ライフサイエンスコーパス: miniaturization

1 prepare, rapid feedback, and possibility for miniaturization.

2 al switching, wavefront-analysis, and device miniaturization.

3 fferentiation, thereby causing hair follicle miniaturization.

4 heir inherent fast response time and ease of miniaturization.

5 c levitator, thus readily promoting reaction miniaturization.

6 desirable for system integration and device miniaturization.

7 few seconds and provides great potential for miniaturization.

8 hile retaining the benefit of further device miniaturization.

9 mple production, ability of multiplexing and miniaturization.

10 ition into a pathological state such as hair miniaturization.

11 ks and magnetometers, and also hinders their miniaturization.

12 g parts and opens the possibility of extreme miniaturization.

13 microtubule-based systems, enabling further miniaturization.

14 ork, the sensing film was also optimized for miniaturization.

15 ditionally present low sensitivity for assay-miniaturization.

16 technique more biocompatible and amenable to miniaturization.

17 cause of their potential for scalability and miniaturization.

18 roteins as reporters; neither is amenable to miniaturization.

19 of hair loss characterized by hair follicle miniaturization.

20 t, electric field optimization, and ion-trap miniaturization.

21 external power sources thus enabling device miniaturization.

22 tionally improved and have the advantages of miniaturization.

23 ss sample consumption to enable future assay miniaturization.

24 0 uL) was observed enabling further scope of miniaturization.

25 creasing the efficiency and enabling further miniaturization.

26 one promising approach to electronic device miniaturization.

27 PPAR pathway is involved in progressive hair miniaturization.

28 nd preserved function in the face of extreme miniaturization.

29 n important prerequisite for efforts towards miniaturization.

30 by a planar electrode array constrains such miniaturization.

31 th the loss of macroscopic surface area upon miniaturization.

32 ectly ancestral to birds undergoes sustained miniaturization across 50 million years and at least 12

33 ordiidae appears to have evolved by stepwise miniaturization adapting from coarser to finer sediments

34 re, it is necessary to better understand how miniaturization affects cell behavior.

35 The distinct, prolonged phase of miniaturization along the bird stem would have facilitat

36 led morphology and structure that also favor miniaturization, an interesting advantage when the sampl

37 Here we report dramatic miniaturization and 2 orders of magnitude reduction in o

38 t response time, minimal sample preparation, miniaturization and ability for real-time monitoring of

39 ion for ammonia is revisited with the aim of miniaturization and addressing interferences as encounte

40 rmances: rapidity, selectivity, sensitivity, miniaturization and affordability.

41 Progress in the miniaturization and automation of complex analytical pro

42 The miniaturization and automation of this technology has le

43 ages of the method are discussed in light of miniaturization and automation.

44 The results are very significant for future miniaturization and automation.

45 The method is amenable to massive scale-up, miniaturization and automation.

46 rofluidic systems offer a high potential for miniaturization and automation.

47 ar layers are at the quantum limit of device miniaturization and can show enhanced electronic effects

48 chip-based devices for improved performance, miniaturization and enhanced functionality.

49 n immense drive in modern microscopy towards miniaturization and fibre-based technology.

50 esent the application of 3D-printing for the miniaturization and functionalization of an ion source f

51 s of these compounds could also benefit from miniaturization and have been investigating capillary el

52 , but visible wavelengths would allow system miniaturization and higher energy confinement.

53 However, current CGM devices need further miniaturization and improved functional performance.

54 ernal power supplies as well as from further miniaturization and increased detection rate.

55 With the continuous miniaturization and increasing complexity of the devices

56 nd novel fabrication technology that enables miniaturization and integration beyond the state-of-the-

57 For miniaturization and integration of chemical synthesis an

58 Microfluidic systems allow miniaturization and integration of complex functions, wh

59 The miniaturization and integration of frequency-agile micro

60 Microfluidic systems allow miniaturization and integration of multiple biochemical

61 Miniaturization and integration of optical tweezers are

62 gth devices and opens up new avenues for the miniaturization and integration of THz and optical compo

63 or batteries, which will greatly enhance the miniaturization and integration requirements for emergin

64 In particular, they lend themselves to miniaturization and integration with cheap electronics.

65 planar acoustic lens is crucial to achieving miniaturization and integration, and should have deep im

66 By virtue of miniaturization and its parallel format, the platform en

67 The remarkable advantages (miniaturization and low-cost) fill the bill of point-car

68 spines in C. praetermissus may indicate that miniaturization and migration to a planktonic lifestyle

69 Miniaturization and parallel processing play an importan

70 licon chips have demonstrated high levels of miniaturization and performance.

71 ectrochemical methods are highly amenable to miniaturization and possess the potential to be multiple

72 Oxford Nanopore technologies (ONT) add miniaturization and real time to high-throughput sequenc

73 ional simplicity, speediness, possibility of miniaturization and real-time nature, electrochemical se

74 ysis at a reduced cost is driving a trend in miniaturization and simplification of procedures.

75 ice requirements such as low analysis times, miniaturization and simplification, and single use.

76 While providing capabilities for miniaturization and system integration thanks to CMOS co

77 Miniaturization and the ability to pack thousands of cry

78 atures or/and complex setups, preventing the miniaturization and wide use of these devices.

79 The high EO response can be leveraged for miniaturization and/or reduction of the operating voltag

80 equirements, the number of procedural steps, miniaturization, and automation are just a few of the mu

81 anks to recent advances in machine learning, miniaturization, and computation, it is newly possible t

82 detection range, fast response time, system miniaturization, and enhanced sensitivity.

83 the future of analytical device fabrication, miniaturization, and functionalization.

84 storage of the glass membrane, difficulty in miniaturization, and interferences from alkali metals.

85 ns owing to their high performance, inherent miniaturization, and low cost.

86 t achieved, the rapid analysis (30 min), the miniaturization, and portability of the instrument combi

87 ic integrated devices for improved fidelity, miniaturization, and reconfiguration.

88 ptics architecture for improved performance, miniaturization, and scalability.

89 tion of the spatial arrangement, modularity, miniaturization, and sharing of information between labo

90 With its advantages in biocompatibility, miniaturization, and versatility, the acoustic tweezers

91 As miniaturization approaches its limits, bringing an end t

92 alytical advantages realized from such assay miniaturization are more uniform target-spot coverage an

93 al features and the factors that limit their miniaturization are of considerable theoretical interest

94 erent advantages including opportunities for miniaturization, autonomous shaping, and controllable st

95 ical devices lend themselves to considerable miniaturization because of their subwavelength features.

96 ers in the point-of-care testing field: easy miniaturization (bedside devices) and low cost.

97 rfering molecules and is readily amenable to miniaturization by association with existing-chip based

98 h-efficiency mechanical components that pose miniaturization challenges governed by force-scaling law

99 cted NWM growth patterns, with callitrichine miniaturization coevolving with a series of reproductive

100 g fraction of energy as cell size decreases, miniaturization comes at a considerable energetic cost f

101 re we create a practical geometry for device miniaturization, consisting of highly crystalline microm

102 aae specimen preserves features that hint at miniaturization constraints, including a unique pattern

103 As miniaturization continues to influence the next generati

104 electronic devices promises the ultimate in miniaturization coupled with the flexibility of organic

105 ies of CARMEN make it practical to scale, as miniaturization decreases reagent cost per test by more

106 The growing miniaturization demand of magnetic devices is fuelling t

107 are not easily compatible with low-cost and miniaturization demands.

108 This liquid reservoir makes sensor miniaturization difficult and leads to devices that are

109 The consequences of miniaturization displayed by different insect taxa inclu

110 and crosstalk, which are critical to system miniaturization, diversity in functionality, and non-inv

111 f potassium optode microspots indicated that miniaturization does not alter response characteristics,

112 says, demonstrating that the near 2,000-fold miniaturization does not influence the cytotoxicity resp

113 he advantageous attributes such as low-cost, miniaturization, energy efficient, easy fabrication, onl

114 atory devices and there is interest in their miniaturization, even towards on-chip systems.

115 than previously thought, and that a profound miniaturization event occurred near the base of the avia

116 iciency, stable optical properties, and easy miniaturization, facilitating the future integration and

117 online remote monitoring, fast response, and miniaturization for its in vivo/in vitro applications in

118 up is very robust and, as we demonstrate via miniaturization for microplate format, amenable for scre

119 the 1 nm length scale that will aid further miniaturization for numerous applications.

120 ave enabled such capabilities, which include miniaturization for point-of-care testing, direct comple

121 the limitations of analyzing the effects of miniaturization from profile data of neurons and demonst

122 associated with nucleotide addition enables miniaturization, greater portability of testing apparatu

123 The need for their miniaturization has fuelled the rapid growth of interest

124 The blossoming of genomic technologies and miniaturization has opened up the field of genomic scale

125 The pursuit to achieve miniaturization has tantalized researchers across the fi

126 This miniaturization has, however, so far been achieved at th

127 Complementing the magnet miniaturization, here we integrate the NMR spectrometer

128 sensitivity, precision, and feasibility for miniaturization, high-throughput format adaptation, and

129 essary to improve performance and for device miniaturization. However, epitaxial growth of atomically

130 However, miniaturization imposes steep demands on the flight syst

131 photonic integrated devices and circuits for miniaturization, improved performance, and enhanced func

132 y, simplicity, and feasibility for apparatus miniaturization in analytical tests.

133 Concurrently, a drive for further miniaturization in applications such as optics, electron

134 ple demonstrates the feasibility of improved miniaturization in CGM based on microfluidics.

135 torage device could bring about the ultimate miniaturization in energy storage.

136 Most studies dealing with the limits to miniaturization in insect brains have until now relied o

137 With advances in automation and miniaturization in material fabrication, hundreds of bio

138 ls can be seen as a functional adaptation to miniaturization in order to maintain a proximal shieldin

139 in the effective wavelength opens a path to miniaturization in the science and technology of negativ

140 Miniaturization increases assay throughput while reducin

141 portable prototype, illustrating its facile miniaturization, integration and potential portability.

142 -infrared imaging systems generally requires miniaturization, integration, flexibility, good workabil

143 Their miniaturization interferes with the multiple functions t

144 Through miniaturization into microchips, new techniques have bee

145 Miniaturization is accompanied by allometric changes in

146 Assay miniaturization is advocated to improve surface-capture

147 Miniaturization leads to considerable reorganization of

148 In insects, miniaturization leads to fundamental changes in wing str

149 sing desires for higher sensitivity, greater miniaturization, lower cost, and better wearability.

150 The device's miniaturization, material, and zero-magnetic-field opera

151 Miniaturization most commonly arises in isolated environ

152 tial benefits they can offer in integration, miniaturization, multiplexing, and real-time label-free

153 Any attempt at compound screening miniaturization must address the significant scaling ine

154 e they approach the absolute limit of sensor miniaturization, nanopores are amenable to parallelizati

155 Advances in miniaturization, nanotechnology, and microfluidics, alon

156 Here, we describe the miniaturization of a pair of assays based on the binding

157 Miniaturization of a thermolysis reactor using commercia

158 portable wireless communication systems.The miniaturization of antennas beyond a wavelength is limit

159 han one-tenth of the wavelength, and further miniaturization of antennas has been an open challenge f

160 reasingly, nano-fabrication have enabled the miniaturization of atomic devices, from vapor cells to a

161 The miniaturization of bioelectronic intracellular probes wi

162 Miniaturization of biosensors is essential for use in th

163 The miniaturization of biosensors using microfluidics has po

164 ke them ideal candidates for engineering and miniaturization of biosensors.

165 However, the miniaturization of cavity resonators, which are the esse

166 However, miniaturization of cell dimensions for portable device a

167 Miniaturization of cell-based assays enables the analysi

168 Microfluidic technology permits the miniaturization of chemical analytical methods that are

169 rfaces was widely seen as the main route for miniaturization of components and interconnect of photon

170 The miniaturization of computation and communication technol

171 EUVL) is the leading technology for enabling miniaturization of computational components over the nex

172 Metasurfaces allow the miniaturization of conventional refractive optics into p

173 s or cavities that tend to constrain further miniaturization of current systems.

174 to study neutrino properties and leads to a miniaturization of detector size, with potential technol

175 The rapid miniaturization of devices and machines has fuelled the

176 nic components on a chip) is crucial for the miniaturization of devices.

177 plications, offering new pathways for future miniaturization of dielectric waveguide-based systems wi

178 The miniaturization of droplet manipulation methods has led

179 At the same time, miniaturization of echocardiography has further expanded

180 Recently, the use of venovenous ECLS and miniaturization of ECLS components have shown potential

181 unctions represent the ultimate limit to the miniaturization of electrical circuits.

182 The miniaturization of electrochemical sensors allows for th

183 devices, technological advances resulted in miniaturization of electronic circuitry and eventually t

184 Miniaturization of electronic circuits into the single-a

185 With the continuing miniaturization of electronic components, low dimensiona

186 The miniaturization of electronic devices has been the princ

187 The current trend in the miniaturization of electronic devices has driven the inv

188 molecular electronics aims at advancing the miniaturization of electronic devices, by exploiting sin

189 Miniaturization of electronics demands electromagnetic i

190 ubstrates and paves the way for the ultimate miniaturization of electronics.

191 nology have necessitated the development and miniaturization of energy storage devices.

192 After the miniaturization of every possible component of the diffe

193 The article considers the miniaturization of existing technologies for sequencing

194 The miniaturization of gene transfer assays to either 384- o

195 e stem cell (HFSC) aging causes the stepwise miniaturization of hair follicles and eventual hair loss

196 ws androgens as the pathogenic driver in the miniaturization of hair follicles of androgenetic alopec

197 ent of such nanoporous structure enables the miniaturization of high-performance electrochemical bios

198 diffractive counterparts, leading to further miniaturization of high-performance optical devices and

199 toward higher maximum pressures and further miniaturization of high-pressure devices, in the process

200 With the miniaturization of integrated devices, current research

201 The miniaturization of integrated optical circuits below the

202 The miniaturization of lateral flow nucleic acid detection p

203 Recent miniaturization of light-level geolocators enabled study

204 sly developed nanoPOTS platform with further miniaturization of liquid chromatography (LC) separation

205 Recently the miniaturization of liquid chromatography (LC) systems an

206 The miniaturization of medical devices and the progress in i

207 With the continued push for miniaturization of medical diagnostics to reduce cost an

208 ese devices could play a pivotal role in the miniaturization of microwave front-end antenna circuits.

209 This confinement both facilitates miniaturization of nanophotonic devices and makes their

210 lets online and represents an advance in the miniaturization of natural products screening.

211 there has been an increasing interest in the miniaturization of NMR detectors.

212 Miniaturization of optical cavities has numerous advanta

213 ngth metasurface platform allows for further miniaturization of optical components and offers a scala

214 With the push towards miniaturization of optical components, static metasurfac

215 otonic integrated circuits (PICs) enable the miniaturization of optical quantum circuits because seve

216 The miniaturization of optical systems (to the micro and nan

217 th diffractive planar components enables the miniaturization of optical systems.

218 The miniaturization of optoelectronic devices is essential f

219 ed strategy to be particularly conducive for miniaturization of pressure-driven separations yielding

220 This flexible design will lead to the miniaturization of quantum devices in a wide range of ho

221 Miniaturization of Raman instruments has created a new g

222 lectronic and energy storage devices, making miniaturization of robots difficult.

223 volume manufacturing to enable the continued miniaturization of semiconductor devices.

224 The miniaturization of semiconductor transistors has driven

225 fied all in vitro sample preparation and the miniaturization of sequencing chemistries, enabling mass

226 Despite advances in the miniaturization of solid-phase extraction, the technique

227 ties for improvement of conductivity and for miniaturization of solid-state ionic devices by the care

228 The miniaturization of SPE within a 3D printed microfluidic

229 ent developments in metamaterials enable the miniaturization of such computing elements down to a sub

230 Miniaturization of such screening systems may overcome p

231 issue reveals the severe penalty incurred by miniaturization of the antenna.

232 nments, which requires the ruggedization and miniaturization of the atomic reference and clock laser

233 To address this, we report here the miniaturization of the AVEXIS (avidity-based extracellul

234 umber of microfluidic platforms have enabled miniaturization of the conventional microtitre plate ELI

235 presented here is particularly suitable for miniaturization of the CZE method and may be easily inte

236 The simple design of the sensor facilitates miniaturization of the device and its implementation for

237 Here is reported a miniaturization of the device described above, in which

238 Miniaturization of the device, beyond that achievable wi

239 is degree of sensitivity will facilitate the miniaturization of the entire assay procedure down to ce

240 3D macroscale hydrogels, indicating that the miniaturization of the experimental system did not alter

241 s, application of magnetic-sector-ICPMS, and miniaturization of the extraction/separation methods we

242 as electrochemical sensing platforms for the miniaturization of the lactate biosensor.

243 anent magnet represents a useful step toward miniaturization of the overall NMR spectrometer into a p

244 Miniaturization of the platform circumvented the need fo

245 illimeter or less ("microimplants"), but the miniaturization of the power source remains challenging.

246 tself amenable to remote delivery and to the miniaturization of the probe head which could be benefic

247 Miniaturization of the procedure enabled determining the

248 nd rapid prototyped devices, the prospect of miniaturization of the reference electrodes using printi

249 in), the simplicity, and easy automation and miniaturization of the required instrumentation make the

250 advantages like low-cost, low-power and easy miniaturization of the required instrumentation.

251 eamlined workflow integration, with possible miniaturization of the sample handling process making it

252 The miniaturization of the solvent-free MALDI approach allow

253 nd provide the ideal platform for the future miniaturization of the technology.

254 ade predators, or hunt prey; and second, the miniaturization of their body size, which profoundly inf

255 and cooling steps in PCR largely hamper the miniaturization of thermocyclers for on-site detection o

256 e write heads, which is important for future miniaturization of these devices.

257 The miniaturization of this concept, however, imposes a rest

258 in microfluidic approach reveals a means for miniaturization of time-resolved emission spectroscopy.

259 anometric features hardly stick owing to the miniaturization of water bridges, whereas kinetics of co

260 ion technology has clearly demonstrated that miniaturization often leads to unprecedented performance

261 t, and low-cost instrument is attractive for miniaturization on a lab-on-a-chip system to deliver poi

262 advantages of the stacked pad assay include: miniaturization, operational simplicity, fast response t

263 developments observed in sensor and actuator miniaturization, optimization of microelectronic circuit

264 tive brain size accompanied the trend toward miniaturization or evolution of flight during the therop

265 titial taxa evolved from larger ancestors by miniaturization, or (3) progenesis [3].

266 length) demonstrates 1-2 orders of magnitude miniaturization over state-of-the-art compact antennas w

267 d handling requirements and enable efficient miniaturization, parallelization, and integration of ass

268 The optimal miniaturization parameters were determined by immersing

269 probes and the experimental simplicity, and miniaturization potential provided by the diffraction-ba

270 coustic wave based biosensors enables device miniaturization, power consumption reduction and integra

271 ed through the strategies of de novo design, miniaturization processes and protein redesign.

272 Device miniaturization produces distinct properties and phenome

273 llenges of Moore's Law, predicting ambitious miniaturization rates of integrated circuits, requires t

274 puting technology needs to allow progressive miniaturization, reduce switching energy, improve device

275 Moreover, miniaturization reduced reagent consumption and residue

276 The successful miniaturization results in an exceptional power density

277 Both progenesis and miniaturization should be considered when investigating

278 ost, promising response speed, potential for miniaturization, simple instrumentation and easy automat

279 As a critical step toward NMR spectrometer miniaturization, small permanent magnets with high field

280 Existing miniaturization strategies involve complex approaches no

281 ng a rationale to understand surface capture miniaturization strategies.

282 Our work not only provides a miniaturization strategy of TENG for the application in

283 Under the trend of miniaturization, such quantum electrodynamical effects a

284 This miniaturization technique provides a new option for fabr

285 been accelerated with the advent of emerging miniaturization techniques, advanced materials and sensi

286 of photonic systems towards integration and miniaturization, the need for an on-chip waveguide type

287 The move towards optical system miniaturization therefore motivates the development of m

288 ndidates for clean and renewable power; with miniaturization, they might also serve as integrated pow

289 Thus, in addition to progenesis [3, 4], miniaturization, thought to be too slow for an adaptatio

290 r electronic devices, such as extended life, miniaturization to improve comfort and conformability, a

291 ertain advantages advocated for capture spot miniaturization using a rationale to understand surface

292 rtz wafer, is a very attractive approach for miniaturization using Micro-Electro-Mechanical Systems(M

293 Considering the potential for system miniaturization using, e.g., dedicated quantum cascade l

294 and phylogenetic position imply that extreme miniaturization was ancestral for Paraves (the clade inc

295 t electronic length scales are desirable for miniaturization, while strong interactions that mediate

296 imaging applications requiring extreme size miniaturization, wide-angle fields of view, and high sen

297 oved to be highly sensitive and robust after miniaturization with IC(50)s for fenretinide and retinol

298 stem was designed to focus on automation and miniaturization with minimal sample and reagent consumpt

299 profile data of neurons and demonstrate that miniaturization within the nervous system can lie beyond

300 cal analysis, validating the hypothesis that miniaturization yields many practical assay advantages.