ライフサイエンスコーパス: encapsulation

1 ble gelation, nanofabrication, and molecular encapsulation.

2 s based upon selective solid-phase molecular encapsulation.

3 -methacrylic acid) as shell material for the encapsulation.

4 However, this limitation may be mitigated by encapsulation.

5 can emerge as the driving force for alcohol encapsulation.

6 nanodroplets stabilized by polymeric ligand encapsulation.

7 ncreased thermal stability of all oils after encapsulation.

8 fe carrier and therefore utilized for MTI-31 encapsulation.

9 ase in activity and selectivity upon polymer encapsulation.

10 ng approach to be suitable for nano-liposome encapsulation.

11 by co-assembly processes rather than simple encapsulation.

12 ding motifs on IL-12 allow for its effective encapsulation.

13 ctively by immune response-induced electrode encapsulation.

14 fic intermolecular interactions are used for encapsulation.

15 e hydrophobic moieties offer stable and high encapsulation.

16 d a slow release for both the vitamins after encapsulation.

17 aracterization indicated a satisfactory TCIN encapsulation (33.20 +/- 0.85%), spherical shape, pH-res

18 In air, without encapsulation, a tandem retained 95% of its initial effi

19 e assembly kinetics, thus enabling efficient encapsulation, a tunable drug release profile, improved

20 clude conjugation of CpGODN with proteins or encapsulation/adsorption of CpGODN into/onto liposomes,

21 Bacterial encapsulation affected the volatile and amino acid profi

22 nctionalized nanotubes, which are wrapped by encapsulation agent (phospholipid-polyethylene glycol),

23 Its customizable filtering and data encapsulation allow it to be adapted to a wide range of

24 Microfluidic encapsulation and barcoding was used to perform single n

25 We have developed a platform for the encapsulation and controlled, tunable release of cell-de

26 ropylene sulfide) (PPS) and use them for Rg3 encapsulation and delivery.

27 oncentration, CaCl(2) level, hardening time, encapsulation and emulsion fabrication methods was studi

28 llowed monitoring the molecular basis of the encapsulation and guest competition processes at a very

29 he inherent lipophilicity of VSDs by dynamic encapsulation and high-affinity ligands to target the co

30 predictive tool for understanding host-guest encapsulation and interactions in numerous supramolecula

31 e picture of the subtle events directing the encapsulation and is thus a predictive tool for understa

32 ons persist regarding the mechanisms of cell encapsulation and mineral polymorphism.

33 l genetic engineering approaches to external encapsulation and modification, and summarize the most r

34 Encapsulation and molecular targeting of therapeutic ant

35 of the cage in the solvent, the (rare) guest encapsulation and release events, and the relative proba

36 While the innovations in drug encapsulation and release mechanisms, biocompatibility,

37 ilizing PCMs as a versatile platform for the encapsulation and release of various types of therapeuti

38 precisely controlled propensity in molecular encapsulation and release process.

39 We show that shell encapsulation and the internal microenvironment of the n

40 too hydrophilic for cell uptake and payload encapsulation, and may cause unintended biological respo

41 Post-storage, hLMSC were released from encapsulation, and viability-assessed cells were plated.

42 mbinatorial nano-engineering and biomaterial encapsulation approach, could therefore offer key advant

43 trodes and varying enzyme producing strains, encapsulation approaches (layer-by-layer (LbL) or one-st

44 ying variety of polymers, drug molecules and encapsulation approaches with primary focus on oral deli

45 ns examined had a high efficiency of prodrug encapsulation (as high as 114 mol% taxane per mole phosp

46 rticles are then identified by droplet-based encapsulation, barcoded 16S rRNA amplification and deep

47 moist environments due to a lack of suitable encapsulation barriers.

48 are vulnerable to the digestive process, and encapsulation becomes an alternative for their preservat

49 the explicit aim of demonstrating liposomal encapsulation, bioavailability in cultured neuroblastoma

50 rance, offer compatible environment for drug encapsulation, biocompatibility, high drug loading and t

51 a supernegatively charged (-30)GFP enhances encapsulation by cationic lipids and delivery into mamma

52 Encapsulation by freeze-drying using maltodextrin, gum A

53 The microbiota directs its own encapsulation by inducing Muc2 production from proximal

54 Encapsulation by these compartments was observed even wh

55 microcapsule and the one-step method of cell encapsulation can be a versatile 3D NIM system for spont

56 This article demonstrates that molecular encapsulation can be used as a powerful tool to tune int

57 ) deficiencies are reported worldwide and co-encapsulation can provide a combined solution to this pr

58 d tumour targeting and nanoparticle-mediated encapsulation can reduce the toxicity of antitumour drug

59 , size-dependent permeability, and selective encapsulation capacity without sacrificing their dynamic

60 interactions that occur upon fullerene guest encapsulation characterized by a range of techniques inc

61 r surfaces, as a soft, elastic substrate and encapsulation coating for wireless electronic components

62 esults in roughly 2.5 times more therapeutic encapsulation compared to loading particles in their con

63 Co-encapsulation demonstrates a synergistic increase in IL-

64 The results indicated that encapsulation depended on organic phase concentration, w

65 The supramolecular self-encapsulation design provides an effective strategy to c

66 The encapsulation dramatically enhances the stability of pro

67 eat promise to the biological separation and encapsulation due to their excellent biocompatibility.

68 s is suggestive of integrins transducing the encapsulation effect into intracellular signalling casca

69 size effect, supercage stabilization in the encapsulation effect, site adsorption in the recognition

70 PRAS-NLCs proposed yield high extraction and encapsulation efficiencies (71 +/- 4%) in combination wi

71 ormulations with only WP or LE showed higher encapsulation efficiencies (EE) (95-98%) and antibacteri

72 h as spray-drying and freeze-drying, finding encapsulation efficiencies (EE) up to 98% and spherical

73 The particle sizes, zeta potentials and encapsulation efficiencies for the prepared nanoliposome

74 llar Nanoprobe (TMNP) had exceptionally high encapsulation efficiencies of a hydrophobic drug simvast

75 Encapsulation efficiencies of nearly 50% were achieved i

76 h zeta-potential of -25 mV, and high vitamin encapsulation efficiency (94-96%).

77 EDTA remote loading methods had a comparable encapsulation efficiency (EE%) into LTSLs in contrast to

78 ed average particle sizes of 107 and 222 nm, encapsulation efficiency (EE) and loading efficiency (LE

79 an exhibited a higher physical stability and encapsulation efficiency (EE) compared with other sample

80 The encapsulation efficiency (EE) was determined as a functi

81 The highest encapsulation efficiency (EE) was found in SPC-CHO-0.5%H

82 me phenolic losses by diffusion and increase encapsulation efficiency (EE).

83 nMIC and nFIB displayed good CsA encapsulation efficiency (up to 4.5 and 2 mg/mL, respect

84 ethod, we formulated nanoparticles with high encapsulation efficiency (~ 100%) of exendin-4, high pay

85 Prepared nanofibers showed a 47.4% encapsulation efficiency and 73% yield.

86 s of sHDL were tested to optimize both T1317 encapsulation efficiency and ability of T1317-sHDL to ef

87 phology, particle size, zeta potential, pGFP encapsulation efficiency and biological properties such

88 Besides, the encapsulation efficiency and in vitro release rate of my

89 t diameter, viscosity, antioxidant activity, encapsulation efficiency and loading capacity of optimal

90 The encapsulated extract showed high encapsulation efficiency and spherical morphology.

91 y and stability, high thermal stability, and encapsulation efficiency carotenoid (>80%) when compared

92 In addition, results from encapsulation efficiency demonstrated that excess concen

93 relationship between antigen properties and encapsulation efficiency for downstream immune activatio

94 ide range of organic solutes, achieving >95% encapsulation efficiency for hydrophilic small molecules

95 to 16.85% showed a corresponding rise in the encapsulation efficiency from 74.0% to 85.8% and drug lo

96 Nanoparticle manufacture achieved 37-60% encapsulation efficiency in HSA particles (169 nm, zeta

97 analyses confirmed EO encapsulation with an encapsulation efficiency of 55%, 71%, and 74% for 1, 3,

98 articles were 322.7, 559.2 and 615.6 nm with encapsulation efficiency of 59.09, 48.30, and 55.00% and

99 repared, rHDL/Do nanodrug achieved high drug encapsulation efficiency of 90.47%, and mimicked the con

100 ogy, a mean diameter of 96.4 nm, and with an encapsulation efficiency of 99%.

101 d strong entrapment of mRNA and pDNA with an encapsulation efficiency of above 95%.

102 The SIO microcapsules showed a high encapsulation efficiency of approximately 94.12% in the

103 Finally, the encapsulation efficiency of aspartic protease in lipid s

104 The encapsulation efficiency of the CD-lipoplex complexes we

105 The antioxidant activity and encapsulation efficiency of the encapsulated material ob

106 The encapsulation efficiency varied from 31.66 to 84.48%.

107 Oil encapsulation efficiency was high (>=89%) and oil within

108 The encapsulation efficiency was higher for LBL microcapsule

109 Micrometric particles with high encapsulation efficiency were produced and thermal analy

110 namic light scattering, electron microscopy, encapsulation efficiency, and drug loading capacity.

111 inning technique, and their structures, drug encapsulation efficiency, and release characteristics we

112 on (span), morphology, drug/gelatin loading, encapsulation efficiency, and residual DCM and water con

113 in terms of morphology, particle size, drug encapsulation efficiency, in vitro release and cytotoxic

114 sodium alginate and emulsifiers, showed high encapsulation efficiency, low antioxidant activity and s

115 /Vis) spectrophotometry, carotenoid profile, encapsulation efficiency, morphology, and thermal analys

116 The encapsulation efficiency, protection of dsRNA from nucle

117 nthocyanin content, antioxidant activity and encapsulation efficiency.

118 ential of -20 mV, and exhibit high docetaxel encapsulation efficiency.

119 rticles with well-controlled shapes and high encapsulation efficiency.

120 cost-effective drug carrier system with high encapsulation efficiency.

121 re not captured, Br, I and Te exhibit strong encapsulation energies while Rb is only weakly encapsula

122 Here, we showed that encapsulation enhanced the antidepressant effects of MSC

123 alysis within the metallocage shows that its encapsulation favors the reaction.

124 Further, the recent studies of vitamins encapsulation for applications in functional foods and n

125 g dendrimer platform and injectable hydrogel encapsulation for delivery of an adenovirus encoding Fla

126 host processes, we develop an aqueous-based encapsulation formulation with a microbiota-based releas

127 of the supramolecular assembly and catalyst encapsulation further engenders reaction selectivity, wh

128 However, encapsulation had a significant effect (p < 0.05) on the

129 moisture content and successful of molecular encapsulation have been evaluated by thermal and spectro

130 ion and separations, chemical adsorption and encapsulation, heterogeneous catalysis, photoredox catal

131 Encapsulation improved retention of PP and AOC upon ther

132 Our results show that encapsulation improves differentiation by significantly

133 e also demonstrate improved outcome of islet encapsulation in a chemically-induced diabetic mouse mod

134 The device is also tested for islet encapsulation in an immunocompetent diabetes rodent mode

135 After sample encapsulation in droplets and target enrichment with the

136 dy explores the mechanical basis of germline encapsulation in Drosophila gametogenesis, reporting tha

137 In contrast, encapsulation in the Dual PEG capsules prevented sensiti

138 tal clusters and nanoparticles through their encapsulation in the voids of zeolite frameworks as well

139 Encapsulation inflates the host, enhancing its ability t

140 Nanoparticle encapsulation inside zirconium-based metal-organic frame

141 Here, we demonstrate that biomaterial encapsulation into alginate using a microfluidic device

142 easy-to-use workflow for precise single-cell encapsulation into picoliter-scale double emulsion dropl

143 Successful encapsulation into these micelles has been demonstrated

144 Encapsulation involves the incorporation of the active m

145 Biosample encapsulation is a critical step in a wide range of biom

146 Modifying the reactivity of substrates by encapsulation is a fundamental principle of capsule cata

147 t generation with a single particle and cell encapsulation is a random process and suffers from a low

148 findings of this study suggest that alginate encapsulation is an effective method of hLMSC preservati

149 improving the stability of MNW networks via encapsulation is discussed.

150 of supramolecular polymerization and droplet encapsulation is used to control the position of self-as

151 as 300 degrees C in ambient air without any encapsulation, is demonstrated.

152 drogenated phosphatidylcholine (HPC) for the encapsulation lactoferrin (LF) was studied; lipid membra

153 lly decomposition) resulted, indicating that encapsulation led to host-selective reaction trajectorie

154 We demonstrate that EC and NSC co-encapsulation maintained NSC quiescence, enhanced NSC vi

155 yer-by-layer approach, we generated nanothin encapsulation materials containing tannic acid (TA), a p

156 By testing different oils, encapsulation matrices and oxidation conditions, results

157 itions in different plants and this range of encapsulation matrices provides a great deal of commerci

158 Cell encapsulation may enhance the survival rate of grafted c

159 ance the stability of chlorophyll, a polymer encapsulation method was proposed.

160 This encapsulation methodology simplifies the screening of re

161 ve sustained drug release using conventional encapsulation methods.

162 However, encapsulation of [Au(25)(Cys)(18)] and CV into the polym

163 bactericidal mechanism shows that additional encapsulation of [Au(25)(Cys)(18)] into the CV treated p

164 report here a supramolecular strategy where encapsulation of a hydrogenation catalyst enables select

165 However, encapsulation of a strong cytotoxic drug completely shut

166 s the significant role of nanotechnology for encapsulation of AIs for pesticides.

167 ar structures known as chromocenters ensures encapsulation of all chromosomes into a single nucleus (

168 e optimized for achieving the most efficient encapsulation of anthocyanin using a three level, three

169 0.3% NBRE-15 was found to be optimum for the encapsulation of anthocyanin with the desirability of 92

170 d WPI-based nanocapsules can be used for the encapsulation of beta-carotene answering the industrial

171 esent structural and functional benefits for encapsulation of bioactive ingredients.

172 The encapsulation of bioactive lipophilic compounds by compl

173 mum) which makes it a suitable candidate for encapsulation of biological samples.

174 s, functionalization for magnetic actuation, encapsulation of biomolecules, and surface functionaliza

175 In addition, the encapsulation of bis-aza[60]fullerene (C(59)N)(2) within

176 C12A7 shows a significant enhancement in the encapsulation of Br, I and Te with all three stable as a

177 The encapsulation of broccoli extract, by electrospraying, w

178 sites in the structure of the cage, and (3) encapsulation of catalysts within the cage.

179 650, 1383, 1148, 1083 and 790 cm(-1) depicts encapsulation of catechin in starch nanoparticles withou

180 on sequencing (i-BLESS), which relies on the encapsulation of cells in agarose beads and labeling bre

181 at active cargo loading reduces non-specific encapsulation of cellular proteins, particularly nucleic

182 Reversible encapsulation of CH(2) Cl(2) or Xe in a non-porous solid

183 helicate containing a bisporphyrin unit upon encapsulation of chiral aromatic guests between the bisp

184 Encapsulation of chiral guest molecules such as [(R/S)-1

185 erived nanobiotics, alone or with additional encapsulation of clofazimine (CFZ), enhance killing of m

186 Encapsulation of clove oil was proposed as a mean to dis

187 an expanded scorpionate ligand suited to the encapsulation of cuboidal clusters.

188 dy two approaches have been explored for the encapsulation of DHA in the pH dependant polymer hydroxy

189 The encapsulation of drugs into lipid-based nanoparticles wi

190 poly(lactic-co-glycolic acid) (PLGA) allowed encapsulation of DSP into biodegradable nanoparticles (N

191 With liposomal encapsulation of each drug pair, we enabled uniform drug

192 ctron transfer rates, paving the way for the encapsulation of electroactive catalysts and electrocata

193 strong acids during synthesis, allowing the encapsulation of enzymes into three prototypical robust

194 The encapsulation of enzymes within porous materials has sho

195 ollowed by a survey of the literature on the encapsulation of enzymes, growth factors, antibodies, ho

196 This proof-of-concept study describes the encapsulation of fatty acids, in vivo bioavailability, a

197 multistage process that starts from diamond encapsulation of ferropericlase followed by decompressio

198 we demonstrate the synthetically controlled encapsulation of first-row transition metals (M = Mn, Fe

199 In this work, we report the controlled encapsulation of gold nanorods (AuNRs) by a scu-topology

200 This study is one of its kind where nano-encapsulation of GPP into W/O emulsion was done to stabi

201 biomaterial during printing, or intermediary encapsulation of growth factors in delivery vehicles suc

202 Encapsulation of homonuclear dimers (Br(2), I(2) and Te(

203 Encapsulation of Imatinib into targeted nanoparticles co

204 hen, investigate the use of hydrogels in the encapsulation of insulin secreting cells with a special

205 fulfill their specialized functions, such as encapsulation of invading pathogens, cell-cell fusion in

206 cular), and induction of immune tolerance or encapsulation of islets.

207 nsights into the beta-cyclodextrin (beta-CD) encapsulation of key compounds in coffee (CGA 1, CFA 2,

208 measurements (CREM) confirmed the successful encapsulation of M within {Mo(132)PO(4)} and furthermore

209 -assembly approach, we demonstrate efficient encapsulation of medium to large proteins (HRP, 44 kDa a

210 therapeutic effects and mechanisms mediating encapsulation of MSCs remain unexplored.

211 Successive encapsulation of multiple Br, I and Te as single anions

212 ng strategies typically require the complete encapsulation of nanostructures, which makes accessing t

213 rine model of systemic infection resulted in encapsulation of NESp and increased virulence during bac

214 The impact of the encapsulation of Oenococcus oeni into SiO(2)-alginate hy

215 In both cases, the encapsulation of OLE led to higher OE contents at the en

216 yringe-injectable and support cytocompatible encapsulation of oligodendrocyte progenitor cells (OPCs)

217 action analysis of [3.F(-)] reveals that the encapsulation of one fluoride, within 3, occurs through

218 gainst some food pathogens revealed that the encapsulation of OR and TCA within micelles crucially im

219 These data demonstrate that encapsulation of P. gingivalis plays a key role in the a

220 ution of Pd into Ag is always preceded by an encapsulation of Pd islands by Ag, resulting in a signif

221 hybrid membranes can be obtained by in situ encapsulation of photoactive molecules (sulfonated spiro

222 , objective of the present investigation was encapsulation of Pimpinella anisum essential oil in chit

223 a-cyclodextrin of high crystallinity for the encapsulation of PIP at high loading capacity.

224 in NS, by microwave-assisted fusion, for the encapsulation of PIP.

225 Encapsulation of plasmid DNA vaccine expressing IBV nucl

226 Encapsulation of polar and non-polar bioactive compounds

227 center of sulfonic acid groups in COFs after encapsulation of polymeric solvent analogues 1-methyl-2-

228 proposed as a "green" wall material for the encapsulation of pomegranate peel extract.

229 Encapsulation of Porphyromonas gingivalis has been demon

230 the use of the lipid sponge (L(3)) phase for encapsulation of proteins has not yet been well explored

231 n act as versatile platforms for the in situ encapsulation of proteins under ambient conditions.

232 Encapsulation of proteins within lipid inverse bicontinu

233 Here, we show that the encapsulation of rituximab within a crosslinked zwitteri

234 Furthermore, it provides a much-needed encapsulation of scattered functionality, making large a

235 Overall, encapsulation of shrimp oil in nanoliposomes was proven

236 We optimize for preferential encapsulation of single cells with extremely low multipl

237 Encapsulation of solid potassium salt of ferrate (K(2)Fe

238 nd ENDOR spectroscopy that substantiated the encapsulation of the first-row transition metal guest.

239 fer multifunctionality in vitro including co-encapsulation of the injury site extracellular matrix mo

240 Subsequent encapsulation of the ion exposed MoS(2) flake with high-

241 Encapsulation of the lipase-coated lipid/PDMS droplets i

242 at euthanasia and displayed progressive bony encapsulation of the screw.

243 ch implies a mechanism that does not involve encapsulation of the substrate.

244 It also, summarizes the latest reports of encapsulation of therapeutic compounds, and critically d

245 Encapsulation of these components within vesicles reorga

246 Here, we studied the encapsulation of three structurally simple BODIPY deriva

247 This work demonstrates that co-encapsulation of TLR4 and lipidated TLR7/8 agonists with

248 The cavity size allowed for the selective encapsulation of two dye molecules, irrespective of the

249 susceptibility measurements showed that the encapsulation of up to 10 equiv showed little magnetic i

250 The present work aimed at encapsulation of vitamin B(12) and D(3) by spray drying

251 m (CMTG) were used as wall materials for the encapsulation of vitamin D(3) (VD(3)).

252 atheroma-targeting ability of sHDL allow for encapsulation of water-insoluble drugs and their subsequ

253 rbon nanotube array with nickel-copper alloy encapsulation on a carbon-fiber paper.

254 ing water in order to evaluate the impact of encapsulation on the hydrophilicity of lutein.

255 as to investigate the impact of nanoemulsion encapsulation on transpapillary delivery in vitro.

256 us, whereas the implantation of MSCs without encapsulation or the implantation of eMSCs into the stri

257 To engineer the microenvironment of seeds by encapsulation, preservation, and precise delivery of bio

258 er focuses on the use of a new type of yeast encapsulation procedure, applying the chitosan-calcium a

259 dumbbell-shaped guest in the dynamics of the encapsulation process and in the stability of the final

260 Encapsulation process by Saccharomyces cerevisiae is a p

261 Halide encapsulation promotes a large conformational rearrangem

262 Overall, encapsulation protected PSO against oxidation over time,

263 Overall, encapsulation protected RPO during storage, with SEDS-mi

264 By introducing graphene encapsulation, proteins in solution can be immobilized o

265 d to the confinement effects involving size, encapsulation, recognition, and synergy.

266 A trend of present encapsulation research indicates an increased interest i

267 Liposomal encapsulation resulted in a circulation half-life of ~2

268 t, light, and air stability with and without encapsulation revealed that specific compounds can be ai

269 y of Adv-Flagrp170 by both G4 coating and SH encapsulation significantly enhanced its therapeutic eff

270 Encapsulation strategies are widely used for alleviating

271 r research adds to current knowledge in cell-encapsulation strategies by highlighting the importance

272 nsfection efficiency and suitable reversible encapsulation strategies for intracellular delivery with

273 The encapsulation strategy of the synthesized red-phosphorus

274 Preparation and characterization of novel encapsulation system based on calcium alginate hydrogels

275 ge proteins in the cytoplasm act as a second encapsulation system preventing starch digestion.

276 Such an encapsulation technique ensures cell viability and enabl

277 Spray drying is the most commonly used encapsulation technique to stabilize sensitive bioactive

278 the device structures(10-13), and using new encapsulation techniques(14,15).

279 Encapsulation technologies can be used to preserve thera

280 ne answering the industrial demand for novel encapsulation technologies to protect sensitive bioactiv

281 Encapsulation technology and the encapsulant agent used

282 Drug encapsulation tests confirmed that they are able to load

283 Such measurements require stable encapsulation, that is no escape of the substrate into b

284 riety of applications including nanoparticle encapsulation, the construction of artificial membrane p

285 es may contribute to the development of cell encapsulation therapies for type 1 diabetes and other ho

286 favorable self-assembly thus enables central encapsulation to amplify guest-binding events around the

287 e activation, shell self-assembly, and cargo encapsulation to construct a robust nanoreactor that inc

288 pneumoniae overcomes these defences through encapsulation to effectively colonize this site.

289 n and to evaluate the effect of spray-drying encapsulation using modified starch on PP, antioxidant c

290 ite of this host promotes new modes of guest encapsulation via hydrogen bonding with the pai systems

291 % for both crops, while the efficiency of PP encapsulation was 79% (RCA) and 88% (RCH).

292 NPs) produced via ultra-sonication for rutin encapsulation was explored.The rutin encapsulated SNPs p

293 Taking advantage of the dynamic nature of encapsulation, we developed a system in which reversible

294 and thermogravimetric analyses confirmed EO encapsulation with an encapsulation efficiency of 55%, 7

295 r, the larger size CNB2 does not exhibit any encapsulation with both C(60) and C(70).

296 ructural change of cytochrome c (Cyt c) upon encapsulation within a hierarchical metal-organic framew

297 lization of biomacromolecules, and live cell encapsulation within a hydrogel scaffold.

298 yl-perfluorophenyl polar-pai interactions by encapsulation within a synthetic host, thus increasing t

299 erved at high temperature, which occurs upon encapsulation within a ZIF-62(Zn) MOF glass matrix.

300 ailed structural changes of the enzymes upon encapsulation within the porous material, which are clos