ライフサイエンスコーパス: molecular oxygen

1 ource (blue LED), and a sustainable oxidant (molecular oxygen).

2 transformations of mercury in the absence of molecular oxygen.

3 lective reaction of an amine/borane FLP with molecular oxygen.

4 ctions can be carried out in the presence of molecular oxygen.

5 photoexcited electrons in the perovskite and molecular oxygen.

6 dations, all involving stepwise reduction of molecular oxygen.

7 mediates light-induced oxidation of water to molecular oxygen.

8 nts during the Archean eon in the absence of molecular oxygen.

9 cur before an irreversible reductive step at molecular oxygen.

10 ility to oxidize methane into methanol using molecular oxygen.

11 of superoxide anion to hydrogen peroxide and molecular oxygen.

12 reducing equivalents without involvement of molecular oxygen.

13 case can catalyze electrooxidation of H2O to molecular oxygen.

14 l product, is reported from (-)-myrtenal and molecular oxygen.

15 ), is actively dissipated in the presence of molecular oxygen.

16 fer from one or more light-excited donors to molecular oxygen.

17 lowed by the strongly favorable reduction of molecular oxygen.

18 nteraction between neutral gold clusters and molecular oxygen.

19 single-site catalysts for the activation of molecular oxygen.

20 radical reactions of organic compounds with molecular oxygen.

21 mely, the ability to convert superoxide into molecular oxygen.

22 y transferring aldehyde-derived electrons to molecular oxygen.

23 achieve selective four-electron reduction of molecular oxygen.

24 plays very little role in the reaction with molecular oxygen.

25 trates using NADPH as the electron donor and molecular oxygen.

26 oxidation when irradiated in the presence of molecular oxygen.

27 lfide isomerase (PDI) and passing them on to molecular oxygen.

28 trolled factors immediately upon exposure to molecular oxygen.

29 on oxidation of ubiquinol in the presence of molecular oxygen.

30 cal species generated upon the activation of molecular oxygen.

31 species via a light-activated reaction with molecular oxygen.

32 he catalytic oxidation of water that evolves molecular oxygen.

33 ates and upon reduction can be reoxidized by molecular oxygen.

34 ompeting with the primary electron acceptor: molecular oxygen.

35 The reactions of excited state singlet molecular oxygen ((1)Delta(g),(1)O(2)) continue to witne

36 Singlet molecular oxygen ((1)O(2)) has well-established roles in

37 The first singlet excited state of molecular oxygen ((1)O(2)) is an important oxidant in ch

38 mentation to generate high yields of singlet molecular oxygen ((1)O(2)).

39 record of the clumped-isotope composition of molecular oxygen ((18)O(18)O in O(2)) trapped in polar f

40 ,22R-dihydroxycholesterol in the presence of molecular oxygen ((18)O2), and coupled assays were used

41 ides can be produced only in the presence of molecular oxygen(3), reactive oxygen species(4,5) or by

42 under anaerobic conditions in the absence of molecular oxygen abrogates Sup35 protein damage and supp

43 The mechanism of molecular oxygen activation is the subject of controvers

44 A unique mode of molecular oxygen activation, involving metal-ligand coop

45 Molecular oxygen acts as the terminal electron sink in t

46 lative energies of the transition states for molecular oxygen addition to C9, C5, and C14 (where spin

47 he experimental values for HO* reactions and molecular oxygen addition, and a factor of 5 for peroxyl

48 isretinoid photocleavage at sites of singlet molecular oxygen addition.

49 crystal structures also revealed "pre-bound" molecular oxygen adjacent to the active site.

50 Studies in the presence and absence of molecular oxygen allow us to conclude that the imidazoli

51 occurs by hydrogen-transfer from Fl(red) to molecular oxygen, allowing radical coupling of the forme

52 capabilities for phototrophy, scavenging of molecular oxygen, anaerobic respiration, and fermentatio

53 iver electrons from the cosubstrate NADPH to molecular oxygen, analogous to other P450s.

54 Molecular oxygen and 1,4-benzoquinone can serve as elect

55 ing dioxygenases requiring for activity both molecular oxygen and 2-oxoglutarate that, under normoxia

56 or nonchiral amines was realized simply with molecular oxygen and a carbonate base.

57 ysaccharides utilizing a mechanism involving molecular oxygen and an electron donor.

58 oxidative cleavage of glycosidic bonds using molecular oxygen and an external electron donor.

59 Molecular oxygen and carbon dioxide are the primary gase

60 alpha-MnO2 nanotubes easily accommodated the molecular oxygen and exhibited excellent catalytic activ

61 he cellular milieu through the assistance of molecular oxygen and glutathione.

62 ineralize manganese oxides in the absence of molecular oxygen and high-potential photosynthetic react

63 phenyliodonium diacetate in the presence of molecular oxygen and N-hydroxyphthalimide or N-hydroxybe

64 om of the C2(1)-formyl group originates from molecular oxygen and not from H2O.

65 cytochrome c to CcO's catalytic site reduce molecular oxygen and produce a water molecule.

66 olol and honokiol radicals do not react with molecular oxygen and produce no superoxide radical under

67 cleavage step was tested using (18)O-labeled molecular oxygen and purified P450 11A1.

68 Release of molecular oxygen and regeneration of resting enzyme are

69 ltaneous resonant two-photon dissociation of molecular oxygen and resonant two-photon pumping of the

70 made, pointing to a mechanism in which both molecular oxygen and the olefinic substrate coordinate t

71 adventitious electron transfer from nNOS to molecular oxygen and thereby preventing accumulation of

72 he quantum yields were enhanced by excluding molecular oxygen and thermally activated delayed fluores

73 crimination during O atom incorporation from molecular oxygen and water.

74 d by experiments performed in the absence of molecular oxygen and with the use of (18)O-labeled water

75 MalE-LacZ lethality requires molecular oxygen, and its expression induces ROS product

76 T), a treatment that uses a photosensitizer, molecular oxygen, and light to kill target cells, is a p

77 rin in the presence of mild reducing agents, molecular oxygen, and no additional cofactors.

78 ational studies on the reactions with water, molecular oxygen, and the superoxide radical anion suppo

79 a capability to reduce Fe(III) minerals and molecular oxygen, and thereby generating Fenton chemistr

80 Molecular oxygen appeared far later, forcing microbes to

81 Here, electrochemical side reactions with molecular oxygen are shown to occur during organic elect

82 phosphate-modified hydrotalcite support and molecular oxygen as a benign oxidant.

83 glutarate-dependent dioxygenases that deploy molecular oxygen as a co-substrate to catalyse the post-

84 that have been characterized to date require molecular oxygen as a cosubstrate.

85 lymer to enable the controlled generation of molecular oxygen as a function of pH.

86 ve aromatization reaction sequence utilizing molecular oxygen as a green oxidant.

87 tertiary amines to tertiary amides by using molecular oxygen as a sole oxidant using a Pd/C catalyst

88 n the presence of an organic base and aerial molecular oxygen as a stoichiometric oxidant.

89 oxidation of (hetero)aryl acetimidates using molecular oxygen as a sustainable oxidant.

90 n and functionalization of styrene utilizing molecular oxygen as a terminal oxidant.

91 none oxidoreductase, Photosystem II produces molecular oxygen as an enzymatic product.

92 coupled with the use of abundant atmospheric molecular oxygen as an oxidant and low catalyst loading

93 rimary alpha-ketoamides by using sustainable molecular oxygen as an oxidant.

94 t oxidative esterification of alcohols using molecular oxygen as benign oxidant.

95 c metabolism therefore makes use of reactive molecular oxygen as co-substrate of oxygenases to hydrox

96 nt formation of an aldehyde intermediate and molecular oxygen as final electron acceptor.

97 lized in the blue bottle experiment, deplete molecular oxygen as long as a sacrificial reduction comp

98 rational bands of nitric oxide, hydroxyl and molecular oxygen as signatures of nitrogen, oxygen, and

99 site and one catalytic residue, and utilizes molecular oxygen as source for the hydroxyl group oxygen

100 drastic reduction in oxidase activity using molecular oxygen as the electron acceptor and a small in

101 rbon bonds of the six-membered ring and uses molecular oxygen as the hydrogen acceptor.

102 utyl-p-benzoquinone enables efficient use of molecular oxygen as the oxidant, high reaction yields, a

103 of two C-H bonds under mild conditions using molecular oxygen as the sole oxidant.

104 readily on most proteins, and (4) the use of molecular oxygen as the sole oxidant.

105 In the presence of molecular oxygen as the terminal oxidant the reaction is

106 inates position C4 in a reaction implicating molecular oxygen, as demonstrated with labeling experime

107 The production of molecular oxygen at a high potential is verified by meas

108 the title compound involves the splitting of molecular oxygen by carbene-stabilized diphosphorus.

109 l gold clusters (Au(n); 4 </= n </= 21) with molecular oxygen by probing the highly characteristic O-

110 rate how light-triggered SiNc reactions with molecular oxygen can be potentially sensed and discuss t

111 genous or xenobiotic small molecules such as molecular oxygen, cellular metabolites, or polyaromatic

112 The presence of molecular oxygen changes product distribution, and only

113 the enzyme are unaffected by the presence of molecular oxygen commonly present in electrolyte.

114 cysteine makes it vulnerable to oxidation by molecular oxygen; consequently, organisms that live in o

115 o-hydroxylation of L-tyrosine to L-DOPA by a molecular oxygen dependent pathway in the presence of di

116 The subsequent molecular oxygen-dependent oxidation of the multicenter

117 roxylation is catalyzed by a membrane-bound, molecular oxygen-dependent, and ferredoxin-dependent act

118 -phenylindeno[2,1-alpha]phenalene (ipp) with molecular oxygen derived from air, yielding 12-hydroxy-7

119 They reduce molecular oxygen (dioxygen) to water, avoiding the produ

120 It is shown that molecular oxygen dissociates easily on the supported Pd(

121 hanges in proportion to the concentration of molecular oxygen dissolved in plasma or interstitial tis

122 e surface are a significant redox partner to molecular oxygen due to the strong hybridization between

123 tible to electrochemical side-reactions with molecular oxygen during device operation.

124 oxygen atom is incorporated from atmospheric molecular oxygen during the present process.

125 the biofuel and the biooxidant, glucose and molecular oxygen, each readily available in human lachry

126 Specifically, the controlled exposure to molecular oxygen efficiently deprotonates terminal alkyn

127 ow that pyrite burial could have resulted in molecular oxygen export exceeding local Fe(2+) oxidation

128 at requires SAM, a thiol reducing agent, and molecular oxygen for activity.

129 In contrast to GFP, which requires only molecular oxygen for chromophore maturation, phytochrome

130 s inherently aerobic due to a requirement of molecular oxygen for one of the key enzymes.

131 Nature often utilizes molecular oxygen for oxidation reactions through monoxyg

132 es (LPMOs) have a unique ability to activate molecular oxygen for subsequent oxidative cleavage of gl

133 es P450 must be reduced to bind and activate molecular oxygen for substrate oxidation.

134 to effect the challenging task of utilizing molecular oxygen for the selective epoxidation of cycloo

135 ploys the reaction of iodoalkyl radical with molecular oxygen: for instance, CH2I + O2 --> CH2OO + I.

136 tertiary C25 atom of the side chain without molecular oxygen forming a tertiary alcohol.

137 As steroid biosynthesis requires molecular oxygen, fossil steranes have been used to draw

138 abolism lead to the release of l-lactate and molecular oxygen from the tissue into the gut lumen.

139 water oxidation, but catalysts that produce molecular oxygen from water are needed to avoid excessiv

140 lkyl-substituted diazenes in the presence of molecular oxygen generates an unexpectedly complex produ

141 er drug with light, which in the presence of molecular oxygen, generates cytotoxic reactive oxygen sp

142 ic amines through a metal-free activation of molecular oxygen has been developed.

143 Molecular oxygen has been explored as an economic and cl

144 urfaces with direct propylene epoxidation by molecular oxygen have not resolved these problems becaus

145 Many primary tumours have low levels of molecular oxygen (hypoxia), and hypoxic tumours respond

146 on of a bare palladium cluster Pd(6)(+) with molecular oxygen in an octopole ion trap under multicoll

147 y reports the incorporation of (18)O-labeled molecular oxygen in azinomycin biosynthesis including bo

148 between redox-active conjugated polymers and molecular oxygen in electrochemical devices for bioelect

149 this review article, we consider the use of molecular oxygen in reactions mediated by polyoxometalat

150 interpreted as proxies for the evolution of molecular oxygen in the Archean eon.

151 ations, we investigate here the migration of molecular oxygen in the bc1 complex in order to identify

152 both confirmed the requirements for DHP and molecular oxygen in the catalytic generation of 5,5'-Br2

153 ing of singlet oxygen, but do not react with molecular oxygen in the ground state, i.e., triplet stat

154 tied to the first widespread availability of molecular oxygen in the ocean-atmosphere system.

155 The balance between sources and sinks of molecular oxygen in the oceans has greatly impacted the

156 , and the reduced flavin is then oxidized by molecular oxygen in the oxidative half-reaction.

157 single-walled carbon nanotubes (C-SWCNT) to molecular oxygen in water in the dark.

158 tribution of oxygen atom sources, water, and molecular oxygen, in a 2:1 ratio.

159 ive low-temperature oxidation catalysts with molecular oxygen, in stark contrast to the nobility of t

160 ) is not reduced by Mn(II) in the absence of molecular oxygen, indicating that substrate oxidation re

161 a sustained electron flow is maintained with molecular oxygen instead of carbon dioxide serving as th

162 nge of biological reactions by incorporating molecular oxygen into organic substrates.

163 PH oxidase to convert substantial amounts of molecular oxygen into superoxide, which, after dismutati

164 in varying yields with the incorporation of molecular oxygen into the structures.

165 ogen peroxide by radical chain reductions of molecular oxygen into water in buffers leads to hinge de

166 Activation of molecular oxygen is a key step in converting fuels into

167 The oxidation of water to molecular oxygen is a kinetically demanding reaction tha

168 Photocatalytic reduction of molecular oxygen is a promising route toward sustainable

169 ient conditions is a major challenge because molecular oxygen is an effective radical quencher.

170 The intramolecular conversion of CO(2) to molecular oxygen is an exotic reaction, rarely observed

171 Although HNO reactivity with molecular oxygen is described in the literature, the pro

172 Molecular oxygen is essential for the development, growt

173 Molecular oxygen is evolved after four sequential light-

174 Hypoxia reduced ARSB activity, since molecular oxygen is needed for post-translational modifi

175 ctive oxidation of methane to methanol using molecular oxygen is possible.

176 Molecular oxygen is produced from water via the followin

177 In this way molecular oxygen is released, maintaining an aerobic atm

178 Molecular oxygen is the most used substrate in the human

179 ng to these results and due to the fact that molecular oxygen is the only known physiological electro

180 In organisms that live aerobically, molecular oxygen is used enzymatically to oxidize cystei

181 When molecular oxygen is used, the structure of the CsPbI3 QD

182 Singlet oxygen, the lowest excited state of molecular oxygen, is an intermediate often involved in n

183 evel of superoxide or peroxide, showing that molecular oxygen itself is the culprit.

184 by endogenous reactive oxygen species or by molecular oxygen itself.

185 ey step in central metabolism is poisoned by molecular oxygen itself.

186 tiphoton ionization (REMPI) scheme targeting molecular oxygen (lambda ~ 287.6 nm).

187 interaction between the neutral polymer and molecular oxygen leading to a reduction in electron mobi

188 Measuring molecular oxygen levels in vivo has been the cornerstone

189 In the late Archean, molecular oxygen likely cycled as a biogenic trace gas,

190 and that electron shuttling through CNTs to molecular oxygen may be a potential mechanism for DNA da

191 ring, and end-game manipulations featuring a molecular oxygen mediated gamma-CH oxidation, a Stetter

192 pe II photosensitization reactions, in which molecular oxygen mediates the radicalization of proteins

193 hown to oxidize an alcohol using a metal and molecular oxygen, not NAD(P)(+).

194 Molecular oxygen (O(2)) and trace metals [e.g., copper(I

195 We also show that molecular oxygen (O(2)) is the source of the oxygen atom

196 Reactive molecular oxygen (O(2)) plays important roles in bioener

197 Molecular oxygen (O(2)) sustains intracellular bioenerge

198 Molecular oxygen (O(2))-utilizing enzymes are among the

199 robic organisms through its interaction with molecular oxygen (O(2)).

200 Singlet molecular oxygen, O(2)(a(1)Delta(g)), can influence many

201 lmalonate), which was used to detect singlet molecular oxygen O2((1)Deltag) production in water.

202 so results in direct enzymatic conversion of molecular oxygen (O2 ) to reactive oxygen species (ROS)

203 f biological detection by optical sensing of molecular oxygen (O2) are reviewed, with particular emph

204 ears to be mediated during the activation of molecular oxygen (O2) by reduced flavoenzymes, forming s

205 Molecular oxygen (O2) is a key substrate for mitochondri

206 rbon monoxide (CO) and the infrared inactive molecular oxygen (O2) products are readily detected from

207 y reactive species formed by the addition of molecular oxygen (O2) to organic radicals.

208 Molecular oxygen (O2), however, despite its detection on

209 w widely appreciated that nutrients, such as molecular oxygen (O2), modulate skeletal muscle formatio

210 n rich terrestrial-type exoplanets including molecular oxygen (O2), ozone (O3), water vapor (H2O), ca

211 ing reactions, we investigated the role that molecular oxygen (O2), solvent and light-source (CF lamp

212 The eighth key metabolite is molecular oxygen (O2), thermodynamically activated for r

213 3), is irreversibly damaged upon exposure to molecular oxygen (O2).

214 s for use as a fluorescent probe for singlet molecular oxygen, O2(a(1)Deltag).

215 e phosphorescence is effectively quenched by molecular oxygen, optical sensors operating in a wide ra

216 ditions but could be enhanced by exposure to molecular oxygen or by the addition of alternative elect

217 Upon reaction with either molecular oxygen or di-tert-butylperoxide in the presenc

218 at rates competitive to sulfide oxidation by molecular oxygen or iron oxides.

219 high activities for the electroreduction of molecular oxygen (oxygen reduction reaction, ORR), which

220 nese speciation appeared to be controlled by molecular oxygen (pe(-) = 15.90).

221 It was shown that molecular oxygen plays the key role in this process.

222 gger critical metabolic pathways to detoxify molecular oxygen produced by photosynthesis, thereby per

223 ubsequent quenching of the triplet states by molecular oxygen produces singlet oxygen ((1)O2), which

224 lysts that promote the oxidation of water to molecular oxygen, protons, and "energized" electrons, an

225 ens of both hydroxyl moieties originate from molecular oxygen rather than water.

226 such as hydrogen peroxide (H2O2) or singlet molecular oxygen, rather than free-radical species, perf

227 , we regulate proton transport to a Cu-based molecular oxygen reduction reaction catalyst.

228 Interactions between biological pathways and molecular oxygen require robust mechanisms for detecting

229 Subsequent reaction of Fl(red) with molecular oxygen restores the postulated Fl(N5[O]) via a

230 360 mV (vs. Ag/AgClsat) in the presence of a molecular oxygen saturated electrolyte with current dens

231 PHD1 to PHD3 are molecular oxygen sensors and increasingly considered as

232 Prolyl hydroxylase enzymes (PHD1-3) are molecular oxygen sensors that regulate hypoxia-inducible

233 ase domain (PHD) enzymes are regarded as the molecular oxygen sensors.

234 pper-catalyzed alkene aminooxygenation where molecular oxygen serves as both oxidant and oxygen sourc

235 e combustion reactor between water vapor and molecular oxygen so that only hydrogen isotope compositi

236 ns to an atmosphere which became enriched in molecular oxygen spurred the development of a layered sy

237 henotypes are invariant within this range of molecular oxygen suggesting that ESR1 mutations confer a

238 T1 Cu species only formed in the presence of molecular oxygen, suggesting the T1 Cu intermediate is a

239 , which is different from isolated atomic or molecular oxygen surface structures, was observed with i

240 primary-tumor subregions have low levels of molecular oxygen, termed hypoxia.

241 umbrella term for an array of derivatives of molecular oxygen that occur as a normal attribute of aer

242 graded in the gut lumen, which gives rise to molecular oxygen that supports the aerobic respiration o

243 Many genetic reporter systems require molecular oxygen; therefore, the use of reporter genes t

244 ited state ensembles against deactivation by molecular oxygen though quenching and photooxidation mec

245 tes methane, which subsequently incorporates molecular oxygen through a radical process.

246 cal processes, including the biosynthesis of molecular oxygen (through the photosystem II complex) an

247 emperature without the rigorous exclusion of molecular oxygen, thus making this newly developed Ir-ph

248 on to 15 aromatic compounds; (2) addition of molecular oxygen to 65 carbon-centered aliphatic and cyc

249 or a dominant delivery channel that shuttles molecular oxygen to a specific region of the active site

250 intermediates may be trapped via exposure to molecular oxygen to afford oxygen-containing adducts.

251 avin species that transfers a single atom of molecular oxygen to an organic substrate.

252 the active site, thereby creating space for molecular oxygen to bind to Fe2.

253 The power of molecular oxygen to drive many crucial biogeochemical pr

254 (P(Ar)(tBu)2)2] (1, Ar=naphthyl) reacts with molecular oxygen to form Pd(II) hydroxide dimers in whic

255 rhenium(V), (ONO(Cat))ReO(PPh3), reacts with molecular oxygen to give triphenylphosphine oxide and th

256 asm; instead, the four-electron reduction of molecular oxygen to harmless water ensures that the acti

257 idizes glucose to gluconolactone and reduces molecular oxygen to hydrogen peroxide.

258 uced TPQ is reoxidized with the reduction of molecular oxygen to hydrogen peroxide.

259 ycle pathway involving reversible binding of molecular oxygen to iridium, which contributes to the ai

260 prene reacts with hydroxyl radicals (OH) and molecular oxygen to produce isoprene peroxy radicals (IS

261 ectron transport chain, which is captured by molecular oxygen to produce reactive oxygen species (ROS

262 copper oxidases that couple the reduction of molecular oxygen to proton translocation across the bact

263 We then added molecular oxygen to the system and modeled the oxidation

264 the quenching of palladium-benzoporphyrin by molecular oxygen to transduce the local oxygen concentra

265 ine oxidase enzyme superfamily which utilize molecular oxygen to transform amines to imines that are

266 The addition of triplet molecular oxygen to two types of conjugatively stabilize

267 dase (CcO), which catalyzes the reduction of molecular oxygen to water in the mitochondrial and bacte

268 pe quinol oxidases catalyze the reduction of molecular oxygen to water in the respiratory chain of ma

269 chondria and bacteria catalyzes reduction of molecular oxygen to water, and conserves much of the lib

270 erobic organisms, catalyzes the reduction of molecular oxygen to water.

271 he cytochrome c oxidases (CcO), which reduce molecular oxygen to water.

272 ffects the calculated OA mass, mass spectra, molecular oxygen-to-carbon ratio (O/C), and f44.

273 h more versatile redox chemistry, biospheric molecular oxygen triggered the selective fixation of the

274 can be directly converted to methanol using molecular oxygen under mild conditions in the gas phase,

275 Oxidation reactions include molecular oxygen under solvent control or using differen

276 The reduction chemistry of molecular oxygen underpins the energy metabolism of mult

277 A material capable of rapid, reversible molecular oxygen uptake at room temperature is desirable

278 as a photoredox catalyst in the presence of molecular oxygen using visible light and, when it was us

279 tly split carbonate into carbon monoxide and molecular oxygen via a low-energy pathway needing no sac

280 oposals have been made for the activation of molecular oxygen via both a Cu(II)-aminoquinol catalytic

281 Abundant molecular oxygen was discovered in the coma of comet 67P

282 trimeric CntA complex for the activation of molecular oxygen was investigated.

283 ithium intercalated into Li(x)V(2)O(5) while molecular oxygen was reduced to form lithium peroxide on

284 Its quenching by molecular oxygen was studied at 25 and 60 degrees C and

285 Cyanide, a mimic of molecular oxygen, was found to bind to the metal ion onl

286 Iron could have consumed molecular oxygen when Fe(3+)-oxyhydroxides formed in the

287 ding py and pz orbitals are degenerate as in molecular oxygen, which has singly occupied orbitals.

288 The reaction requires molecular oxygen, which is activated by a di-iron centre

289 of a small organic molecule, luciferin, with molecular oxygen, which is catalysed by the enzyme lucif

290 cotinamide adenine dinucleotide phosphate to molecular oxygen, which leads to the production of super

291 ion of gem-difluoroalkenes using phenols and molecular oxygen, which retains both fluorine atoms and

292 s become active sites for oxidizing water to molecular oxygen, which was investigated with the photoc

293 ained the predicted di-iron center and bound molecular oxygen with an apparent K (d) of ~1 uM.

294 ransfer from the Breslow intermediate to the molecular oxygen with formation of a radical couple that

295 Triplet carbenes react with molecular oxygen with rates that approach diffusion cont

296 Interaction of molecular oxygen with semiconducting oxide surfaces play

297 mitochondria could occur by the reaction of molecular oxygen with the ferrous CL:cyt c complex in ad

298 NadB turnover depends upon its oxidation by molecular oxygen, with H(2)O(2) as a product.

299 intramitochondrial [NAD(+) ]/[NADH] pool to molecular oxygen, with irreversible reduction of oxygen

300 Under low molecular oxygen within the physiological range (~5-20%)