ライフサイエンスコーパス: biosensing

1 e roles of carbon nanotubes in optical-based biosensing.

2 s including nanomaterials, drug delivery and biosensing.

3 nomous sensor functionalization and enhanced biosensing.

4 ative electrochemical peptide-based protease biosensing.

5 y prevent aluminum plasmonics from real-life biosensing.

6 ules or whole cells for use in point of care biosensing.

7 bio recognition events, resulting in precise biosensing.

8 retain cell phones' ubiquity for distributed biosensing.

9 vapour deposition limits its application in biosensing.

10 s for affordable, user-friendly and portable biosensing.

11 n localized surface plasmon resonance (LSPR) biosensing.

12 infrared (UV-vis-NIR) plasmon resonances for biosensing.

13 oarrays for rapid and multiplexed label-free biosensing.

14 ructures is demonstrated to be effective for biosensing.

15 nanorods (GNRs) is attractive for label-free biosensing.

16 otein biochip development in the era of nano-biosensing.

17 ring biomolecule for on-chip electrochemical biosensing.

18 m DNA computing to signal amplifications for biosensing.

19 d analytical devices and the single-molecule biosensing.

20 introduces a conceptually new perspective in biosensing.

21 be elite and offered amazing electrochemical biosensing.

22 atform for high-sensitive label-free optical biosensing.

23 films, allowing for further applications in biosensing.

24 sis, electronics, nanomaterial synthesis and biosensing.

25 ause disruptive improvements in the field of biosensing.

26 for real-time, accurate, and high throughput biosensing.

27 e it ideally suited for applications such as biosensing.

28 th special interest on in situ catalysts and biosensing.

29 ransducing components critical for efficient biosensing.

30 raphene-enzyme electrode for electrochemical biosensing.

31 , in vivo, and point-of-care electrochemical biosensing.

32 icator species for enzymatic, immune and DNA biosensing.

33 cluding cavity quantum electrodynamics(1-3), biosensing(4), microfludics(5), and cavity optomechanics

34 In ICR biosensing, a nanopore coated with an analyte specific b

35 nerated by a short rinsing step for multiple biosensing analyses.

36 tes of improved electron transfer in various biosensing and bioelectronics devices.

37 n nanotube sorting, controlled assembly, and biosensing and bioimaging applications.

38 n their vesicular shell makes ultrasensitive biosensing and bioimaging possible.

39 zed quantum dots have been widely applied in biosensing and bioimaging.

40 s, such as protein-protein interactions, for biosensing and biotechnological applications.

41 he over 3-decade-long progress on transistor biosensing and develop the holistic assay platform and p

42 likely be at the forefront of development in biosensing and imaging fields in the foreseeable future.

43 tosensitizers, in light-emitting diodes, for biosensing and in photocatalysis.

44 nd optimize MPI drive waveforms for in vitro biosensing and in vivo imaging with MPI.

45 lications for enhanced materials templating, biosensing and investigating lipid-membrane processes.

46 to harness the upconversion enhancement for biosensing and light harvesting applications.

47 metry has empowered an impressive variety of biosensing and medical imaging techniques.

48 e engaging cognitive training with real-time biosensing and neurostimulation have the potential to op

49 romising applications in areas as diverse as biosensing and photocatalysis.

50 asmonics and surface plasmon resonance (SPR) biosensing and probes distinctive colloidal properties o

51 y applicable to other bioconjugated systems, biosensing and related bioanalytical applications.

52 malism is articulated before examining their biosensing and related ET utility.

53 x sensing-logic, may lead to tools for novel biosensing and targeted-delivery applications.

54 n of wearable and implantable nanodevices in biosensing and thermotherapic treatments where thermal d

55 ene is especially involved in drug delivery, biosensing and tissue engineering, with strong contribut

56 rapy, radiation therapy, drug/gene delivery, biosensing, and bioimaging.

57 -have become powerful tools in chemical- and biosensing, and have achieved notable success in portabl

58 s (1997) on the use of PS interferometer for biosensing, and lowers of 4 orders of magnitude DL attai

59 medical applications such as: drug delivery, biosensing, and synthetic nanopore formation.

60 mmunosensor strongly improves sensitivity in biosensing, and therefore can be considered as a very pr

61 s with non-invasive diagnostic capabilities, biosensing, and tissue engineering.

62 receiving growing interest for their use in biosensing applications based on such unique properties

63 sterone aptamers can be exploited in further biosensing applications for environmental, clinical, and

64 use of mobile phones and similar devices for biosensing applications in which diagnostics and communi

65 roducibility, making it well suited for many biosensing applications including noninvasive diagnostic

66 In addition, we briefly present the biosensing applications of these 2D-GAs for the detectio

67 inescence has been widely used for important biosensing applications such as the measurement of adeno

68 ich confers significant potential for future biosensing applications where detection of low quantitie

69 d as electrode for enzyme immobilization and biosensing applications without suffering any influences

70 ggering variety of lab-on-a-chip systems for biosensing applications, are presented, tabularized for

71 In spite of being widely used for in liquid biosensing applications, sensitivity improvement of conv

72 als have been increasingly incorporated into biosensing applications, with various nanostructures hav

73 unctionalized transition metal nanosheets in biosensing applications.

74 ry promising platform for fast and efficient biosensing applications.

75 gaps and similar devices for single molecule biosensing applications.

76 e practical usage of graphene in sensing and biosensing applications.

77 for proof-of-concept studies of perspective biosensing applications.

78 materials are thus an appealing platform for biosensing applications.

79 uctor nanostructures for ultrasensitive SERS biosensing applications.

80 ming defects and as synthetic inclusions for biosensing applications.

81 tegrity, offering numerous opportunities for biosensing applications.

82 ractive for Point-of-Care or On-Site-Testing biosensing applications.

83 ced Graphene-Oxide (rGO) based FETs used for biosensing applications.

84 blems that have rendered ECA ineffective for biosensing applications.

85 photonics, optical data storage devices and biosensing applications.

86 construction of the novel biointerfaces for biosensing applications.

87 A novel label-free biosensing approach based on bioreceptor networks patter

88 Here, we employ a label-free biosensing approach based on simultaneous quartz crystal

89 This unconventional biosensing approach involves measuring the change in sam

90 Biosensing approach overcomes these disadvantages, as th

91 Recent advanced developments in biosensing approaches for cancer biomarker owes much cre

92 A wide coverage of recent biosensing approaches involving aptamers, enzymes, DNA p

93 ances (PSLR), are not always compatible with biosensing arrangement implying the placement of the nan

94 ghlight current challenges in all-electrical biosensing as these systems shrink toward the nanoscale

95 approach to develop label-free platforms for biosensing as well as to overcome eventual leakage curre

96 ells, implying its potential applications in biosensing, as well as in cancer diagnosis.

97 iring rules are also being widely applied in biosensing based on their excellent recognition capabili

98 we report the first proof-of-concept of dual biosensing based on this bulk ECL method for the simulta

99 cial role in imaging and display technology, biosensing, beam shaping, optical switching, wavefront-a

100 he biomedical applications of YSNs including biosensing, bioimaging, drug/gene delivery, and cancer t

101 lications in the fields of chemical sensing, biosensing, bioimaging, nanomedicine, photocatalysis and

102 immobilized enzymes underpins development of biosensing, bioprocessing, and analytical chemistry tool

103 only provides a facile approach for in vitro biosensing, but also shed a light on the real-time detec

104 Thus, DNA methylation biosensing can help in the better understanding of cance

105 exemplar, we use the strategy to enhance the biosensing capabilities of a chiral plasmonic substrate.

106 report the first assessment of the plasmonic biosensing capabilities of capping agent-free gold nanos

107 ca coating was found to be only 16%, and the biosensing capabilities of the substrates were assessed

108 capacity to accommodate chemical sensing and biosensing capabilities.

109 ines two orthogonal analysis techniques: the biosensing capability of SPR and the chemical identifica

110 Finally, to assess the label-free biosensing capability of the new sensor, we have evaluat

111 , we first transformed the GNR's multiplexed biosensing capability to a robust chip-based format.

112 Such new biosensing capability will be important for distributed

113 other devices will allow us to integrate the biosensing capability with probe control, data acquisiti

114 ield of biomedical engineering, particularly biosensing, cell and tissue engineering, actuators, and

115 In this work, we introduce a label-free biosensing chip made of glass with a single anti-reflect

116 c materials with current front runners being biosensing, chiral catalysis, and chiral photonics.

117 ensing mechanism, a new and highly sensitive biosensing concept by the use of SH-beta-CD-Gr/AuNPs as

118 In this study, a multiplex cadmium biosensing construct was assembled by cloning a single-o

119 work, describes for the first time, a simple biosensing design to yield an ultrasensitive electrochem

120 on elements improving the performance of the biosensing device.

121 erene explain its outstanding performance in biosensing devices as a mediator, e.g. fullerene in orga

122 Incorporation of nanomaterials in biosensing devices has found to improve the electroactiv

123 A new approach to biosensing devices is demonstrated aiming an easier and

124 ors, enzymatic biosensors, the most explored biosensing devices, have an interesting property, the in

125 nherent attributes offered by the label-free biosensing devices.

126 is potentially useful for the development of biosensing devices.

127 blies, such as DNA origamis, hold promise in biosensing, drug delivery, nanoelectronic circuits, and

128 hich has gained a great deal of interest for biosensing due to its sensitivity, selectivity, and mult

129 (QDs) have been widely used in chemical and biosensing due to their unique photoelectrical propertie

130 study of the self-assembly dynamics and the biosensing efficacy of Tobacco mosaic virus-like particl

131 ncentration can be performed directly at the biosensing electrodes.

132 sta BKM Y-2559 cells were then employed as a biosensing element for the detection of methanol.

133 Three of the most versatile biosensing elements are antibody single-chain Fv fragmen

134 The choice of biosensing elements is crucial for the development of th

135 PK/ERK1&2 crosstalk by using multi-parameter biosensing experiments to correlate biochemical activiti

136 Field Effect Biosensing (FEB) with monoclonal antibodies covalently l

137 developments in the microfluidic-integrated biosensing field by delineating the fundamental theory o

138 als or nanostructures towards ultrasensitive biosensing for disease markers or pathogens is of high i

139 These results opens clearly novel avenues in biosensing for fast screening diagnostics, decentralized

140 t further expand the utility of lateral flow biosensing for point-of-care applications.

141 encapsulation, drug delivery, catalysis and biosensing.Functional nanoscale objects can be prepared

142 mise that FeS-based bioanodes are capable of biosensing glycerol successfully and may be applicable f

143 n of optical components for high-performance biosensing has not yet been demonstrated.

144 d localized surface plasmon resonance (LSPR) biosensing have been created by DNA-directed immobilizat

145 The enzyme integrated and RGO supported biosensing hybrid systems show high stability, excellent

146 of self-assembled smart nanosystems used in biosensing, imaging, controlled release and other applic

147 ovides a generalized platform for SERS-based biosensing in complex real-world media.

148 dated methodology for multiparametric kinase biosensing in living cells using FRET-FLIM.

149 tes the potential of SMLM for characterising biosensing interfaces and as the transducer in a massive

150 Here self-referenced biosensing is demonstrated with the detection of Neutrav

151 hese films in surface plasmon resonance-type biosensing is described, where they provide specific adv

152 erior to, previously reported devices in the biosensing literature.

153 etic DNA target sequences and applied to DNA biosensing, lowering 610-fold the detection limit from 6

154 es insight into the nanopore engineering for biosensing, making aerolysin applicable in genetic and e

155 The nanohybrid biosensing materials can be combined with screen-printed

156 r and flexible polyester films as diagnostic biosensing materials with various detection modalities t

157 ere significantly expands the utility of ICR biosensing measurements for detecting low-abundance biom

158 Of late, ion current rectification (ICR) biosensing measurements have received a great deal of at

159 s and building blocks for bionanotechnology, biosensing, memory devices and the synthesis of material

160 rated in this study, we expect that the LSPR biosensing method can be applied to label-free detection

161 we demonstrate a novel electrokinetic liquid biosensing method for the sensitive label-free detection

162 of carbon nanotube (CNT)-based impedimetric biosensing method has been developed for rapid and selec

163 The thermophoresis-based biosensing method is found to be simple and effective fo

164 The biosensing method was based on the measurement of proteo

165 Novel biosensing methodologies offer highly specialised monito

166 In addition, the nonlinear HCR based SPR biosensing methodology is extended to the detection of a

167 While current biosensing methods are capable of sensitively detecting

168 Label-free biosensing methods are very effective for studying cell

169 Biosensing methods for a plenty of cancer biomarkers has

170 Biosensing methods overcome these drawbacks, as these ar

171 have updated the literature concerning novel biosensing methods such as various optical and electroch

172 e artifacts limiting the use of conventional biosensing methods, such as fluorescent indicators.

173 Advancing biosensing nanotechnologies in chemically "noisy" bioenv

174 n in organic transistors has led to enhanced biosensing, neuromorphic function, and specialized circu

175 Biosensing nitrogenous compounds like urea is required t

176 Supramolecular nanoparticle hybrids for biosensing of analytes have been a major focus due to th

177 ls for allergen recognition in the practical biosensing of Cry j 2, leading to preventive measures ag

178 nt trends in the electrochemical sensing and biosensing of DNA methylation.

179 A millimeter-sized tubular motor for mobile biosensing of H2O2 in environmental and relevant clinica

180 he as-synthesized composites were tested for biosensing of hydrogen peroxide (H2O2) and as supercapac

181 The MQCM is applied for multi-analyte biosensing of IgG and HSA.

182 m nanocauliflower for use in electrochemical biosensing of small molecules (glucose) or detection of

183 Biosensing of these parameters represents an important t

184 finity protein-protein interactions, such as biosensing or calorimetry, the high size resolution of c

185 Lastly, biosensing performances of printed or printable graphene

186 Here we report a biosensing platform based on Electrochemical Impedance S

187 A novel biosensing platform based on fractal-pattern of iron oxi

188 y responsive aptasensor, the newly developed biosensing platform exhibits synergistic effect of the n

189 The biosensing platform facilitated charge transfer through

190 ensor can be further developed as a low-cost biosensing platform for detection of small molecule biom

191 a non-invasive, label-free and an efficient biosensing platform for detection of the oral cancer bio

192 developed nanocomposite offers an excellent biosensing platform for rapid, sensitive and selective d

193 We present a biosensing platform for the detection of proteins based

194 , which provides a universal electrochemical biosensing platform for the ultrasensitive detection of

195 We report a biosensing platform for viral load measurement through e

196 logical investigations of the ZrO2-RGO based biosensing platform have been accomplished using X-ray d

197 The biosensing platform involves immobilization of a 40-mer

198 In this work, a Love wave biosensing platform is described for detecting cancer-re

199 A dry-reagent immunomagnetic (DRIM) biosensing platform is developed for rapid high-precisio

200 A novel cell-based biosensing platform is developed using a combination of

201 The salient feature of this biosensing platform is that one step calcination process

202 The versatility of the biosensing platform makes it easily adaptable for quanti

203 study of the different steps involved in the biosensing platform preparation (DNPs/Au and GOx/DNPs/Au

204 Thus, the smartphone-based biosensing platform provided a convenient and efficient

205 Furthermore, this biosensing platform shows good anti-interference ability

206 y, a pAAO-based biosensor was developed as a biosensing platform to detect proteinase K, an enzyme wh

207 ate the ability of the label-free pAAO-based biosensing platform to detect the presence of the protei

208 realize a reliable ultrasensitive electrical biosensing platform which will be able to detect multipl

209 A novel enzyme/nanoparticle-based DNA biosensing platform with dual colorimetric/electrochemic

210 e present a rapid and integrated single-cell biosensing platform, termed dropFAST, for bacterial grow

211 ELISA) onto a commercial PCB electrochemical biosensing platform, We adapted a commercially available

212 In order to develop a DNPs-based biosensing platform, we have selected glucose oxidase (G

213 opens up new routes for designing chip-type biosensing platform, which may allow for highly sensitiv

214 establishment of a low-cost and miniaturized biosensing platform.

215 cavities as a luminescence-enhancing optical biosensing platform.

216 ation of highly sensitive, flexible and thin biosensing platform.

217 oxide (RGO) for the development of versatile biosensing platform.

218 Biosensing platforms are functionalized with polymyxin B

219 est development in the design of sensing and biosensing platforms based on functional nanomaterials f

220 Use of nanomaterials offers to biosensing platforms exceptional optical, electronic and

221 sensitive, robust, portable, and inexpensive biosensing platforms is of significant interest in clini

222 MIPs have been utilized as receptors in biosensing platforms such as electrochemical, optical an

223 Biosensing platforms that combine high sensitivity, oper

224 towards continued growth of electrochemical biosensing platforms, which have fascinated the interdis

225 g various biocompatible hybrid materials and biosensing platforms.

226 bility to the fabrication of electrochemical biosensing platforms.

227 natural and engineered ICs as transducers in biosensing platforms.

228 n we provide an overview of a broad range of biosensing possibilities, from optical to electrochemica

229 lements the G-quadruplex structure-switching biosensing principle in graphene nanoelectronics.

230 rotein outer surfaces, making them selective biosensing probes with self-assembly capability on senso

231 er considerable promise for developing novel biosensing protocols involving 'on-the-fly' recognition

232 ng enzymes in a single assay using multiplex biosensing provides a multidimensional workspace to eluc

233 immobilization of biological species aiming biosensing purposes.

234 range of applications for renewable energy, biosensing, quantum optics, high-density magnetic data s

235 tein has been used as a receptor molecule in biosensing scheme.

236 screening, and can be extended to fit other biosensing schemes.

237 in light-emitting diodes (LEDs), and optical biosensing schemes.

238 re, potentially enabling new capabilities in biosensing, sequencing, and imaging.

239 molecules for highly sensitive and selective biosensing, shedding new light on cellular behaviour.

240 than state-of-the-art microneedles used for biosensing so far.

241 emical biosensors has created many ingenious biosensing strategies for applications in the areas of c

242 This biosensing strategy exhibits good reproducibility and pr

243 A label-free biosensing strategy for amoxicillin (AX) allergy diagnos

244 enzyme-free surface plasmon resonance (SPR) biosensing strategy has been developed for highly sensit

245 In this work, a biosensing strategy has been developed for simultaneous

246 Thus, this developed biosensing strategy presents a simple and stable platfor

247 Third, examples of current biosensing structures created from hybrid nanomaterials

248 elective, and highly sensitive protein based biosensing system employing the Fluorescence Resonance E

249 report for the first time a novel bi-enzyme biosensing system incorporating electrostatically intera

250 Rationally designed biosensing system supports multiplex analyses is warrant

251 crystal microbalance (QCM) is a label-free, biosensing system that has, in the past fifty years, evo

252 a simultaneous microfluidic electrochemical biosensing system to detect multiple biomarkers of pulmo

253 The developed biosensing system, which can detect AI-2 at subnanomolar

254 ensive, reliable, user-friendly, and compact biosensing systems at the POC.

255 Recently, the low-cost effective biosensing systems based on advanced nanomaterials have

256 ansition metal nanosheets and nucleic acids, biosensing systems can be easily assembled.

257 there is strong interest for developing new biosensing systems for early detection of plant diseases

258 vancement in the development of advantageous biosensing systems for plant pathogen detection based on

259 the development of innovative and sensitive biosensing systems for the detection of pathogens (i.e.

260 Many biosensing systems rely on surface plasmon resonance (SP

261 Microfluidic biosensing systems with enzyme-based detection have been

262 Among all types of biosensing systems, paper based biosensors are commercia

263 Unlike RFID-based biosensing systems, which require large proximal power s

264 steps for the advancement of electrochemical biosensing systems.

265 r the development of low costs and efficient biosensing systems.

266 les have opened new horizons, especially for biosensing, targeted delivery of therapeutics, and so fo

267 embranes and membrane proteins are important biosensing targets, motivating the development of label-

268 The iontophoretic-biosensing tattoo platform is reduced to practice by app

269 Magnetorelaxometry (MRX) is a promising new biosensing technique for point-of-care diagnostics.

270 y a demonstration of the performance of this biosensing technique in the presence of cell culture med

271 of accuracy provided by convenient methods, biosensing techniques are at the center of attention to

272 t the forefront of ultrasensitive label-free biosensing techniques, especially for point-of-care clin

273 Such a merger of microfluidics with biosensing technologies allows for the precise control o

274 ts are being made to develop electrochemical biosensing technologies for fast, accurate, selective, a

275 tection of single molecules is vital to many biosensing technologies, which require analytical platfo

276 face plasmon resonance (LRSPR) is a powerful biosensing technology due to a substantially larger prob

277 present a broadly applicable and inexpensive biosensing technology for accurate quantification of bio

278 The SiNW-on-a-chip biosensing technology paves the way to the translational

279 cement of current state-of-the-art plasmonic biosensing technology toward single molecule label-free

280 ectronic materials can solve key problems in biosensing thanks to their unique material properties an

281 ivity, portability, etc.) and to advances in biosensing, the coupling of these two technologies is en

282 plications ranging from superconductivity to biosensing, the realization of a stable and atomically t

283 luorescence lifetime microscopy (FLIM)-based biosensing to demonstrate intratumoral heterogeneity of

284 tages and disadvantages of using graphene in biosensing tools, based on screen-printed sensors.

285 ensors is essential for developing effective biosensing tools.

286 It is therefore important to develop new biosensing transducer elements for recognizing binding e

287 ore initiates the low-cost, high-performance biosensing using aluminum plasmonics, which would find w

288 suitable for on-site duplex electrochemical biosensing using drop-size sample volumes.

289 sonances in plasmonic metamaterial arrays to biosensing using standard streptavidin-biotin affinity m

290 Real-time impedance biosensing verified in vitro early, dose-dependent quant

291 E. coli strains containing gene circuits for biosensing were able to transduce the input signals from

292 oint-of-care diagnostics or cellular in vivo biosensing when using ultrathin fiber optic probes for r

293 latform for early-stage bacterial mutations, biosensing with a selective microtoroid surface was sugg

294 ng of surface plasmon resonance (SPR) immuno-biosensing with ambient ionization mass spectrometry (MS

295 f bare P3HT based EGOFET confirming reliable biosensing with bio-functional EGOFET immunosensor.

296 These new membrane devices enable duplex biosensing with distinct advantages over existing approa

297 urface-enhanced Raman spectroscopy (SERS) to biosensing, with a focus on in vivo diagnostics.

298 bor- and cost-efficient form of quantitative biosensing, with a reduced risk of operator errors.

299 Biosensing within complex biological samples requires a

300 ve to deliver nanotechnological solutions to biosensing, yet there remains an unmet need in the devel