ライフサイエンスコーパス: biocompatibility

1 emistry, chemical versatility, low cost, and biocompatibility.

2 ized for size, bioavailability, toxicity and biocompatibility.

3 ion and encapsulation due to their excellent biocompatibility.

4 scopy because of their high conductivity and biocompatibility.

5 demonstrate chronic stability and excellent biocompatibility.

6 ity to absorb a broad spectrum of light, and biocompatibility.

7 he design of appropriate interfaces ensuring biocompatibility.

8 rong adhesion, demonstrating their excellent biocompatibility.

9 e their biological functions, stability, and biocompatibility.

10 pulp stem cell cultures indicated their good biocompatibility.

11 a deeper tissue penetration depth and better biocompatibility.

12 echanical properties, chemical inertness and biocompatibility.

13 efficient, high photostability and excellent biocompatibility.

14 bility of osteoblasts, confirming their high biocompatibility.

15 proteins would be promising because of their biocompatibility.

16 ticular attention to the aspects influencing biocompatibility.

17 operties, including strength, elasticity and biocompatibility.

18 rious in the EFP site, probably due to lower biocompatibility.

19 utic platforms with enhanced performance and biocompatibility.

20 utrient availability, capsule stability, and biocompatibility.

21 tory activity, but failed to improve overall biocompatibility.

22 tic properties without compromising cellular biocompatibility.

23 caused by GO on cell metabolism and increase biocompatibility.

24 chable kinetics, excellent orthogonality and biocompatibility.

25 oadening the sensing application of CDs with biocompatibility.

26 positive features are also coupled with high biocompatibility.

27 showed that the nanoparticles possessed good biocompatibility.

28 otal hip arthroplasty due to their excellent biocompatibility.

29 robial/antibiofilm activities and acceptable biocompatibility.

30 ism of cellular entry, and is central to its biocompatibility.

31 with superior therapeutic efficacy and high biocompatibility.

32 lement to enhance antibacterial activity and biocompatibility.

33 ue to their exceptional biodegradability and biocompatibility.

34 ated with these molecules and increase their biocompatibility.

35 g agents and provides enhanced stability and biocompatibility.

36 lume ratio, which may seriously affect their biocompatibility.

37 zebrafish embryos to demonstrate their great biocompatibility.

38 arance of the nanomaterial, guaranteeing the biocompatibility.

39 enantioselectivity, catalytic activity, and biocompatibility.

40 siRNA from degradation, and showed excellent biocompatibility.

41 maintaining mechanical strength and cellular biocompatibility.

42 h signal amplification schemes, and inherent biocompatibility.

43 f chemical modification, as well as moderate biocompatibility.

44 the 3D porous networked structure and great biocompatibility.

45 high energy density, long lifetime and good biocompatibility.

46 ive metal of low-toxicity and of established biocompatibility.

47 materials, ranging from phonon transport to biocompatibility.

48 xcellent reaction kinetics, selectivity, and biocompatibility.

49 tric performance and excellent stability and biocompatibility.

50 nd BPQDs), superior stability, and excellent biocompatibility.

51 to their superior mechanical compliance and biocompatibility.

52 The high degree of biocompatibility along with high porosity and good mecha

53 ymeric layers (P(3) coating), imparting high biocompatibility and >90 % excretion of QDs within 2 wee

54 appropriate for this activity owing to their biocompatibility and ability to generate microscale forc

55 caprolactone (PCL) possess biodegradability, biocompatibility and affinity with other organic media t

56 n and CIR were monitored and correlated with biocompatibility and antimicrobial assessment of eluates

57 ganic bioelectronic materials entail greater biocompatibility and biodegradability compared to conven

58 Its biocompatibility and biodegradability were also demonstr

59 Because of its good biocompatibility and biodegradability, albumins such as

60 irst reported, and this biopolymer with good biocompatibility and biodegradability, binding ability t

61 due to their biocompatibility and biodegradability.

62 In vitro studies confirmed the platform's biocompatibility and biodegradability.

63 livery and nanomedicine as a result of their biocompatibility and biodegradability.

64 Finally, the biocompatibility and biological tolerance of structures

65 tion of QDs to address a much wider range of biocompatibility and biorecognition issues.

66 fects of device implantation with regards to biocompatibility and brain heterogeneity are then explor

67 With improved biocompatibility and capability of emitting high-frequen

68 s the upconversion nanoprobes with excellent biocompatibility and circumvents the problem of particle

69 Biocompatibility and colloidal stability were confirmed

70 MNP exhibited excellent colloidal stability, biocompatibility and drug retaining capability in physio

71 or magnetic resonance imaging owing to their biocompatibility and ease of incorporation into a large

72 Because of good biocompatibility and excellent photostability, the probe

73 the hemin-doped serum albumin mats have both biocompatibility and fabrication simplicity, they should

74 the field of biosensing due to the excellent biocompatibility and flexibility of design.

75 The NPs showed excellent cellular biocompatibility and gene delivery efficacy using the gr

76 rits of silica (e.g., mechanical robustness, biocompatibility and great versatility in surface functi

77 r properties of novel polymers, and have the biocompatibility and hemodynamics comparable to tissue s

78 cal applications because it exhibits general biocompatibility and high tensile material properties.

79 The biocompatibility and long-term biostability of the impla

80 es without using batteries, which compromise biocompatibility and long-term residence.

81 t and exhibiting proper immunocompatibility, biocompatibility and mechanical characteristics, has not

82 gelatin-SH/PEGDA IPN hydrogels demonstrated biocompatibility and mechanical properties for a possibl

83 glycolide) (PLGA) mats, which have excellent biocompatibility and mechanical properties, were combine

84 extensive applications due to its excellent biocompatibility and mechanical properties.

85 um (Mg) and its alloys have shown attractive biocompatibility and mechanical strength for medical app

86 or degree of conversion, low CIR, acceptable biocompatibility and moderate antibacterial activity.

87 To improve the biocompatibility and modify the UCNPs with a polypeptide

88 BMP2 in the body fluid environment with good biocompatibility and no cytotoxicity.

89 The proposed biosensor with highly biocompatibility and nontoxicity, can be developed for d

90 In vivo biocompatibility and organ biodistribution studies of L-

91 -modified magnesium alloy with the excellent biocompatibility and osteoconductivity of bioglass-magne

92 s were durable, leak-proof, and demonstrated biocompatibility and patency in rabbit eyes.

93 sation or blending in order to improve their biocompatibility and physical properties.

94 In conclusion, BMs display excellent biocompatibility and potential for use in the treatment

95 ly, such efforts are stymied by the inherent biocompatibility and recalcitrance of cellulose fibers.

96 d passive non-fouling approaches to increase biocompatibility and reduce infection associated with me

97 Histological evaluations suggest conduit biocompatibility and Schwann cell infiltration and organ

98 ene glycol (PEG) significantly enhanced both biocompatibility and stability in physiological medium.

99 me a research hotspot due to their excellent biocompatibility and stability.

100 On the fabricated 69nm PSNG, biocompatibility and structural characteristics were ver

101 Further, biocompatibility and suitability of formulations were te

102 on for practical applications owing to their biocompatibility and sustainability.

103 nd processing conditions that preserve their biocompatibility and the integrity of encapsulated compo

104 Nanocrystalline hydroxyapatite (HA) has good biocompatibility and the potential to support bone forma

105 In addition, the biocompatibility and the very high SNR exhibited during

106 nificant improvements in the sensitivity and biocompatibility and thereby open up opportunities in fu

107 ed cells or natural tissues exhibit superior biocompatibility and trigger favourable immune responses

108 f GNPs lie in its superior optical property, biocompatibility and versatile conjugation chemistry, wh

109 fluidic microstructures with a high level of biocompatibility and, importantly, the capacity to withs

110 n some cases no polymer (to improve vascular biocompatibility) - and new antiproliferative drug types

111 for FDM, based on solvent compatibility and biocompatibility, and (iii) application of FDM technolog

112 retreatment, long-term responses, stability, biocompatibility, and a rich surface chemistry.

113 ed materials, primarily for their abundance, biocompatibility, and ability to readily organize into p

114 als that exhibit exceptional hydrophilicity, biocompatibility, and antifouling properties.

115 etals, which can be biodegradable, have good biocompatibility, and are pH-sensitive, could have broad

116 r high surface areas, metallic conductivity, biocompatibility, and attractive optoelectronic properti

117 erfacing due to their high transconductance, biocompatibility, and availability in a variety of form

118 etc., due to their inherent sustainability, biocompatibility, and biodegradability.

119 hemical challenges to attain bioselectivity, biocompatibility, and biostability required by modern ap

120 wever, these constructs present engraftment, biocompatibility, and cell functionality limitations in

121 (PTX) to humans due to drug solubilization, biocompatibility, and dose escalation.

122 e it sacrifices reproducibility, uniformity, biocompatibility, and durability due to its strong depen

123 logy due to their large water capacity, high biocompatibility, and facile functional versatility.

124 vantage of the high phototherapeutic effect, biocompatibility, and flexible operability in this syste

125 , pH-dependent membrane disruptive activity, biocompatibility, and gene silencing efficiency.

126 res are chosen for their multifunctionality, biocompatibility, and giant effective sensing surface.

127 properties, remarkable in vitro and in vivo biocompatibility, and high electrical conductivity witho

128 nd exhibits high fluorescent stability, good biocompatibility, and low biological toxicity in normal

129 herent mechanical flexibility, printability, biocompatibility, and low cost.

130 ations due to their robust piezoelectricity, biocompatibility, and low dielectric property.

131 features of uveal biocompatibility, capsular biocompatibility, and postoperative IOL opacification.

132 ctive option due to their low toxicity, high biocompatibility, and potential to carry a large amount

133 ATRA-PLLA microparticles had good biocompatibility, and significantly enhanced the inhibit

134 gh cargo-loading capacity, biodegradability, biocompatibility, and stimuli-responsiveness.

135 vantages of enhanced stability, kinetics and biocompatibility, and the superior pharmacokinetics of t

136 a proof of concept of its manufacturability, biocompatibility, and transparency, we performed a cell

137 n drug encapsulation and release mechanisms, biocompatibility, and treatment duration have become hig

138 to their tunable physiochemical properties, biocompatibility, and ultralow friction.

139 versely affecting their mechanical strength, biocompatibility, and/or bioactivity remains challenging

140 tionalized conductive graphene with enhanced biocompatibility, anti-oxidation, and solderability, whi

141 s through the blood-ocular barrier and their biocompatibility are essential characteristics that must

142 ronics where conformability, reliability and biocompatibility are key-enabling features.

143 luorescence emissions, high sensitivity, and biocompatibility are the driving forces for the applicat

144 Owing to the outstanding conductivity and biocompatibility as well as numerous other fascinating p

145 tions of rupture, harvest site morbidity and biocompatibility associated with autografts, allografts

146 of suitable bioinks with high printability, biocompatibility, biomimicry, and proper mechanical prop

147 er in the world with key properties, such as biocompatibility, biorenewability, and sustainability ha

148 ns, high structural resolution and excellent biocompatibility can be cheaply fabricated using magnetr

149 s well as pathophysiologic features of uveal biocompatibility, capsular biocompatibility, and postope

150 ause of its high electrical conductivity and biocompatibility caused by its hydrophilic nature, low-t

151 at our DDS exhibit excellent properties like biocompatibility, cellular uptake, and photoregulated du

152 signal-transduction pathways involved in the biocompatibility complex.

153 e materials due to toxicity, durability, and biocompatibility concerns.

154 vaginal progesterone absorption and vaginal biocompatibility could be more effective for PTB prevent

155 Finally, the superior biocompatibility demonstrated by in vitro cytotoxicity a

156 of host responses to biomaterials, known as biocompatibility, depends on chemical principles as the

157 ver the past few decades, restriction on the biocompatibility due to the required synthetic condition

158 Biocompatibility evaluation indicated that the hydrogels

159 PEEK mesh was selected due to its biocompatibility, excellent resistance to various organi

160 Furthermore, the biocompatibility exhibited by many carbon nanomaterials

161 patibility with microfluidic components, and biocompatibility for cellular studies, has been extensiv

162 arbons have negligible cytotoxicity and high biocompatibility for human cells, promising a wide range

163 compatibility studies demonstrated excellent biocompatibility for in vivo administration.

164 ion, maximum stretchability, durability, and biocompatibility for multiday wear time.

165 ng probes with improved sensitivity and good biocompatibility for single plasmonic particle tracking

166 2D nanoparticles so valuable, as well as the biocompatibility framework that has been investigated so

167 id the drawbacks of poor controllability and biocompatibility from traditional scleroid skeletons, bu

168 ttracted considerable attention due to their biocompatibility, functional molecular recognition and u

169 perties for designing advanced DDS including biocompatibility, gelation properties and/or mucoadhesiv

170 ts high conductivity, chemical stability and biocompatibility, gold exhibits high plasticity, which l

171 r electromagnetic properties, tunability and biocompatibility, gold nanorods (GNRs) are being investi

172 atural protein renowned for its strength and biocompatibility, has been widely studied in this contex

173 operties of viruses, along with their innate biocompatibility, have led to their development as activ

174 to untreated mice, demonstrating kidney and biocompatibility health.

175 possess wide clinical utility owing to their biocompatibility, high antigen specificity, and targeted

176 mpatible environment for drug encapsulation, biocompatibility, high drug loading and tailorable relea

177 ges of this system include water solubility, biocompatibility, high quantum yield for catalyst releas

178 cancer theranostics, ranging from excellent biocompatibility, high stability, prolonged blood lifeti

179 Au@Rh-ICG-CM shows good biocompatibility, high tumor accumulation, and superior

180 t are gaining increasing attention for their biocompatibility, highly functional surfaces, optical pr

181 ectomy models, and its surgical efficacy and biocompatibility in a non-human primate retinal-detachme

182 applications and (5) proven feasibility and biocompatibility in an animal model of ligament reconstr

183 ndustrial manufacturing methods, and improve biocompatibility in biomedical applications conducted wi

184 layer nanosheets for greatly improving their biocompatibility in biomedical applications.

185 tivity, sensitivity, sensocompatibility, and biocompatibility in challenging biological environments.

186 sis, UCNP@p-Au exhibited little toxicity and biocompatibility in head and neck cancer cells.

187 ed sorbents are yet to satisfy environmental biocompatibility in situ but opportunities are there to

188 In this review, we discuss biocompatibility in the context of chemistry, what it is

189 anotherapeutics have demonstrated safety and biocompatibility in treating surgical diseases.

190 and showed their functionality in vitro and biocompatibility in vivo.

191 oxygen species (ROS) scavenging ability and biocompatibility is a promising way for the treatment of

192 Biocompatibility is evidenced by the absence of cell dea

193 iosensors present the potential for improved biocompatibility, localized sample volumes, and much fas

194 y availability, general biodegradability and biocompatibility, low or negligible toxicity, often a lo

195 tobacteraceae Its high strength, purity, and biocompatibility make it of great interest to materials

196 implants such as dissolution in body fluids, biocompatibility, mechanical properties and bioelectrica

197 onic structures owing to their renewability, biocompatibility, mechanical robustness, ambient process

198 tein biomaterial allowing us to leverage its biocompatibility, nonthrombogenic features, programmable

199 autofluorescence, solvent compatibility, and biocompatibility of 12 representative FDM materials were

200 GMs exhibit a biocompatibility of 80% cell viability with primary fibr

201 In this study, the in vivo biocompatibility of albumin nanoparticles was investigat

202 igh anti-interference ability, and excellent biocompatibility of beta-CD-CDs made this probe system s

203 which can in turn tune the functionality and biocompatibility of bioelectronic devices.

204 Our findings suggest that the in vivo biocompatibility of biomedical devices can be significan

205 ty, working characteristics and osteoblastic biocompatibility of bone cement.

206 an efficient strategy to further improve the biocompatibility of BPs.

207 Given the biocompatibility of Cas12a-like enzymes, this versatile

208 Due to strong fluorescence and good biocompatibility of CDs, the capture probe was covalentl

209 udy demonstrated that the restoration of the biocompatibility of contaminated titanium surfaces is al

210 The protective effect and good biocompatibility of Cu(5.4)O USNPs will facilitate clini

211 ditionally, we need to ensure the blood cell biocompatibility of developed devices prior to that of t

212 e to the robustness, chemical inertness, and biocompatibility of diamond.

213 n osteoblasts subsequently demonstrated good biocompatibility of functionalised albumin hydrogels com

214 tudy evaluates the osteogenic properties and biocompatibility of growth factor-rich demineralized bon

215 ign considerations for this polymer, and the biocompatibility of its constituent materials.

216 aimed to investigate the cardiac safety and biocompatibility of mono-2-ethylhexyl phthalate (MEHP),

217 Biocompatibility of nanoparticles, containing toxic elem

218 d in the food, drug and cosmetic industries, biocompatibility of nanoscale titania is still under car

219 l (GelMA)-based hydrogels, which combine the biocompatibility of natural matrices with the reproducib

220 sis, or other pathologic changes, suggesting biocompatibility of NETs.

221 heteroatom doping (such as N, S, P) and good biocompatibility of precursor.

222 ulticopy display on the phage scaffold, good biocompatibility of recombinant phage, the fibrous nanos

223 clinical settings due to its miniature size, biocompatibility of silica glass and reflector less set

224 The in vivo biocompatibility of SPNs is discussed first in details,

225 x 10(9) A m(-1) s(-1) ), and highly required biocompatibility of superparamagnetic nanoparticle (SPNP

226 Both treatments maintained a good biocompatibility of surfaces to Saos-2 osteoblasts.

227 ts showed that the mechanical properties and biocompatibility of the adhesive were not affected.

228 We validate in vivo biocompatibility of the bioadhesive and the triggering s

229 We demonstrated the biocompatibility of the C-S bond coupling reaction by ap

230 Biocompatibility of the components of this device was te

231 robe interactions, consistent with long-term biocompatibility of the device.

232 oactive surface, electronic conductivity and biocompatibility of the electrode surfaces which then im

233 on around depot site, suggesting exceptional biocompatibility of the formulation for long-term use.

234 Moreover, the biocompatibility of the formulations was determined on i

235 ns from the hydrogel network, as well as the biocompatibility of the gels, are evaluated both in vitr

236 e-escalation cytotoxicity assays confirm the biocompatibility of the inks, extending their possible u

237 Additionally, biocompatibility of the materials used have been tested.

238 ydrogel layers provides a high yield and the biocompatibility of the micro-rolls with any length in t

239 f 14.2 and 35.5s respectively, revealed high biocompatibility of the nanogels.

240 The biocompatibility of the nanoparticles was proven.

241 More specifically, the biocompatibility of the naturally polymerized hydrogel w

242 We tested the long-term biocompatibility of the polymer endotamponade in rabbit

243 The biocompatibility of the printed platform is tested using

244 To improve conductivity and biocompatibility of the screen-printed electrodes, we ha

245 The biocompatibility of these functionalized nanotubes, whic

246 Chlorhexidine may compromise the biocompatibility of titanium surfaces, and its use is no

247 evaluate the efficiency, effectiveness, and biocompatibility of two agents used for the chemomechani

248 Biocompatibility of two newly developed porcine skin sca

249 ces that strive to achieve the transparency, biocompatibility, patient comfort, and biointegration th

250 particles with further improved function and biocompatibility, paving the path to eventual in vivo st

251 g slow adhesion formation, weak bonding, low biocompatibility, poor mechanical match with tissues, an

252 ns of the capsules were used to assess their biocompatibility postmortem.

253 me inherent hydrophobicity and improve their biocompatibility, pristine SWCNTs are often coated with

254 the clinical parameters including stability, biocompatibility, protein corona, cellular internalizati

255 photothermal conversion efficacy (PTCE) and biocompatibility remains a key challenge.

256 s, cellulose-based materials, owing to their biocompatibility, renewability, and sustainability, are

257 terized in terms of cell retention capacity, biocompatibility, scalability, and long-term reliability

258 characteristics for bioorthogonal chemistry: biocompatibility, selectivity, and a rapid and high-yiel

259 NIR-II emitters, RNase-A@AuNCs had excellent biocompatibility, showing >50-fold higher sensitivity in

260 However, requirements of DNP probes such as biocompatibility, signal sensitivity, and spin-lattice r

261 ent, and therapeutics owing to its excellent biocompatibility, simple design, and label-free automate

262 vantages of excellent optical properties and biocompatibility, single-strand DNA-functionalized quant

263 n their outstanding ability in balancing the biocompatibility, stability, biodegradability, and funct

264 The as-prepared CDPGM NPs show good biocompatibility, strong NIR absorption, high relaxivity

265 A biocompatibility study was performed to evaluate materia

266 aterial, strong X-ray attenuation, excellent biocompatibility, tailorable surface chemistry, and tuna

267 n of salt-based ATPS microdroplets and their biocompatibility test.

268 environments remains unpredictable, whereby biocompatibility testing usually occurs in serum.

269 micropump components successfully passed key biocompatibility tests.

270 atalytic activity, therapeutic efficacy, and biocompatibility that are critical for clinical translat

271 elected as former material both for its high biocompatibility that guarantees the proper environment

272 Owing to the flexibility and biocompatibility, the lipid-based nanocarriers, includin

273 bove renal threshold without impairing their biocompatibility, thereby leading to significant improve

274 moted azide-alkyne reaction, and exploit its biocompatibility to accelerate the discovery of cell-act

275 f touch pads that require stretchability and biocompatibility to allow their integration with a human

276 DNA and 2.0% alginate), and thus showed good biocompatibility to various tissue cells.

277 2) surface change induction; and 3) residual biocompatibility toward osteoblasts.

278 quire undertaking of fundamental research on biocompatibility, toxicology and biopersistence in the l

279 protein adsorption while retaining cellular biocompatibility, transparency, and good mechanical prop

280 uantum yield, the chemical stability and the biocompatibility turned them into a valid alternative to

281 ntioxidant activity (using DPPH radical) and biocompatibility (using calf-thymus DNA) of curcumin-loa

282 The electrode arrays biocompatibility was demonstrated through in-vitro cell

283 Biocompatibility was evaluated using cytotoxicity assays

284 Scaffold biocompatibility was evaluated using human adipose-deriv

285 The sealer biocompatibility was measured by cell function and proli

286 Biocompatibility was studied in vivo in an ovine model b

287 n addition, for use orally, cytotoxicity and biocompatibility were important considerations for the n

288 -CS-AuNP) nanocomposite films with excellent biocompatibility were synthesized and characterized by s

289 anical adhesion, transparency, oil type, and biocompatibility, were optimized in comprehensive in vit

290 s) is to achieve inorganic-organic composite biocompatibility while improving the activity and select

291 oxicity results, loaded particles had a good biocompatibility, while there were slight prevention eff

292 properties such as high carrier mobility and biocompatibility with antibodies and bacteria.

293 que advantages including mild conditions and biocompatibility with aqueous media.

294 rocess, while flexibility and softness favor biocompatibility with surrounding tissue.

295 Dlink(m)-PDLLA nanoparticles show comparable biocompatibility with the clinically used PEG-b-PDLLA mi

296 non-polar molecules that exhibit remarkable biocompatibility, with applications in liquid ventilatio

297 hile, there is also a growing concern on its biocompatibility, with little known on its interactions

298 lants, blood, and the vital organs confirmed biocompatibility without any adverse effect after implan

299 fibrosis inhibition, and improve biomaterial biocompatibility without the need for broad immunosuppre

300 h signal-to-noise ratio, photostability, and biocompatibility; yet, making nanoparticles small yields