ライフサイエンスコーパス: magnetic particle

1 occur inside the matrix of a hydrogel-coated magnetic particle.

2 mentation supernatant onto a nickel-modified magnetic particle.

3 s are attached to carboxylated dextran-based magnetic particles.

4 ween cell-membrane adherent and phagocytosed magnetic particles.

5 s and eliminates cells that are not bound to magnetic particles.

6 bilized on the initial tosylated polystyrene magnetic particles.

7 be deflected to a larger extent than single magnetic particles.

8 irection of laminar flow than the 2.0-microm magnetic particles.

9 need to immobilize them or wash away unbound magnetic particles.

10 ot require separation and removal of unbound magnetic particles.

11 ylated virions using streptavidin-conjugated magnetic particles.

12 properties of a solution affect the flux of magnetic particles.

13 the end-product of immunoassay performed on magnetic particles.

14 d SrtA in the fermentation supernatant using magnetic particles.

15 s between CTCs and antibodies immobilized on magnetic particles.

16 ied by rolling circle amplification (RCA) on magnetic particles.

17 effectiveness of protein capture by actuated magnetic particles.

18 ical/chemical detection while combining with magnetic particles.

19 entailed the dispersion of a small amount of magnetic particles (20-70 mug) in a droplet of biofluid

20 Here, we combine magnetic particle actuation with rotational and translat

21 issue, we applied mechanical forces through magnetic particles adhered to the PM of single cells and

22 By enhancing magnetic particle agglutination via application of stron

23 e change was achieved, while domains bearing magnetic particles allowed movement of the structures in

24 chnology from BioScale called acoustic micro magnetic particle (AMMP) detection, two pathway biomarke

25 This tool uses a magnetic particle and a strong magnetic field gradient t

26 inylated capture probe for immobilization on magnetic particles and a readout probe for electrochemic

27 ic region is captured by streptavidin-coated magnetic particles and analyzed by standard genotyping,

28 ing the binding rate between antibody-linked magnetic particles and bacteria.

29 a method for performing microscale IP using magnetic particles and digital microfluidics (DMF-IP).

30 , the sample is mixed with antibody-modified magnetic particles and free antibodies conjugated to bet

31 e we show that magnetic interactions between magnetic particles and magnetized sensors dramatically i

32 PE) sorbent was synthesized by incorporating magnetic particles and MWCNTs into a PVA cryogel.

33 nanoparticle experts seeking to characterize magnetic particles and optimize MPI drive waveforms for

34 cellularizing Drosophila embryo by injecting magnetic particles and studying their response to extern

35 nomagnetic separation with antiCD81 modified magnetic particles and the labeling based on CD24 and CD

36 ch around the target in conjunction with the magnetic particle) and hundreds of thiolated single-stra

37 ls, facilitate reorientation of the embedded magnetic particles, and enable reprogrammable magnetoact

38 apanese tree frogs, colloidal suspensions of magnetic particles, and other biological and physical sy

39 kel(II) nitrilotriacetic acid-functionalized magnetic particles are added to a parasite-spiked sample

40 ration method has a wide applicability since magnetic particles are commonly used in bioanalysis as a

41 minar flow platform, in which functionalized magnetic particles are deflected through alternating lam

42 paration and characterization of gold-coated magnetic particles are described for use as more efficie

43 Simultaneous bulk-charged and bulk-magnetic particles are fabricated for the first time via

44 The new gold-coated magnetic particles are further used as a solid phase for

45 The magnetic particles are synthetic antiferromagnets formed

46 The biomarker-bound magnetic particles are then entrained by an external mag

47 of the bacteria was achieved by using silica magnetic particles as a carrier and three different elec

48 By using magnetic particles as a mobile substrate for nucleic aci

49 By using magnetic particles as a proximity sensor to amplify mole

50 ith the potential use of streptavidin-coated magnetic particles as a universal label for antigen dete

51 se magnetic biosensors require well-tailored magnetic particles as detection probes, which need to gi

52 ge numbers of peptides using reversed-phase, magnetic particle-assisted sample processing with a matr

53 strategy for automation and multiplexing of magnetic particle-based agglutination assays.

54 ELISA) and the 50 min necessary for off-chip magnetic particle-based assays.

55 ng reversed-phase (RP) batch processing in a magnetic particle-based format, automated on a liquid ha

56 A rapid and simple magnetic particle-based immunoassay has been demonstrate

57 y of techniques used to screen for potential magnetic particle-based magnetoreceptor candidates.

58 When compared to other types of magnetic particle-based surface coverage assays, our str

59 n oligonucleotide hybridization assay, using magnetic particles bearing 21-mer, deoxyribose analogues

60 allowing the extraction and resuspension of magnetic particles between consecutive nanoliter droplet

61 y of tapes contain polyester-urethane as the magnetic particle binder, the degradation of which threa

62 We investigate the dynamics of magnetic particles' biomolecular binding and magnetic ad

63 e to perform multiple injections of plugs of magnetic particles by periodic application of a magnetic

64 The DNA-padlock probe-complex is captured on magnetic particles by sequence specific capture oligonuc

65 Magnetic particles can act as magnetic relaxation switch

66 nsient laser heating, the orientation of the magnetic particles can be re-aligned upon change of a pr

67 This work shows how future magnetic particles can be successfully designed for appl

68 observations assume that naturally occurring magnetic particles can retain their primary magnetic rec

69 lize localized magnetic fields to manipulate magnetic particles carrying biological entities are attr

70 ing for on-chip detection of biomolecules: a magnetic particle, carrying a low number of antigens (Ag

71 biotinylated amplification products by using magnetic particles coated with specific oligonucleotide

72 pared by using lectin microarrays and lectin-magnetic particle conjugate-assisted LC-MS/MS analyses.

73 mobility through selection of antibodies and magnetic particle conjugates.

74 Magnetic particles could thus be separated from each oth

75 Magnetic particle delivery had no overt effects on physi

76 lly invasive thrombotic stroke model through magnetic particle delivery that does not require craniot

77 ubstantial increases in the concentration of magnetic particles deposited on the leaves after exposur

78 ro assays that require fast and quantitative magnetic particle detection.

79 agent and two hardware devices: a hand-held Magnetic Particle detector for identifying residual tumo

80 that models new and effective approaches for magnetic particle drug delivery to the lung, all support

81 method) and rapid lock-in of their detrital magnetic particles during calcite precipitation.

82 ating, the magnetocaloric mechanism can cool magnetic particles during demagnetization.

83 of the average position and distribution of magnetic particles during phagocytosis by giant-magnetor

84 number (Mn) was employed to characterize the magnetic particle dynamics; a previously determined crit

85 The unique combination of broad benefits of magnetic particles, e.g., rapid enrichment and purificat

86 containing protein bound to the surface of a magnetic particle, elicits a rapid, long-lived phosphore

87 composite film is made from an elastomer and magnetic particles encapsulated by a phase change polyme

88 lysis by mass spectrometry and FXIII-coupled magnetic particles excluded binding of DMB to FXIII.

89 While magnetic particle extraction is commonly used, it may no

90 ethod is useful for selecting and optimizing magnetic particles for a wide range of magnetic sensor p

91 followed by reviewing the advances in using magnetic particles for diagnosis and therapy of lung can

92 transposon mutants by screening with immuno-magnetic particles for ligand expression (SIMPLE).

93 ap enables repetitive capture and release of magnetic particles for sequential analysis of multiple s

94 ses the use of bacteriophages immobilized on magnetic particles for the biorecognition of the pathoge

95 demonstrates a novel approach of controlling magnetic particles for treating malignant glioma that sh

96 discs with chiral axial spinning, and steric magnetic particles forming self-limiting microrobots.

97 transport of low-mobility particles into the magnetic particle fraction) in particles and in biologic

98 is primarily related to the debonding of the magnetic particles from the polymer binder.

99 unoassay was developed to isolate BDEs using magnetic particles functionalized with an anti-neuroligi

100 ed from 10 mL of sample at pH 5 using 3mg of magnetic particles functionalized with carboxylic groups

101 s are usually observed with relatively large magnetic particles (>250 nm) that would be difficult if

102 le, cement paste with micro-sized iron-based magnetic particles had the greatest improvement of perfo

103 Combining magnetic microspheres with a magnetic particle-handling robot enables rapid (45 min),

104 f bacteriophages onto solid supports such as magnetic particles has demonstrated ultralow detection l

105 anation of these effects on the transport of magnetic particles has not been developed yet.

106 t under a low-frequency magnetic field using magnetic particles has not yet been demonstrated.

107 Targeting of tissues by magnetic particles has tackled several limitations of tr

108 tly, considerable attention has been paid to magnetic particle imaging (MPI) because of its better se

109 We demonstrate that Magnetic Particle Imaging (MPI) enables monitoring of ce

110 Magnetic Particle Imaging (MPI) enables non-invasive, vo

111 We assess the potential of Magnetic Particle Imaging (MPI) for intraoperative margi

112 Magnetic Particle Imaging (MPI) is a promising new tomog

113 Magnetic Particle Imaging (MPI) is a promising new trace

114 Magnetic particle imaging (MPI) is a promising tomograph

115 Magnetic particle imaging (MPI) is an emerging imaging m

116 oefficient and have been proposed for direct magnetic particle imaging (MPI) of brain electrophysiolo

117 Application of Magnetic Particle Imaging (MPI) to humans is similarly P

118 as to evaluate an emerging imaging modality, magnetic particle imaging (MPI), for intra-articular tra

119 nctions of magnetic resonance imaging (MRI), magnetic particle imaging (MPI), photoacoustic imaging (

120 neering a new medical imaging method, called Magnetic Particle Imaging (MPI), to replace X-ray and CT

121 solution and scanning time on the quality of magnetic particle imaging (MPI)-reconstructed images acr

122 its the sensitivity of their detection using magnetic particle imaging (MPI).

123 calized in situ 3D temperature monitoring by magnetic particle imaging (MPI).

124 ging (MRI), photoacoustic imaging (PAT), and magnetic particle imaging (MPI).

125 al for biomedical technologies, particularly magnetic particle imaging and hyperthermia, and rigorous

126 Two applications in biomedicine, magnetic particle imaging and magnetic fluid hyperthermi

127 Quantification of SPIONs in the hearts using magnetic particle imaging demonstrates that the formulat

128 We have developed a high-resolution magnetic particle imaging instrument and implemented a l

129 ive assay system based on a chemiluminescent magnetic particle immunoassay.

130 ly, enhancing a cement paste with iron-based magnetic particles improves the bandwidth and S11 of emb

131 om only 1.0 mL of human serum using specific magnetic particles, improving the analytical simplificat

132 ul use of spin-vortex, disk-shaped permalloy magnetic particles in a low-frequency, rotating magnetic

133 Motion of micron and sub-micron size magnetic particles in alternating magnetic fields can ac

134 The composite consists of two types of magnetic particles in an amorphous shape memory polymer

135 This review will examine the recent uses of magnetic particles in cancer diagnosis and treatment.

136 nomic material was automated by manipulating magnetic particles in droplets using a series of planar

137 The assembly of tiny magnetic particles in external magnetic fields is import

138 e aquatic organisms that produce subcellular magnetic particles in order to orient in the earth's geo

139 Our findings show that magnetic particles in RS-1 initially form randomly withi

140 The novel design enables the movement of the magnetic particles in the same or opposite directions wi

141 ely on the presence of both magnetic and non-magnetic particles in the sea of dimer singlets.

142 eemingly new microrheology approach based on magnetic particle infiltration in growing biofilms.

143 ling between a levitated submillimeter-scale magnetic particle inside a type I superconducting trap a

144 However, the handling of magnetic particles inside microfluidic chips for miniatu

145 ly relevant, constant forces to apCAM-coated magnetic particles interacting with apCAM-coated model s

146 ic separation based on biologically-modified magnetic particles is a preconcentration procedure commo

147 lectrochemical magneto genosensing on silica magnetic particles is reported.

148 th the imprinted layer on the surface of the magnetic particles (magnetic MIPs).

149 optomagnetic setup and two differently sized magnetic particles (micron-sized particles acting as cap

150 The use of magnetic particles minimizes the matrix effect allowing

151 pernatant (and eventually in human serum) on magnetic particles modified with antibodies against the

152 hole blood by immunomagnetic separation with magnetic particles modified with antiCD3 antibodies.

153 In this work, magnetic particles (MPs) are used as supports for the im

154 Delivery of magnetic particles offers the key advantage of high effi

155 Following target isolation using the magnetic particles, oligonucleotide-functionalized gold

156 rocessing of stable large-scale graphene and magnetic particles on a micrometer-thick conductive supp

157 barriers between stable states in nonuniform magnetic particles on geological timescales.

158 fied targets, e.g., by conjugating them with magnetic particles or encapsulating them in micelles.

159 exposed to atmospheric pollution, accumulate magnetic particles over time, providing a record of loca

160 etween an Ag-carrying particle and the small magnetic particle pattern is described by stochastic mov

161 clonal antibodies were anchored on amorphous magnetic particles preferably chosen to capture OP-AChE

162 The assay uses DNA-functionalized magnetic particle probes that act as scavengers for targ

163 itions, liquid-handling characteristics, and magnetic particle processor programming all contributed

164 al portable multichannel reader based on the magnetic particle quantification technique.

165 isolated, near-equidimensional single-domain magnetic particles rather than the chain patterns observ

166 achieving precise and local reorientation of magnetic particles remains challenging.

167 Such surface functionalization of magnetic particles represents a promising strategy to br

168 We describe the concept of magnetic particle-scanning for on-chip detection of biom

169 The magnetic particle-scanning principle is investigated in

170 Our model shows that magnetic particle-scanning results in a very high probab

171 d processes ultralow nanoliter quantities of magnetic particles, simultaneously increasing the effici

172 gates the impact of two different iron-based magnetic particle sizes (micro- and nanosized particles)

173 The study utilized microbead-based magnetic particle sorting and flow cytometry to detect 3

174 In this work, the concept of magnetic particle spray mass spectrometry (MPS-MS) is re

175 lymer-based sensor is comprised of Au-plated magnetic particles structured into conducting chains by

176 The magnetic particle surface coverage at the limit of detec

177 herapy of lung cancers: (i) a combination of magnetic particle targeting with MRI imaging for diagnos

178 ge of controlled drug delivery, particularly magnetic particle targeting.

179 dye, which serves as a chemical sensor, to a magnetic particle that is used for measurement of the vi

180 Our research unveils a macroscopic magnetic particle that shares many known traits of quant

181 nsists of a pattern of substrate-bound small magnetic particles that are functionalized with antibodi

182 MRs for the detection of streptavidin-coated magnetic particles that are selectively captured by biot

183 Magnetic particles that can be precisely controlled unde

184 ted devices with conductive, dielectric, and magnetic particles that functionally heal after damage,

185 in zygotes, we generated cortical domains of magnetic particles that spontaneously cluster endogenous

186 ron transport through single nanometer scale magnetic particles, the current can also cause the magne

187 reconcentrated by the bacteriophage-modified magnetic particles through the host interaction with hig

188 Thermo-responsive magnetic particles (TM) have already been developed to a

189 of such molecules is converted into a single magnetic particle to which thousands of copies of DNA id

190 irigami, made by soft material embedded with magnetic particles, to realize target shape-morphing upo

191 For the magnetic particles, transfer between flow streams is gre

192 f gel matrix and allows for reorientation of magnetic particles under a modest magnetic field.

193 on-a-chip system for real-time monitoring of magnetic particle uptake by human fibroblast (NHDF) cell

194 truct, virus, and an antibody-functionalized magnetic particle used for extraction.

195 CA) products are detected in solution and on magnetic particles using a resistive pulse sensing (RPS)

196 Batch extraction with MIP coated on to magnetic particles was relatively time-consuming compare

197 Incorporating magnetic particles, we engineer HPH-based soft robots ca

198 The magnetic particles were 2.0 and 4.5 microm in diameter w

199 In continuous flow, magnetic particles were deflected from the direction of

200 Furthermore, agglomerates of magnetic particles were found to be deflected to a large

201 ase digestions using RNase T1 immobilized on magnetic particles were performed in conjunction with hi

202 d (Gly/Fe3O4) and non-functionalized (Fe3O4) magnetic particles were synthesized in an autoclave and

203 The synthesized magnetic particles were used for magnetic separation of

204 the relaxation properties of antibody-coated magnetic particles when they aggregate upon exposure to

205 ramagnetism is an unwanted property of small magnetic particles where the magnetization of the partic

206 ochemical competitive enzyme-linked assay on magnetic particles, which allows the measurement of as l

207 ized animal and vegetable rennet on aminated magnetic particles, which has been proven to be an appro

208 ission electron microscopic imaging of these magnetic particles, whose concentration in the natural s

209 The gold-coated magnetic particles with anti-CRP monoclonal Fab' reagent

210 ocedure based on isothermal amplification on magnetic particles with electrochemical readout.

211 ion of much larger, micron-scale, iron oxide magnetic particles with enhanced MR susceptibility, whic

212 nucleic acid extraction using silica-coated magnetic particles with real-time polymerase chain react

213 conjugation method, the functionalization of magnetic particles with streptavidin requires square met

214 Magnetic particles with various physical, geometric, and