ライフサイエンスコーパス: liberation

1 to its description as the 'paradox of pollen liberation'.

2 atter also supporting antiapoptotic molecule liberation.

3 omoted linker breakdown resulting in prodrug liberation.

4 wind-gust aerodynamic models of fungal-spore liberation.

5 switch controlling EstA-assisted sialic acid liberation.

6 inositol 1,4,5-trisphosphate-mediated Ca(2+) liberation.

7 supporting physiological regulation of DIII liberation.

8 SC49992 blocked ADP-induced arachidonic acid liberation.

9 tinuous unit, which enables efficient Ca(2+) liberation.

10 rk-like events, or apparently sustained Ca2+ liberation.

11 ng had no or a negative effect on carotenoid liberation.

12 o be chosen carefully to maximise carotenoid liberation.

13 programs (86%) had protocols for ventilation liberation, 66 (73%) for sedation management, and 54 (60

14 d antiendotoxin antibodies reduces TNF-alpha liberation after hemorrhage/resuscitation and confers a

15 ceptor (GPCR) signaling events lead to IP(3) liberation, although its importance in transducing the h

16 he sheddase ADAM17, which is responsible for liberation and activation of EGFR ligands.

17 he in vitro digestion unraveled the enhanced liberation and bioaccessibility of zeaxanthin from these

18 econdary analyses confirmed the simultaneous liberation and consumption of acetate during mucin degra

19 Liberation and cyclization of SFTI-1, however, was ineff

20 Characteristic signs of pigment liberation and deposition throughout the anterior segmen

21 conditioning dentine slices on growth factor liberation and DPSC behavior.

22 antagonist) each prevented E2-induced HB-EGF liberation and ERK activation.

23 ammation and may play a role in arachidonate liberation and in destruction of invading bacteria.

24 ion and fat type on lutein and beta-carotene liberation and in vitro accessibility from spinach were

25 Lutein liberation and in vitro accessibility were three-fold hi

26 wo previously proposed mechanisms, enzymatic liberation and mechanical force.

27 Bradykinin stimulates tPA liberation and nitric oxide formation.

28 KKbeta, which is required for both NF-kappaB liberation and p65 phosphorylation, IKKalpha is required

29 ding and induced apoptosis partially through liberation and reactivation of FOXO3a.

30 in the refining stage by effective materials liberation and separation are proposed as potential impr

31 Liberation and subsequent biodegradation of the 8:2 fluo

32 radical-mediated mechanism facilitating iron liberation and the production of the tetrapyrrole produc

33 2) activation, resulting in arachidonic acid liberation and thromboxane A(2) generation.

34 Its liberation and transfer to an unsaturated organic molecu

35 rt a dual role for cleavage of Rad9: (1) the liberation and translocation of the BH3 domain-containin

36 xpectations from the Fenn effect that energy liberation (and acto-myosin ATPase rate) in muscle are i

37 reexisting kidney disease, failed ventilator liberation, and acute kidney injury +/- hemodialysis req

38 to plasma kallikrein, leading to bradykinin liberation, and degrades angiotensin II.

39 Severe sepsis, difficult ventilator liberation, and prolonged mechanical ventilation are ass

40 usive spread of calcium evoking regenerative liberation at heterogeneous discrete sites, the sensitiv

41 We probed the SOAF-I(s) liberation at the center of this activation and show tha

42 Thus, ADP-induced arachidonic acid liberation, but not subsequent conversion to thromboxane

43 , in order of decreasing importance, peptide liberation by cellular proteases, T cell repertoire, and

44 Ca(2+) liberation by inositol 1,4,5-trisphosphate (IP(3)) is 'q

45 use of synthetic therapeutics, thus peptide liberation by lactic acid bacteria and probiotics has re

46 ver, in terms of heat stability, kinetics of liberation by the yeast cells, and divalent cation requi

47 The ICU Liberation Collaborative is a real-world quality improve

48 We conclude that the initiation of calcium liberation depends co-operatively upon [InsP3] whereas t

49 In the other cells, basal pole InsP3 liberation did not elicit active Ca2+ release, even at t

50 with changes in NEFA, consistent with their liberation during adipose lipolysis.

51 s is suggested to have major impact on their liberation efficiency from the food matrices.

52 rce but also acts as a cocatalyst for the H2 liberation, enabled by conformational flexibility of the

53 inergic receptor stimulation resulting in AA liberation for PGE(2) formation.

54 n can be accomplished on a time-scale of ion liberation from a droplet in the ESI ion source.

55 The liberation from a mechanical ventilator at 3 months was

56 irst demonstration of photochemical enediyne liberation from a metal complex has led to a new class o

57 Steaming significantly improved lutein liberation from Asia salads, but had no or a negative ef

58 rgic subjects and allergen-induced histamine liberation from basophils in allergic donors.

59 f hydrogen bonds to that promoted by solvent liberation from binding sites.

60 H 9.5, the rate enhancement of p-nitrophenol liberation from BNPP relative to background hydrolysis i

61 bZIP28 to be crucial for its processing and liberation from Golgi bodies.

62 at empty at varying [IP(3)]; and (ii) phasic liberation from homogeneously sensitive stores.

63 ly binds to the NF-kappaB RelA subunit after liberation from IkappaBalpha inhibitor leading to its ub

64 and success and length of time required for liberation from mechanical ventilation (MV) were compare

65 The median time to liberation from mechanical ventilation after respiratory

66 nship between patient characteristics and a) liberation from mechanical ventilation and b) survival.

67 nts often receive sedatives, which may delay liberation from mechanical ventilation and intensive car

68 se; and protocol use as having protocols for liberation from mechanical ventilation and lung protecti

69 Interventions that lead to earlier liberation from mechanical ventilation can improve patie

70 guideline addresses six questions related to liberation from mechanical ventilation in critically ill

71 s evidence-based recommendations to optimize liberation from mechanical ventilation in critically ill

72 Reintubation after liberation from mechanical ventilation is viewed as an a

73 arge destination among survivors, successful liberation from mechanical ventilation while in hospital

74 death during hospitalization and successful liberation from mechanical ventilation.

75 associated with delirium, coma, and delayed liberation from mechanical ventilation.

76 ble evidence relevant to key questions about liberation from mechanical ventilation.

77 The panel provides recommendations regarding liberation from mechanical ventilation.

78 ing spontaneous breathing trials resulted in liberation from mechanical ventilatory support before an

79 intermediate (Fe-NH2NH2(+)) en route to NH3 liberation from N2.

80 ive Ikkgamma(-/-) cells, RSV induced RelA by liberation from p100 complexes.

81 is from glycerol or various fatty acids; its liberation from phosphatidylcholine (PC); and the activi

82 Fat addition increased beta-carotene liberation from raw and steamed puree, but reduced lutei

83 Butter addition led to a 2.5 fold increased liberation from raw spinach puree, while the effect of o

84 This release occurs due to NO liberation from S-nitrosothiols.

85 heat treatments on lutein and beta-carotene liberation from spinach and Asia salads by applying an i

86 itors, thereby potentially retarding glucose liberation from starches and alleviation of postprandial

87 om raw and steamed puree, but reduced lutein liberation from steamed leaves and raw puree.

88 The suppressive activity of YbcL requires liberation from the bacterial periplasm, though the mech

89 Thus, upon liberation from the complex, the positive regulator NasT

90 ssing; one based on highly efficient peptide liberation from the COOH terminus of membrane proteins i

91 ocytes and numerous other cells after Ca(2+) liberation from the endoplasmic reticulum (ER).

92 re local Ca(2+) signals that arise by Ca(2+) liberation from the endoplasmic reticulum through concer

93 re local Ca(2+) signals that arise by Ca(2+) liberation from the endoplasmic reticulum through the co

94 e receptors (IP3Rs) control localized Ca(2+) liberation from the endoplasmic reticulum to generate re

95 health benefits depend among others on their liberation from the plant matrix.

96 eceptor signaling pathways, impaired calcium liberation from the sarcoplasmic reticulum, and impaired

97 atients but had greater difficulty achieving liberation from the ventilator and being discharged from

98 kers were assessed to ensure their efficient liberation from their parent proteins.

99 ortality was 31% [26-37] vs 18% [14-24]; and liberation from ventilation was 47% [42-51] vs 63% [59-6

100 sufficient to achieve, consistent and timely liberation from ventilator support.

101 ventilation, increasing the risk for failed liberation from ventilatory support.

102 he products of the nine ptl (pertussis toxin liberation) genes.

103 ress allowing kinetic monitoring of glycerol liberation has facilitated substrate profiling of the hu

104 ce inositol triphosphate (IP3)-mediated Ca2+ liberation in nonexcitable cells.

105 Spot InsP3 liberation in the basal pole region of approximately 50%

106 Spot InsP3 liberation in the secretory pole region consistently eli

107 and Petit Verdot pomace suppressed TNF-alpha liberation in vitro.

108 (1,4,5)-trisphosphate (IP(3)) evokes Ca(2+) liberation in Xenopus oocytes as elementary events (Ca(2

109 transfer of the drugs across FLM and gradual liberation into acceptor solution (30-240 s).

110 protein is removed from epithelial cells by liberation into the surrounding milieu.

111 The inferred enzymatic mechanism for DMS liberation involves an initial step in which DMSP is mod

112 ICU liberation is an extensive program designed to facilitat

113 bin, induced vaso-occlusion, indicating heme liberation is necessary.

114 The smallest resolved events corresponded to liberation of < 2 x 10-20 mol Ca2+, and large events to

115 nine decarboxylase (SAMdc), were measured by liberation of ((14)CO(2))(.) Migration was assessed in c

116 ole-derived analogue with CuBr(2) results in liberation of 3-(pyridin-2-yl)-1H-indole.

117 No liberation of [(33)P]phosphate is observed from the gamm

118 ion in two ways: release of amyloid-beta and liberation of a bioactive carboxyl-terminal domain from

119 The synthetic strategy used--liberation of a borylene ligand from a transition metal

120 sequelae can be rationalized by invoking the liberation of a common, diffusible, reactive chemical in

121 ity in enzymatic digestion efficiencies, the liberation of a mass-labeled leucine monomer from an oct

122 Subsequent liberation of a second equivalent of p-nitrophenol from

123 The AVP-induced liberation of AA from A-10 cells was selectively inhibit

124 o us that cPLA(2) is not responsible for the liberation of AA to be converted into PGE(2) by F. tular

125 C-H and C-O bonds of the benzylimidates with liberation of alcohols as the only byproduct.

126 ucture calculations, elemental analyses, and liberation of ammonia after treatment with water.

127 or basement membrane proteoglycan and in the liberation of an anti-angiogenic factor.

128 ng steps, beginning with the recognition and liberation of an miRNA-containing precursor miRNA hairpi

129 ially deep in the peat profile, facilitating liberation of ancient carbon as CO2.

130 The synthesis of PGE2 begins with the liberation of arachidonic acid (AA) from membrane phosph

131 imiting step of eicosanoid generation is the liberation of arachidonic acid by phospholipase A2, and

132 pase A(2), a critical enzyme involved in the liberation of arachidonic acid from cellular membranes.

133 e to intracellular membranes with subsequent liberation of arachidonic acid.

134 ion protocol was developed to facilitate the liberation of ARs from mango peels (Mangifera indica L.)

135 Further liberation of Bak specifically from the p53-activated Ba

136 effector activation is a consequence of the liberation of betagamma subunits from endogenous G prote

137 s preceded by the release of Bak from Mcl-1, liberation of Bim from both Bcl-2 and Mcl-1, and the for

138 used to document the in vivo degradation and liberation of bioactive constituents in an s.c. rat impl

139 of high molecular weight kininogen (HK) with liberation of bradykinin.

140 which proteolyzes kininogen, leading to the liberation of bradykinin.

141 ow found a new activity of SPP that mediates liberation of C-terminal peptides.

142 imulation of IP(3) production and consequent liberation of Ca(2+) from the endoplasmic reticulum by i

143 The liberation of calcium ions sequestered in the endoplasmi

144 al accelerated long-term growth owing to the liberation of cancer stem cells and formation of self-me

145 Herein we demonstrate for the first time the liberation of CH4 and NH3 from a well-defined iron cyani

146 onyl complexes is demonstrated by photolytic liberation of CO and subsequent intramolecular carbon-ca

147 nd potassium metabisulfite, also promote the liberation of CO from CORM-3.

148 experiments indicated that AMPK leads to the liberation of cofilin from 14-3-3 protein.

149 l transitions were associated primarily with liberation of CoREST from promoters with transcriptional

150 of the proteolytic enzyme necessary for the liberation of daughter cells following mitosis.

151 that efficient, cyclic nucleotide-dependent liberation of diffusible PKA catalytic subunits from cyt

152 Protonation of the hydrosilane followed by liberation of dihydrogen is key to success, fulfilling t

153 Using water as the oxygen donor with liberation of dihydrogen represents a safe and clean pro

154 o the corresponding nitriles and imines with liberation of dihydrogen.

155 lic acid group, and the actual oxidant, with liberation of dihydrogen.

156 -O bond with concomitant O-atom transfer and liberation of dinitrogen.

157 DPP5 elaborately complemented DPP7 in liberation of dipeptides with hydrophobic P1 residues.

158 pecific requirement for IRF1 and GBPs in the liberation of DNA for sensing by AIM2 depending on the p

159 adation of trapped TOP2-cleavable complexes, liberation of DNA strand breaks, and repair of those bre

160 or withdrawal in the opposite manner, by the liberation of E2F from inactivating complexes and by con

161 timulation and, by inference, the subsequent liberation of E2F in terminally differentiated myocytes

162 We suggest that the liberation of effector function is tightly controlled th

163 D scrambling in methanol without concomitant liberation of either methane or dihydrogen (k(H)/k(D) =

164 s, IB is a potent inhibitor of STAT5 through liberation of endogenous phosphatase activity following

165 sclerosis may provide a new strategy for the liberation of endogenous VEGF-C and the prevention of ly

166 s hydrolyzed by the enzyme, resulting in the liberation of excess ammonia, some of which neutralizes

167 n at Met(469)-Thr(470), which results in the liberation of ezrin from the apical membrane of the pari

168 the cAMP-dependent protein kinase to promote liberation of fatty acids as a fuel source.

169 as greater than predicted for stoichiometric liberation of free talin-H.

170 duction in the particle phase accompanied by liberation of gaseous HCl from the particles.

171 estin-mediated signaling but rather involves liberation of Gbetagamma subunits and activation of calc

172 sphosphate (IP(3))-sensitive Ca2+ stores via liberation of Gbetagamma.

173 lactosidase was established by analyzing the liberation of GlcNAcalpha1-->4Gal from GlcNAcalpha1-->4G

174 tissue triacylglycerol stores results in the liberation of glycerol and nonesterified fatty acids tha

175 The liberation of gravitational potential energy then bright

176 to form the Si-E bond (E = N, S, O) with the liberation of H2 (21 examples).

177 he absence of oxidants and is accompanied by liberation of H2, with water serving as a source of oxyg

178 nd (d) the geometric factors involved in the liberation of H2.

179 r mixing of the acid with the sample and the liberation of HCN.

180 ion of EGFR by E2 was dependent on the rapid liberation of heparin-binding EGF (HB-EGF) from cultured

181 y in older animals, likely because of slower liberation of hepatic lipid.

182 Ub-AMC is efficiently hydrolyzed with liberation of highly fluorescent AMC by two rabbit retic

183 Liberation of HMGB1, a nuclear protein that contributes

184 ce of dioxygen, result in the stoichiometric liberation of hydrogen peroxide, diminishing the perceiv

185 form bonds between main group elements with liberation of hydrogen, dehydrocoupling or dehydropolyme

186 atory cytokine interleukin 17A (IL-17A), and liberation of IL-17A was required for transmission of No

187 ease assay format, where the enzyme-mediated liberation of individual nanoparticles from a surface is

188 rine interface is likely to be important for liberation of intact islets.

189 We established that liberation of intracellular Ca(2+) with T cell receptor

190 The microextraction method is based on the liberation of iodine in the presence of selenium; the li

191 resulted in a three- to fourfold increase in liberation of lutein and beta-carotene when comparing wh

192 ated cap attached to RNA and resulted in the liberation of m7GDP.

193 ol(-1) K(-1) per nucleotide, which signifies liberation of manifold frozen degrees of freedom involve

194 uitination in vitro and in vivo, inefficient liberation of Mga2p90 by Cdc48p(Npl4p/Ufd1p)in vitro, an

195 sly applied peptide precursors, we show that liberation of MHC I epitopes may directly require PC7.

196 decarbonylation of primary alcohols with the liberation of molecular hydrogen and carbon monoxide was

197 we propose that the exoglycosidase-dependent liberation of monosaccharides from these glycoconjugates

198 hip between commensal sialidase activity and liberation of mucosal sialic acid, a receptor and nutrie

199 Selective liberation of N-atoms from multiple commercial standards

200 sine triphosphate (GTP)ase implicated in the liberation of nascent vesicles from the plasma membrane

201 nenzymatic reactions leading to the ultimate liberation of NB or nitroxyl, thereby inhibiting AlDH.

202 However, the uncontrolled or excessive liberation of NETs also damages surrounding cells and ca

203 The liberation of NF-kappaB dimers from inhibitors of kappaB

204 tivates IkappaB kinase (IKK), leading to the liberation of NF-kappaB from its complex with IkappaB.

205 NF-kappaB, a process quite distinct from the liberation of NF-kappaB from its cytoplasmic inhibitor I

206 the destruction of IkappaB proteins and the liberation of NF-kappaB to enter the nucleus and activat

207 new structural architecture for the tunable liberation of nitrite and nitric oxide from organic comp

208 times faster than the primary nitrate, with liberation of nitrite.

209 fungi commonly participate in the enzymatic liberation of nitrogen (N) from soil organic matter (SOM

210 oteins, leading to their degradation and the liberation of nuclear factor kappaB for gene transcripti

211 ted activation of Galphai caused concomitant liberation of NuMA from LGN.

212 e enzyme-bound ADP is attacked by water with liberation of orthophosphate and formation of AMP.

213 M1 and 7SK snRNA, implicating the PID in the liberation of P-TEFb from the 7SK small nuclear ribonucl

214 We found that liberation of p53 through chemical antagonism of one of

215 parasitophorus vacuolar membranes (PVM); and liberation of parasites enclosed within the vacuole from

216 other is more slowly activated and involves liberation of particulate MEKK1 by proteolytic cleavage

217 Bioamplification means the liberation of persistent lipophilic organic pollutants (

218 icated, or if air leakage occurred after the liberation of pleural adhesions.

219 icated, or if air leakage occurred after the liberation of pleural adhesions.

220 d to destruction of epithelial cells and the liberation of potential nutrients for the bacterium.

221 NC domain and the PR domain, the proteolytic liberation of PR previously was inferred to be essential

222 diation that was attributed to the increased liberation of precursor linolenic acid mainly from monog

223 Liberation of presynaptic Gbetagamma causes substantial

224 vitis of spondyloarthropathy is secondary to liberation of proinflammatory mediators from the enthesi

225 of the transmembrane domains that avoids the liberation of protons from cells to stomach.

226 r104 and supports a role for the loop in the liberation of pyrophosphate.

227 etinal revascularization in part through the liberation of repulsive guidance cue semaphorin 3A (Sema

228 inhibition of rRNA transcription and, thus, liberation of RNA polymerase for binding to other promot

229 T cell-specific signal for the induction and liberation of sFasL.

230 The system, which is based on liberation of sgRNAs by processing flanking tRNAs, permi

231 These data implicate dermal liberation of specific chemokines in the recruitment of

232 gastrointestinal tract greatly depend on the liberation of sugar moieties.

233 de renders the growth factor latent, and the liberation of TGF-beta from this state is crucial for si

234 yclic heterocyclic products was coupled with liberation of the active catalyst.

235 hosphonate prodrugs to bone and slow release liberation of the active constituents in vivo.

236 us solvents and in thin films results in the liberation of the alcohol moiety from the ester.

237 side in separate domains of the protein, and liberation of the amidase domain from the synthetase dom

238 IBAL-H), hydrolysis of the oxazolidine ring, liberation of the amino group, and installation of the N

239 , followed by hydrolysis of the oxazolidine, liberation of the amino group, and N-acylation.

240 hat Fe65 stimulates gamma-secretase-mediated liberation of the APP intracellular domain (AICD).

241 Liberation of the contact ion pair through displacement

242 ure for the removal of the BF(2) moiety, and liberation of the corresponding free-base dipyrrin.

243 t also in a paracrine manner via proteolytic liberation of the EGF-like domain.

244 ne disrupts neuronal calcium homeostasis via liberation of the endoplasmic reticulum (ER) store and i

245 and degradation, a condition exacerbated by liberation of the excitatory amino acid glutamate.

246 IR, support a N2 fixation mechanism in which liberation of the first NH3 occurs upon delivery of five

247 Oxidative decomplexation of 14 results in liberation of the free oxabicyclo[3.2.0]heptadiene 15, w

248 tion of the autoinhibitory prodomain and the liberation of the functional activity of the emerging en

249 is transformation cannot be recycled because liberation of the homologated product destroys the compl

250 major shedding protease, responsible for the liberation of the inflammatory cytokine TNFalpha and lig

251 ergoes efficient self-cleavage, resulting in liberation of the internal hammerhead Rz, which we targe

252 (RT-PCR) analyses documented efficient self-liberation of the internal targeted Rz in vivo, and show

253 brane Notch receptors results in proteolytic liberation of the intracellular domain of Notch, which t

254 e (Zea mays ssp. mays) domestication was the liberation of the kernel from the hardened, protective c

255 the sp(3)-sp(3) carbon-carbon bond with the liberation of the ketone.

256 he number average molecular weight (M(n)) or liberation of the maleimide, furan, or anthracene moieti

257 ase, angiotensin converting enzyme, to allow liberation of the minimal epitope.

258 ient cell killing by BCNU as a result of the liberation of the more potent inactivators, O(6)-benzylg

259 canonical Notch pathway involves proteolytic liberation of the Notch-1 intracellular domain (NIC-1),

260 0.1 M NaCl and 1% (v/v) Triton X-100 caused liberation of the Ru(bpy)32+ from the liposome.

261 Liberation of the sequestrated bioactive molecules from

262 to the inactivation of AAT, to the follow-up liberation of the Ser protease activity, and because of

263 endothermic and entropically favored by the liberation of the solvent molecules.

264 In contrast, slow codons lead to slow liberation of the start codon by initiating ribosomes, t

265 or gamma-secretase activity, indicating that liberation of the tyrosine kinase intracellular domain (

266 Therefore, the DNA-binding capability and liberation of the YtgR domain from a membrane-anchored p

267 The liberation of these fragments in the muscle microenviron

268 y decoded in the hypothalamus by proteolytic liberation of uroguanylin, inducing GUCY2C signaling and

269 dysfunction, virus clearance, and shortened liberation of ventilator and ventilator days.

270 As expected, cooking enhanced the production/liberation of volatile compounds.

271 luorescence zinc indicator, demonstrated the liberation of zinc from intracellular stores by peroxyni

272 intracellular zinc release demonstrated the liberation of zinc from intracellular stores by peroxyni

273 tioned near the start of the coding region, 'liberation' of the initiation codon for loading of the n

274 V) is required for optimal bacteriorhodopsin liberation on the FT-ICR, in comparison to the Q-ToF and

275 dependent extraction and resort to enzymatic liberation only if mechanical forces fail to retrieve an

276 nach samples, possibly due to differences in liberation or degradation between the two plant matrices

277 waves, and then a near-simultaneous calcium liberation originating at multiple sites.

278 orescence intensity, suggesting that calcium liberation persists even while the fluorescence begins t

279 e literature that led to the creation of ICU liberation philosophy and to explain how this patient- a

280 y mobilization, be managed with a ventilator liberation protocol, be assessed with a cuff leak test i

281 ated to rehabilitation protocols, ventilator liberation protocols, and cuff leak tests.

282 analysis yields an expression for the energy liberation rate that implies a reduced rate in stretch v

283 ions specifically disrupt intracellular Ca2+ liberation rather than reduce cytosolic Ca2+ buffering o

284 involving widely varying amounts of calcium liberation, rather than falling into separate population

285 The mean latency to onset of calcium liberation shortened as about the square of the flash st

286 protein profiling without labeling or glycan liberation steps.

287 Albumin liberation, testosterone metabolism, and P450 induction

288 decomposition by benzyne formation and Li-F liberation, than the Ga-C(aryl) species.

289 Ca2+ liberation through inositol 1,4,5-trisphosphate receptor

290 Ca2+ liberation through inositol 1,4,5-trisphosphate receptor

291 n ER Ca(2+) store content, by imaging Ca(2+) liberation through inositol trisphosphate receptors (IP(

292 ing chain that includes the steps from waste liberation through materials refining.

293 ed that oxidant-induced intraneuronal Zn(2+) liberation triggers a syntaxin-dependent incorporation o

294 howed a graded dependence of rate of calcium liberation upon [InsP3], due to recruitment of additiona

295 The final liberation was carried out under slightly acidic conditi

296 ayed inhibition, whereas IP(3)-evoked Ca(2+) liberation was potentiated by Ca(2+) entry during action

297 Results for beta-carotene liberation were similar, whereas that of beta-carotene a

298 xisting kidney disease and failed ventilator liberation, were measured at the time the patients met c

299 eration in MS lesions leads to waves of iron liberation, which may propagate neurodegeneration togeth

300 on from amines and water with concomitant H2 liberation with no added oxidant, catalyzed by a well-de