ライフサイエンスコーパス: disposable

1 provide rapid analysis, and are portable and disposable.

2 devices that are robust, cost-effective and disposable.

3 asy to use, low-cost, widely accessible, and disposable.

4 n allows the sensor to be cost-effective and disposable.

5 veloped a dielectrophoretic platform using a disposable 3D electrode geometry that accurately (r(2) >

6 e introduce a simple protocol to manufacture disposable, 3D-printed microfluidic systems for sample p

7 fied with TNT-specific peptides were used as disposable a biosensor to produce impedance responses to

8 a 635 nm high-output LED powered by three AA disposable alkaline batteries, to achieve strong cytotox

9 been developed recently as simple, cheap and disposable alternatives to conventional ones for on-site

10 ove the image quality, a mini dark box and a disposable analytical cartridge containing all the reage

11 nable new applications ranging from low-cost disposable analytical devices to large-area sensor netwo

12 They are disposable and can be produced fairly rapidly and at low

13 re specific, simple, portable, and generally disposable and can carry out in situ or automated detect

14 ing outside a clinical setting would require disposable and durable sensors to provide better therapi

15 The gold-sputtered paper electrode is disposable and easily interchangeable, meanwhile the pla

16 per-based device to provide a sensor that is disposable and easy to use, and thus is suitable for app

17 This low-cost disposable and easy-to-use device will prove valuable fo

18 This low-cost disposable and easy-to-use device will prove valuable fo

19 A reagentless pH sensor based upon disposable and economical graphite screen-printed electr

20 An inexpensive, disposable and highly selective microfluidic paper-based

21 eal diagnostic platform for low-cost, easily disposable and lightweight implementation, but requires

22 The numerous advantages of disposable and screen-printed electrodes (SPEs) particul

23 In this study, a disposable and simple electrochemical immunosensor was f

24 their detection is compatible with low-cost disposables and because application of a magnetic field

25 They are light, flexible, portable, disposable, and do not generate potentially negative env

26 the high-throughput production of flexible, disposable, and human-interactive cutting-edge electroni

27 roughput technology to manufacture flexible, disposable, and inexpensive printed electronic devices.

28 ensors can be exploited to develop low-cost, disposable, and rapid assays for the detection of a larg

29 Therefore, innovative, inexpensive, disposable, and rapid diagnostic platform technologies a

30 The fabricated sensor is cheap, is disposable, and requires only 150 muL of samples.

31 t lithography technology to aim low cost and disposable applications, the memory capacity tends to be

32 To emphasize potential applications of the disposable ATR module in life science studies exploring

33 nclusion, this approach permits the use of a disposable biosensor chip that can be mass-produced at l

34 An electrochemical disposable biosensor for the specific and sensitive dete

35 lectronic decals (WPEDs): highly conformable disposable biosensors capable of monitoring sweat and va

36 ure due to increasing demand of low-cost and disposable biosensors.

37 ocess monitoring applications, and low-cost, disposable biosensors.

38 Here, we demonstrate a proof-of-concept disposable breathalyzer using an organic electrochemical

39 nsor with both a nondisposable (monitor) and disposable (calcium alginate pads with immobilized bacte

40 undergo ERCP with a novel duodenoscope with disposable cap, or to a control group who will undergo E

41 e has recently been developed that employs a disposable cap.

42 garding the use of a novel duodenoscope with disposable cap.

43 lulose ester dialysis membranes coupled with disposable carbon and copper electrodes for monitoring a

44 d bronchial lavage samples using unmodified, disposable carbon electrode sensors that detect the pres

45 Disposable carbon paper electrodes were functionalized w

46 etoimmunosensor involving magnetic beads and disposable carbon screen-printed electrode (CSPE) for Fu

47 Importantly, this system features a disposable cartridge and a sensitive custom designed flu

48 ssue was loaded in this configuration into a disposable cartridge and delivered into the anterior cha

49 The sample is directly added to a disposable cartridge containing all reagents for sample

50 DMEK grafts were loaded into a disposable cartridge in a tri-folded, endothelium-in con

51 -throughput parallel drug screening, modular disposable cartridge, and biocompatibility, which can po

52 d study encourages the future development of disposable cartridges, which function with simple operat

53 asy-to-use, inexpensive, point-of-care (POC) disposable cassette that carries out all the unit operat

54 eveloped, such as radiosynthesizers based on disposable "cassettes," that do not require reconfigurat

55 achable acoustofluidic system comprised of a disposable channel device and a reusable acoustic transd

56 Moreover, the 3D printed MALDI targets are disposable, cheap, and easy to produce.

57 ofluidic channel, and the other in which the disposable chip is externally fixed to a reusable substr

58 At the heart of the flow-cell is a disposable chip made of porous aluminum oxide (PAO), whi

59 icles in low volumes of liquids (25 nL) on a disposable chip, using an acoustically actuated lens-fre

60 on method, using 3D electrodes on a low-cost disposable chip; one cell type is allowed to pass throug

61 rmed once-daily bathing of all patients with disposable cloths impregnated with 2% chlorhexidine or n

62 h patients were bathed with nonantimicrobial disposable cloths, before crossover to the alternate bat

63 We have developed disposable color-changing polymeric films for quantifica

64 omolecule adsorption media, as structural or disposable components of the optical biosensors.

65 ess makes them less amenable as low-cost and disposable components.

66 multiplexed biorecognition in a compact and disposable configuration with clinical-level sensitivity

67 In multivariate analysis, the use of a disposable conjunctival mould assist device and the use

68 pose ecological and human health risks, with disposable contact lenses constituting a potential high-

69 the target molecule in low sample volume at disposable cost-effective SPCE.

70 Here we report a disposable, cost effective electrochemical paper-based s

71 osts were subdivided in costs of devices and disposables, costs of additional human resources, and su

72 Serving coffee in a ceramic or disposable cup were found to influence the cooling dynam

73 sor represented the features of sensitivity, disposable design, low sample volume, rapid and simple p

74 mportantly, these sensors offer low-cost and disposable detection platforms for real-world applicatio

75 A prototype of a self-contained, automated, disposable device for chemically amplified protein-based

76 nology and has the potential to be used as a disposable device for in situ and real-time clinical dia

77 ents with minimal pipetting, in a hand-held, disposable device intended for point-of-care use in reso

78 Thus, this disposable device may be useful for personalized diagnos

79 onventional stool containers and GutAlive, a disposable device that minimizes exposure of the gut mic

80 tail the progress of a novel electrochemical disposable device, which has a relatively low cost and e

81 ce with low production costs essential for a disposable device.

82 These inexpensive, disposable devices can be created rapidly (<2 hours) wit

83 mmunity since 2007 as low-cost, wearable and disposable devices for point-of-care diagnostic due to t

84 The disposable devices show excellent conductivity and fast

85 The immunosensor design involves disposable devices using carboxylic acid-functionalized

86 reliable technology, low cost for potential disposable devices, the potential for extreme minituariz

87 essing, may fulfill requirements of low-cost disposable devices.

88 al power supply and can be used as any other disposable dressing.

89 for IL-8 mRNA and amperometric detection at disposable dual screen printed carbon electrodes.

90 24 e-cigarette flavors from the top selling disposable e-cigarette brands.

91 to the development of breathalyzers that are disposable, ecofriendly, and integrated with wearable de

92 The disposable, efficient, sensitive and low-cost non-enzyma

93 In this work a disposable elastomeric piezoresistive strain sensor was

94 A novel disposable electrochemical biosensor based on immobilize

95 A flexible disposable electrochemical biosensor device comprising o

96 A novel and disposable electrochemical biosensor for PCR-free and se

97 Novel disposable electrochemical DNA sensors were prepared for

98 In this study, we have fabricated a simple disposable electrochemical immunosensor for the point of

99 This assembly provides a portable and disposable electrochemical platform, assembled by the ea

100 nstrate a flexible, mechanically stable, and disposable electrochemical sensor platform for monitorin

101 mediated isothermal amplification (LAMP) and disposable electrochemical sensors based on screen-print

102 A disposable electrochemical test strip for the quantitati

103 Reusability of the probe-functionalized disposable electrode was investigated by comparing diffe

104 the hybridization event without labeling on disposable electrodes and with a 1.5 h response time.

105 Screen-printed disposable electrodes are used as electrochemical sensin

106 carbon nanotubes (CNT)-based inkjet-printed disposable electrodes for the direct ECL imaging of a la

107 much simpler and faster protocol (~1 h) and disposable electrodes for the transduction.

108 cence spectroelectrochemistry using low-cost disposable electrodes is reported.

109 From paper based electrodes to disposable electrodes obtained from CD/DVD, in the last

110 ng-term goal is to use these inexpensive and disposable electrodes to measure biomarkers of wound hea

111 Electrochemical flow cells with integrated disposable electrodes were directly coupled with mass sp

112 Disposable electrodes were fabricated by thermal evapora

113 Here an overview of recycled and recyclable disposable electrodes, sustainable electrode modifiers a

114 dases were detected rapidly within 1 h using disposable electrodes.

115 ith the H(2)O(2)/hydroquinone (HQ) system at disposable electrodes.

116 meaningful examples to redesign the world of disposable electrodes.

117 A disposable electrodic system consisting of two working e

118 The rapid development of wearable and disposable electronic devices and the rising awareness o

119 ation of these components into an automated, disposable, electronic ELISA Lab-on-PCB diagnostic platf

120 n effective platform for green, foldable and disposable electronics based on low cost and versatile m

121 tical method for fabrication of flexible and disposable electronics devices.

122 e range of new applications such as low-cost disposable electronics for health monitoring and wearabl

123 A disposable energy source made of GO was also written on

124 We conclude that this disposable enzyme sensor strip system for measuring GA i

125 We have developed a disposable evanescent wave fiber optic sensor by coating

126 The disposable, evaporated electrodes were morphologically c

127 high porous surface structure, inexpensive, disposable, excellent stability, good reproducibility an

128 Furthermore, we show that UNC-45A is disposable for NK cell immunological synapse formation a

129 of 3D printing for on-demand fabrication of disposable, functionally integrated devices for low-cost

130 Here, we present a portable, online, and disposable gas sensor platform for the in situ determina

131 A disposable gas-sensing paper-based device (gPAD) was fab

132 Leachates of 10 different types of disposable gloves were analyzed using Raman microspectro

133 A novel and highly sensitive disposable glucose sensor strip was developed using dire

134 uld be used for high volume manufacturing of disposable glucose strips.

135 To develop the electrochemical device, a disposable gold electrode was functionalized with the sp

136 ophene films on the surface of miniaturized, disposable, gold screen-printed electrodes, followed by

137 D-amino acids (AAs) has been developed using disposable graphene oxide nanoribbon (GON) screen printe

138 These BiO nanorods were cast onto mass disposable graphite screen-printed electrodes (BiO-SPEs)

139 ined thin aqueous layer, the construction of disposable halide sensors, and portability for measuring

140 rfectly circular anterior capsulotomy with a disposable handheld instrument that can be used in the n

141 Capsulotomies are performed using a disposable handpiece with a soft collapsible tip and cir

142 SES was measured using disposable household income and divided in tertiles.

143 This paper describes a novel, simple, and disposable immunosensor based on indium-tin oxide (ITO)

144 ed to fabricate the sensitive, selective and disposable immunosensor electrodes.

145 tion with large doses of virus, it is wholly disposable in both control of virus replication and indu

146 epwise inverse association between household disposable income and all-cause mortality: the adjusted

147 nvestigate the association between household disposable income and long-term mortality after cardiac

148 lleviation pilot policy increases per-capita disposable income in a county by approximately 7%-8%.

149 ing Cox regression by quintiles of household disposable income.

150 y-substituted polythiophene polymer modified disposable indium tin oxide electrode.

151 ble, foldable, biocompatible, biodegradable, disposable, inexpensive, and wearable sensors and the ri

152 es of sample holders, including the standard disposable inserts classically used in HR-MAS NMR-based

153 s cost-effective at $100,000/QALY if robotic disposable instrument costs decrease below $1341 per cas

154 Therefore, we report on a disposable integrated chip-based capillary immunoassay f

155 Disposable ITO coated Polyethylene terephthalate (PET) e

156 ups containing poly(phosphazene) film coated disposable ITO electrode were utilized as an immunosensi

157 man serum by using easy and quickly prepared disposable ITO immunoelectrode.

158 man serum by using easy and quickly prepared disposable ITO immunoelectrode.

159 oduced (99m)Tc using an automated system and disposable kits.

160 lize on such resource, the use of autonomous disposable lab-on-a-chip (LOC) devices-conceived as only

161 aper proposes a novel handheld analyzer with disposable lab-on-a-chip technology for the electrical d

162 itive visible detection scheme for low-cost, disposable lab-on-chip point-of-care (POC) diagnosis sys

163 rpretation due to substances associated with disposable laboratory gloves or reagents used during sam

164 d we present BiliSpec, a low-cost reader and disposable lateral flow card designed to measure the con

165 ses of a smartphone accessory, an app, and a disposable lateral flow immunoassay test strip to quanti

166 The RADPAD is a sterile, disposable, lead-free shield placed on the patient with

167 was attached on a trapezoidal prism for the disposable light source module.

168 In conclusion, a disposable, light-weight, all-printed and flexible biose

169 This protocol can be used to develop of disposable, low cost, and portable various types of dehy

170 in blood at very low levels of infection, on disposable, low-cost chips.

171 e improvements in bacterial detection, fast, disposable, low-cost, sensitive, and user-friendly metho

172 which could be used as a one-step, portable, disposable, low-cost, simple, instrument-free and point-

173 the operation of the multi-use immunosensor, disposable magnetic microbeads were used to immobilize b

174 5,981 (58.8%) participants reported reusing disposable masks, with nearly two thirds (n=3923, 65.6%)

175 onmental emissions include the production of disposable materials and single-use surgical devices, en

176 sed on the combination of both, reusable and disposable materials in order to generate simple, versat

177 a viable method to improve the precision of disposable MCE devices-giving matched or superior result

178 Participants reported wearing disposable medical masks (93.8%), followed by N95 respir

179 A disposable microextraction device compatible with inject

180 The proposed disposable microfluidic biochip with an on-chip anesthet

181 ring of ATP, with an integrated and low-cost disposable microfluidic chamber for handling of biologic

182 e where the electrodes are embedded into the disposable microfluidic channel, and the other in which

183 A disposable microfluidic chip, prefilled with biomarker-s

184 have demonstrated the concept of a low cost disposable microfluidic device with a receptor functiona

185 t range, using unprocessed human serum and a disposable microfluidic device; no optics are involved i

186 A novel fully disposable microfluidic electrochemical array device (mi

187 Infrared thermal imaging was combined with disposable microplates to perform enthalpimetric analysi

188 A system of ITI was combined with disposable microplates to perform enthalpimetric analysi

189 cost disposable pipet tips and conventional disposable microtiter well plates.

190 A disposable mu-EME unit is filled with five consecutive p

191 Here, we describe a disposable multi-walled carbon nanotubes (MWCNTs) labele

192 ing the way towards mass-produced, low-cost, disposable, multi-parametric chemical sensing diagnostic

193 ed the development and clinical testing of a disposable, multiplexed sensing device (ToMMx), which is

194 ts were monitored for up to 3 months using a disposable multisensor patch placed on the chest that re

195 Furthermore, the quick and complete disposable nature demonstrated here is attractive for se

196 ng, and after wearing a 3-layer plane-shaped disposable nonmedical face mask widely used to protect a

197 es such as useful for naked-eye observation, disposable, not time-consuming, inexpensive, no need of

198 A novel electrochemical disposable nucleic acid biosensor for simple, rapid, and

199 similar or lower for menstrual cups than for disposable pads or tampons (n=293).

200 electrochemical detection, is performed at a disposable paper electrode microfluidic device.

201 fordable instrument, in conjunction with the disposable paper sensor chip, would have a great potenti

202 r through a glass fiber filter disk within a disposable paper spray cartridge.

203 hydrogel which was subsequently used to coat disposable paper strips for easy, low-cost detection of

204 Fabrication of a disposable paper test cartridge along with using a camer

205 sing approaches with interest for simple and disposable paper-based (bio)sensing applications.

206 provides a potential platform for automated, disposable paper-based biosensors with multiplexed detec

207 As a proof of concept, disposable paper-based Cl(-) sensing devices that contai

208 An inexpensive and disposable paper-based lateral flow strip (PLFS) has bee

209 current study describes the development of a disposable paper-based microfluidic system, which unlike

210 el cells (MFCs) arranged in a large-capacity disposable, paper-based testbed.

211 embly should enable broad use of noncontact, disposable particle manipulation techniques in practical

212 constructed by modifying the surface of the disposable pencil graphite (PGE) with physical adsorptio

213 se voltammetry (DPV) in combination with the disposable pencil graphite electrode (PGE) was progresse

214 tive determination of caffeic acid (CA) on a disposable pencil graphite electrode (PGE).

215 sed on reduced graphene oxide (rGO) modified disposable pencil graphite electrodes (PGEs) were develo

216 able autosampler platform utilizing low cost disposable pipet tips and conventional disposable microt

217 cluding common laboratory materials, such as disposable pipet tips, filter paper, tooth picks, and ny

218 ed and was used into the pipette tip for the disposable pipette extraction (DPX) of carbendazim resid

219 In this work, we evaluated the use of a disposable pipette tip, opportunely configured to demons

220 The disposable planar paper-based ion-sensing platform is su

221 This work describes disposable plasma generators made from metallized paper.

222 In general, these disposable plasma generators represent progress toward b

223 Development of low-cost disposable plasmonic substrates is vital for the applica

224 repeat (STR) forensic profiling in a single disposable plastic chip is demonstrated.

225 These GON disposable platforms use just 50 muL of sample and a tot

226 Simple and disposable point of care systems are usually the best so

227 We report a disposable point-of-care sensing platform specific to sa

228 substrate for the production of economical, disposable, point-of-care (POC) analytical devices.

229 d version of conventional MIC) placed inside disposable polypropylene (PP) vessels.

230 tical flow immunogold assay (SVIA)' based on disposable porous filter-membrane was developed for on-s

231 short, this report presents an inexpensive, disposable, portable, and field-deployable paper-based d

232 The reusability of such disposable Pt-SPEs, after the surfaces had been experime

233 The disposable quartz biochip, based on microelectronic comp

234 he SSG paper as a substrate, we fabricated a disposable resistive random access memory (RRAM) which h

235 " platform that relies on a combination of a disposable rotation-driven microdisc (RDM), and a simple

236 The new sensor reported here is inexpensive, disposable, safe, and user-friendly.

237 er, soaked in a RTIL or a DES, placed upon a disposable screen printed carbon cell, so as to contact

238 b with gold nanoparticle electrochemistry on disposable screen printed carbon electrodes.

239 This work describes the application of disposable screen printed carbon paste sensors for the a

240 This biosensor incorporated disposable screen-printed carbon electrode (SPCE) and co

241 dified MBs were captured on the surface of a disposable screen-printed carbon electrode (SPCE) and th

242 captured magnetically under the surface of a disposable screen-printed carbon electrode for amperomet

243 (-0.20 V vs Ag pseudoreference electrode) at disposable screen-printed carbon electrodes (SPCEs) in t

244 Disposable screen-printed carbon electrodes (SPCEs) modi

245 ch immunoassay and amperometric detection at disposable screen-printed carbon electrodes (SPCEs) modi

246 amplification and amperometric detection at disposable screen-printed carbon electrodes is reported.

247 The ad hoc designed sensor, based on disposable screen-printed carbon electrodes modified wit

248 A commercially available disposable screen-printed carbon electrodes modified wit

249 pseudoreference electrode was carried out at disposable screen-printed carbon electrodes.

250 Disposable screen-printed electrode modified with captur

251 human metabolic pathways (HMPs) demonstrates disposable screen-printed electrodes (SPEs) as an altern

252 measured by difference pulse voltammetry on disposable screen-printed electrodes.

253 r management system (PMS) was developed as a disposable self-support real-time "shock" biosensor for

254 ange of shocks, posing a great potential as "disposable self-support shock sensor" for real time in s

255 Finally, views on how the field of disposable sensing devices will continue its evolution a

256 developed point-of-care device encompasses a disposable sensor cartridge attached to an electrochemic

257 Herein we present the development of a disposable sensor for fast and straightforward detection

258 This CSWV-based disposable sensor strip system provides an information-r

259 be the detection of MMP-9, using a low-cost, disposable sensor system for MMP-9 suitable for home-mon

260 Disposable sensors are low-cost and easy-to-use sensing

261 The capabilities of disposable sensors can extend beyond measuring tradition

262 a comprehensive and critical overview of the disposable sensors currently used for medical diagnostic

263 nformation in a vastly connected world makes disposable sensors increasingly important.

264 r the development of single-use and wearable disposable sensors.

265 chronoamperometry, enabling construction of disposable sensory electrodes.

266 cant decrease in physical load when removing disposable shoe covers (P = .04), and participants repor

267 upling layer and into a low-cost and, hence, disposable silicon superstrate on which various microflu

268 Here, we report a disposable silicon-based integrated Point-of-Need transd

269 , the chip-to-chip variabilities inherent in disposable, single-use devices must be addressed.

270 The disposable soma theory is a central tenet of the biology

271 tionary theories of senescence, such as the 'disposable soma' theory, propose that natural selection

272 ted microextraction approaches using on-chip disposable sorbents, and (iv) automatic dynamic permeati

273 ociated with changing outer gloves and using disposable spunlace paper versus reusable cloth gowns.

274 e demonstrated sensing architecture, being a disposable stand-alone chip, can be operated as a point-

275 high (5000) rpm, to induce the rotation of a disposable stir disc that causes chaotic mixing of glass

276 mprises the following parts: A polymer based disposable substrate with metallized electrodes that are

277 f cost and waste through re-sterilisation of disposable supplies, and locally sourcing consumables (e

278 d for 3 utilization measures: intraoperative disposable supply costs, procedure time, and postoperati

279 filters between the generator and commercial disposable surface pads.

280 The system uses disposable swab vials with phosphorescent oxygen sensors

281 usable plastic filter holders connected to a disposable syringe.

282 al intradermal dose by needle and syringe or disposable-syringe jet injector at a second visit.

283 dermal doses of IPV by needle and syringe or disposable-syringe jet injector compromises the immunity

284 fractional dose using needle and syringe or disposable-syringe jet injector.

285 devices, including intradermal adapters and disposable-syringe jet injectors, have also been develop

286 Finally, we used disposable test strips to detect nineteen H1N1 and H3N2

287 change the sensor after each analysis in the disposable tests prevent widespread application of the t

288 A disposable thin-film electrode modified with a droplet o

289 Therefore, single-use tonometer tips or disposable tonometer covers should be considered when tr

290 erits of immunosensor approach towards truly disposable tools for food-safety monitoring.

291 ovide optimal performance on inexpensive and disposable transparency film platforms.

292 Here we report a disposable ultrasound-sensing CCW (usCCW) featuring an i

293 sed based on microwave-induced combustion in disposable vessels (MIC-DV) for trace elements determina

294 dvantages, combined with the use of low-cost disposable vessels and instrumentation, make MIC-DV suit

295 The additional cost of using RFD-embedded disposables was $0.17 for a 4X18 laparotomy sponge and $

296 No-rinse disposable wash gloves are increasingly implemented in h

297 g without water' consists of a bed bath with disposable wash gloves made of non-woven waffled fibers,

298 ronmentally sustainable and cheap option for disposable water purification devices.

299 e EPADs provide a portable, inexpensive, and disposable way of measuring concentrations of electrolyt

300 posed adhesive electrode is easy to prepare, disposable, within non-restrictive nature, which allows