ライフサイエンスコーパス: biosensor

1 e a 30 fold chemiluminescent read-out of the biosensor.

2 generate an L-lysine insensitive LysG-based biosensor.

3 r as the carrier to prepare this paper strip biosensor.

4 veloped GLU and reagent-free GABA shank-type biosensor.

5 rporating a gold nanorod-locked nucleic acid biosensor.

6 nce/activation screen integrated with an ATP biosensor.

7 e Phantom Interface (RPI) label-free optical biosensor.

8 lopment of novel electrochemical sensors and biosensors.

9 dates for engineering and miniaturization of biosensors.

10 of the advanced multifunctional sensors and biosensors.

11 arameter often overlooked in electrochemical biosensors.

12 njugates are the most commonly used ones for biosensors.

13 engineering of in vitro pathology-sensitive biosensors.

14 nic electronic analog filtering elements for biosensors.

15 few limitations of traditional and emerging biosensors.

16 nomaterials provide excellent properties for biosensors.

17 y electrochemical, optical and piezoelectric biosensors.

18 xed biosensor systems, and iv) bioelectronic biosensors.

19 ucibility, accuracy, and stability in modern biosensors.

20 y to produce stable, specific, and sensitive biosensors.

21 ew era in the design of robust and sensitive biosensors.

22 velopment of a range of advanced all-polymer biosensors.

23 ecognition elements to create a new class of biosensors.

24 merging field of printed organic sensors and biosensors.

25 Three categories of affinity-based biosensors (ABBs) have been developed, depending on thei

26 The biosensor achieved a limit of detection (LOD) of 14 CFU/

27 The biosensor achieved an effective response to DNA concentr

28 oncept for a paradigm of microbially-derived biosensors adaptable to inexpensive, real-time sensor de

29 Field-effect transistor (FET)-based biosensors allow label-free detection of biomolecules by

30 In addition, the biosensor allows performing the determination of the ant

31 The modified biosensor also offered its credibility towards detection

32 ensor, surface plasmon resonance (SPR)-based biosensor and artificial intelligence (AI) assisted diag

33 ges to be overcome in developing a PGM-based biosensor and bring it to market.

34 virus reaction in the design process of the biosensor and enhances our preparation for any future ou

35 The proposed biosensor and method of native kinetic registration can

36 Utilizing our new biosensor and procedures, we demonstrate the first selec

37 ndscape of an engineered fluorescent glucose biosensor and showed that its features could be modeled

38 ted to a multivalent interaction between the biosensor and the heximeric form of UlaG.

39 The incorporation of the single cell biosensor and transient gene knockdown into the system r

40 Finally, we outline our recommendations on biosensors and biosensing-related issues towards pandemi

41 , on the use of pH sensors as transducers in biosensors and chemical sensors, and their integration i

42 New biosensors and live imaging in zebrafish revealed that n

43 ative determination of CTCs by aptamer-based biosensors and nanobiosensors.

44 ective on the future of bioelectronics-based biosensors and systems.

45 the time limitation of permanently implanted biosensors and that the biosensors detect relevant chang

46 vations of aptamer-functionalized MOFs-based biosensors and their bio-applications.

47 antum yield, genetically encoded fluorescent biosensor, and a data analysis framework to quantify the

48 g delivery systems, tumor detection markers, biosensors, and other biomaterial-based devices.

49 healing, tissue regeneration, drug delivery, biosensors, and other high-tech applications.

50 istor (FET) is a very promising platform for biosensor applications due to its magnificent properties

51 form for simple and low-cost electrochemical biosensor applications.

52 idering that a wide range of electrochemical biosensor architectures rely on this signaling mechanism

53 the advantages and drawbacks of each type of biosensor are highlighted, discussed, and compared to tr

54 The developed biosensors are capable of assaying five different types

55 llenges and future perspectives of 1D/2D-FET biosensors are covered.

56 Solid-phase, single-step biosensors are crucial for the development of portable,

57 Nanoparticle-based biosensors are essential for the early detection of dise

58 Paper-based DNA biosensors are powerful tools in point-of-care diagnosti

59 rster Resonance Energy Transfer (FRET)-based biosensors are powerful tools to illuminate spatiotempor

60 dditionally, our plasmonic nanoantenna-based biosensors are regenerative, allowing multiple measureme

61 se the development of wt or 29E4 PpDyP based biosensor as a valuable alternative to devices that rely

62 tidic acid enables this lipid to act as a pH biosensor as changes in its protonation state with intra

63 gnificant improvements on multiple green-red biosensors as a FRET acceptor and is an efficient FRET d

64 tive testing and the development of emerging biosensors as point-of-care tests.

65 The roles of biosensors as powerful analytical tools are emphasized f

66 Cellular biosensor assays are increasingly used in human tissue t

67 e report a cost-effective, simple and robust biosensor based on localized surface plasmon resonance a

68 In this work, a field-effect transistor biosensor based on molybdenum disulfide/graphene (MoS(2)

69 eloped a localized surface plasmon resonance biosensor based on succinimidyl-ester-functionalized gol

70 approach taken allows flexible design of new biosensors based on inherently stable protein scaffolds

71 luorescence resonance energy transfer (FRET) biosensor-based assay, a variety of photopharmacological

72 Biosensor-based strategies have emerged as potential alt

73 AuNPs is a key-step to build up a sensitive biosensor, but an ideal coverage requires to be perfectl

74 ort the novel concept of a microalgae living biosensor by enhancing photocurrent through nanocavities

75 r Resonance Energy Transfer (FRET)-based ERK biosensors by creating a series of improved biosensors t

76 This biosensor can be used to isolate L-histidine-producing s

77 We show that these biosensors can be used to monitor equilibrium binding of

78 ment, which reduce the range of input values biosensors can measure accurately.

79 This causes problems when the biosensor cannot be easily replaced (e.g., implanted ele

80 volved the fabrication of a tyrosinase-based biosensor capable of determining catechol in natural wat

81 he platform was demonstrated by constructing biosensors capable of detecting common POC targets, incl

82 pt, a rapid assay consisting of a cell-based biosensor (CBB) panel of pure bacterial strains, a fluor

83 mercially available but an user-friendly ATP biosensor characterized by low-cost, portability, and ad

84 Evaluation of dual biosensor chip in untreated serum samples indicated favo

85 Biosensor coatings were based on our previously develope

86 Resonance Energy Transfer (FRET)-based cGMP biosensor combined with scanning ion conductance microsc

87 energy transfer (FRET) to detect changes in biosensor conformation that accompany the targeted cell

88 al-clad leaky waveguide (MCLW) is an optical biosensor consisting of a metal layer and a low index wa

89 The biosensor, consists of two gold microelectrodes on a gla

90 Label-free affinity electrochemical biosensors constructed with semiconductor manufacturing

91 Since the discovery of biosensor, continuous efforts are being made to design a

92 Biosensors contribute a lot to the reliable and sensitiv

93 In addition, the developed biosensor could be a simple and economically cheap platf

94 Hence this dual aptamer-based impedimetric biosensor could be used as a minimally invasive method f

95 rster resonance energy transfer (FRET) based biosensor deemed BioSTING.

96 torade(R), Red bull(R) and Pepsi(R) with the biosensor demonstrated excellent agreement with those re

97 We first review the basis of biosensor design and remark on recent technologies that

98 Emerging areas of electrochemical biosensor design are reviewed, including electrode modif

99 an overview of ongoing efforts in microbial biosensor design, highlight translational opportunities,

100 ermanently implanted biosensors and that the biosensors detect relevant changes in GLU and GABA level

101 The biosensor detected SDE1 biomarkers for citrus greening i

102 Biosensor development exploiting various transduction pr

103 on of suitable platforms for drug testing or biosensor development.

104 on recent technologies that are accelerating biosensor development.

105 ytical application of MWCNTs-Av platform for biosensors development.

106 ntly, by targeting only the EBD, the evolved biosensors display DNA-binding affinities similar to Ben

107 As-prepared PEC biosensor displayed superb performance for the detection

108 electrodes in the realisation of sensors and biosensors (e.g. enzymatic, immunosensors, and DNA-based

109 ing rat over fourteen weeks, inserting fresh biosensors each time, thus demonstrating that the microw

110 s a key application in many disciplines, and biosensors emerged as powerful analytic tools for use in

111 tabolic pathway designs, and high-throughput biosensor-enabled screening for training diverse machine

112 Thus, our FRET-based nanoparticle biosensor enables detection of nucleic acid targets usin

113 Here, we developed a bicistronic biosensor encoding distinct repeat epitopes in two open

114 paB binding sequence for bioluminescence and biosensor evaluation.

115 The biosensor exerted high sensitivity, fast response, and g

116 The proposed biosensor exhibited high selectivity, sensitivity, and g

117 zymes without significant activity loss, the biosensors exhibited high stability over a period of sev

118 The biosensor exhibits excellent peak potential difference (

119 The biosensor exploits three coupled enzymatic reactions cat

120 rface enhanced Raman scattering (SERS)-based biosensor, field-effect transistor (FET)-based biosensor

121 A biosensor for androstenone was fabricated using a Meldol

122 molecule for the development of a sensitive biosensor for bacteria detection is reported: nisin mole

123 However, there is no existing electrical biosensor for detecting biomarkers for AIV in clinically

124 chemiluminescence (CL) foldable paper-based biosensor for detection of AChE inhibitors.

125 ification strategy for achieving a sensitive biosensor for DNA detection and diagnostic applications.

126 providing a way to develop a potentiometric biosensor for glucose.

127 n (DE) are studied aiming at the design of a biosensor for H(2)O(2) detection.

128 or the fabrication of a Bio-Nano-PEDOT-based biosensor for lactate detection which had a response tim

129 a nanotechnology-assisted LC materials-based biosensor for rapid, cost-effective, selective diagnosti

130 munity with the ability to design a specific biosensor for requested point-of-care (POC) applications

131 Here, we report a biosensor for specifically visualizing active conformati

132 lly grown on sapphire, to develop an optical biosensor for the breast cancer biomarker miRNA21.

133 ctrodes were then used as an immunoenzymatic biosensor for the detection of HT-2 mycotoxin based on c

134 ation-boosted, translational electrochemical biosensor for the detection of pancreatic cancer-associa

135 Moreover, the developed biosensor for the detection of Tpm demonstrated excellen

136 highly sensitive label-free electrochemical biosensor for the detection of Tpm in seafood samples.

137 successfully developed a PNE-based imprinted biosensor for the early detection of Troponin I, a cruci

138 Using FRET-force biosensors for E-cadherin, we observed significant incre

139 ding optical, electrochemical and electrical biosensors for exosomes detection in the field of cancer

140 s and discussing their interest in designing biosensors for improved analytes detection.

141 an be utilized to construct high-performance biosensors for numerous applications ranging from medica

142 Electrochemical biosensors for pathogen detection are broadly reviewed i

143 for the development of real-time electrical biosensors for studying and understanding different stag

144 But biosensors for the continuous real-time monitoring of an

145 omaterials-based electrochemical sensors and biosensors for the detection and quantification of six c

146 Applications of electrochemical biosensors for the detection of pathogens in food and wa

147 nomaterial-based electrochemical sensors and biosensors for the detection of pharmaceutical compounds

148 ble method for generating near-ideal aptamer biosensors for various analytical applications, includin

149 luorescence-resonance-energy-transfer (FRET) biosensor (FynSensor) that reveals cellular Fyn activity

150 surface plasmon resonance (SPR) enhanced DNA biosensor has been developed for real-time detection of

151 free, and ultrasensitive electrochemical DNA biosensor has been developed, based on "urchinlike" carb

152 The analytical performance of fabricated biosensor has been evaluated using EIS, where linear dyn

153 The laccase-based biosensor has been tested for phenolic compound detectio

154 The development of wearable multiplexed biosensors has been focused on systems to measure sweat

155 Their application as genetically encoded biosensors has the potential to contribute to diagnostic

156 260, 292, and 342 mV) of the constructed MFC biosensor have a linear relationship with Zn(2+) concent

157 DNA-based biosensors have been largely applied in this direction,

158 Biosensors have shown a great potential in overcoming th

159 The designed biosensor hereby, evolves as a promising approach for th

160 Live cell Forster resonance energy transfer biosensor imaging of cultured myocytes revealed that Ca(

161 Intravital biosensor imaging showed that wound peroxide and arachid

162 yl hydrocarbon receptor (AHR) functions as a biosensor in intestinal neural circuits, linking their f

163 scent Protein (GFP) to construct a novel SDS biosensor in Pseudomonas aeruginosa chassis.

164 e them some of the most common point of care biosensors in a variety of fields.

165 st reported library of metabolite-responsive biosensors in an automated high-throughput screen.

166 es of adipose tissue were analysed using the biosensors in conjunction with chronoamperometry.

167 tants was validated using G protein activity biosensors in mammalian cells.

168 ty was further validated by implementing the biosensors in multiple contexts, from characterizing can

169 In addition, the progress in the 1D/2D-FET biosensors in North America, in the last decade, is summ

170 ing Foerster resonance energy transfer-based biosensors in patch clamp experiments, we discovered a r

171 We review fluorescent single-molecule biosensors in the second part, highlighting nanoparticle

172 approach for analyzing interaction data from biosensors instruments is based on the simplified assump

173 The biosensor is based on the spectral-correlation interfero

174 A multiplex label-free biosensor is developed for diagnostics of autoimmune dis

175 ue to the simplicity and rapidness, the SERS biosensor is expected to become a promising tool for cli

176 The proposed immuno-biosensor is highly selective and quantitative and can e

177 This biosensor is highly specific for SDS and has minimal int

178 A Love-wave based biosensor is introduced for analyzing a standardized wou

179 disorder; thus, a fast, simple and reliable biosensor is needed to routinely determine the UA concen

180 design parameters on the performance of the biosensor is presented.

181 A key requirement of such a biosensor is the simple and direct functionalization wit

182 The utility of these biosensors is diminished by empirical errors in fluoresc

183 tures, the new generation of SPR-intelligent biosensors is qualifying to perform automated testing.

184 ese major developments, the field of glucose biosensors is still facing major challenges.

185 idual's health state, the design of wearable biosensors is subject to critical challenges, such as hi

186 rol electronics to test this impedance-based biosensor, it was found that the capacitive nature of bl

187 blem by introducing a lateral flow plasmonic biosensor (LFPB) based on gold-viral biomineralized nano

188 Furthermore, fully-printed biosensors made with a tyrosinase-containing ink were us

189 The biosensor measures impedance in terms of magnitude and p

190 histological, mass spectrometry imaging, and biosensor-mediated measures of glutamate were conducted

191 tivated phosphodiesterase LAPD, and the cAMP biosensor mlCNBD-FRET to the cilium.

192 test a fibronectin (FN)-based nanomechanical biosensor (NMBS) that can be applied to the surface of c

193 del using autologous CD8(+) T cell clones as biosensors of antigen presentation, neither HDACi-treate

194 ntials of LC materials properties to develop biosensors of desired performance.

195 dress this, we used genetically encoded FRET biosensors of molecular tension in a nesprin protein of

196 The novel electrochemical biosensor offered a detection limit of 0.26 pM, with a n

197 installation position and properties of the biosensor on its performance were investigated in 11 cas

198 ble personal devices are producing data from biosensors on an unprecedented scale.

199 by a two-step validation protocol: with the biosensor operating off- and on-bodily, correlating the

200 opment of portable, reusable, and convenient biosensors, otherwise known as point-of-care (POC) testi

201 time, thus demonstrating that the microwire biosensor overcomes the time limitation of permanently i

202 ts using the genetically encoded fluorescent biosensor Peredox-mCherry.

203 on elements, electrochemical techniques, and biosensor performance.

204 urement, photons or electrons, yields better biosensor performance.

205 Here, we developed the first biosensor platform for rapid detection of otolin-1 and p

206 Then, we show in a pilot study that the biosensor platform successfully discriminates histopatho

207 The glucose biosensor presents a linear range of response within the

208 itionally used supporting substrate-based 2D biosensors produces a scattering effect, which leads to

209 scarcely explored so far in electrochemical biosensors, provides high sensitivities for a synthetic

210 Many genetically encoded biosensors rely on the measurement of Forster resonance

211 Label free biosensors relying on electrochemical, mechanical, and m

212 at the point-of-care have been one focus of biosensor research for several years now with a number o

213 Results show the biosensor responds to changes in Ca(2+) concentration wi

214 Recently, they have also been used in biosensors, resulting in enhanced sensitivity and simple

215 The biosensor's performance in tap water proves that its det

216 Properties of the biosensor, sample, buffer fluid and even the microfluidi

217 The multiplexed biosensor showed a limit of detection of 0.26 IU/mL (624

218 The GFP intensity of the biosensor showed a linear relationship (R(2) = 0.99) fro

219 The biosensor showed a satisfactory and reproducible recover

220 The biosensor showed detection limit of 1.6 ng . mL(-1) and

221 The developed biosensor showed high selectivity towards ALP with negli

222 The CL foldable paper-based biosensor showed suitable for the rapid detection of OP

223 Finally, the biosensors showed a fast response time, with an average

224 vious studies with various Src family kinase biosensors showed that the nuclear kinase activities are

225 eus upon light activation and upregulate the biosensor signals in the nucleus.

226 two decades has been devoted to engineering biosensors specific for ions, nucleotides, amino acids,

227 Specially, potential electrochemical (EC) biosensor, surface enhanced Raman scattering (SERS)-base

228 osensor, field-effect transistor (FET)-based biosensor, surface plasmon resonance (SPR)-based biosens

229 The multiplex biosensor system with on-demand panel composition can be

230 s, ii) responsive polymers, iii) multiplexed biosensor systems, and iv) bioelectronic biosensors.

231 ide chain length are chosen to construct two biosensor systems, observing their fluorescence enhancem

232 Compact multiplexed biosensors systems hold great potential for diagnosis of

233 biosensors by creating a series of improved biosensors targeted to various subcellular regions via s

234 s, great effort has gone into developing new biosensor technologies for applications in different fie

235 ntial for the development of electrochemical biosensors thanks to their electronic properties, porous

236 y, ready-to-use and stable ATP sensing paper biosensor that can be combined with smartphone detection

237 reports a sensitive and selective label-free biosensor that combines the physical and chemical advant

238 Here, we present a transistor-based biosensor that detects the net charge of tau protein dir

239 me this challenge, based on GPCR-interacting biosensors that are disconnected from endogenous transdu

240 lternative for the generation of multiplexed biosensors that can detect both protein and nucleic acid

241 on developing novel wearable electrochemical biosensors that can noninvasively and continuously scree

242 Medical interventions increasingly rely on biosensors that can provide reliable quantitative inform

243 Biosensors that continuously measure circulating biomole

244 Here, we developed fluorescence-based biosensors that detect WNT-induced FZD conformational ch

245 to realise the concept of all-polymer-based biosensors that do not depend on traditional nanocatalys

246 lly encodable fluorescent and bioluminescent biosensors that have led to scientific or technological

247 Aptasensors are biosensors that include aptamers for detecting a target

248 es enzyme-mediator pairs used in traditional biosensors thus, offering enhanced molecular recognition

249 de is universal and may be applied for other biosensors, thus open possibilities for the new generati

250 dering complex, biocompatible constructs for biosensors, tissue and regenerative engineering and bioe

251 al for wide application as a high-throughput biosensor to analyze pathogens in clinical, food, and en

252 chemical responses after the exposure of the biosensor to different bacteria.

253 It is challenging to tune the response of biosensors to a set of ligands, for example, cross-react

254 ence lifetime imaging (2pFLIM) with new FRET biosensors to chronically image in vivo signaling of CRE

255 and Forster resonance energy transfer (FRET) biosensors to monitor the changes in Ran and importin be

256 Finally, we use these novel biosensors to observe ATR release from an activated, unl

257 This is potentially useful for developing biosensors to quantify microRNAs in clinical samples and

258 This allows cell based biosensors to respond more rapidly and sensitively to lo

259 antify the signals from different FRET-based biosensors to simultaneously measure changes in the acti

260 environmental monitoring applications, from biosensors to therapeutic treatment agents, their toxici

261 ly, it focuses on newly emerged enhanced SPR biosensors towards high-throughput and ultrasensitive sc

262 Electrochemical biosensors transduce biochemical events (e.g., DNA hybri

263 We developed a miniaturized optoelectronic biosensor using a vertical cavity surface-emitting laser

264 quences were amplified and identified by the biosensor using specific DNA probes.

265 e limit of detection for our electrochemical biosensor was 0.8 pg/mL for SARS-CoV-2, indicating very

266 The biosensor was applied for detection of three species, na

267 rimental parameters by factorial design, the biosensor was applied to the voltammetric determination

268 The biosensor was applied to wastewater with different Zn(2+

269 The biosensor was characterized by electrochemical impedance

270 This biosensor was designed based on interaction of poly clon

271 A novel amperometric algae-based biosensor was developed for the detection of photosynthe

272 A novel, low-cost, and portable paper strip biosensor was developed for the detection of tetracyclin

273 Finally, validation of the proposed biosensor was evaluated by spiked wheat samples and aver

274 n the obtained results, the linearity of the biosensor was found between 5 and 400 ng/mL, and the det

275 A nanostructured electrochemical DNA-based biosensor was prepared using a commercial electrode asse

276 Moreover, the biosensor was successfully applied for the detection of

277 ntually, as a proof of concept, the designed biosensor was successfully used for detection of donkey

278 This suggests that the paper strip biosensor was suitable for detecting both tetracycline a

279 The paper strip biosensor was suitable for tetracycline concentrations i

280 The proposed biosensor was tested for the detection of thrombin molec

281 r an introduction to electrochemical glucose biosensors, we highlight recent progress based on using

282 The results obtained with developed MFC biosensor were comparable to conventional methods such a

283 The biosensors were developed by using commercial graphene o

284 In addition, the microwire biosensors were in the same geometric plane for the impr

285 efficiency, we employ a one-step FRET-based biosensor which monitors the single cancer cells' protea

286 This biosensor, which combines the synergistic properties of

287 ment of surface acoustic wave (SAW) flexible biosensors, which are highly reproducible, reliable and

288 ers in their future work of developing smart biosensors, which can further improve detection sensitiv

289 llowing multiple measurements using the same biosensors, which is essential in low- and middle-income

290 In summary, MFC biosensor with biosynthetic strain is an efficient and a

291 ough the use of a unique linker, producing a biosensor with exceptional reproducibility, impressive a

292 arker for heart failure, by coupling the MIP biosensor with surface plasmon resonance (SPR) detection

293 Furthermore, the integration of biosensors with different devices for accelerating the p

294 We calibrate paper-based EIS biosensors with different morphologies of ZnO NWs and ac

295 The integration of plasmonic biosensors with established and upcoming technologies of

296 Hybrid integration of such biosensors with extremely well-established silicon-based

297 , efficient and highly selective LRSPR based biosensors with SiO(2) as tunable dielectric layer.

298 This design was leveraged to generate biosensors with specificity for different heterotrimeric

299 Recently, electrochemical biosensors with the integration of nanomaterials have em

300 ity for the development of new host-agnostic biosensors with user-defined small-molecule specificitie

301 phenolic traces by HRP-based electrochemical biosensors, yet in a more straightforward and sensitive