ライフサイエンスコーパス: encapsulation

1 rom 0.136 (moderately hypointense) to 0.529 (encapsulation).

2 tion with starch to facilitate some types of encapsulation.

3 o obtain the desired properties for targeted encapsulation.

4 psules were altered depending on the mode of encapsulation.

5 ity and the melting temperature decreased on encapsulation.

6 Kdo transferase domain resulted in a loss of encapsulation.

7 dge-ingress of water or moisture through the encapsulation.

8 into amorphous alpha-CD powder prior to the encapsulation.

9 lite and provide final evidence of the metal encapsulation.

10 direct liver invasion, and absence of tumor encapsulation.

11 The DSC technique was used to confirm the encapsulation.

12 imensional binding cavities capable of guest encapsulation.

13 with lower GPE concentrations (P<0.05) after encapsulation.

14 nly provides suitable spaces for both iodine encapsulation and cation intercalation but also generate

15 We measured liposomal encapsulation and cellular uptake of the monodisperse pa

16 for the reconstitution of membrane proteins, encapsulation and concentration of nanomaterials, and th

17 meworks (MOFs) as novel delivery systems for encapsulation and controlled release of volatile allyl i

18 This resulted in the loss of encapsulation and intrinsic lipooligosaccharide sialylat

19 , a cryptic cell type, dedicated to pathogen encapsulation and killing.

20 Sox10(+) adult stem cells contribute to both encapsulation and microvessel formation.

21 Here we demonstrate the encapsulation and noncovalent stabilization of organic r

22 led a systematic study of the impact of both encapsulation and proximal polyanionic surfaces on a set

23 tomated C. elegans analyzer based on droplet encapsulation and real-time image processing was develop

24 id deposits, resulting in ineffective plaque encapsulation and reduced plaque compaction, which is as

25 te the application of these microcapsules in encapsulation and release of proteins without impairing

26 er give rise to materials for the controlled encapsulation and release of therapeutics.

27 ynthesized and applied to reversible bromine encapsulation and release.

28 on-adhesive layer, enabling highly efficient encapsulation and retention of small molecules and activ

29 les combining copigmentation for anthocyanin encapsulation and stabilization were fabricated.

30 dation are cytocompatible and allow for cell encapsulation and subsequent release.

31 it a wide range of applications that require encapsulation and sustained release of molecules in aque

32 ies support the use of CC (PEG MG) for islet encapsulation and transplantation in clinically relevant

33 isture content, hygroscopicity, curcuminoids encapsulation and volatile release.

34 ssible monomers, which can be tuned for drug encapsulation and which retain good cellular compatibili

35 ethyl methacrylate, E) to enhance vancomycin encapsulation, and (iv) a chitosan derivative called ZWC

36 rolled drug delivery, protein delivery, cell encapsulation, and cell delivery applications.

37 a group of promising methods; complexation, encapsulation, and hot melting.

38 patibility as materials for cell culture and encapsulation applications.

39 Thus, this encapsulation approach may have the potential applicatio

40 The fabrication of a new type of solar cell encapsulation architecture comprising a periodic array o

41 Silicon solar cells comprising this encapsulation architecture show greater total external q

42 he squaraine fluorescence quantum yield upon encapsulation as a rotaxane.

43 alpha-cyclodextrin (alpha-CD) powder on CO2 encapsulation at 0.4-1.6 MPa pressure for 1-72 h through

44 ies decorated with biomolecules by insertion/encapsulation/attachment, serve for development of multi

45 iled mechanistic investigation of host-guest encapsulation behavior in a new enzyme-mimetic metal-lig

46 also minimized down to 20% by adopting a new encapsulation bilayer of octadecyltrichlorosilane/polyme

47 hought to be the major cell type involved in encapsulation, but it is unclear whether and how stem ce

48 s in catalysis, energy storage and molecular encapsulation, but large domain sizes (on the order of 5

49 induce foreign body reaction and end up with encapsulation by a dense avascular fibrous layer enriche

50 The encapsulation by spray drying method of coriander essent

51 act between the metal and metal oxide sites, encapsulation by the nanoporous oxide film provided a si

52 ion of CO2-alpha-CD complexed powders during encapsulation, by which amount of CO2 encapsulated by am

53 Overall, we demonstrate that nanoparticle encapsulation can improve targeting, provide low off-tar

54 The results showed that the alpha-CD encapsulation capacity was over 1 mol CO2/mol alpha-CD a

55 The encapsulation caused higher temperature stability compar

56 Encapsulation causes 35-55% suppression in kappa and app

57 aces were achieved using 1.0 mg mL(-1) swell encapsulation concentrations of 2 nm AuNPs.

58 The best encapsulation conditions were obtained at 2% v/v of thym

59 mic exposure such as would be experienced in encapsulation devices damages islet viability and beta c

60 Encapsulation devices have the potential to enable cell-

61 However, reasonably sized encapsulation devices promote ischemia due to high beta

62 ol within niosomes was approximately 80% and encapsulation did not influence the radical scavenging a

63 ial applications in areas such as biomimetic encapsulation, drug delivery, catalysis and biosensing.F

64 Alginate encapsulation effectively controlled carbohydrate releas

65 ated uniform size distribution and high drug encapsulation efficacy of the electrosprayed nanoparticl

66 on with carrier lipidoids, promoting protein encapsulation efficacy, and facilitated cancer cell targ

67 Loading capacities and encapsulation efficiencies of freeze-dried inclusion com

68 ontaining microgels by a factor of ten, with encapsulation efficiencies over 90%.

69 The encapsulation efficiency (82.8%), loading capacity (35.3

70 polydispersity index (PDI), zeta potential, encapsulation efficiency (EE) and morphology.

71 Size, zeta potential and encapsulation efficiency (EE) of the produced spherical

72 The process was optimized to achieve higher encapsulation efficiency (EE=82.7%) and a smaller size (

73 lly high drug loading-up to five fold higher encapsulation efficiency and drug loading compared to na

74 n complex was prepared and characterized for encapsulation efficiency and loading capacity using UV-V

75 was to evaluate the odour masking property, encapsulation efficiency and physicochemical properties

76 Nevertheless, the encapsulation efficiency and the deliver kinetics differ

77 lutein concentration inside the capsules and encapsulation efficiency are key parameters that must be

78 were ~100nm in size and exhibited high drug encapsulation efficiency as 94.7%.

79 extract (SOE) exhibited significantly higher encapsulation efficiency compared to encapsulates contai

80 CYnLIP (132.00+/-6.23nm) had encapsulation efficiency of 49.04+/-2.54% for erlotinib.

81 as the optimized treatment with a reasonable encapsulation efficiency of 5.6% and a nanoparticle size

82 c acids (HA-NCs) have diameter of 224-253nm, encapsulation efficiency of 53-78%, and are stable over

83 The S/O/W emulsion had an encapsulation efficiency of 75%, a hydrodynamic diameter

84 Encapsulation efficiency of alpha-tocopherol within nios

85 opigmentation can significantly increase the encapsulation efficiency of anthocyanin in CaCO3, wherea

86 a hydrodynamic diameter of 200-300nm and an encapsulation efficiency of approximately 90% were self-

87 , oil and surfactant content on the size and encapsulation efficiency of nanocarriers containing pepp

88 The particle size and lutein encapsulation efficiency of nanoemulsions prepared by em

89 The loading capacity and encapsulation efficiency of the proposed system was stud

90 Results indicated that the encapsulation efficiency of the whole oleoresin in the p

91 the particles ranged from 78 to 1100mum and encapsulation efficiency ranged from 67.9 to 93.9%.

92 (29.9mum) when cashew gum was used, and the encapsulation efficiency reached 76%, similar to that of

93 The loading capacity of lycopene was 9% and encapsulation efficiency was 89%.

94 The encapsulation efficiency was 97%.

95 Encapsulation efficiency was greater than 95%, and the y

96 Also, it was found that the encapsulation efficiency was inversely proportional to t

97 tent, bulk density, wettability, morphology, encapsulation efficiency were evaluated.

98 ing cashew gum were more hygroscopic however encapsulation efficiency were higher and surface oil oxi

99 The gelatin/pectin complex had highest encapsulation efficiency with 17.91%.

100 ver the particle size and shape, (ii) a high encapsulation efficiency, (iii) mild processing conditio

101 ed good reproducibility and over 89% protein encapsulation efficiency, and practically feasible to ad

102 Encapsulation efficiency, loading and loading efficiency

103 pheres were evaluated regarding size, shape, encapsulation efficiency, loading capacity and antimicro

104 The viscosity, encapsulation efficiency, loading capacity, transmission

105 n, large oxygen loading capacity, high LLL12 encapsulation efficiency, well protection of bioactivity

106 s was strengthened, which therefore enhanced encapsulation efficiency.

107 wer carotenoids losses, and higher yield and encapsulation efficiency.

108 buted within the liposomes, even at the same encapsulation efficiency.

109 erties of the guests was also observed, with encapsulation either changing or switching-on luminescen

110 ing, chemical inactivation, incineration, or encapsulation) followed by burial or transportation to a

111 n for biological tissue and reversible focal encapsulation for sensitive components in flexible elect

112 Surprisingly, encapsulation impaired DC maturation independent of its

113 Most importantly, PFP encapsulation improved Dox penetration in the tumor peri

114 ned and produced a synthetic ecosystem by co-encapsulation in a silica gel matrix, which enabled prec

115 alyst as well as bridging two enzymes for co-encapsulation in a single capsid while maintaining their

116 FTIR demonstrated successful TE-HCL encapsulation in aligned fibers.

117 Here we describe the encapsulation in alpha-cyclodextrins (alpha-CDs) of whea

118 ibilities of integrating vascularization and encapsulation in bioprinted tissues are expounded, and f

119 Results showed that encapsulation in CDs significantly increased the solubil

120 Effects of the encapsulation in cyclodextrins (CDs) on the solubility,

121 ity and stability; this could be resolved by encapsulation in cyclodextrins (CDs).

122 Starting with cell encapsulation in digested lymphoid tissues, clusters of

123 e developed a technique based on single-cell encapsulation in droplets of a monodisperse microfluidic

124 Encapsulation in ethyl cellulose nanocarriers delayed De

125 urea-based outer cleft, followed by a second encapsulation in its urea-based inner cleft.

126 ese data define the genetic requirements for encapsulation in K. kingae and demonstrate an atypical o

127 In addition, encapsulation in liposomes enhanced in vitro bioaccessab

128 attempted to improve its bioavailability by encapsulation in mixed phosphatidylcholine micelles.

129 gested that conjugation with CPP followed by encapsulation in MNPs provides an effective strategy for

130 The obtained results indicated that FA encapsulation in MSPs significantly improved its stabili

131 ticancer drugs can be further potentiated by encapsulation in nanocarriers and/or affinity targeting

132 ic interactions, coordination chemistry, and encapsulation in porous materials.

133 Storage at 4 degrees C synergized with encapsulation in preventing degradation of bioactives.

134 beetroot molasses as substrate and used for encapsulation in proniosome powders after extraction, wi

135 fected the stability of CTX drastically, but encapsulation in proniosomes retarded its degradation.

136 Encapsulation in silica allows one to create robust arch

137 ing (lyophilisation), biomineralisation, and encapsulation in sugar glass and organic polymers.

138 Oxidation was significantly promoted by iron encapsulation in the aqueous phase, even at 25 degrees C

139 TIC phenotype delivered by multiplexed siRNA encapsulation in the lipopolymeric nanoparticle 7C1.

140 The PE encapsulation in the liposomes was responsible for chang

141 -term bioavailability and that citrus pectin encapsulation increased intestinal accessibility during

142 r with self-complementary hydrogen bonds, by encapsulation inside a pair of cyanostar macrocycles.

143 Encapsulation introduces a physical barrier that prevent

144 ells for hundreds of years and that nematode encapsulation is a pleisomorphic trait, prevalent in bot

145 The field of encapsulation is being explored widely and new informati

146 Its selectivity of encapsulation is driven by the coordination of guest fun

147 Membrane encapsulation is frequently used by the cell to sequeste

148 visual system is one thing; the question of encapsulation is quite another.

149 Kinetic analysis of the encapsulation-isomerization event revealed that increasi

150 Two probiotic strains were selected for encapsulation (Lactobacillus plantarum CECT 220 and Lact

151 The encapsulation layer is permeable to reactants, stable un

152 use of a micropatterned polydimethylsiloxane encapsulation layer to form narrow ( 20 mum) microchanne

153 Islet encapsulation may allow transplantation without immunosu

154 This encapsulation mechanism of lithiated/delithiated polysul

155 gen, nutrient, and hormonal passage over the encapsulation membrane is solely dependent on diffusion

156 e extension of the ammonium-sulfate gradient encapsulation method to nucleobase analogues, a liposoma

157 TO/g beta-CD), suggesting an effective solid encapsulation method.

158 th or without gelatin or by the self-healing encapsulation method.

159 We were able to show, that whey protein encapsulation modulated short-term bioavailability and t

160 Upon encapsulation, molecular ion peaks derived from the host

161 n and a ligand fragment was also isolated by encapsulation of a Cs(+) counterion with 2.2.2-cryptand.

162 The unprecedented double concave encapsulation of a metal ion by two bowl-shaped sumaneny

163 Here we report the encapsulation of a Ni-containing polyoxometalate (POM) [

164 bodies, with or without co-administration or encapsulation of a Toll-Like Receptor 9 agonist.

165 ene in water allows for the light-controlled encapsulation of a variety of second guest compounds, in

166 The encapsulation of actinide ions in intermetalloid cluster

167 Encapsulation of allergens or DNA vaccines into nanostru

168 :Chol:DCP was the optimum formulation in the encapsulation of alpha-TOC applying niosome system.

169 t have revealed a role of these cells in the encapsulation of amyloid deposits ("microglia barrier").

170 Encapsulation of an anticancer therapeutic, alpha-cyano-

171 the coating material greatly influenced the encapsulation of antioxidant PC.

172 the presented study, we investigated how the encapsulation of bilberry extract (BE), a source of anth

173 Here, a novel concept for the encapsulation of bioactive proteins in DNA flowers (DNF)

174 arkably high-spin-stabilizing effect through encapsulation of C70 was observed.

175 hell wall, and these unique structures allow encapsulation of cargo that can be contained, virtually

176 Therefore, we hypothesize that co-encapsulation of CDDP and metformin will avoid the promi

177 Encapsulation of compound 2 in PLGA nanoparticles or cyc

178 theory (PST) seems to be very plausible, the encapsulation of content generation deserves further ela

179 The CNA-containing particles show high encapsulation of DNA complementary to the CNA sequence,

180 ing molecular and chemotherapy together with encapsulation of drugs in nanocarriers provides effectiv

181 eins by albumin fusion technology (AFT), and encapsulation of drugs into albumin nanoparticles.

182 , we report on a strategy enabling efficient encapsulation of drugs via remote loading into membrane

183 withdrawing transition metals, thus allowing encapsulation of electron-rich guests mainly driven by a

184 protein based nanocompartments for targeted encapsulation of enzyme pathways.

185 ployed in biotechnology, for example, in the encapsulation of enzymes and for fusion proteins in tiss

186 ategy to promote an efficient noncovalent co-encapsulation of enzymes within a single protein cage of

187 DSC confirmed encapsulation of erlotinib within CYnLIP.

188 Results showed that the encapsulation of flavor nanoemulsions in filled hydrogel

189 of unstable garlic active compounds and the encapsulation of garlic extract proves to be a promising

190 rged as a versatile hydrophilic platform for encapsulation of guest molecules with a capability to re

191 ns, functional hybridization of ZIFs via the encapsulation of guest species (such as metal and metal

192 lution data, showing for the first time that encapsulation of guests by a complex self-assembled fold

193 Therefore, the encapsulation of H. pluvialis oleoresins is an alternati

194 Our results also suggest that the encapsulation of heterologous pathways in bacterial micr

195 water and soil by a mechanism involving the encapsulation of hydrophobes into the self-assembled agg

196 Overall, the encapsulation of labile compounds in more complex system

197 These findings may allow for the encapsulation of large amounts of water-soluble componen

198 shown to be crucial for achieving effective encapsulation of large hydrophobic guests, including ful

199 ity free transfer process and subsequent top encapsulation of large-area CVD-grown graphene.

200 The encapsulation of limonene in freeze-dried gellan systems

201 Encapsulation of lipophilic bioactive compounds using pl

202 two classes of assembly pathways leading to encapsulation of many-molecule cargoes.

203 critical review, the phase transitions upon encapsulation of more than 130 amphiphilic and soluble a

204 bility to tune the dynamic range, as well as encapsulation of multiple dyes to generate a ratiometric

205 Importantly, we demonstrate that 7C1 nano-encapsulation of multiplexed RNAi is a viable BTIC-targe

206 This study evaluated the encapsulation of NO by CDs using phase solubility studie

207 olved elegantly in biological systems by the encapsulation of nucleic acids.

208 The encapsulation of oleoresins improved the stability of AX

209 Oven or microwave roasting and alginate encapsulation of pea flour and starch to produce novel p

210 Encapsulation of peptides can be used to enhance their s

211 d spray-drying techniques were evaluated for encapsulation of phenolic compounds (PC) extracted from

212 We report the encapsulation of platinum species in highly siliceous ch

213 The present work describes the encapsulation of probiotics using a by-product as wall m

214 the obtained data strongly indicate that the encapsulation of pyrazolo[3,4-d]pyrimidines in liposomes

215 in the support and cause HCOx-functionalized encapsulation of Rh nanoparticles by the support.

216 The encapsulation of single cells in tunable hydrogels shoul

217 Encapsulation of specific enzymes in self-assembling pro

218 e the most extensively-used design strategy: encapsulation of sulfur cathodes in carbon host material

219 barrier materials for packaging, sealing, or encapsulation of the active substances, which prevent ox

220 Encapsulation of the Ahmed glaucoma valve (AGV) plate is

221 cert with quantum chemical calculations that encapsulation of the alkali metal cations in the cavity

222 Interestingly, encapsulation of the compound within poly(lactic-co-glyc

223 supramolecular adduct based on the symmetric encapsulation of the Dawson-type [P2W18O62](6-) anion by

224 2 possesses an enclosed cavity suitable for encapsulation of the fullerene C60, whereas original cag

225 Polymer encapsulation of the magnetometer and fiber optical conn

226 roteins in C. elegans, which is based on the encapsulation of the proteins of interest within cationi

227 and nucleic acids without any formulation or encapsulation of the therapeutic.

228 ied by H-bonding to eight MeOH molecules and encapsulation of two benzene guests.

229 t liposomes constitute a suitable system for encapsulation of unstable garlic active compounds and th

230 Encapsulation of unstable guests is a powerful way to en

231 ulsion solvent evaporation method with 72.8% encapsulation of VD3.

232 Cell encapsulation, of up to 8 samples at a time, takes place

233 To evaluate the effects of encapsulation on p40 production in vivo and prevention o

234 gy that enables measurement of the impact of encapsulation on the thermal conductivity (kappa) and th

235 of protein drugs as an alternative to either encapsulation or chemical modifications with polymers.

236 ithout immunosuppression or immunoprotective encapsulation or with only targeted protection from auto

237 ed with either glucose oxidase (via chitosan encapsulation) or a RNA aptamer (via covalent linking) f

238 ich can be prevented by surface passivation, encapsulation, or in-situ cleaving to recover the topolo

239 ke extracellular matrix (Matrigel; MG) islet encapsulation (PEG MG) to improve capsule immunoisolatio

240 ehydratase with a new type of intramolecular encapsulation peptide.

241 e unstable enzyme, including alumina sol-gel encapsulation, physisorption to PDMS channels with, and

242 ored as oral delivery systems with promising encapsulation potentials.

243 compared to free polyphenols regardless the encapsulation procedure and storage conditions.

244 The encapsulation process presented a 1:1 stoichiometry in a

245 The obtained results revealed an optimal encapsulation process was 5% of core loading mass with a

246 Firstly, the effect of the type of CD on the encapsulation process was studied.

247 ogy was applied to investigate the effect of encapsulation processing variables, including core loadi

248 , the similar spectral profile suggests that encapsulation protects cheese fat from interaction with

249 , during larval development for an efficient encapsulation response and for the formation of lamelloc

250 Nano-liposome encapsulation resulted in a significant reduction in aci

251 r inflammatory response, fouling and fibrous encapsulation resulting from the host foreign body respo

252 The encapsulation results in stable 21-22 nm sized CCMV-like

253 layout optimization, assembly processes and encapsulation schemes to yield 3D configurations that sa

254 The encapsulation showed no negative effect on the antioxida

255 degradation have clear correlations with the encapsulation stability of guest molecules within these

256 ative silk micrococoons enable the effective encapsulation, storage and release of other aggregation-

257 ological possibilities and limitations of an encapsulation strategy to establish near-normoglycemia i

258 Novel food-grade hybrid encapsulation structures based on the entrapment of phos

259 in novel properties, not present in previous encapsulation structures.

260 Various methods of crafting the starch-based encapsulation such as electrospinning, spray drying, ant

261 These data indicated that the encapsulation system developed in this study preserves v

262 (BSA) and tannic acid (TA) were tested as Lf encapsulation system for oral administration.

263 Suggested encapsulation system has a great potential for functiona

264 The aim of this study was to develop an encapsulation system to preserve viability of probiotics

265 ers, deployable space structures, reversible encapsulation systems and medical tools and robots.

266 The encapsulation systems can positively influence the contr

267 urally occurring membrane- and protein-based encapsulation systems in microbes and their recent appli

268 from this field aim at pharmaceutical agent encapsulation, targeted drug-delivery, and theranostics.

269 o covalent labeling techniques, we developed encapsulation techniques, where the cargo is loaded into

270 After encapsulation, the active principle was released slower

271 ed include the stabilization of catalysts by encapsulation, the introduction of molecular sieving or

272 Following encapsulation, the printed black phosphorus is stable ag

273 ment of new generation microspheres for cell encapsulation therapy.

274 icles in several applications including cell encapsulation, three-dimensional cell culture, and cell-

275 Here we adapt liposome encapsulation to enable the modular, controlled compartm

276 in a pairwise model simulating high-density encapsulation to normoxic or ischemic culture for 12 hou

277 study, we evaluated the use of nanoparticle encapsulation to overcome this limitation.

278 yer (LbL) approach is reported for probiotic encapsulation to protect probiotics against GI tract ins

279 e pathogen as it liberates bacteria from GBP encapsulation to resume actin-mediated motility and cell

280 Guest encapsulation underpins the functional properties of sel

281 he entropic and enthalpic driving forces for encapsulation versus sequential exterior guest binding t

282 The encapsulation was performed by direct mixing, and direct

283 Betalain encapsulation was performed by ionic gelation as a stabi

284 Encapsulation was shown to promote oxidative stability,

285 Biogenic silica encapsulation was used to stabilize the enzyme and enabl

286 ing the hybrid microcontainers for the siRNA encapsulation we demonstrate the reduction of viral nucl

287 For monolayer encapsulations, we identify representative two-dimension

288 e most common complication was recurrence of encapsulation with elevated IOP (15.9%).

289 while gentle reaction conditions permit cell encapsulation with high viability.

290 beta-CD, since it enabled high curcuminoids encapsulation with low volatile release, moisture conten

291 lantarum displayed high survival (98%) after encapsulation with mixtures of maltodextrin (MD) combine

292 Encapsulation with the ternary blends reduced particle s

293 PFP encapsulation within ELTSLs and ENTSLs did not impact si

294 One option is encapsulation within liposomes, which enables chemical r

295 Based upon Indocyanine Green encapsulation within the nanoparticles, UPA ligand targe

296 rticles exhibited high CS/DNA NP loading and encapsulation within ZN microparticles.

297 Encapsulation yield (%) of resistant starch microspheres

298 High encapsulation yield values were obtained (91-97% and 77-

299 The encapsulation yield was over 80%.

300 ng optical and scanning electron microscopy, encapsulation yield, particle size, thermogravimetry, Fo