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1 branes constructed from nuclear track-etched polycarbonate.
2 used in synthesis of an aromatic bisphenol A polycarbonate.
3  need for a readily degradable biocompatible polycarbonate.
4 ighboring dielectric material, either air or polycarbonate.
5 through ortho ester linkages on an aliphatic polycarbonate.
6 , polyurethanes, polyureas, polyacetals, and polycarbonates.
7  and molecular weight distribution as virgin polycarbonates.
8 cracks propagating in opposite directions in polycarbonate, a material with high ductility and a larg
9 mpered glass, chemically tempered glass, and polycarbonate, all with 3.0-mm center thickness) were te
10 resistant to chemical degradation than their polycarbonate analogues and exhibit excellent mechanical
11 ommon greenhouse materials such as glass and polycarbonate and are therefore depleted in many commerc
12 ries (polyvinyl chloride, polyurethanes, and polycarbonates) and in the activation of light hydrocarb
13 zed glass, poly(methyl methacrylate) (PMMA), polycarbonate, and poly(dimethylsiloxane) were tested as
14 polystyrene, acetonitrile-butadiene-styrene, polycarbonate, and poly(dimethylsiloxane), were used as
15  esters of cellulose, regenerated cellulose, polycarbonate, and polyvinylidene fluoride, were assayed
16  to convert these monomers to polyesters and polycarbonate, and the different end-of-use options for
17 mpered glass, chemically tempered glass, and polycarbonate, and with center thickness ranging from 1
18 educe emission by 1-6 tons of CO2 per ton of polycarbonates, and reduce polymer accumulation in landf
19                     Aliphatic polyesters and polycarbonates are a class of biorenewable, biocompatibl
20                                        These polycarbonates are of interest as engineering materials
21 tential candidates, aliphatic polyesters and polycarbonates are promising materials due to their rene
22 cal polymerization of aniline on gold-coated polycarbonate asymmetric nanochannels.
23 ps), polyurethanes (aliphatic, aromatic, and polycarbonate-based), and selected Fluka plasticizers (2
24  of selected dental ceramics bonded to clear polycarbonate bases (simulating crown/dentin structures)
25                                           CD polycarbonate bases were coated with these reflecting ma
26 tral poly(ethylene oxide) block and terminal polycarbonate blocks with pendant 1,2-dithiolane functio
27 ufactured chemical, is found in canned food, polycarbonate-bottled liquids, and other consumer produc
28 uccessfully used to assess BPA leaching from polycarbonate bottles at 45 degrees C and 80 degrees C,
29 X = OAc, N(SiMe3)2, OMe, O(i)Pr all produced polycarbonate by the alternated insertion of CHO and CO2
30                   The resulting ABA triblock polycarbonate can be further functionalized with various
31 North Pacific and amended duplicate 20 liter polycarbonate carboys with nitrate or ammonium, tracking
32 single-molecule fluorescence measurements in polycarbonate chips using visible wavelengths for excita
33  carbon dioxide and epoxides into degradable polycarbonates (CO(2)-based copolymer) has been regarded
34  folding method to generate aligned graphene/polycarbonate composites with as many as 320 parallel la
35                            The thus produced polycarbonate contained >99% carbonate linkages and had
36  Mn and Sr; BPA was detected in samples from polycarbonate containers.
37 ction of detailed solvent-resistance maps of polycarbonate copolymers and in determination of quantit
38 ion of the solvent resistance of a family of polycarbonate copolymers prepared from the reaction of b
39                    This class of amphiphilic polycarbonates could embody a powerful platform for biom
40 odology was developed for the preparation of polycarbonates derived from glucose as a natural product
41 uction by the i.p. implantation of 21 x 2 mm polycarbonate discs.
42                 Here, we engineer a nanotube-polycarbonate film with a wide bandwidth (>300 nm) aroun
43 y on isolated single molecules of MEH-PPV in polycarbonate films that exclude O(2) reveals two distin
44 mm diameter) of a 5-microm uniform pore size polycarbonate filter is continuously wetted by a 0.25 mL
45                   A thin (80 microm) colored polycarbonate filter was placed on the top of the embedd
46 , through a layer of Matrigel on a 5-um pore polycarbonate filter was stimulated up to 5-fold by 10(-
47 across platelets bound to fibronectin-coated polycarbonate filters by mAbs to Mac-1.
48 dent hippocampal neurons, we grew neurons on polycarbonate filters etched with 3 microm pores.
49                 Intact retinas are placed on polycarbonate filters floating on explant culture medium
50 d at approximately the same rate on uncoated polycarbonate filters in the Boyden chambers.
51 icle SEM/EDX analysis of aerosols is done on polycarbonate filters or solid carbon substrates.
52 parations were evaluated over 6 hr utilizing polycarbonate filters ranging from 0.03 to 10 microns.
53 etermined on 24-mm Transwell (Cambridge, MA) polycarbonate filters with the End-Ohm device (World Pre
54 dothelial cells (BRECs) were grown on porous polycarbonate filters, and water flux across BREC monola
55  spheroplasts are lysed by extrusion through polycarbonate filters.
56 Stx was examined in four cell lines grown on polycarbonate filters.
57 rier for production of cyclic carbonates and polycarbonates for the two different classes of epoxides
58 levated temperatures, at ambient temperature polycarbonate formation is dominant.
59  By way of comparison, the similarly derived polycarbonate from the sterically less congested monomer
60 lvents cannot be used to selectively extract polycarbonates from mixtures of polymers with similar pr
61 ess than 30% of the cost of producing virgin polycarbonates from petroleum.
62                More than one million tons of polycarbonates from waste electrical and electronic equi
63                                 An amorphous polycarbonate host effectively disperses the chromophore
64 heir compatibility as guests in an amorphous polycarbonate host.
65     Under the test conditions of this study, polycarbonate lenses demonstrated greater impact resista
66                                              Polycarbonate lenses demonstrated resistance to impact f
67            The microdevice was attached to a polycarbonate manifold with external electrode reservoir
68                                            A polycarbonate membrane (100-nm-diam pore size) hydrated
69 ents separated by either a porous alumina or polycarbonate membrane as a model system, diffusive flux
70 ists of a double-side gold-coated perforated polycarbonate membrane as part of a microfluidic system
71 ted with a one-pot hydrothermal method using polycarbonate membrane as the template.
72 images of relatively soft samples, such as a polycarbonate membrane filter and living diatoms in a co
73 mer on insulating substrates (glass slide or polycarbonate membrane filter).
74 ent the successful inclusion of track-etched polycarbonate membrane filters into the reservoirs of po
75                                              Polycarbonate membrane filters were used to assess prima
76                                          The polycarbonate membrane improved the quantification of Cd
77 an LEC migration assays were performed using polycarbonate membrane inserts and 20% fetal bovine seru
78 nducted in tissue culture plates fitted with polycarbonate membrane inserts exhibited mortality (100%
79 imary culture of human choroidal ECs through polycarbonate membrane inserts was quantified in the pre
80 f capturing proteins by interaction with the polycarbonate membrane of the NEE.
81  investigate whether an additional nuclepore polycarbonate membrane on the surface of DGT devices can
82 were grown to confluence on an 8-microM pore polycarbonate membrane precoated with an artificial base
83  by addressing microregions of a gold-filled polycarbonate membrane through the UMEs of an underlying
84  cells release NO, it flows through a porous polycarbonate membrane to the probe.
85 abeled GM1 RPE cells through a 2-microm-pore polycarbonate membrane using an extruder device.
86 he proteoliposomes after extrusion through a polycarbonate membrane was 94 +/- 4 nm.
87 ay (ANEMA) based on a Au-filled track-etched polycarbonate membrane was fabricated.
88  the seal between the gold nanowires and the polycarbonate membrane was not compromised as a result o
89  the number of ECs that migrated through the polycarbonate membrane was significantly higher than ECs
90 er chamber were allowed to migrate through a polycarbonate membrane with 8 microns pores toward VEGF
91 styrene spheres (43-150-nm diameter) using a polycarbonate membrane with conically shaped pores, the
92              The PDMS chamber was bound to a polycarbonate membrane, which itself was bound to a mole
93 ipids and cholesterol by extrusion through a polycarbonate membrane.
94  bias due to biofilms by using an additional polycarbonate membrane.
95 ts whose bottoms are constructed of a porous polycarbonate membrane; this insert enables molecular tr
96    This principle is demonstrated by imaging polycarbonate membranes (6-12-microm thickness) containi
97 pH-induced hysteretic gating of track-etched polycarbonate membranes (TEPC) has been achieved by depo
98 ectrodes (RNEs) fabricated from track-etched polycarbonate membranes (TEPCMs) having cylindrical nano
99               Cells were plated on transwell polycarbonate membranes and stimulated by a stable vitam
100 st strategy to bond semiporous polyester and polycarbonate membranes between layers of PDMS microchan
101      Cellular invasion was investigated with polycarbonate membranes coated with collagen.
102 within the cylindrical pores of track-etched polycarbonate membranes compared to the multilayers on p
103 nterconnects, employing nuclear track-etched polycarbonate membranes containing nanometer-diameter ca
104 etching procedure based on the solubility of polycarbonate membranes in solvent mixtures is reported
105 rmability evaluated using filtration through polycarbonate membranes revealed that the cortical tensi
106 trolled etching of the surface layers of the polycarbonate membranes to expose up to 200-nm lengths o
107                             The track-etched polycarbonate membranes were filled using a gold electro
108 ween single protein molecules and nanoporous polycarbonate membranes were investigated at the single
109                                              Polycarbonate membranes with 0.1-1-microm vertical pores
110 of magnitude higher than those of commercial polycarbonate membranes, despite having pore sizes an or
111 nt lipids were prepared by extrusion through polycarbonate membranes.
112 amide-modified DNA probes are immobilized in polycarbonate microfluidic channels via photopolymerizat
113 luorescent dyes at controlled locations in a polycarbonate microfluidic device.
114 ayer of basement membrane-like Matrigel on a polycarbonate micropore filter was evoked by vasoactive
115 ally, the modification scheme was applied to polycarbonate microprojection arrays, and we show that t
116                                  Two similar polycarbonate models were used to simulate a single root
117 erial comprised of polyethylene glycol and a polycarbonate of dihydroxyacetone (MPEG-pDHA).
118 icrofluidic channels ("biochannels") made of polycarbonate, optionally with an integrated pump.
119 elective preparation of either polyesters or polycarbonates or copoly(ester-carbonates).
120                                          For polycarbonate, our results show that Ar4000+ bombardment
121  nitrate/cellulose acetate filter membranes, polycarbonate, paraffin, polyethylene terephthalate, pap
122                        With the exception of polycarbonate (PC) baby bottles, little attention has be
123 fiably different for eDNA fragments with the polycarbonate (PC) binding the least and mixed cellulose
124 monella typhi (S. typhi) on modified isopore polycarbonate (PC) black membranes.
125 consisted of two different microchips: (1) a polycarbonate (PC) chip for performing an allele-specifi
126 nfiguration carried out in a microfabricated polycarbonate (PC) chip.
127 script, we discuss the use of photoactivated polycarbonate (PC) for purification of dye-labeled termi
128    This study is aimed to compare Tritan and polycarbonate (PC) from a point of view of migration of
129 ed bioreceptors modified 2D matrix of porous polycarbonate (PC) membrane with densely packed 20microm
130  into the pores of a templating track-etched polycarbonate (PC) membrane.
131  flexible hybrid polydimethylsiloxane (PDMS)-polycarbonate (PC) microfluidic chip with integrated scr
132 ure gradient gel electrophoresis (TGGE) in a polycarbonate (PC) microfluidic device, is reported.
133 the ammonia borane was encapsulated within a polycarbonate (PC) microtube array membrane, the tempera
134 ctrophoresis (CE) devices were fabricated in polycarbonate (PC) plastic material by compression moldi
135 ) is immobilized as a capturing agent on the polycarbonate (PC) surface of the track-etched templatin
136 piral microfluidic channel hot-embossed into polycarbonate (PC) that had three well-defined temperatu
137 aration channels that were hot-embossed into polycarbonate (PC) using a high-precision micromilled me
138 0 microm diameter posts, on a single 3" x 5" polycarbonate (PC) wafer fabricated by hot embossing.
139 thyl methacrylate) (PMMA), polystyrene (PS), polycarbonate (PC), and cyclic olefin copolymer (COC) as
140 erties are demonstrated in polystyrene (PS), polycarbonate (PC), and polyethylene (PE) by demonstrati
141 hyl methacrylate (PMMA) micro-reactor with a polycarbonate (PC)-based prism coated with a 50 nm Au fi
142 n resource-limited settings, we fabricated a polycarbonate (PC)-polydimethylsiloxane (PDMS) hybrid mi
143                                  Amphiphilic polycarbonate/PEG copolymer with a star-like architectur
144                Bisphenol A (BPA) is found in polycarbonate plastic and epoxy resins and is used in a
145 ic chemical widely used in the production of polycarbonate plastic and epoxy resins found in numerous
146 umes and disposal of products made from BPA, polycarbonate plastic and epoxy resins, BPA has entered
147 l]propane, BPA), the monomer used to produce polycarbonate plastic and epoxy resins, is weakly estrog
148                   BPA is used to manufacture polycarbonate plastic and epoxy resins; APs are used to
149 high production volume chemical used to make polycarbonate plastic and is found in many consumer prod
150 A (BPA) is widely used in the manufacture of polycarbonate plastic bottles, food and beverage can lin
151  These integrated devices were fabricated in polycarbonate plastic material by CO2 laser machining an
152 verages because of significant leaching from polycarbonate plastic products and the lining of cans.
153 ermination of bisphenol A migrated from some polycarbonate plastic products.
154  UV irradiation treatment of the hydrophobic polycarbonate plastic surfaces prior to thermal bonding.
155 n-volume chemical used in the manufacture of polycarbonate plastic, is associated with higher body we
156 a common chemical used in the manufacture of polycarbonate plastics and epoxy resins, and > 93% of U.
157 ic compound widely used in the production of polycarbonate plastics and epoxy resins.
158 enol analogues are used in the production of polycarbonate plastics and epoxy resins.
159 rial production and after degradation of the polycarbonate plastics and nonionic surfactants.
160 enoestrogen widely used in the production of polycarbonate plastics.
161 rent types of plastic surfaces (polystyrene, polycarbonate, poly(methylmethacrylate), and polypropyle
162       We discuss the use of a photoactivated polycarbonate (PPC) microfluidic chip for the solid-phas
163                                              Polycarbonate preforms containing microchannels with cro
164  134 degrees C, the highest yet reported for polycarbonates produced from CO(2)/epoxides coupling.
165 asurements on supported lipid bilayers and a polycarbonate sample using pipets with opening radii dow
166 ith a pressure of approximately 170 MPa in a polycarbonate sample, with a subsequent quantitative sta
167 reported TOF of 3200 h(-1) together with 99% polycarbonate selectivity.
168 larized monolayers on tissue culture-treated polycarbonate semipermeable supports were transduced wit
169 ust and the after-effects of mud formed on a polycarbonate sheet, which is commonly used as a protect
170 roximately 5-10 microm) nuclear track-etched polycarbonate sheets containing approximately 10(8) cm(-
171 lysates or whole blood using a photactivated polycarbonate solid-phase reversible immobilization (PPC
172               The plates were then bonded to polycarbonate substrates and subjected to fatigue loadin
173 Monolithic glass plates were epoxy-bonded to polycarbonate substrates as a transparent model for an a
174 Monolithic glass plates were epoxy-joined to polycarbonate substrates as a transparent model for an a
175 icroelectrospray emitters were fabricated on polycarbonate substrates using a laser etching technique
176 uch ability to modify characteristics of the polycarbonate surface could address the dust/mud-related
177 work required to remove the dry mud from the polycarbonate surface upon drying.
178 s then detected by an ELISA assay on the CNT-polycarbonate surface with an ECL assay.
179 hanical, and textural characteristics of the polycarbonate surface, and to increase the adhesion work
180 body-nanotube mixture was immobilized onto a polycarbonate surface.
181 phobicity via entrapment of nanoparticles in polycarbonate surfaces.
182 particles derived from a CO2 -based triblock polycarbonate system.
183 ctrodeposition within the conical pores of a polycarbonate template membrane.
184 deposit Au nanotubules within the pores of a polycarbonate template membrane.
185 tubes within the conically shaped pores of a polycarbonate template membrane.
186 ve been electrosynthesized using the conical polycarbonate template.
187 e first time the utility of tyrosine-derived polycarbonate terpolymer electrospun fiber mats as tunab
188              The construction of amphiphilic polycarbonates through epoxides/CO2 coupling is a challe
189 protocol using poly(methyl methacrylate) and polycarbonate to produce functional scaffolds consisting
190  cylinder encased by sleeves of aluminum and polycarbonate to simulate trabecular bone, cortical bone
191 y replication of the pores of 70 nm diameter polycarbonate track etch membranes.
192 was fabricated by sandwiching two nanoporous polycarbonate track etched (PCTE) membranes with differe
193 wn on silicon carbide substrates to flexible polycarbonate track etched supports with well-defined cy
194          A thin layer of gold is plated onto polycarbonate track-etched nanoporous membranes via elec
195  scalable chemical vapor deposition (CVD) to polycarbonate track-etched supports.
196 riments and inhibited their invasion through polycarbonate Transwell filters.
197 ge evolution in a transparent glass/zirconia/polycarbonate trilayer, post mortem damage evaluation of
198                           First, we modified polycarbonate wafers using an electrophilic aromatic sub
199                               The surface of polycarbonate was activated by UV radiation resulting in
200      A preformed T-microchannel imprinted in polycarbonate was postmodified with a pulsed UV excimer
201                                              Polycarbonates were successfully synthesized for the fir
202 rfaced with a photomultiplier tube through a polycarbonate window.
203  carbon dioxide to provide the corresponding polycarbonate with a minimal amount of ether linkages.
204 tively in a controlled fashion to afford the polycarbonate with a tunable degree of polymerization, n
205                                The resulting polycarbonates with -OH end groups can thus be directly
206 e nonrandom chain packing for two commercial polycarbonates with decidedly different mechanical prope
207 g two mixed solvents is developed to recover polycarbonates with high yield (>95%) and a similar puri

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