ライフサイエンスコーパス: biocompatible

1 nt activity of curcumin and additionally are biocompatible.

2 u ion release demonstrated Ti-Cu alloy to be biocompatible.

3 semiconductor nanocrystals) and render them biocompatible.

4 d histology showed the material to be highly biocompatible.

5 bable suture material, and therefore, highly biocompatible.

6 ins are highly stretchable, transparent, and biocompatible.

7 e concept of metamaterials, are scalable and biocompatible.

8 interest and should be resorbable as well as biocompatible.

9 soft, flexible, transparent, and potentially biocompatible.

10 p are highly selective, relatively safe, and biocompatible.

11 tion provides a snapshot on the use of these biocompatible 2D-GAs for a broad spectrum of biomedical

12 PD patients compared to healthy controls (PD biocompatible, 5.86x, P = 0.0001; PD conventional, 7.09x

13 ticancer drug delivery into human cells with biocompatible 50-nm diameter halloysite nanotube carrier

14 Inexpensive, biocompatible additives to slow down the degradation of

15 is tunable, ranging from highly cytotoxic to biocompatible Ag-DNA, independent of their optical sensi

16 eveloped for use in synthetic chemistry, are biocompatible and accelerate flux through a styrene prod

17 ssue engineering scaffolds that can serve as biocompatible and bioactive pulp-capping materials, driv

18 e developed facile strategy to prepare novel biocompatible and biodegradable autofluorescent protein

19 c-soluble synthetic materials, we utilized a biocompatible and biodegradable biopolymer that underwen

20 a simple lab-on-a-chip (LOC) device based on biocompatible and biodegradable CaCO3- poly(ethyleneimin

21 The size-specific imprinted polymer is biocompatible and biodegradable in nature and was able t

22 early cardiac lineage and encapsulated in a biocompatible and biodegradable micromatrix, are suitabl

23 Herein, we report the preparation of biocompatible and biodegradable poly(epsilon-caprolacton

24 ster derivatives of beta-lap encapsulated in biocompatible and biodegradable poly(ethylene glycol)-b-

25 tic systems, LDL particles are intrinsically biocompatible and biodegradable, together with reduced i

26 k fibers are expected to become a pathway to biocompatible and bioresorbable waveguides, which could

27 rt distances, when the waveguide needs to be biocompatible and bioresorbable, such as embedding the w

28 ivo studies demonstrate that these IONPs are biocompatible and can produce significant contrast enhan

29 Light-sensitive nanoparticles are biocompatible and cause no adverse effects on the eye as

30 Using SYTO62, a biocompatible and cell-permeable dye, we demonstrate pho

31 Here we introduce a biocompatible and degradable mesostructured form of sili

32 bricated devices such as biosensors that are biocompatible and degradable over a controlled period of

33 The MNA was fabricated with biocompatible and dissolvable hyaluronic acid with a dee

34 The nanoscale CC-ZIFs are biocompatible and easily scaled-up offering excellent lo

35 The resulting TAC polymers are biocompatible and efficient transfection agents.

36 alized (PEGylated) nanomaterials are largely biocompatible and elicit less dramatic immune responses

37 sent thin film TiO2 as a viable material for biocompatible and flexible integrated photonics.

38 Exploiting this further, a strong, biocompatible and fluorescent hydrogel was obtained as a

39 This gel-containing capsule is biocompatible and free of toxic electronic or battery co

40 We show that DNPs are photostable, biocompatible and have a narrow emission bandwidth and v

41 quinoline-malononitrile (QM) nanoprobes are biocompatible and highly desirable for cell-tracking app

42 These biocompatible and highly sensitive nanosensors offer gre

43 the ionophore-based working electrode and a biocompatible and nonpolarizable Donnan exclusion anion-

44 Both electrodes are biocompatible and parylene provides flexibility to the s

45 an organic material-based, ultraconformable, biocompatible and scalable neural interface array (the '

46 s cellular membranes, while being remarkably biocompatible and serum-stable.

47 cell tracking by T2-weighted MRI as they are biocompatible and show no evidence of cytotoxic effects

48 This offers a simple strategy for generating biocompatible and stable fluorescent nanoparticles whose

49 r biomedical purposes, as they are generally biocompatible and stimuli-responsive.

50 rms to obtain efficient luminescent, stable, biocompatible and targeted agents for biomedical applica

51 mances of a temperature and a pH sensor on a biocompatible and wearable board for healthcare applicat

52 polycarbonates are a class of biorenewable, biocompatible, and biodegradable materials.

53 ight-delivery devices made of bio-derived or biocompatible, and biodegradable polymers.

54 able, earth abundant, strong, biodegradable, biocompatible, and chemically accessible for modificatio

55 a highly stable, NIR fluorescent, nontoxic, biocompatible, and highly excreted compound that retains

56 egrable semiconducting polymers in low-cost, biocompatible, and ultralightweight transient electronic

57 twisting, and has potential for lightweight, biocompatible, and versatile wearable applications.

58 ly for medical applications because they are biocompatible, biodegradable and in selected cases promo

59 ing targeted drug for HCC therapy as PLLA is biocompatible, biodegradable and nontoxic to humans.

60 A set of biocompatible, biodegradable, and biofunctionalizable di

61 tep, cost-effective route to produce a novel biocompatible, biodegradable, and non-toxic controlled r

62 porous organosilica nanoparticle (HMON) as a biocompatible/biodegradable nanocarrier for the co-deliv

63 hagi inside a perfusion bioreactor to create biocompatible biological rat scaffolds that mimic native

64 ticles (Alb NPs) were prepared from inherent biocompatible bovine serum albumin (BSA).

65 Here, biocompatible branched block copolymer nanoparticles wit

66 The resulting biocompatible, bright 1550 nm emitting nanoparticles ena

67 res: (1) simple and robust construction from biocompatible building blocks, demonstrating prolonged b

68 DNA has proven to be an extremely versatile biocompatible building material on the nanoscale.

69 e and effective method to make SS electrodes biocompatible by means of flame oxidation.

70 que symmetrical and 3D globular structure-as biocompatible carbon platforms for the multivalent prese

71 ydrates by using 3D fullerenes as controlled biocompatible carbon scaffolds represents a real advance

72 hia coli, we identify a highly efficient and biocompatible catalyst for intracellular modification of

73 ss-linked around the polymer, resulting in a biocompatible chemical barrier able to eliminate about 1

74 used to study FA in living systems; however, biocompatible chemical probes for FA are currently lacki

75 he combination of microbial fermentation and biocompatible chemistry.

76 ity of the ceria nanoparticles embedded in a biocompatible chitosan matrix facilitated enzyme stabili

77 Cu-MONPs enter cells and perform efficient, biocompatible click chemistry, thus acting as intracellu

78 We introduce a biocompatible CO-releasing molecule (CORM, A) as Mn(I) t

79 Optically-transparent and biocompatible coatings that simultaneously possess chara

80 FCs should not only be made of non-toxic and biocompatible compounds but should also be able to opera

81 s undergo rapid thiol Michael-addition under biocompatible conditions in stoichiometric amounts.

82 ir simplest molecular building blocks, under biocompatible conditions is proposed.

83 Tetrazine-mediated decaging proceeded under biocompatible conditions with good yields and reasonable

84 3)) bond-forming reactions on proteins under biocompatible conditions, which exploit unusual carbon f

85 y to heterogeneous palladium catalysis under biocompatible conditions, with a reaction half-life of l

86 iary) in a chemoselective manner under mild, biocompatible conditions.

87 esidues present as disulfides under mild and biocompatible conditions.

88 We synthesized a biocompatible conductive biomaterial (PPy-chitosan) that

89 ical applications because they are flexible, biocompatible, cost-effective, solution-processable, and

90 strategy opens the door for the creation of biocompatible, custom-tailored biomimetic nanoparticles

91 le transition metal catalysts and accelerate biocompatible cyclopropanation in vivo.

92 The design of the biocompatible decal allows for the physical isolation of

93 water-free solvent, namely a low-volatility biocompatible deep-eutectic solvent composed of a 4:1 mi

94 elopment of a DNA nanoprocessor, a small and biocompatible device capable of performing complex analy

95 ive materials as support to manufacture SPME biocompatible devices for a wide range of applications,

96 ounds in such biomatrices creates a need for biocompatible devices which can be implemented for in vi

97 environmentally safe (biodegradable) and/or biocompatible devices.

98 with barbituric acid (BA), a small, organic, biocompatible diaCEST contrast agent.

99 These PLGNPs were considerably robust and biocompatible-displaying extraordinary stability against

100 d porous silicon nanoparticle-functionalized biocompatible double emulsion are developed for versatil

101 versus newer-generation DES coated with more biocompatible DP have not been investigated in depth.

102 Moreover, the biocompatible DPA-MnQdots were used for long-term monito

103 ter splitting-biosynthetic system based on a biocompatible Earth-abundant inorganic catalyst system t

104 at can be inflated to a desired volume using biocompatible effervescent chemicals.

105 With an instant start-up, the as-fabricated biocompatible electrodes could hold bacteria in an activ

106 t require transparent, highly conductive and biocompatible electrodes.

107 led piezoelectricity provide a renewable and biocompatible energy source for biomedical applications

108 A biocompatible fluorescent nanoprobe for singlet oxygen (

109 atic central core affords a highly efficient biocompatible fluorescent probe that can be taken up in

110 A new biocompatible fluorescent receptor 1 was synthesized by

111 The synthesized compounds have been used as biocompatible fluorophores in cell bioimaging.

112 ole-linked DNA backbone that is sufficiently biocompatible for PCR amplification to generate a cDNA l

113 The CP is biocompatible, forms an environment suitable for islet e

114 rs are lipid-based, offering a wide range of biocompatible formulations.

115 ous micro-/nanomotors that can be powered by biocompatible fuels.

116 on device, the Micro-funnel, fabricated from biocompatible fused silica capillary.

117 -NP gel formation that is utilized to design biocompatible gels for drug delivery.

118 -coordination-polymer (ICP) nanoparticles as biocompatible gene-regulation agents.

119 ped the synthesis of novel water-soluble and biocompatible glucose-coated gold nanoparticles (GNPs) c

120 e we report the successful construction of a biocompatible guidance device, in which a linear propaga

121 s of suitable, reversible reactions that are biocompatible have been established and the portfolio of

122 ntion because of their propensity to furnish biocompatible, hierarchical, supramolecular architecture

123 tablish a novel platform for the creation of biocompatible, high-aspect ratio nanoparticles for biome

124 ecellularization to human scale and obtained biocompatible human acellular cardiac scaffolds with pre

125 omaterials is crucial for developing various biocompatible hybrid materials and biosensing platforms.

126 nt renewable feedstock, is used to develop a biocompatible hydrogel as anti-infective ointment.

127 lowed by encapsulation in recently developed biocompatible hydrogel capsules.

128 and reservoirs into stretchable, robust, and biocompatible hydrogel matrices.

129 ao and co-workers develop on page 4035 a new biocompatible hydrogel system that is extremely tough an

130 A new biocompatible hydrogel, resulting from the self-assembly

131 nd devices based on stretchable, robust, and biocompatible hydrogel-elastomer hybrids that host vario

132 an earth-abundant substitute, alpha-NiS, as biocompatible hydrogen evolution reaction (HER) electroc

133 ively immobilize probes and to detect DNA on biocompatible, hydrophilic cellulose coated supports wit

134 Host reactivity to biocompatible immunoisolation devices is a major challen

135 ction of hydrogen from water splitting using biocompatible inorganic catalysts.

136 i-implantitis represents a disruption of the biocompatible interface between the titanium dioxide lay

137 hanging electrolyte gel provides a pervading biocompatible interface for charge conduction through hi

138 Herein we report a biocompatible iron(III) phthalocyanine catalyst capable

139 sites of chemical ligation, and yet is fully biocompatible; it is replicated by DNA polymerases in vi

140 at of aluminium, is abundant on Earth and is biocompatible; it thus has the potential to improve ener

141 and preparation as stable, monodisperse, and biocompatible liposomes and polymersomes called for the

142 Photocurable, biocompatible liquid resins are highly desired for 3D st

143 cells (RBCs) are readily available and fully biocompatible long-circulating intravascular carriers (n

144 In fact, biocompatible luminescent probes with unique photochemic

145 Here, newly developed highly biocompatible magnesium shallow doped gamma-Fe2 O3 (Mg0.

146 Here we introduce a technique that employs biocompatible, magnetically responsive ferrofluid microd

147 es to adherent states, all in a contactless, biocompatible manner.

148 encapsulation in single layer graphene in a biocompatible manner.

149 properties in a label-free, contactless, and biocompatible manner.

150 rface area to volume ratio, and by employing biocompatible material gallic acid, immobilized enzyme s

151 e nanoscale shape control of this inherently biocompatible material is combined with the potential to

152 f low-cost, highly stable, electroactive and biocompatible material is one of the key steps for the a

153 The balloon is made from a thin and biocompatible material that can be inflated to a desired

154 process, zirconia (ZrO2) powder is a kind of biocompatible material, red phosphorus can be used to pr

155 ion nanoparticles in order to generate a new biocompatible material.

156 ible, lightweight, optically transparent and biocompatible material.

157 thermal, optical, electrical, chemical, and biocompatible materials properties to its complete sp (3

158 -muscle ECM, can be fabricated using various biocompatible materials to guide cell alignment, elongat

159 se dioxide (MnO2) nanoparticles (MDNP) using biocompatible materials to reoxygenate the TME by reacti

160 currence, infection, fistula, bioprosthesis, biocompatible materials, absorbable implants, dermis, an

161 The sensors can be made from biocompatible materials, are themselves detectable down

162 Recent advances have enabled 3D printing of biocompatible materials, cells and supporting components

163 ght, and since it is flexible and is made of biocompatible materials, it offers a promising solution

164 lowing an injury, through the combination of biocompatible materials, stem cells and bioactive factor

165 the development of synthetic collagen-based biocompatible materials.

166 h cells derived in vitro in combination with biocompatible materials.

167 is 1.5 orders of magnitude deeper than other biocompatible materials.

168 locks for the construction of bio-active and biocompatible materials.

169 the physical entrapment of proteins within a biocompatible matrix and their immobilization on electro

170 trodeposited calcium alginate hydrogels as a biocompatible matrix in the development of enzymatic amp

171 have encapsulated an anti-cancer drug into a biocompatible matrix.

172 Biocompatible MDE enables in-droplet cultivation of diff

173 s requires electrical power sources that are biocompatible, mechanically flexible, and able to harnes

174 The use of collagen as a biocompatible membrane represents a general approach to

175 M) technique is an easy-to-use, compact, and biocompatible method, permitting rotation regardless of

176 ts capabilities for gas sorption, the highly biocompatible Mg2(olz) framework was also evaluated as a

177 chemical ligation strategies for assembly of biocompatible modified DNA, we have synthesized oligonuc

178 NO is an endogenous and biocompatible molecule, contrasting with other potential

179 The development of new biocompatible molecules relies on the identification and

180 For designing of imprinted polymer two biocompatible monomers (cystine monomer and N-vinyl capr

181 Demonstration examples include various biocompatible, multifunctional systems with autonomous b

182 ghly efficient, environmentally friendly and biocompatible nano-dispersant has been developed compris

183 By adding biocompatible nanoclay, the tough hydrogel is 3D printed

184 f anti-HIV drugs targeting (dis)assembly and biocompatible nanocoatings are discussed.

185 A biocompatible nanocomposite including bovine serum album

186 A strategy to develop water soluble, biocompatible nanocomposite probe for the detection of p

187 In this study, a highly biocompatible nanocomposite protein hydrogel with excell

188 However, the preparation of biocompatible nanocrystals is made difficult by the pres

189 It is a natural biocompatible nanomaterial available in thousands of ton

190 ently, as metal-, polymer-, and carbon-based biocompatible nanomaterials have been increasingly incor

191 re in turn beneficial for manufacturing more biocompatible nanomaterials in many industrial fields.

192 Biocompatible nanomaterials with enzymatic properties co

193 en established in recent years as a route to biocompatible nanomaterials with novel mechanical, optic

194 r therapeutic compounds to neutrophils using biocompatible, nanometer-sized synthetic vesicles, or po

195 ese compounds in liver-tropic biodegradable, biocompatible nanoparticles confers hepatoprotection aga

196 ubes, and organic dyes, are constructed into biocompatible nanoparticles using the layer-by-layer (Lb

197 pproach to the layer-by-layer fabrication of biocompatible, nanoscale 'polyelectrolyte multilayers' (

198 A thin layer of a biocompatible nanostructured polypyrrole (PPy) was elect

199 ell delivery applications because of the all-biocompatible nature of the water-in-water ATPS environm

200 A bright, renal-excreted, and biocompatible near-infrared II fluorophore for in vivo i

201 With a view to identify novel and biocompatible neuroprotectants, we designed nucleoside 5

202 recently been investigated as efficient and biocompatible oil dispersants utilizing their encapsulat

203 ermal detections, computational memories and biocompatible optoelectronic probes.

204 Biocompatible organic dyes emitting in the near-infrared

205 mer nanosystems binding a model antigen, are biocompatible over a wide range of concentrations, and s

206 point at 39 degrees C, and can be used as a biocompatible phase-change material for NIR-triggered dr

207 ovel concept of a "photonic cell": namely, a biocompatible photonic structure that is encased by a pe

208 The approach consists of a biocompatible plate surgically fixated to the mouse femu

209 advanced photothermal responsive all-in-one biocompatible platform can be easily formed with great t

210 integration of these modalities in a single biocompatible platform remains a challenge.

211 Biocompatible poly (lactic-co-glycolic acid) was selecte

212 w theranostic platform is developed based on biocompatible poly(acrylic acid) (PAA)-Co9 Se8 nanoplate

213 ocapsules (NCs) based on a biodegradable and biocompatible poly(epsilon-caprolactone) polymer.

214 uryl)phosphine]palladium(II) dichloride in a biocompatible poly(lactic-co-glycolic acid)-b-polyethyle

215 ory protein-II (vMIP-II) was conjugated to a biocompatible poly(methyl methacrylate)-core/polyethylen

216 controlled conjugation and polymerization, a biocompatible poly(methyl methacrylate)-core/polyethylen

217 The novel biocompatible poly(p-phenylenediamine) (PpPDA)-Fe3O4 nan

218 h BMS, DES implantation using a stent with a biocompatible polymer and fast drug-eluting characterist

219 g the features of EVA as a highly versatile, biocompatible polymer for drug delivery devices.

220 ion protein was encapsulate into MNPs with a biocompatible polymer for use as a boosting vaccine.

221 ing the fluoroionophore into water-swellable biocompatible polymer matrices (polyurethane hydrogels),

222 The tranexamic acid biocompatible polymer microneedle used in this study was

223 The biocompatible polymer microneedle was fabricated at 60 d

224 ecifically bind polyethylene glycol (PEG), a biocompatible polymer routinely used in protein and nano

225 Using a biocompatible polymer that self-assembles at high concen

226 cessfully fabricated fully disintegrable and biocompatible polymer transistors.

227 Herein, we demonstrate that a noncationic, biocompatible polymer, polyethylene glycol, can be used

228 Poly(ethylene glycol) (PEG) is a widely used biocompatible polymer.

229 Biocompatible polymeric device coatings were integrated

230 comprised only of a chemically cross-linked biocompatible polymeric hydrogel is developed.

231 derivation of graphene oxide (GO) to form a biocompatible polymeric matrix on RGO nanosheet.

232 Recently-introduced biocompatible polymeric microneedles offer an efficient

233 Efficient delivery of Platin-M using a biocompatible polymeric nanoparticle (NP) based on biode

234 ineered with adjuvant-loaded, biodegradable, biocompatible, polymeric particles, with the aim of gene

235 This work provides potential biocompatible polymers for stabilization of the importan

236 Biocompatible polymers have been extensively applied to

237 Next, the biocompatible polymers PLGA-PEG-A were synthesized and u

238 icle coatings, composed of biodegradable and biocompatible polymers poly(caprolactone) and poly(glyce

239 ld serve as promising monomers for producing biocompatible polymers via alternating copolymerization

240 ect of crowding as mimicked by commonly used biocompatible polymers.

241 ast cancer treatment, into biodegradable and biocompatible polypeptide-based nanogels.

242 orseradish peroxidase, were immobilized on a biocompatible polysaccharide matrix to develop a functio

243 he smooth surface and small pore size of the biocompatible PPy coating, which was prepared in the pre

244 hin whole dental pulp tissue are shown to be biocompatible, preserving local tissue architecture.

245 y to serve as a super-bright, water-soluble, biocompatible probe capable of generating stimulated emi

246 evaluate their mechanical, rheological, and biocompatible properties.

247 nergism in their electrical, mechanical, and biocompatible properties.

248 hold implications for the next generation of biocompatible proton-conducting materials and protonic d

249 Furthermore, disintegrable and biocompatible pseudo-complementary metal-oxide-semicondu

250 ximately 15 nm in hydrodynamic diameter) and biocompatible quantum dot (QD) -Ab conjugates.

251 robust methionine labeling under a range of biocompatible reaction conditions.

252 This efficient biocompatible reaction may be useful for creating novel

253 tic incorporation followed by two sequential biocompatible reactions allows convenient synthesis of p

254 We expect that this biocompatible reductive chemistry will be broadly useful

255 rionic phosphocholine (PC) lipids are highly biocompatible, representing a major component of the cel

256 er printing technique, into smart and highly biocompatible scaffolds capable of supporting growth of

257 ch provides a non-radioactive, non-metallic, biocompatible, semi-quantitative, and clinically transla

258 port an example of totally disintegrable and biocompatible semiconducting polymers for thin-film tran

259 l utility of the scaffolds as a flexible and biocompatible sensor.

260 ry, and brings the prospect for all-organic, biocompatible sensors if implantation is ever required.

261 onto gold nanoparticles, these dyes produce biocompatible SERRS nanoprobes with attomolar limits of

262 easibility of in vivo imaging of cancer with biocompatible SERS probes have emerged.

263 onically cross-linked hydrated network using biocompatible silicate nanoparticles (SiNPs).

264 As the ink is made of porous, biocompatible silicone that can be printed directly insi

265 ed on piezo-resistive, high-conductance, and biocompatible soft materials that enable integration of

266 We report an extremely biocompatible solvent for plant cell walls based on a po

267 pment, in situ quantification methods, and a biocompatible solvent.

268 issues associated with the use of different biocompatible solvents in SPI systems is also discussed.

269 cute chemical reactions in live systems in a biocompatible, specific, and autonomous manner.

270 his study, we present the direct coupling of biocompatible SPME (Bio-SPME) fibers to mass spectrometr

271 probe (OPP) as a robust interface to couple biocompatible SPME (Bio-SPME) fibers to MS systems for d

272 AgNPs are biocompatible stable noble materials especially in biolo

273 A biocompatible step-index optical fiber made of poly(ethy

274 d nature are particular advantageous for the biocompatible storage and processing of biomacromolecule

275 a nanowell and are in direct contact with a biocompatible substrate of choice.

276 he Si electrode from oxidation and acts as a biocompatible support layer for the productive adsorptio

277 overlayer of SiO2 provides a protective and biocompatible surface to facilitate Raman microspectrosc

278 sing evanescent optical waves generated at a biocompatible surface.

279 Biocompatible surfaces hold key to a variety of biomedic

280 graphene oxide (GO-COOH) composites to form biocompatible surfaces on sensing films for use in surfa

281 mitigated by increasing the concentration of biocompatible surfactant in the suspensions, likely alte

282 k introduces in situ stapling as a versatile biocompatible technique with many other potential high-t

283 into a single extremely versatile and wholly biocompatible technology.

284 fficulties still exist in the engineering of biocompatible theranostic nanoparticles with highly spec

285 adsorbates and reactants, and are non-toxic, biocompatible, thermally stable and suitable as synerget

286 Moreover, besides being biocompatible to mammalian cells, the heterodimer of the

287 rosslinked biologic scaffold implantation is biocompatible to the host tissue and somehow underlying

288 ATC may serve as a promising biocompatible tool to improve hESC culture.

289 ) improved therapeutic response, (iv) use of biocompatible transporter material, and (v) ease of prep

290 lymers combines imaging multimodality with a biocompatible, tunable, and functional nanomaterial carr

291 Biocompatible two-dimensional (2D) graphene analogues (e

292 sfer has set the field on a course to design biocompatible vectors that demonstrate increased DNA sta

293 polymer nanoparticles alone were found to be biocompatible, via the nasal route, on chronic dosing.

294 netic encodability, and response to the more biocompatible visible light.

295 e body soon after use, the biodegradable and biocompatible waveguides may be used for long-term light

296 Acoustic streaming is an effective and biocompatible way to create rapid microscale fluid motio

297 tion of a low-power acoustic field, which is biocompatible with biological samples and with the ambie

298 issue and implant biofilm formation and were biocompatible with enhanced osseointegration.

299 the cellulose, CO2, and air, are natural and biocompatible without adverse effects on the downstream

300 er micelles, and was used to coordinate with biocompatible Zn(2+) and encapsulate the photosensitizer