ライフサイエンスコーパス: methylene blue

1 one, chloroquine, proguanil, cycloguanil and methylene blue.

2 Pt(IV) center of SAT and surface-immobilized methylene blue.

3 alytic signal caused by addition of H2O2 and methylene blue.

4 d by nitric oxide pathway inhibitors such as methylene blue.

5 tivity for the photocatalytic degradation of methylene blue.

6 ar probes, such as 4-hydroxybenzoic acid and methylene blue.

7 n the presence of iron(III) chloride to form Methylene Blue.

8 ic acid "scaffold" modified with a reporting methylene blue.

9 ontributing to increasing the sensitivity of methylene blue.

10 l reduction by the addition of ascorbate and methylene blue.

11 e E3 ubiquitin ligase CHIP and is blocked by methylene blue.

12 dent proteasomal degradation is inhibited by methylene blue.

13 s in the dynamics for delivery of model drug methylene blue.

14 eatment, washed with water, and stained with methylene blue.

15 mers and fibrils may be tested in vivo using methylene blue.

16 00, 200, 300, 400, 500, or 1000 microCi of I methylene blue.

17 minal deoxynucleotidyl transferase (TdT) and methylene blue.

18 tion of small organic target compounds, here methylene blue.

19 nts up to 3.4 x 10(3) for the probe molecule methylene blue.

20 Methylene blue (1 muM and 10 muM) significantly protecte

21 Methylene blue (1 muM and 10 muM) significantly protecte

22 Combination of Methylene Blue + 1,9-Dimethyl Methylene Blue demonstrate

23 A second pump infused the model drug methylene blue (3 mL/hr), joining the carrier immediatel

24 Methylene blue (4 muM) irradiated with red light (660 nm

25 employ a modified signal probe containing a methylene blue (a redox moiety) label and a "sticky end.

26 Here we test the effects of methylene blue, a recently described inhibitor of Hsp70

27 We also demonstrate that methylene blue, a reported tau aggregation inhibitor, mo

28 Methylene blue accumulation in SLNs was confirmed photoa

29 s xylem flux toward the bud, as evidenced by Methylene Blue accumulation in the bud after CK treatmen

30 es of rat SLNs clearly help visualization of methylene blue accumulation, whereas coregistered photoa

31 These findings reveal that the ATPZs and methylene blue act by a mechanism that may affect their

32 the memory-enhancing effects of posttraining methylene blue administration on retention of fear extin

33 determine the affinity constant, KD, of the methylene blue Affimer to be comparable to that of antib

34 tored the drainage of intradermally injected methylene blue after 7 weekly injections.

35 Methylene blue alone extended survival time but without

36 ng electrochemical biosensors, ferrocene and methylene blue, along with the effect of changing both t

37 Interestingly, methylene blue, an inhibitor of Tau fibrillization under

38 We also observed that Methylene Blue, New Methylene Blue and 1,9-Dimethyl Methylene Blue increased

39 grade silicone incorporating crystal violet, methylene blue and 2 nm gold nanoparticles.

40 t exhibited a moderate rejection (46-66%) of Methylene blue and a high rejection (93-95%) of Rhodamin

41 s demonstrate a nearly 100% removal rate for methylene blue and an impressively high removal rate for

42 ible light to photocatalyse the oxidation of methylene blue and both the oxidation and reduction of w

43 toring of the photocatalytic degradations of methylene blue and methyl orange under different flow ra

44 sections of fixed tissue stained in azure II-methylene blue and on frozen sections immunolabeled for

45 analogous to the Calvin cycle) between leuco-methylene blue and the onium salt oxidant that is respon

46 rgery using both blue dye (isosulfan blue or methylene blue) and a radiolabeled colloid mapping agent

47 ucts with DNA, a duplex intercalating agent (methylene blue), and a cytotoxic metal ion (Hg(II)) whic

48 f small hydrophilic compounds (theophylline, methylene blue, and fluorescein sodium) across neonatal

49 ected following breast surgery, stained with methylene blue, and imaged.

50 guest adsorbate, containing both HgCl(2) and Methylene blue, and offered unprecedented snapshots of t

51 Our data also identify methylene blue as a potent inhibitor of gametocyte devel

52 h to highlight the exceptional properties of methylene blue as a redox reporter in such applications

53 S shows 2-fold enhancement in degradation of methylene blue as compared to the bulk CdS.

54 atalytic hydroxylation of boronic acids with methylene blue as photosensitizer proceeds with high eff

55 Apt and CS and so, increases accumulation of methylene blue as redox agent on the surface of electrod

56 ectrochemical detection of cholesterol using Methylene Blue as redox indicator.

57 ndicates that a PEG-based peptide, employing methylene blue as redox reporter, and deposited on an el

58 ay of simultaneously using two redox probes: Methylene blue as the reporter of the conformational cha

59 ensors) fabricated using either ferrocene or methylene blue as the signaling redox moiety.

60 S-FF in dispersive solid phase extraction of methylene blue (as a cationic dye model) in water and sh

61 The electron transfer rate constants of methylene blue, as determined using alternating current

62 lectrodes modified with polythymine, bearing methylene blue, as redox probe, in 3' position.

63 d in the agar is quantified using an in situ methylene blue assay.

64 generally due to more redox molecules (e.g., methylene blue) associating with the probe DNA bases in

65 The epinephrine-methylene blue association was the most effective treatm

66 fied with a redox reporter (in this protocol methylene blue) at one terminus and attached to a gold e

67 and studies of the electron transfer rate of methylene blue attached to the hexanethiol monolayer sug

68 we describe a very simple method for fixing methylene blue bands in nucleic acid polyacrylamide gels

69 Doing so we find that the performance of methylene blue-based, thiol-on-gold sensors is unmatched

70 ither vehicle (ovalbumin group) or a 3-mg/kg methylene blue bolus (methylene blue group) or epinephri

71 alytic activity in the reduction reaction of methylene blue by stannous chloride.

72 UV-visible light irradiation for four hours, methylene blue can be photocatalytically degraded (>90%)

73 Methylene blue can be used as a stain for visualizing nu

74 Conclusion Low-dose methylene blue can increase functional MR imaging activi

75 nic photoredox catalysis (photocatalysis) of methylene blue chromophore with a sacrificial sterically

76 ed when Methylene Blue was combined with New Methylene Blue (Combination Index = 0.84).

77 t of the Stern-Volmer quenching constant for methylene blue compared to a model complex.

78 ion and vesicle degradation as a function of methylene blue concentration follows a diffusion law in

79 g release from nanocarriers via a paclitaxel-methylene blue conjugate (PTX-MB) with redox activity.

80 Pyronin Y, Auramine O, Brilliant green, and Methylene blue) contaminants, and, in addition, this MTV

81 he purpose of this study was to determine if methylene blue could protect RGCs from noxious stimuli.

82 based sensors are far less stable than their methylene blue counterparts, particularly with regards t

83 sized, and their photocatalytic activity for methylene blue decomposition in water compared.

84 me to target for initiation and cessation of methylene blue delivery.

85 Combination of Methylene Blue + 1,9-Dimethyl Methylene Blue demonstrated superior efficacy compared t

86 (MB), New Methylene Blue (NMB), 1,9-Dimethyl Methylene Blue (DMMB) and Toluidine Blue O (TBO) on N. c

87 Methylene blue dye accumulation in axillary lymph nodes

88 Topically applied methylene blue dye chromoendoscopy is effective in impro

89 tic activity for H2 generation using H2S and methylene blue dye degradation is performed under visibl

90 this method using the 1000-microCi dose of I methylene blue dye for sentinel lymph node biopsies.

91 ians use radio-labeled sulfur colloid and/or methylene blue dye to identify the SLN, which is most li

92 rparts for the photocatalytic degradation of methylene blue dye under visible-light irradiation.

93 ely detect SLNs based on the accumulation of methylene blue dye.

94 e feasibility of the foam as an adsorbent of methylene blue dye.

95 d classification system, ex vivo videos of a methylene blue dyed pig esophagus and images of differen

96 Methylene blue enhances memory and the retention of fear

97 Compared with epinephrine alone, the methylene blue-epinephrine association avoided neuronal

98 or epinephrine (epinephrine group) or both (methylene blue-epinephrine group).

99 reduction reaction between ascorbic acid and methylene blue, followed by a dispersive liquid-liquid m

100 suring leukocyte hydrogen sulfide synthesis; methylene blue formation following zinc acetate capture

101 -dependent multimatrix structure, a per-oral methylene blue formulation (MB-MMX) can be delivered dir

102 terial displayed instantaneous adsorption of methylene blue from aqueous solution reaching complete e

103 the cyclic "ON"/"OFF" binding of ATP to the methylene blue-functionalized aptamer through cyclic oxi

104 in group) or a 3-mg/kg methylene blue bolus (methylene blue group) or epinephrine (epinephrine group)

105 blocked by the methemoglobin reducing agent methylene blue, haptoglobin, or the heme-binding protein

106 Finally, we demonstrate that methylene blue impairs degradation of the polyglutamine

107 Redox reactions of the chromophore methylene blue in aqueous solution, commonly visualized

108 Double strand specific intercalator methylene blue in combination with [Fe(CN)6](3-) is used

109 We demonstrate that methylene blue in combination with reducing compounds su

110 Our data demonstrate the utility of methylene blue in defining Hsp70-dependent functions and

111 c images demonstrate dynamic accumulation of methylene blue in SLNs after traveling through lymph ves

112 issue expansion effects and a visual lack of methylene blue in the fibroids.

113 ral correlates of the oral administration of methylene blue in the healthy human brain.

114 hat underwent LN excision had no evidence of methylene blue in the iliac nodes; mice without surgical

115 nzthiazoline-6-sulfonic acid), dopamine, and methylene blue in the presence of O2.

116 r catalytic activity toward the reduction of methylene blue in the presence of sodium borohydride.

117 at, antibiotic resistant bacteria turned the methylene blue in to white color while the bacteria that

118 sible for exo-HAV infectivity as assessed by methylene blue inactivation of non-encapsidated RNA.

119 ne Blue, New Methylene Blue and 1,9-Dimethyl Methylene Blue increased by 5000% the reactive oxygen sp

120 Methylene blue increased cytochrome c oxidase activity i

121 Results Administration of methylene blue increased response in the bilateral insul

122 Preclinical studies have shown that low-dose methylene blue increases mitochondrial cytochrome oxidas

123 to assess the cognitive-enhancing effects of methylene blue independent of its effects on fear attenu

124 Methylene blue induced (1)O(2) formation triggers furan

125 to steady-state delivery after initiation of methylene blue infusion differed between CVCs.

126 from steady state to zero after cessation of methylene blue infusion was fastest with the 18-gauge lu

127 e Cu from these aggregates, while drugs like methylene blue inhibit O(2) reactivity of the heme cofac

128 Methylene blue inhibited oligomerization when used at su

129 First, we demonstrate that methylene blue inhibits the ability of the purified Hsp9

130 (endoscopic ultrasound-guided rendezvous and methylene blue injection).

131 Twenty minutes following methylene blue injection, photoacoustic signals from SLN

132 5), or no intervention (n = 5), followed by methylene blue injection.

133 h was confirmed by the use of intraoperative methylene blue injection.

134 d concentration may be altering the modes of methylene blue interaction with the nucleic acids and ch

135 raction (DLLME) to extract the aqueous-phase methylene blue into organic media.

136 Methylene blue is a neuroprotective compound that can pr

137 mbined with intraoperative localization with methylene blue is an important and innovative technique

138 on alters the accessibility of Cr(VI) to the methylene blue label on the surface-immobilized DNA prob

139 s comprised of a single, self-complementary, methylene blue-labeled DNA probe possessing a triple-ste

140 f the probe into mononucleotides including a methylene blue-labeled electro-active mononucleotide (eN

141 tuberculosis and Escherichia coli) by using methylene blue-labeled structure-switching DNA stem-loop

142 separation and recombination dynamics in PbS-methylene blue (MB(+)) complexes by femtosecond transien

143 sociation dynamics in CdSe QDs adsorbed with methylene blue (MB(+)) molecules by transient absorption

144 Methylene blue (MB(+)), a common cationic thiazine dye,

145 ecule with its cavities matching the size of methylene blue (MB(+)), a versatile organic molecule use

146 binding constants and adsorb ca. 7 equiv of methylene blue (MB) and ca. 30 equiv of aspirin in chlor

147 Furthermore, 1 can enrich methylene blue (MB) and can also serve as an effective a

148 NA biosensor is developed based on employing methylene blue (MB) as a redox indicator.

149 ated by differential pulse voltammetry using methylene blue (MB) as an electrochemical indicator.

150 Using methylene blue (MB) as an electrochemical probe and diff

151 us DNA sequence of Dengue virus (DENV) using methylene blue (MB) as an intercalating agent.

152 UV/H(2)O(2) as the (*)OH generation system, methylene blue (MB) as the probe compound, and isopropyl

153 otocatalytic effect was also confirmed using methylene blue (MB) dye degradation under natural sunlig

154 he nanoprobes, i.e. the electroactive marker methylene blue (MB) encapsulated within nanometer-sized

155 Methylene Blue (MB) forms an inclusion complex with Grp-

156 valuated as an inexpensive sorbent to remove methylene blue (MB) from aqueous solution.

157 In the current study, we demonstrated that methylene blue (MB) functions as an alternative electron

158 We studied the inhibitory activity of methylene blue (MB) gamma-carbolines (gC) conjugates (MB

159 Methylene blue (MB) has been shown to be safe and effect

160 Methylene blue (MB) has been used clinically for about a

161 gate the influence of nanostructuring on DNA-methylene blue (MB) interactions and their application t

162 gs through a case study of the conversion of methylene blue (MB) into a reduced MB ion radical on the

163 By restoring mitochondrial function, methylene blue (MB) is an effective neuroprotectant in m

164 that the fluorescence polarization (Fpol) of Methylene Blue (MB) is significantly higher in cancer th

165 Methylene blue (MB) is used as an electrochemical indica

166 transfer (ET) between the gold electrode and methylene blue (MB) label conjugated to a double-strande

167 Then, thiolated capture probe (CP) with methylene blue (MB) labeled at 5' end is modified on the

168 ragment of dimebon and phenothiazine core of methylene blue (MB) linked by 1-oxo- and 2-hydroxypropyl

169 uch higher amount of sulforhodamine B (SRB), methylene blue (MB) or a model vaccine ovalbumin (OVA) w

170 ker at the 3'-end and having internal either methylene blue (MB) or anthraquinone (AQ) redox labels,

171 Among these derivatives, methylene blue (MB) possesses high reversibility with ex

172 -VEGF165 aptamers, resulted in desorption of methylene blue (MB) probe from aptamer and its release i

173 rapid biorecognition of carrageenan by using methylene blue (MB) redox indicator.

174 tical in all aspects but the location of the methylene blue (MB) redox label.

175 ers were labeled with anthraquinone (AQ) and methylene blue (MB) redox reporters respectively.

176 nding aptamer was thiolated, conjugated with methylene blue (MB) redox tag, and immobilized on a gold

177 knesses and pore morphologies coupled with a methylene blue (MB) reporter-tagged DNA probe for DNA ta

178 Here, we documented that methylene blue (MB) reverses the Warburg effect evidence

179 ocessed graphene oxide nanoribbon (GONR) for methylene blue (MB) sensing.

180 vely, whereas bovine serum albumin (BSA) and methylene blue (MB) showed nonspecific adsorption on alm

181 We measured the redox current of methylene blue (MB) to determine the concentration of hu

182 The methylene blue (MB) two-phase titration method is a rapi

183 otocatalytic activity for the degradation of methylene blue (MB) under visible light irradiation.

184 ce through hybridization with the ssDNA1 and methylene blue (MB) used as the redox probe.

185 ht source, the estimated detection limit for methylene blue (MB) was 30 nM, corresponding to 120 amol

186 Methylene blue (MB) was employed as electrochemical indi

187 tabilized gold nanoparticles (PLA-AuNPs) and methylene blue (MB) was employed as the redox indicator

188 Subsequently, methylene blue (MB) was immobilized into the aptamer as

189 reactor (FBR) for the treatment of simulated methylene blue (MB) wastewater for 9 weeks under aerobic

190 applied in an adsorption column, to pretreat methylene blue (MB) wastewater with high concentration (

191 ne show a highly sensitive SERS detection of methylene blue (MB) with calculated enhancement factors

192 ed by interaction of anionic mediator, i.e., methylene blue (MB) with free guanine (3'G) of ssDNA.

193 tion in current, generated by interaction of methylene blue (MB) with free guanine (3'G) of ssDNA.

194 fic to MMP9 was modified with a redox label (methylene blue (MB)) and immobilized on microfabricated

195 ased on these findings, we hypothesized that methylene blue (MB), a mitochondria-permeant redox-activ

196 Methylene blue (MB), a phenothiazine dye that crosses th

197 Methylene blue (MB), a traditional mitochondrial-targeti

198 ntrathecal administration of sGC inhibitors, methylene blue (MB), and ODQ, in the Vc, attenuates mass

199 ation (in high yields) of New Fuchsine (NF), Methylene Blue (MB), Erythrosine B (ER) and 4-chlorophen

200 Methylene blue (MB), has been shown to modulate aggregat

201 a unique competitive detection scheme using methylene blue (MB), hydrazine and platinum nanoparticle

202 anti-parasitic effects of the phenothiaziums Methylene Blue (MB), New Methylene Blue (NMB), 1,9-Dimet

203 Methylene Blue (MB), Nile Blue (NB), and Anthraquinone (

204 zed oxidation of leucomethylene blue (LB) to methylene blue (MB), the redox label conjugated to the a

205 We characterized methylene blue (MB)- and thiol-based redox reactions wit

206 n the presence of target molecules, moving a methylene blue (MB)-conjugated oligonucleotide close to

207 latin sensor fabricated with a thiolated and methylene blue (MB)-modified oligo-adenine (A)-guanine (

208 formation of these complexes rigidifies the methylene blue (MB)-modified oligoadenine probes, result

209 The methylene blue (MB)-modified probe assumes a linear unst

210 ction between Cr(VI) and surface-immobilized methylene blue (MB).

211 a primary role in driving the degradation of methylene blue (MB).

212 ion time on the electrochemical reduction of methylene blue (MB).

213 ne reductase inhibitor and redox cycler drug methylene blue (MB).

214 catalytic reduction of H2O2 by oxidation of methylene blue (MB).

215 ry after extinction training by low-dose USP methylene blue (MB).

216 ; ii) electropolymerization of the mediator, methylene blue (MB); iii) immobilization of the enzyme l

217 Methylene blue (MB, methylthioninium chloride) is a phen

218 pain-gel with a red-light absorbing pigment (methylene blue - MB) to mediate photodynamic therapy (PD

219 n used to treat malaria (quinacrine [QC] and methylene blue [MB]) or to study P. falciparum (acridine

220 The fluorescent dyes methylene blue, MB(+), and thionine, Th(+), can be trapp

221 uced plasma sound source) to deliver agents (methylene blue, MB, in PBS) into bovine AC.

222 es of S(-II) measured by voltammetry and the methylene blue method showed that the majority of S(-II)

223 concentration, measured by ferrozine and the methylene blue method, predict precipitation of FeS with

224 plemented with 2% dextrose and 0.5 microg/ml methylene blue [MGM], Shadomy [SHA], and RPMI 1640 [RPMI

225 Addition of methylene blue (minus ascorbate) to CPR-supported reacti

226 Importantly, we find that the oxidized methylene blue-modified aptamers bind to ATP with microm

227 itchable aptamer binding to ATP. A series of methylene blue-modified ATP-aptamers was synthesized, re

228 th which electrons are transferred between a methylene blue moiety on the distal end of a short, sing

229 f two DNA adaptor strands modified with four methylene blue molecules and electrocatalysis using gluc

230 to double-blind administration of 260 mg of methylene blue (N=23) or administration of placebo (N=19

231 The methylene blue, N-methylquinolinium tetrafluoroborate, a

232 We also observed that Methylene Blue, New Methylene Blue and 1,9-Dimethyl Meth

233 the phenothiaziums Methylene Blue (MB), New Methylene Blue (NMB), 1,9-Dimethyl Methylene Blue (DMMB)

234 Photooxidation of methylene blue-NP41-bound nerves, followed by biotin hyd

235 e surface, resulting in less accumulation of methylene blue on the electrode surface and a weak curre

236 immobilization of horseradish peroxidase and methylene blue on the functionalized carbon buckypaper s

237 g the retention of the ion-pairs formed with Methylene Blue on the muMNPC.

238 differential pulse voltammetric response of methylene blue on the probe modified electrode upon cont

239 eak molecular adsorption of polar molecules (methylene blue) on the ta-C surface.

240 and 1 hour after administration of low-dose methylene blue or a placebo.

241 which could be inhibited in vivo with either methylene blue or apocynin.

242 t years utilize redox-labeled (most commonly methylene blue or ferrocene) oligonucleotide probes site

243 The efficiency of the BNNTs for capturing methylene blue particles in water was approximately 94%,

244 Some fibroids exhibited regions with partial methylene blue penetration into the tumor environment.

245 responsible for regeneration of the organic methylene blue photocatalyst.

246 f light by diffusion of the metastable leuco-methylene blue photoproduct.

247 f photocatalytic reactions in an Ag nanocube-methylene blue plasmonic system.

248 talization, here we profiled spontaneous and methylene blue plus light-induced mutations in the cII g

249 ar at the 1-month follow-up if they received methylene blue posttraining compared with placebo.

250 fare worse at the follow-up if they received methylene blue posttraining.

251 Methylene blue potentiates the electron transport chain

252 cero-3-phosphocholine (POPC), by irradiating methylene blue present in the giant unilamellar vesicles

253 synergistic effects of 17beta-estradiol and methylene blue, previously shown by our group and others

254 a low limit of detection (10(-9) M) for the methylene blue probe molecule.

255 One agent, methylene blue, protects neurons during several neurodeg

256 part of the second stem, is modified with a methylene blue redox tag at its 3' terminus and covalent

257 n, we employ MLS to analyze contrast agents (methylene blue, rhodamine 800, Alexa Fluor 750, IRDye 80

258 We used three synthetic photosensitizers (methylene blue, rose bengal, and nitrite) and two model

259 Methylene blue's ability to increase cytochrome c oxidas

260 Methylene blue's enhancement of contextual memory was un

261 entification of a small zinc finger protein, methylene blue sensitivity (MBS), that is required for i

262 The methylene blue sensitized reactions exhibit all of the c

263 e second probe, decorated on its 5'-end with methylene blue (SH-ssDNA-MB), is complementary to cDNA r

264 The procedure makes the methylene blue stain permanent and increases the visibil

265 ounds could be visualized after the jumps by methylene blue staining and scanning electron microscopy

266 In situ methylene blue staining showed the morphological feature

267 on's r=-0.68 or beyond) between collagen and methylene blue staining.

268 Because primaquine and methylene blue sterilize gametocytes before affecting th

269 the target DNA recognition sequence, with a methylene blue tag close to the 3' terminus, is designed

270 ofabrication technologies, and modified with methylene blue tagged aptamer using standard gold thiol

271 Present work describes the methylene blue tagged thiolated aptamer-modified gold mi

272 Methylene blue-tagged peptides combined with a polyethyl

273 rves in dye aggregation systems like that of methylene blue tend to be sufficiently similar so as to

274 the voltammetric behavior of a redox-active methylene blue tethered to an electrode surface via shor

275 n Toray paper as support and a layer of poly(methylene blue)/tetrabutylammonium bromide/Nafion and gl

276 Electrocatalysis with methylene blue that is covalently tethered to the DNA by

277 A binding is measured by a redox active dye, methylene blue, that intercalates in dsDNA, leading to a

278 Teeth were stained with 1% methylene blue, the largest interproximal calculus depos

279 r solution containing blood vessel stain and methylene blue to analyze intratumoral transport.

280 action procedure is employed to transfer the methylene blue to aqueous media, followed by analysis of

281 trial (IND#70627) of sterile pyrogen-free I-methylene blue to identify sentinel nodes in patients wi

282 on and subsequently promote the reduction of methylene blue to its colorless leuco form.

283 Addition of methylene blue to preformed oligomers resulted in oligom

284 first adaptor strand contains a redox label methylene blue to trigger the current change in response

285 Mice were dissected to determine whether methylene blue traveled to the iliac LN.

286 tion was assayed in vitro in the presence of methylene blue, using immunoreactivity with the prefibri

287 on or with sham LN excision consistently had methylene blue visible in the ipsilateral iliac nodes.

288 lysis of variance was performed with a drug (methylene blue vs placebo) and time (before vs after adm

289 As methylene blue was able to passively diffuse into fibroi

290 Methylene blue was also associated with a 7% increase in

291 ) and a synergistic effect was achieved when Methylene Blue was combined with New Methylene Blue (Com

292 Methylene blue was then assessed for protection of RGCs

293 ced 5-Lys-Sp exclusively when Rose Bengal or methylene blue was used to photochemically generate (1)O

294 Two milliliter of methylene blue were instilled above the cuff to quantify

295 amely 9,10-anthraquinone-1,5-disulfonate and methylene blue, were used as surrogates for dissolved or

296 First, methylene blue which is an electroactive polymer was ele

297 Among Gram-negative bacteria, only methylene blue with E. coli K12 and rose bengal with C.

298 eading to an improved electronic exchange of methylene blue with the electrode surface due to the red

299 Further testing is needed to determine if methylene blue would be an efficacious treatment for the

300 ber, with the prediction that the effects of methylene blue would vary as a function of fear reductio