ライフサイエンスコーパス: device design

1 ing, electromyography-driven simulation, and device design.

2 s with important implications in stretchable device design.

3 de the groundwork for future improvements in device design.

4 ation, and define engineering guidelines for device design.

5 e VO(2) film and use the results to optimize device design.

6 ncertainty regarding its energy has hindered device design.

7 s apply to nanoelectronics and semiconductor device design.

8 et operations can be achieved using the same device design.

9 c devices, as well as providing guidance for device design.

10 arrier relaxation times required for optimum device design.

11 the electric fields and fluid flow to guide device design.

12 mbrane, and the implications for biology and device design.

13 ges for successful TAVI, despite advances in device design.

14 h used in the discovery of new materials and device design.

15 ir intrinsic length and time scales to guide device design.

16 ductance, low working voltage, and versatile device design.

17 tion and structure, as well as innovation in device design.

18 SiGe heterostructures necessary for scalable device design.

19 resenting a new tool for advanced perovskite device design.

20 of sex within in vitro studies for clinical device design.

21 des a strategy for efficient and compact SOT device design.

22 rusted to be used in domains such as medical device design.

23 t in QD solids and additional principles for device design.

24 t the next generation of intelligent optical device design.

25 the traditional von Neumann architecture in device design.

26 All values are within expectations for this device design.

27 elationships to guide rationale material and device design.

28 evelopment, and nucleic acid based biosensor device design.

29 h electromagnetic solvers for optomechanical device design.

30 perties via substrate engineering for future device design.

31 e-scale high-quality vertical light emitting device design.

32 unction width, providing guidance for future device design.

33 inclusion of an acoustic transition layer in device design.

34 in recent times has opened up new avenues in device design.

35 this is due to inadequate training, or poor device design.

36 iscuss future prospects for QD materials and device design.

37 ay open up new opportunities for spintronics device designs.

38 though nearly all work has focused on planar device designs.

39 0 particles per second using the simplest of device designs.

40 , which are prone to instability and complex device designs.

41 arch the full parameter space for fabricable device designs.

42 road range of target molecules and different device designs.

43 tractive for applications in new nanofluidic device designs.

44 s that could be exploited in novel nanoscale device designs.

45 raphene heterostructure and strain-releasing device designs.

46 d ionic transport, and will enable new ionic device designs.

47 l magnetic fields and enables new spintronic device designs(1-4).

48 By careful device design, a new class of SAW pumping devices is pre

49 ess energy, and the simpler and more compact device design allows direct integration into PEMFC stack

50 In addition, this device design allows for multiplexed recording from sing

51 cal cooling in humans, including the optimal device design and cooling parameters.

52 Device design and fabrication methods are described that

53 which finally contributes to better material/device design and improved device performance.

54 We introduce innovations in device design and material fabrication that improve the

55 formance top-emitting organic light-emitting device design and maximized piezoelectric generator outp

56 Device design and modeling strategies were also discusse

57 Various parameters, related both to device design and operation were studied.

58 c surfactant or reducing agents, simplifying device design and operation.

59 Improvements in device design and patient selection appear likely to con

60 e of the front electrode are key for optimal device design and performance.

61 ynamic deformations as well as for informing device design and placement.

62 Advances in device design and postoperative care have made implantat

63 f the ACURATE neo2 valve with improvement in device design and procedural iterations will translate i

64 However, device design and process optimization to achieve the be

65 e complexity associated with experimental or device design and requires substantial labor for impleme

66 ed in contemporary fuel cells severely limit device design and restrict catalyst choice, but are esse

67 Furthermore, the device design and small footprint optimize imaging throu

68 nductors with the potential to revolutionize device design and substantially enhance doping efficienc

69 Accordingly, MCS device design and technology continue to develop at a ra

70 Here, we report materials, device designs and fabrication approaches for integratin

71 es labor-intensive empirical optimization of device designs and flow conditions that limit adoption t

72 Materials, device designs and manufacturing approaches are presente

73 toPAD-developed to quickly create and modify device designs and provide a free alternative to commerc

74 of solar modules through improved materials, device designs and strategies for light management.

75 analysis was performed to compare different device designs and was verified with flow modeling to op

76 influence thermoelectric material behavior, device design, and device performance, which presents a

77 along with microscopic sizes, can influence device design, and give examples from our own work using

78 microelectronics, energy conversion, sensing device design, and many other fields of science and tech

79 ry, ink formulation, flexible or conformable device design, and processing strategies, with an emphas

80 esults should lead to more reliable graphene device design, and provide a framework to interpret expe

81 viability and function, its relationship to device design, and the role of, and factors affecting, o

82 that these transitions can be controlled by device design, and tuned in-situ using gates.

83 erial science, chemical analysis techniques, device designs, and assembly methods form the foundation

84 rs are addressed through advanced materials, device designs, and system-level integration.

85 d consistent comparison of new materials and device designs, and they will be used to identify advanc

86 Device Thrombogenicity Emulation (DTE) is a device design approach for enhancing VAD thromboresistan

87 es to study novel photovoltaic materials and device design architectures where structural parameters

88 h as the electrical waveform composition and device design are critical to PFA's efficacy and safety,

89 s and opportunities for bionanotechnological device design are self-evident.

90 Materials and device designs are presented for electronic systems that

91 Recommendations for future device designs are proposed based on band structure and

92 h and disease conditions, as well as cardiac device design, are time-consuming and require powerful c

93 interesting results that are informative to device design as well as experimental data interpretatio

94 proach, including a technical description of device design as well as quantitative and qualitative su

95 dual skyrmions controllably in an integrated device design at a selected position has been reported y

96 rol ripple structure in graphene could allow device design based on local strain and selective bandga

97 lmark of DMF is its "flexibility": a generic device design can be used and reused for many different,

98 slow and often limits the rate at which new device designs can be built and tested.

99 However, the process of prototyping device designs can be tedious, error-prone, and time-con

100 s motivated the search for new materials and device designs capable of splitting water using only ene

101 d Auger recombination and a current-focusing device design, combined with short-pulse pumping.

102 ate materials will ensure that future fusion devices design components with optimal thermal strength.

103 Furthermore, the review delves into device design considerations, such as well arrays, flow

104 The basic device design consisted of a single channel for the firs

105 This effective device design enables both targeted and large-scale reco

106 Novel device design ensures distance-independent coalignment b

107 rtance of material selection in microfluidic device design, especially in applications involving drug

108 The device design exploits the strong light-matter coupling

109 Device design, fabrication and assembly can be completed

110 Challenges remain, not least encouraging device design focused on smaller infants and the inevita

111 afety assessment and advancing bioelectronic device design for cardiac research.

112 The theoretical foundation and device design for FF-CGF are provided in this work, foll

113 on biological tissues, as well as optimized device design for high signal-to-noise ratio.

114 rs the opportunity for simplified diagnostic device design for resource-limited environments.

115 hermotaxis and rheotaxis microfluidic (TRMC) device designed for efficient motile spermatozoa sorting

116 A microfluidic device designed for electrochemical studies on a microli

117 development of a microcuvette: a specialized device designed for exposing cell cultures to intense PE

118 In addition, we present a portable device designed for onsite ammonia production which cons

119 Implemented on a portable, fully automated device designed for point-of-care settings, our system f

120 ofluidic continuous-flow electrotransfection device designed for precise, consistent, and high-throug

121 hable skin health analyzer (BSA), a wearable device designed for prolonged use, capable of accurate,

122 ins a highly sensitive and selective medical device designed for the early detection of circulating m

123 e, to a jet-stirred reactor, an experimental device designed for the study of low-temperature combust

124 We describe a novel computer-controlled device designed for this purpose.

125 ul in the study of more advanced nanofluidic device designs for tailoring ionic current rectification

126 easing sophistication of specific collection devices designed for alternative samples and the enhance

127 own work using fluid flow in microfabricated devices designed for biological processing.

128 Transcatheter devices designed for calcific aortic stenosis are not op

129 ly when applied at low blood-flow rates with devices designed for higher blood flows, and a recent la

130 of U.S. Food and Drug Administration-cleared devices designed for indocyanine green-based perfusion i

131 This Review will cover materials and devices designed for mimicking the skin's ability to sen

132 Flexible medical devices designed for monitoring human vital signs, such

133 road application potential in optoelectronic devices designed for near-infrared and ultraviolet appli

134 Fabricated devices designed for operation at central wavelengths of

135 ritical care setting; mechanical circulatory devices designed for pediatric patients; and surgery in

136 Given the recent interest in paper-based devices designed for quantitative analysis in point-of-c

137 Wearable devices designed for the somatosensory system aim to pro

138 monstrate through the recreation of numerous device designs from the literature.

139 predicting the concentration profile and the device design guidelines, functional prototypes can be f

140 In vitro testing revealed that the initial device design had detection limits for amino acids of ap

141 The device design has a high degree of structural similarity

142 While progress in material and device design has been astonishing, low environmental an

143 ical experiments, but open-source sharing of device designs has lagged behind sharing of other resour

144 g regardless of soil drying time, as well as device designs (i.e., features) that are appropriate for

145 hybrid materials incorporation, conformable device design, implantation procedures, and mechanical a

146 Among other material and device design improvements studied, use of a methanol-ba

147 nd hydrodynamics predict animal movement and device design in air and water through the computation o

148 in engineering has been a critical aspect of device design in semiconductor manufacturing for the pas

149 system, it remains difficult to predict how device design influences system performance.

150 AAI device design is a major determinant of successful adren

151 An improved device design is here proposed, where the relative exten

152 The device design is optimized by analyzing the quality fact

153 The device design is optimized to make all fluid particles i

154 h cm(-2) surpassing zinc ion batteries, this device design is particularly promising for high-enduran

155 Device design is then directed down either a semi-custom

156 The device design is versatile and tunable to work with emis

157 Nevertheless, the lithography-based device design is versatile, allowing for precise flow-fi

158 gical radiation of microfluidic cell culture device designs is currently in progress.

159 experimental data, we demonstrated that the device design leads to rapid mixing and rapid throughput

160 uming motions with a single-channel pipet or device designs limited to the configurations of traditio

161 The nanofibrous device design may therefore provide a translatable solut

162 ency single-junction devices, nanostructured device designs must be developed that maximize the open

163 frequent type of revision, changes involving device design (n = 667; 24%) and labeling (n = 417; 15%)

164 eliminates this impediment, thereby allowing device designs of arbitrary specification and size to be

165 ntrinsically soft and elastic materials, and device designs of innovative configurations and structur

166 computational fluid dynamic analysis guided device design optimization along the way.

167 The obtained results provide guidance on CBS device design optimization and the effective automation

168 m pre-operative surgical planning to medical device design optimization.

169 with a wide size range without changing the device design or drastically altering the fluid properti

170 Device design or implementation strategies require furth

171 The median number of changes altering device design or labeling was 3.5 (IQR, 1-9).

172 This is driven by advances in device design, patient selection, surgical techniques, a

173 e structures, but the kink configuration and device design places limits on the probe size and the po

174 The device design principles presented here balance the phot

175 characteristics as well as high-performance device design principles with fine-tuned transient respo

176 The unique device design produces a two-dimensional flow, which red

177 y relations and opens new avenues for future device design related to TPs.

178 ecause of frequently competing materials and device design requirements.

179 The device designs serve as the basis for bioresorbable card

180 Engineering involved device design, sourcing or manufacturing individual comp

181 , single-group trial of a ventricular assist device designed specifically for children as a bridge to

182 an implantable mixed-flow ventricular assist device designed specifically for patients up to 2 years

183 Although eye protective devices designed specifically for paintball sports are e

184 mental understanding of these materials, for device design, stability studies, and quality control be

185 y of the device at system level during early device design stages.

186 tegies for forming partnerships, prototyping devices, designing studies, and evaluating POC diagnosti

187 A second device design that allowed electric fields of 1320 V/cm

188 However, the optimal device design that gives rise to the desired controlled

189 intronic circuits with a versatile, scalable device design that is adaptable to emerging material phy

190 these questions by combining a microfluidic device design that mimics multiple tumor microenvironmen

191 here a microfluidic coplanar Coulter counter device design that overcomes the problem of constriction

192 lement advanced single-junction photovoltaic device designs that can capture energy typically lost in

193 totyping workflow, we demonstrate a range of device designs that generate diverse concentration profi

194 Molecular device designs that utilize such bridges will need to ad

195 ding manufacturing changes that do not alter device design, the number of supplements approved each y

196 Two of these device designs, the Intrastromal Corneal Ring and the In

197 Despite advances in device design, there remains an apparent bleeding diathe

198 ls, and polycrystalline bulks), and advanced device design (thermoelectric modules, miniature generat

199 By controlling the device design through the study of the emission of DDMA-

200 o assess the preliminary results of a custom device designed through bioscanner imaging and manufactu

201 Using a device designed through optimization by Monte Carlo simu

202 of the proposed soft materials and ultrathin device designs through theoretical modeling and finite e

203 or material choice, material properties, and device design to achieve low-loss PS-BAW resonators alon

204 es, and underline the importance of holistic device design to achieve the intrinsic performance limit

205 are stack needed to develop useful QC - from device design to applications.

206 ires and comment on both material choice and device design to form biointerfaces spanning multiple le

207 By linking device design to system behavior across time and spatial

208 GumChucks is a novel flossing device designed to assist children with proper flossing

209 Here, we describe a wireless device designed to be conformally placed on the supraste

210 illness was detected after in-home use of a device designed to be highly effective in removing micro

211 We develop and validate a microfluidic device designed to capture tumor-derived EVPs in gliobla

212 We evaluated a new device designed to clean the endotracheal tube in mechan

213 The blinq (Rebion Inc) is a new screening device designed to directly detect amblyopia and strabis

214 We used a device designed to enhance fluid and salt loss via the e

215 atheter (BEC) is a novel pharmaco-mechanical device designed to enhance thrombolysis by increasing th

216 a cost-effective, customizable, and scalable device designed to facilitate multipolar iEBS experiment

217 scribe a simple, easy-to-fabricate perfusion device designed to focally deliver pharmacological agent

218 ichia coli cells by employing a microfluidic device designed to follow steady-state growth and divisi

219 f a transesophageal echocardiographic-guided device designed to implant artificial expanded polytetra

220 The Helex septal occluder is a new type of device designed to improve the results of transcatheter

221 he OrganoidChip+, an all-in-one microfluidic device designed to integrate both culturing and HCI of A

222 ctroporation using a home-built high-voltage device designed to lyse cells grown in colonies on agar

223 MPORTANCEMITUBE is a new in vitro diagnostic device designed to meet a need in the clinical microbiol

224 In a microfluidic device designed to mimic naturally occurring bacterial n

225 We present a microfluidic device designed to monitor the endothelium on two fronts

226 , we present a capillary-driven microfluidic device designed to perform the critical biomarker captur

227 In this study, we present a microfluidic device designed to permit biomechanical investigations o

228 er activation of an intermittent compression device designed to prevent DVT.

229 The "veil of ignorance" is a moral reasoning device designed to promote impartial decision making by

230 lollipop-inspired open-fluidic oral sampling device designed to provide a comfortable user sampling e

231 s, we created an in vitro diagnostic medical device designed to quantitatively detect serum K18, cons

232 PLAATO is a device designed to seal the neck of the left atrial (LA)

233 o characterization pipeline for prescreening device designs to identify promising candidates for in v

234 NISs are emerging medical devices designed to allow persons with paralysis to oper

235 nal mechanical cardiopulmonary resuscitation devices designed to augment circulation, and may soon ad

236 Intracortical microelectrodes (IMEs) are devices designed to be implanted into the cerebral corte

237 analyte species in nanoscale cantilever-type devices designed to detect small concentrations of biomo

238 IVD have been confined to purely mechanical devices designed to either eliminate or enable flexibili

239 Although AEDs are complex medical devices designed to function during life-threatening eme

240 ontrol signals for neuroprosthetic assistive devices designed to interact with objects in a flexible

241 s assumption through the use of microfluidic devices designed to mimic human capillary constrictions

242 e surface modification of glass microfluidic devices designed to perform electrophoretic separations

243 struction of nanoscale protein-based sensing devices designed to present proteins in defined orientat

244 grams, smartphone applications, and wearable devices designed to prevent, treat, or manage clinical c

245 also have implications for the evaluation of devices designed to reduce effort during walking, as loc

246 ficiency of the evaluation of techniques and devices designed to reduce such events.

247 consist of implantation of iris prostheses, devices designed to reduce symptoms of aniridia.

248 ally used in reference to sensory prosthetic devices designed to replace input from one defective mod

249 Thus, any device design using graphene has to take into considerat

250 the conventional strategy of iterating over device design variations by fabricating the actual devic

251 Our device design was based on the deregulation of HfQ prote

252 To optimize our device design, we carried out systematic simulations of

253 To aid in device design, we employed a pseudo-steady-state diffusi

254 Thus, device designs where lateral electron hopping is promote

255 ique is compatible with standard quantum dot device designs, where highly-polarized nuclear spins can

256 provide guidelines for future materials and device design with an eye towards tailoring device perfo

257 rrier dynamics and can help realise advanced device designs with "on-demand" optoelectronic propertie

258 We present microfluidic device designs with a two-dimensional planar format and

259 ther methods, and also offers flexibility in device designs within that growth environment.

260 This facilitates a host of device designs, within a relatively simple growth enviro