is deve

206 3D printing of the injection molds and skeletons requires 3

207 On the basis of open-source packages, 3D printing of thin silica gel layers is demonstrated as pr

208 Here, the challenges involving printing of two emissive materials to form polymer light

209 hniques, for example, three-dimensional (3D) printing, of all-liquid constructs.

210 The sensor is inkjet printed on a paper substrate with a metalloporphyrin bas

211 nk undergoes directional solidification upon printing on a cold substrate.

212 pattern of different DNA strands covalently 'printed' on their exterior, and further assemble with pr

213 ining hydrogel printing ink is developed and printed onto treated PDMS with no visible signs of delam

214 Lastly, biosensing performances of printed or printable graphene-based electrochemical and

215 d graphene-based biosensors including screen-printed oxidase-functionalized graphene biosensor have b

216 In this study, a novel wax-printed paper-based lateral flow device has been develop

217 ged from 6 x 10(8) to 6 x 10(11) per gram of printed part, depending on the type of filament used.

218 of material from metal powder to a solid as-printed part.

219 The printed patch void size also influenced antibiotic relea

220 A key step in the fabrication process is a print-pause-print approach for integrating membranes dir

221 e be easily extended to craft other solution-printed perovskite-based optoelectronics.

222 For this purpose, 3-dimensional (3D)-printed phantoms of different geometries were manufactur

223 ite, and used as a uniform coating on top of printed photonic devices.

224 PDA vesicles were prepared by inkjet-printing, photopolymerized and characterized by dynamic

225 As such an example, separations on a printed plane layer were compared with those obtained fr

226 ped surface area has been realized upon a 3D printed polymer substrate to facilitate chromatographic

227 attice cubes by 3D printing followed by post-printing polymerization are reported.

228 , we demonstrate the development of a screen-printed potentiometric immunosensor for in vitro evaluat

229 Through optimization of the printing process and orientation, a suitably developed s

230 The printing process combines soft silicone elastomer printi

231 lting and solidification dynamics during the printing process lead to intolerable microstructures wit

232 ruded hot melt solidifies rapidly during the printing process.

233 r 3D printing, but the sample cracked in the printing process.

234 surface accumulation three dimensional (3D) printing process.

235 g method, and the structures of the final 3D-printed products.

236 ly printed without support material, and the print quality can be improved with increasing CNC concen

237 proved with increasing CNC concentration and printing resolution.

238 Stacks of 100 prints resulted in three-dimensional phantoms of 1 cm th

239 raphene in biosensing tools, based on screen-printed sensors.

240 al and binder jetting (inkjet and aerosol 3D printing), sheet lamination (LOM), extrusion (FDM, 3D di

241 ere assembled, positioned firmly within a 3D printed shell mold simulating the skin boundary, and cas

242 on of THz SAs by transfer coating and inkjet printing single and few-layer graphene films prepared by

243 reatment) in maximum reading speed, critical print size, and reading acuity (higher number indicates

244 d engineering of biological actuators and 3D-printed skeletons for any design application.

245 ators can be coupled to a wide variety of 3D-printed skeletons to power complex output behaviors such

246 A high resolution (3 km foot print) SM/ST dataset prepared from a land data assimilat

247 The shape-change of 3D printed smart materials adds an active dimension to the

248 to fabricate supercapacitors (SCs) via vapor printing, specifically oxidative chemical vapor depositi

249 The 3D printed specimens show, at two of its opposing faces alo

250 re the first achieved using an unmodified 3D printed stationary phase.

251 s of different functionality during the same printing step is presented.

252 Furthermore, the hybrid 3D additive printing strategy for biosensors facilitates both rapid

253 on and application of three-dimensional (3D) printed structures have gained appreciable interest in r

254 ty (90% on average) and HEK cells within the printed structures were shown to proliferate under cultu

255 pose the nonenzymatic sensor based on screen-printed structures with the working surface modified in

256 the two-step fabrication of the first inkjet-printed sulfide-selective electrode (IPSSE) is described

257 channels to accelerate drug release from 3D printed tablets.

258 ity and low thermal conductivity, the screen-printed TE layers showed high room-temperature ZT values

259 Thus, the novel multiphoton-excited 3D printing technique produces extracellular matrix-based s

260 The EHDA printing technique provides an exciting opportunity to t

261 as manufactured using three-dimensional (3D) printing techniques and operates in the open air at ambi

262 RATIONALE: Conventional 3-dimensional (3D) printing techniques cannot produce structures of the siz

263 rect experimental comparison of the three 3D printing technologies dominating microfluidics was condu

264 Ethoscopes can be built easily by using 3D printing technology and rely on Raspberry Pi microcomput

265 Printing technology has recently emerged as a low-cost a

266 vide guidance toward the selection of the 3D printing technology most suitable for specific microflui

267 Using the inkjet printing technology, we are able to deliver multiple 100

268 Braille readers, but not sighted readers of print, the VWFA region is active during grammatical proc

269 Al6V4, CoCr and Inconel 718, can be reliably printed; the vast majority of the more than 5,500 alloys

270 n on using a visible laser pen or projection printing through a photomask.

271 A combination of techniques from 3D printing, tissue engineering and biomaterials has yielde

272 tic acid filament (graphene/PLA) has been 3D printed to fabricate a range of 3D disc electrode (3DE)

273 imple and low-cost techniques such as inkjet printing to be used for device fabrication.

274 grate microfluidics, electronics, and inkjet printing to build an ultra-low-cost, rapid, and miniatur

275 For the first time, 3D printing to construct an all-in-one evaporator with a co

276 le light-based projection stereolithographic printing to form a scaffold with desired architectures.

277 Here, we used multiphoton-excited 3D printing to generate a native-like extracellular matrix

278 gs), and influence technologies ranging from printing to genotyping.

279 f a precisely controlled solvent free inkjet printing to produce drug loaded solid dosage forms is de

280 This paper reports a 100% inkjet printed transistor with a short channel of approximately

281 Additive manufacturing (AM) alias 3D printing translates computer-aided design (CAD) virtual

282 A method to print two materials of different functionality during th

283 e a stable black phosphorus ink suitable for printed ultrafast lasers and photodetectors.

284 PAm hydrogel was also printed using collagen coated micro-grooved Parylene C.

285 silica powder suspended in a liquid and are printed using direct ink writing.

286 D structures and inner pore architecture are printed using the direct ink write (DIW) technique.

287 lingual immunization and the development of "printed vaccine technology".

288 diameter by stretching the extruded ink, and print various thickened or curved patterns with straight

289 In this research, Laser 3D Printing was applied to explore a new Ti6Al4V to SS316 m

290 Fully printed wearable electronics based on two-dimensional (2

291 h potassium iodide solutions (600 mg/mL) and prints were realized on plain paper (80 g/m(2)).

292 his work is an example of the impact that 3D-printing will have on the future of analytical device fa

293 High-resolution 3D geometries were printed with features of </=200 mum; these included an a

294 Fluidic devices printed with filament extruded at 60 degrees to the flow

295 Devices were printed with filament orientations at 0 degrees , 30 deg

296 strate, the surface of which has been inkjet printed with silver nanoparticles, for surface enhanced

297 This approach enabled simultaneous printing with multiple printing heads and, thus, multipl

298 ated, sealed device was realized as a single print within 30 min.

299 Various 3D structures are successfully printed without support material, and the print quality

300 vestigated noise-compensation for spoken and printed words in two experiments.