ライフサイエンスコーパス: salt solution

1 ed by in situ redox replace reaction in a Pd salt solution.

2 DPs, bovine serum albumin (BSA), or balanced salt solution.

3 altering the height of a bottle of balanced salt solution.

4 a calcium- and potassium-containing balanced salt solution.

5 es separating compartments of pure water and salt solution.

6 strates via laser photoreduction of a silver salt solution.

7 after 24 h in 25 microM total Al in a simple salt solution.

8 DNA flexibility in gels, compared to aqueous salt solution.

9 matrix was returned to a serum-free balanced salt solution.

10 trifugation, C is a monomer in physiological salt solution.

11 ing is substantially inhibited by hypertonic salt solution.

12 ation of perfluorinated ionomer membranes in salt solution.

13 binding is strongly inhibited by hypertonic salt solution.

14 iven a subconjunctival injection of balanced salt solution.

15 njection of either TGF-beta or of a balanced salt solution.

16 connected to an elevated bottle of balanced salt solution.

17 and subsequently regenerated by washing with salt solution.

18 mparison with the value measured in a simple salt solution.

19 tinum adatoms on the monolayer in an aqueous salt solution.

20 the nanoparticles from aggregating in a high-salt solution.

21 PAM solution to solidify upon contact with a salt solution.

22 , intensifying scaling on the CEM and in the salt solution.

23 nned in oil and transferred to physiological salt solution.

24 s are also extractable from bread crumb with salt solution.

25 ng increased "hedonic responsiveness" to the salt solution.

26 to date of salting-in behavior in a protein-salt solution.

27 ed with tobramycin/dexamethasone or balanced salt solution.

28 spension (10 mg) prepared in 0.1 mL balanced salt solution.

29 rolyte, propylene carbonate (PC), and its Li salt solutions.

30 th larger amounts of higher-concentration Li salt solutions.

31 mistry for labeling carbohydrates in aqueous salt solutions.

32 wo nanoscale hydrophobic surfaces in aqueous salt solutions.

33 te to the high thermostability of HDL in low-salt solutions.

34 lar phases swell when immersed in monovalent salt solutions.

35 imilar studies of bilirubin in micellar bile-salt solutions.

36 sformational effect on protein solubility in salt solutions.

37 m hydroxide separation from alkaline aqueous salt solutions.

38 and related non-telomeric isomers in aqueous salt solutions.

39 ed by excess Al in agarose gels or in simple salt solutions.

40 most apparent when assayed in micellar bile salt solutions.

41 ated PTL activity normally in monomeric bile salt solutions.

42 ed in high-concentration, near-physiological salt solutions.

43 , and tends to precipitate in buffered 0.1 M salt solutions.

44 s different in 50 mM Tris buffer compared to salt solutions.

45 f an ion exchange membrane equilibrated with salt solutions.

46 in modifying interactions compared to simple salt solutions.

47 e electrostatic interactions in concentrated salt solutions.

48 le precisely the reverse occurs in potassium salt solutions.

49 network not present in bulk water and dilute salt solutions.

50 -ice interface during the freezing of dilute salt solutions.

51 membrane in multisalt solutions than single-salt solutions.

52 in the presence of symmetric and asymmetric salt solutions.

53 erm stability in biological buffers and high-salt solutions.

54 used to generate acids and bases from 100 mM salt solutions.

55 midity from 16% RH to 88% RH using saturated salt solutions.

56 or reversible protein-protein aggregation in salt solutions.

57 t near the vapor-liquid interface of aqueous salt solutions.

58 nanoparticle templates and aqueous palladium salt solutions.

59 d by ions in dilute and concentrated aqueous salt solutions.

60 ty-gradient energy from ammonium bicarbonate salt solutions.

61 Bathing each channel with a high salt solution (1.5 M NaCl) produced stochastic openings

62 s of C. albicans incubated in Hanks balanced salt solution (+/-10% bovine serum albumin [BSA]) or RPM

63 eurofilaments to a solid substrate in a high-salt solution (170 mM NaCl), in the presence of coisolat

64 tic particles suspended in low concentration salt solutions (~ 2 mS/m).

65 t efficiency (~75%) in a highly concentrated salt solution (20 wt% NaCl) under 1 sun irradiation, as

66 soaked for 12 h in salt solution; 3.

67 soaked for 4 h in salt solution; 4.

68 rneas were administered with either balanced salt solution AAV5-naked vector, or AAV5-Id3 vector (n =

69 of systems: 1), ternary mixtures of MO with salt solutions above the hydration boundary; and 2), qua

70 Ns were suspended in HEPES-buffered balanced salts solutions adjusted to pH 6.7, 7.2, 7.7, or 8.2.

71 er 14 days of local endothelin-1 or balanced salt solution administration to the microvasculature of

72 ely seek out a once-undesirable concentrated salt solution after being depleted of bodily sodium desp

73 ficantly higher than ECs exposed to balanced salt solution alone or to BSA (P < 0.05) in all experime

74 icrog) in balanced salt solution or balanced salt solution alone was injected intravitreally immediat

75 Temperature increases are monitored in salt solutions analogous to those in small aquatic organ

76 but the tissue can be washed using balanced salt solution and gently injected.

77 lysis of unlabelled bacteriophage T7 in both salt solution and mouse blood plasma, using just ~1 x 10

78 Isotonic salt solution and normal donor samples of milk, colostru

79 Incubation of lenses in low-K+ balanced salt solution and TC-199 medium, containing physiologica

80 apable of moving in various media, including salt solutions and artificial serum.

81 Leu peptide does not precipitate in buffered salt solutions and binds to lipid bilayers.

82 generated from the nebulization of ammonium salt solutions and collected using a filter pack samplin

83 ing to the density by flotation in different salt solutions and to the diameter.

84 of randomized double-blind 120-s exposure to salt solutions and water.

85 n in samples with high ionic strength, (e.g. salt solutions) and allow highly sensitive detection of

86 and was abolished in Ca2+-free physiological salt solution, and by pretreatment with La3+, 2-APB, tha

87 ected to sequential treatments with enzymes, salt solutions, and detergents to expose the NC.

88 ock involve incubation in high-concentration salt solutions, and lower permeability of the capsids to

89 ated by adding terephthalic acid (TA) to our salt solutions, and the product of its reaction with OH,

90 Mixed salt solutions approximating physiological conditions ex

91 h mononucleosomal calf thymus DNA in aqueous salt solutions are characterized by vapor pressure osmom

92 Osmotic pressure measurements of spermidine salt solutions are consistent with this interpretation.

93 y-synthesized Cs(2)SnCl(6) powders from CsCl salt solutions are successfully encapsulated into a sili

94 contralateral eye was injected with balanced salt solution as a control.

95 fluid interior of muscle resembles a simple salt solution as in a 4% agarose gel.

96 based beads as the stationary phase and bile salt solution as the mobile phase.

97 of 1% trifluorothymidine (TFT) and balanced salt solution as the vehicle control.

98 ms of reproducing the interfacial tension of salt solutions as a function of the salt molality; the s

99 When using mixed salt solutions as feed, NF membranes with strong negativ

100 nted long-fragment DNA bundles in monovalent salt solutions as first order, with a small but finite v

101 interface of NaHSO4, NH4HSO4, and Mg(HSO4)2 salt solutions as well as H2SO4 and HCl acid solutions a

102 of the propeptide of subtilisin E in aqueous salt solution, as well as for strong intermolecular inte

103 In a glucose-salt solution (Earle's balanced salt solution), asparagine (Asn) stimulates ornithine de

104 ed with oxygenated/heparinized physiological salt solution at 37 degrees C.

105 hermal unfolding of lipid-free apoA-1 in low-salt solution at pH approximately 7, by using differenti

106 mized to receive intracameral TA or balanced salt solution at the end of surgery.

107 d --> condensed DNA transition in polyvalent salt solutions at small enough polyvalent salt concentra

108 individual particles generated by bubbling a salt solution before and after addition of heterotrophic

109 or very low salt concentrations at which the salt solution behaves ideally.

110 aneous intercalation of cations from aqueous salt solutions between two-dimensional (2D) Ti3C2 MXene

111 r filtration (angiotensin II, Hanks Balanced Salt Solution, Bovine Serum Albumin), NL-D3 is detected

112 1, an 8.0-mm diameter treated with balanced salt solution (BSS) and an 8.0-mm removal; group 2, an 8

113 patients who received enoxaparin in balanced salt solution (BSS) during cataract surgery, while stand

114 rature of the fragmatome tip in the balanced salt solution (BSS) increased from 22.0 to 24.0 oC, whil

115 Seprafilm also was soaked in balanced salt solution (BSS) incubated at 37 degrees C, and the p

116 hyaluronic acid (Healon) or sterile balanced salt solution (BSS) into the subretinal space of 4-5-day

117 apentinoids, chilled intraoperative balanced salt solution (BSS) irrigation, cycloplegia, and specifi

118 An IVT injection of balanced salt solution (BSS) or lipopolysaccharide (LPS) was foll

119 rmalin for 2 hours and equilibrated in basic salt solution (BSS) over a 24-hour period.

120 roups of rabbits had IVI of sterile balanced salt solution (BSS), MTX (400 microg), dexamethasone (De

121 ips between T1 relaxation times and balanced salt solution (BSS), to simulate human vitreous and aque

122 rouracil (5-FU; 5 mg, 50 mg/mL), or balanced salt solution (BSS; 0.1 mL, control).

123 rth, TX) ophthalmic suspension, and balanced salt solution (BSS; Alcon Laboratories).

124 , case length, vitreous substitute (balanced salt solution [BSS], gas, air, or oil), sclerotomy sutur

125 to calculate CO2 solubility in aqueous mixed-salt solution by using the additivity rule of the Setsch

126 Since detachments were created with balanced salt solution, by examination, all retinas had spontaneo

127 mobilities observed in all buffer and buffer/salt solutions can be predicted within approximately 20%

128 In lowered salt solutions, CFTR P(o) declined within 1 s to a stabl

129 with experiments in aqueous media, including salt solutions commonly used in the study of proteins an

130 drives water flow from the pure-water to the salt-solution compartment.

131 In the case of bulk water and aqueous salt solutions, complete tranformation of liquid to soli

132 Nanosprayed salt solutions comprised of stable analogs, as proxies t

133 All three salt solutions contained WSOM with a higher fluorescence

134 ated for 5, 10 or 20 min in Earle's balanced salt solution containing 1.2 mM tannic acid (to enable v

135 TALH cells were incubated in a physiological salt solution containing high or low levels of NaCl.

136 ollicles incubated in vitro in physiological salt solution containing small amounts of blood and fluo

137 By immersing these gel fibers in salt solutions containing both Ca(2+) and Na(+) at varyi

138 he presence of elastin fragments or balanced salt solution (control).

139 phase conditions upon exposure to high ionic/salt solutions, corroborated by T(m) experiments.

140 detergents (SDS plus Nonidet P-40) and high-salt solutions, could convert NF-P1 into NF-P2.

141 Elevated concentrations of nondenaturing salt solutions defeat the effects of reverse micelle-pro

142 he charge states formed from the nonvolatile salt solutions do not change significantly for up to 7 m

143 In a glucose-salt solution (Earle's balanced salt solution), asparagi

144 Earle's balanced salts solution (EBSS) with limited NaCl concentration wa

145 nfluent salt concentration of 15 g.L(-1) and salt solution flow rate of 0.04 mL.min(-1), and to be op

146 of 2.5 mg/mL collagenase type 2 in balanced salt solution followed 1 hour and 15 minutes later by an

147 ATP-sepharose matrix and washed with a high salt solution followed by nicotinamide adenine dinucleot

148 It was found that protein aggregation in salt solutions followed 2 distinct Hofmeister series dep

149 bridement was produced by injecting balanced salt solution forcefully into the subretinal space.

150 (Im chi((2))) spectra of acid and bisulfate salt solutions further reveal that hydrogen-bonded water

151 RNA molecules in monovalent salt solutions generally adopt a set of partially folded

152 Radiolysis-induced reactions in salt solutions have substantially different results in p

153 of two inhalation exposures: Hanks' balanced salt solution (HBSS) and corn dust extract (CDE; 0.4 mic

154 d with EMD, AMEL, and PGA in Hank's balanced salt solution (HBSS) for 1, 3, and 24 hours.

155 apped but unopened bottle of Hank's balanced salt solution (HBSS) grew O. anthropi.

156 njections of either HSV-1 or Hanks' balanced salt solution (HBSS).

157 LTB4]), or negative control (Hanks' balanced salt solution [HBSS]).

158 lacing hemofiltration volume with a balanced salt solution (HF group).

159 In addition, VSFG spectra of bisulfate salt solutions highly resemble that of the dilute H2SO4

160 613 +/- 13 pM for CE of fluorescein disodium salt solution in borate buffer.

161 only source of Ca(2+) was the physiological salt solution in the patch pipette containing 2 mM Ca(2+

162 sive mechanisms when perfused with isosmolal salt solutions in a bath with appropriate salt and urea

163 Concentrated salt solutions in nonaqueous solvents exert a remarkable

164 additional simulations of 20 different pure salt solutions-in which no hydrophobic solutes are prese

165 of Pronase, but not DNAse, RNAse, or strong salt solutions, indicating covalent attachment to protei

166 e hydrochloride and subconjunctival balanced salt solution injection (Control group) or topical anest

167 After diclofenac sodium salt solution injection, drug levels declined rapidly wi

168 nal animals received either drug or balanced salt solution injections into normal eyes, and paraffin

169 ontrols that received only peribleb balanced salt solution injections.

170 rate that the usage of specific ionic liquid salt solutions instead of NaCl or KCl solution as suppor

171 from LWS elevates pH near the CEM and in the salt solution, intensifying scaling on the CEM and in th

172 stingly, contrary to some other near-neutral salt solution interfaces (e.g., chlorides and nitrates),

173 jecting 0.25% sodium hyaluronate in balanced salt solution into the subretinal space.

174 nd 5 IU/ml dalteparin) and placebo (balanced salt solution) intravitreally applied during routine par

175 n in OmpF porin bathed by a 1M KCl symmetric salt solution is examined.

176 2-step (n = 6) procedure, in which balanced salt solution is first used to define the subretinal spa

177 (DMPC) bilayer bathed by a 1 M [KCl] aqueous salt solution is generated to explore the microscopic de

178 ted overall paramagnetism in the oxoammonium salt solutions is explained by a redox equilibrium as sh

179 ion of isolated fiber cells in physiological salt solutions is mediated by Ca(2+)-activated protease(

180 The conductive marker segment, e.g., a salt solution, is protected on both sides from the princ

181 n between the magnetic susceptibility of the salt solution, its concentration, and ease of actuation.

182 rrents between BN nanosheets in a variety of salt solutions (KCl, NaCl and CaCl2) at low salt concent

183 much higher than those reported for standard salt solutions (KD) of about 40 and 130 nM, respectively

184 etely stripped from their surfaces with high salt solutions, leaving the IgG-PG/GCN4 DNA binding comp

185 The salting-out effect induced by aqueous salt solutions lowers the phase transition temperature o

186 g it, while excess OH(-) accumulating in the salt solution migrates across the anion exchange membran

187 Understanding the freezing of salt solutions near solid surfaces is important in many

188 In these salt solutions, numerous illite fibers precipitated afte

189 ing was reversibly controlled by exposure to salt solution of varying concentration, which "doped" co

190 for a monoclonal antibody in the monovalent salt solutions of KF, KCl, and KSCN under different pH c

191 understanding of nucleation and freezing of salt solutions on solid surfaces and the effects of salt

192 Palomid 529 (600 microg) in balanced salt solution or balanced salt solution alone was inject

193 compared with treatment with Hank's balanced salt solution or DCs transduced with rat HER-2/neu.

194 compared to the decrease induced by balanced salt solution or to the decrease in rabbits without mini

195 rol nasal spray, which consisted of buffered salt solution; or 3) no treatment.

196 ), quaternary mixtures of MO with betaOG and salt solutions over a wide range of hydration conditions

197 ossible salt concentrations: (a) in a dilute salt solution, PE chains possess an extended coil confor

198 MA network was superfused with physiological salt solution (pH 7.4, 37 degrees C).

199 nal fluid at pH 4.5 and 7.2, (2) physiologic salt solutions (phosphate-buffered saline and saline) co

200 mples such as gold nanoparticles and aqueous salt solution placed on the back side of a window.

201 repared by incubating PMN in Hanks' balanced salt solution plus TNF-alpha for 1-4 hrs.

202 ng on Sephacryl HR S500 in buffered balanced salts solution plus albumin.

203 ng with soap (observation), oral rehydration salt solution preparation (demonstration), and zinc use

204 f an intervention effect on oral rehydration salt solution preparation and breastfeeding outcomes.

205 s dissolved in a low-pH isotonic physiologic salt solution produced significant force generation in a

206 herwise untreated follicles in physiological salt solution (PSS) containing either calmidazolium or W

207 mL Kenalog in one eye and 0.1 mL physiologic salt solution (PSS) in the fellow eye.

208 fluid balance following ingestion of a high-salt solution-rats produced significantly more urine, co

209 OP) model for (CAG)(n) repeats in monovalent salt solutions reproduce experimentally measured melting

210 g the films of agarose and lipids in aqueous salt solutions resulted in swelling and partial dissolut

211 ary outcomes were intake of oral rehydration salt solution, severity of vomiting, and serum levels of

212 0.005 mg, 0.02 mg, and 0.08 mg) and balanced salt solution showed normal ciliary body epithelium at t

213 arge properties (zeta-potential) in 1 mM KCl salt solution showed that apo-Lf reached the net charge

214 r elements leach from composites stored in a salt solution simulating saliva than from composites sto

215 n-specific and explains why all concentrated salt solutions slow down water dynamics.

216 sulfate (SDS)), Fe(3)O(4)/SDS, seawater, and salt solutions (sodium chloride (NaCl) and calcium chlor

217 covered that exposure to highly concentrated salt solutions such as seawater only moderately reduced

218 t here that the application of some ammonium salt solutions, such as citrates and phosphates, instead

219 of a metal salt, or the controlled mixing of salt solutions supplying a metal cation and an elemental

220 x 50, and Dowex Mac 3) were compared in pure salt solutions, synthetic urine, and real stored urine.

221 2+)-K(+), and Ca(2+)-K(+)) occurred in these salt solutions than in water (H(+)-K(+)).

222 e in the chemistry of concentrated inorganic salt solutions than was previously recognized.

223 nsformed and directly captured into a liquid salt solution that is suitable for subsequent distillati

224 of 2.5 mg/mL collagenase type 2 in balanced salt solution that was left in the stroma for 1 hour and

225 Using salt solutions that could be continuously regenerated wi

226 lightly reduced from 7.4 to 6.6, in isotonic salt solutions that simulate the acidic extracellular mi

227 At 25 degrees C in the presence of this salt solution, the enzyme was approximately 100% stable

228 In highly concentrated salt solutions, the water hydrogen bond (H-bond) network

229 s tested by filling the globes with balanced salt solution through an anterior chamber port and slowl

230 Increasing protein solubility in salt solutions through polymer conjugation could lead to

231 S to image the mixing of aqueous glucose and salt solutions throughout the entire helix volume.

232 alpy calculation for noble gases in a molten salt solution to a single functional form using van der

233 Likewise, the application of an aqueous salt solution to one side of the pizza crust led to an e

234 ration of topical 2% epinephrine or balanced salt solution to six cynomolgus monkeys.

235 er as the chemoattractant and Hanks balanced salt solution to test random migration.

236 aqueous solutions by subjecting six chloride salt solutions to controlled centrifugal acceleration ac

237 Langmuir-type charge compensation in dilute salt solutions to nonclassical charge overscreening in h

238 of rose bengal (0.1% or 0.2% RB in balanced salt solution) to the de-epithelialized cornea for 30 mi

239 tances, such as nanofluids, surfactants, and salt solutions, to modify rock wettability and improve c

240 -100, tobramycin/dexamethasone, and balanced salt solution treatments.

241 in a dosage of 0.1 microgram/day or balanced salt solution (two rabbits) was delivered to the perineu

242 ropium bromide nasal spray 0.06% in buffered salt solution, two 42-micrograms sprays per nostril admi

243 to mice that were dialyzed with an isotonic salt solution under quiescent conditions for 1 h produce

244 cting membrane-confined nanowires with metal salt solutions under reducing conditions, site-specific

245 compounds by reaction with appropriate metal salt solutions under reducing conditions.

246 orgoing perfusion, fixation, and addition of salt solutions upon inflation that resulted in an ungapp

247 laque forming unit in 0.1 ml Hank's balanced salt solution) was inoculated 4 days after gas compressi

248 chloride (8-20 microg in 0.04 mL of balanced salt solution) was performed in 9 eyes, followed by inje

249 hed male C57BL/6 mice injected with balanced salt solution were used as control subjects (five for ea

250 and isopropylamine volatilized when aqueous salt solutions were dried to a residue at ~20 degrees C,

251 In the w|RTIL system, two rubidium salt solutions were employed: RbNO(3) and RbNO(3) plus R

252 of proteins from aqueous ammonium and sodium salt solutions were investigated.

253 trations in air-saturated phosphate-buffered salt solutions were monitored by measuring the decay of

254 Microclimates, obtained with saturated salt solutions were used for conditioning samples and th

255 salt solutions, where the corresponding findings were re

256 6, but they transfer chloride salts from 1 M salt solutions, whereas B18C6 does not.

257 se forces by varying the ionic strength of a salt solution, which has been shown to be a parameter th

258 ration rates and high deliquescence of these salt solutions, which are essential for stability within

259 incubated at 37 degrees C in a physiological salt solution while the solution was bubbled with four d

260 ug recognition occurs over "other" in sodium salt solutions while precisely the reverse occurs in pot

261 formation was examined using Hanks' balanced salt solution with and without selective inhibitors of A

262 Here we show that illumination of gold salt solutions with circularly polarized light induces t

263 ons of stroma-free hemoglobin and hypertonic salt solutions with colloid, searches for the optimal co

264 ltage-clamped with patch pipettes containing salt solutions with defined [Mg(2+)] and [Ca(2+)].

265 tions are rationalized by the association of salt solutions with increased surface tension and the pr

266 superconcentrated regimes, such as "water-in-salt" solutions with concentrations above 10 to 20 m, wh