ライフサイエンスコーパス: biocompatibility

1 robial/antibiofilm activities and acceptable biocompatibility.

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

3 with superior therapeutic efficacy and high biocompatibility.

4 echanical properties, chemical inertness and biocompatibility.

5 lement to enhance antibacterial activity and biocompatibility.

6 ue to their exceptional biodegradability and biocompatibility.

7 bility of osteoblasts, confirming their high biocompatibility.

8 ated with these molecules and increase their biocompatibility.

9 g agents and provides enhanced stability and biocompatibility.

10 lume ratio, which may seriously affect their biocompatibility.

11 proteins would be promising because of their biocompatibility.

12 zebrafish embryos to demonstrate their great biocompatibility.

13 ure of the coatings positively affects their biocompatibility.

14 se of their functional versatility and their biocompatibility.

15 ticular attention to the aspects influencing biocompatibility.

16 echanical stability of coatings or films, or biocompatibility.

17 o toxicity studies demonstrated their unique biocompatibility.

18 e glyco-moiety to bring water solubility and biocompatibility.

19 oprosthetic device: efficiency, lifetime and biocompatibility.

20 ical stability, high catalytic activity, and biocompatibility.

21 mical characteristics influences toxicity or biocompatibility.

22 ated quantitatively in relation to pulmonary biocompatibility.

23 operties, including strength, elasticity and biocompatibility.

24 ueous systems which results in their limited biocompatibility.

25 ccessibility, scaffolding ability as well as biocompatibility.

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

27 Its hydrophilic nature facilitates biocompatibility.

28 aces and surface modifications with improved biocompatibility.

29 thetic modification of surfactants to impart biocompatibility.

30 transparency, ease of functionalization, and biocompatibility.

31 ch as ion-to-electron transduction given its biocompatibility.

32 ntimicrobial properties while retaining host biocompatibility.

33 utic platforms with enhanced performance and biocompatibility.

34 utrient availability, capsule stability, and biocompatibility.

35 tory activity, but failed to improve overall biocompatibility.

36 tic properties without compromising cellular biocompatibility.

37 caused by GO on cell metabolism and increase biocompatibility.

38 chable kinetics, excellent orthogonality and biocompatibility.

39 a deeper tissue penetration depth and better biocompatibility.

40 oadening the sensing application of CDs with biocompatibility.

41 positive features are also coupled with high biocompatibility.

42 showed that the nanoparticles possessed good biocompatibility.

43 otal hip arthroplasty due to their excellent biocompatibility.

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

45 ring functional groups that display inherent biocompatibility alongside abiotic components for organi

46 or xenogeneic, decellularized scaffolds are biocompatibility and absence of rejection.

47 nd-manufactured spider silk meshes with good biocompatibility and beneficial mechanical properties se

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

49 ange of biomedical applications due to their biocompatibility and biodegradability in vivo, as well a

50 Its biocompatibility and biodegradability were also demonstr

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

52 Owing to their low toxicity, biocompatibility and biodegradability, aliphatic poly(ca

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

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

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

56 s a means to increase drug delivery systems' biocompatibility and biodegradation.

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

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

59 The properties of silk such as biocompatibility and controlled degradation are utilized

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

61 therapeutic purposes due to its exceptional biocompatibility and efficiency over typical DNA.

62 NCaPP demonstrated higher levels of biocompatibility and efficiently transfected PDGF plasmi

63 polyethylene (PE-UHMW), a material with high biocompatibility and excellent mechanical properties, is

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

65 anical properties of the hydrogel, while the biocompatibility and functionality of the gels are maint

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

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

68 c of zebrafish embryos and display excellent biocompatibility and local catalytic activity.

69 The biocompatibility and long-term biostability of the impla

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

71 tive fabricated design evaluation, evaluates biocompatibility and mechanical properties, and models a

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

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

74 ung capillary bed, largely due to their poor biocompatibility and non-degradability under physiologic

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

76 In vivo biocompatibility and organ biodistribution studies of L-

77 cium phosphate cements (CPCs) have excellent biocompatibility and osteoconductivity for dental, crani

78 GDBM demonstrated acceptable biocompatibility and osteogenic potential comparable to

79 To assess biocompatibility and osteoinductivity, the respective bo

80 C products, with emphasis on improvements in biocompatibility and oxygen delivery.

81 er a new and attractive means to improve the biocompatibility and performance of implantable chemical

82 Biocompatibility and potential biomedical applications o

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

84 that best take advantage of the small size, biocompatibility and programmability of DNA-based system

85 fixed in the bone for 4 and 8 weeks, exhibit biocompatibility and promote bone remodelling.

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

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

88 o their high corrosion resistance, excellent biocompatibility and relatively low elastic modulus.

89 dothelial cells (HUVECs), thus demonstrating biocompatibility and relevance for evaluating drug metab

90 The long-term biocompatibility and reliability of neural micro-electro

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

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

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

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

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

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

97 al environment is a key determinant of their biocompatibility and therapeutic performance.

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

99 Biocompatibility and tissue response outcomes were evalu

100 an promote efficient binding, clearance, and biocompatibility and to assess their safety to other bio

101 onsequences in terms of chemical reactivity, biocompatibility and toxicity.

102 Biocompatibility and transfection of the nanoplexes in f

103 bited excellent stability, cost-effectivity, biocompatibility and tunable NIR absorption.

104 and materials fields due to their increased biocompatibility and tuneable response.

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

106 x matching), multiplexed microRNA detection (biocompatibility) and embedded labelling of high-tempera

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

108 oating provides high colloidal stability and biocompatibility, and a versatile surface functionality.

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

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

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

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

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

114 hieve two-way cell sorting with high purity, biocompatibility, and biosafety.

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

116 biorecognition, biodegradability, potential biocompatibility, and control over mechanical properties

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

118 tion with the established nonimmunogenicity, biocompatibility, and enhanced tumor accumulation of HSA

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

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

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

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

123 side effects of the drug, enhances the drug biocompatibility, and improves the drug therapeutic inde

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

125 superb sensitivity, specificity, resolution, biocompatibility, and minimal perturbation.

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

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

128 n above the size regime of 15-20 nm!), their biocompatibility, and the direct integration approach ar

129 cycles at 60-94 degrees C) while maintaining biocompatibility, and the reaction efficiency of RPA is

130 ng the transformation, evolution, transport, biocompatibility, and toxicity of graphene derivatives i

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

132 try schemes, its high reaction speed and its biocompatibility are key features of iEDDA making it a p

133 n, being mediator free, high sensitivity and biocompatibility are the major advantages of the propose

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

135 sical properties such as spectral spread and biocompatibility, as well as cellular and in vivo applic

136 programmability, excellent biostability and biocompatibility, as well as selective recognition and t

137 Biocompatibility assessment of Ti disks included in vitr

138 High stability and biocompatibility attribute these microwires with myriad

139 any unique properties, including exceptional biocompatibility, biodegradability, mechanical behavior,

140 The delivery systems demonstrated excellent biocompatibility both in vitro and in vivo and were non-

141 is shown to not play a role in the observed biocompatibility by using a NER-deficient human cell lin

142 The same coatings that are meant to increase biocompatibility can actually invoke cytotoxicity.

143 s and shown to offer long-term transparency, biocompatibility, cell-viability, and light-guiding prop

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

145 d electrochemical distinctiveness as well as biocompatibility characteristics have proven to be power

146 sing platform for drug delivery owing to its biocompatibility, degradability and high surface area av

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

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

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

150 Furthermore, the biocompatibility exhibited by many carbon nanomaterials

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

152 ionization (DESI) were optimized to achieve biocompatibility for clinical applications while obtaini

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

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

155 th N-hydroxysuccinimide (NHS) to improve the biocompatibility for the conjugation of protein.

156 2D nanoparticles so valuable, as well as the biocompatibility framework that has been investigated so

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

158 Due to their good biocompatibility, glass ionomer cements are an interesti

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

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

161 n various biomedical applications, while its biocompatibility has also attracted growing concerns.

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

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

164 because they provide the advantages of good biocompatibility, high brightness, and easy biofunctiona

165 tages of contactless cell manipulation, high biocompatibility, high controllability, simplicity, and

166 ivo results demonstrate these NPs' excellent biocompatibility, high selectivity of redox-triggered dr

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

168 ces should consist of materials that exhibit biocompatibility in accordance with the international st

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

170 etr azolium reagent assay demonstrated their biocompatibility in fibroblasts.

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

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

173 y, degree of decellularization, and scaffold biocompatibility in vitro.

174 latively low toxicity to mammalian cells and biocompatibility in vivo, suggest that gold nanoparticle

175 the geometry of implanted materials on their biocompatibility in vivo.

176 normal blood pressure and to determine their biocompatibility in vivo.

177 Biocompatibility is evidenced by the absence of cell dea

178 -resistant strains with in vitro and in vivo biocompatibility is observed.

179 ties of a gene reporter-probe system include biocompatibility, lack of immunogenicity, low background

180 However, poor biocompatibility limits its successful application today

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

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

183 on temperature phase transition behavior and biocompatibility make them useful materials for stimulus

184 The demonstrated in vitro biocompatibility makes this a versatile platform that ca

185 With its advantages in biocompatibility, miniaturization, and versatility, the

186 ptimization of various parameters, including biocompatibility, molecular recognition, high fluorescen

187 In the quest for superior photostability and biocompatibility, nanodiamonds are considered one of the

188 while retaining the nonaggregated state and biocompatibility needed for bioapplications, we integrat

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

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

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

192 The biocompatibility of a triazole mimic of the DNA phosphod

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

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

195 Hemolysis assay further authenticated the biocompatibility of bi-ligand liposomes in blood up to 6

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

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

198 ndamental understanding of how to adjust the biocompatibility of carbon based spherical nanoparticles

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

200 The biocompatibility of click DNA ligation sites at close pr

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

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

203 Comparison of the adsorption properties and biocompatibility of devices in different plastics reveal

204 Considering the biocompatibility of diamond towards cells, the device's

205 the large surface-to-volume ratio, excellent biocompatibility of GQD, porosity of GQD|CCE, and the ab

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

207 Associating with this biocompatibility of IF-MoS2\INT-WS2, we demonstrate in n

208 ng strategies for addressing the poor tissue biocompatibility of implantable glucose biosensors.

209 investigated the mineralization capacity and biocompatibility of injectable, dual-gelling hydrogels i

210 ally, a toxicity test demonstrated excellent biocompatibility of LipoLLA to normal mouse stomach.

211 Our earlier in vitro studies described the biocompatibility of multidomain peptide (MDP) hydrogel s

212 Biocompatibility of nanoparticles, containing toxic elem

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

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

215 Due to the biocompatibility of NiOxNPs toward biomolecules, this mo

216 l structures, which significantly reduce the biocompatibility of PD fluids and impair long-term PD th

217 ition of the degradation products to improve biocompatibility of PD fluids.

218 The biocompatibility of plate material may also influence sh

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

220 valuated in order to improve the whole-blood biocompatibility of previously developed C18-polyacrylon

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

222 Together with the known biocompatibility of SiO2, the feature of controllable dr

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

224 IONPs-coating dramatically enhanced the biocompatibility of SS felt and consequently resulted in

225 mmon strategy to tune the hydrophilicity and biocompatibility of such materials, minimize unspecific

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

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

228 m (Ti) backplate has improved the design and biocompatibility of the Boston Keratoprosthesis (BKpro).

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

230 mportance of in vivo studies, the problem of biocompatibility of the carrier systems, intracellular e

231 Biocompatibility of the components of this device was te

232 re tests indicated favorable bioactivity and biocompatibility of the composite scaffold.

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

234 to polysulfone-based membranes increases the biocompatibility of the dialysis membranes.

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

236 ensions to ensure renal clearance for better biocompatibility of the functional materials.

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

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

239 The biocompatibility of the materials was tested by comparin

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

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

242 The biocompatibility of the nanoparticles was proven.

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

244 The biocompatibility of the printed platform is tested using

245 uivocal requirement for this approach is the biocompatibility of the resulting triazole-linked DNA.

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

247 on before implant placement may increase the biocompatibility of titanium.

248 Biocompatibility of two newly developed porcine skin sca

249 ection limit, which, in combination with its biocompatibility, offer unique opportunities for the rea

250 with a traditional needle without effect on biocompatibility or safety.

251 s as functional assays for in vitro material biocompatibility, particularly for materials that compri

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

253 , superb photo- and physical stability, good biocompatibility, potential biodegradability and facile

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

255 tion of TH in the NP formulation exhibited a biocompatibility profile similar to that of protamine, w

256 ls had favorable optical, biomechanical, and biocompatibility properties necessary for replacing the

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

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

259 ived from syngeneic rats and its morphology, biocompatibility, secretion of beneficial factors, and i

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

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

262 ively charged cell-penetrating peptides, the biocompatibility, stability, and simplicity of the enzym

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

264 These HDL NPs demonstrate excellent biocompatibility, stability, nontoxic, and nonimmunogeni

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

266 Biocompatibility studies and in vivo rat skin tolerance

267 Biocompatibility study indicates that the addition of NL

268 Biocompatibility tests indicate good cell viabilities fo

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

270 lly in the field of life sciences, including biocompatibility, the controlled uptake/release of guest

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

272 nic materials provide some evidence of their biocompatibility, thereby suggesting potential for use i

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

274 of the most prominent methods used to impart biocompatibility to aqueous-in-oil droplets is to synthe

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

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

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

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

279 gradation into non-inflammatory by-products, biocompatibility, utility in drug stabilization, and rob

280 Biocompatibility was assessed by culturing human hepatom

281 Biocompatibility was demonstrated by either omental or s

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

283 The sealer biocompatibility was measured by cell function and proli

284 Biocompatibility was studied in vivo in an ovine model b

285 Biocompatibility was tested with human mesenchymal stem

286 tested with several bacterial strains, while biocompatibility was verified with human dermal fibrobla

287 oping new MnPs as Gd-free CAs with optimized biocompatibility were established to improve relaxivity

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

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

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

291 screening, modular disposable cartridge, and biocompatibility, which can potentially speed up the ent

292 ry trace imaging capability with outstanding biocompatibility, which is exceptionally well secreted b

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

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

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 The micelles showed high biocompatibility, with even the cationic micelles exhibi

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

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

300 ce area provided by assembled AuNPs and high biocompatibility yielded excellent analytical performanc