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1 uorescein during enzymatic hydrolysis of the polyester.
2 e incorporation of C(16) monomers into cutin polyester.
3 t and the existence of an extended aliphatic polyester.
4 to give the corresponding highly alternating polyester.
5 ion efficiency of semi-crystalline bio-based polyesters.
6 ed to convert dimethacrylates to unsaturated polyesters.
7 ng well-defined high molecular weight cyclic polyesters.
8 g the trehalose- and zwitterion- substituted polyesters.
9 sis of increasingly complex and well-defined polyesters.
10  in several monomers of cell wall-associated polyesters.
11  for hydrolysis of small molecule esters and polyesters.
12 s a strategy to generate well-defined cyclic polyesters.
13  monomers derived from non-extractable lipid polyesters.
14 merous types of functionality onto aliphatic polyesters.
15 ethane generated the homologated nitroalkane-polyesters.
16  group reduction, afforded the desired amino-polyesters.
17 ol process upon dendritic modified aliphatic polyesters.
18 ated to hydrolyze all structurally different polyesters.
19 tween the structures and properties of these polyesters.
20 approach to generate well-defined functional polyesters.
21 lymerized into the corresponding unsaturated polyesters.
22 containing no protic groups into unsaturated polyesters.
23 o prepare clinically translatable degradable polyesters.1 A variety of functional groups have been in
24 d with disperse blue 3 and disperse blue 14, polyester 777 dyed with disperse red 1 and disperse red
25 es were overexpressed together the epidermal polyesters accumulated new C20 and C22 omega-hydroxyacid
26  finishes, acrylic melamine (clear coating), polyester acrylic melamine (white coating) automotive fi
27 pecifically, two isomeric arylene-ethynylene polyesters afforded significantly different product dist
28 achieved using a hybrid polydimethylsiloxane/polyester amperometric lab-on-a-chip (LOC) microsystem w
29 an oxidant mechanism, whereas the non-coated polyester analogue and the Pluronic F68 alone had no eff
30                In the case studied here, the polyester anchors were incorporated into the patient's f
31  ingestion of a range of polymers, including polyester and acrylic fibers.
32 e systematically investigated the effects of polyester and carboxylesterase structure on the hydrolys
33  this work highlights the importance of both polyester and carboxylesterase structure to enzymatic po
34 le fibres with high tensile strength such as polyester and nylon.
35 tic slings, particularly those made of woven polyester and other tightly woven material erode 15 time
36 imple but robust strategy to bond semiporous polyester and polycarbonate membranes between layers of
37 lcohol)(PVA) sizes for high-speed weaving of polyester and polyester/cotton yarns to substantially de
38 es were significantly greater in cotton than polyester and similar for BFRs and high molecular weight
39 conjugation of hydroxyl-containing agents to polyesters and formation of corresponding nanoparticles.
40 ynthetic routes to convert these monomers to polyesters and polycarbonate, and the different end-of-u
41                                    Aliphatic polyesters and polycarbonates are a class of biorenewabl
42        Among potential candidates, aliphatic polyesters and polycarbonates are promising materials du
43  of metal-free polymers, including aliphatic polyesters and polyethers, poly(alpha-peptoid)s, poly(me
44 d 75% for rayon, 71.2% for cotton, 81.3% for polyester, and 53.2% for calcium alginate.
45                                              Polyester apparel accounts for a large proportion of the
46     Implications for materials properties of polyesters are discussed.
47                                              Polyesters are extensively used in drug delivery because
48                                The resulting polyesters are highly alternating and have high molecula
49              The roles of cutin- and suberin polyesters are often attributed to their dominant alipha
50                         Degradable aliphatic polyesters are the cornerstones of nanoparticle (NP)-bas
51                                Water-soluble polyesters are used in a range of applications today and
52  nanoparticle core functionalized with eight polyester arms.
53 pplication and success of hydroxy acid based polyesters as degradable sutures and controlled drug del
54 reaction are shown to be compatible with the polyester backbone, this method is a generally useful me
55 y(aminoesters) with N-acylated amines in the polyester backbone.
56                                  A series of polyesters based on 2-propargyl-1,3-propanediol or 2,2-d
57                     Although many studies on polyester biodegradability have focused on aerobic envir
58 zymes and aquatic microorganisms involved in polyester biodegradation and mineralization.
59 ases is considered the rate-limiting step in polyester biodegradation.
60 ide evidence for a critical role of GPAT5 in polyester biogenesis in seed coats and roots and for the
61  knockout mutant lines for genes involved in polyester biosynthesis (att1, fatB and gpat5) were exami
62 ndent acyltransferase functioning in glucose polyester biosynthesis by Lycopersicon pennellii.
63 substrate specificities (1) strongly support polyester biosynthetic pathways in which acyl transfer t
64 , 100% cotton terry (towels), 60% cotton-40% polyester blend (scrub suits and lab coats), 100% polyes
65 lonyl-CoA reductase applied for biotechnical polyester building block synthesis.
66 tive analysis of the hydrolysis of two model polyesters by eight different carboxylesterases revealed
67  the enzymatic hydrolysis of eight aliphatic polyesters by two fungal esterases (FsC and Rhizopus ory
68 roval of the fat substitute olestra (sucrose polyester) called for active postmarketing surveillance
69        The results obtained suggest that new polyesters can be synthesized with desirable properties
70 yl azide, namely CF3(CF2)7CH2CH2N3, to yield polyesters carrying long-chain alkylene segments in the
71 ed to a combination of temperature-dependent polyester chain flexibility and accessibility of the enz
72  the catalytic site of RoL due to increasing polyester chain mobility.
73    Hydrolyzability increased with increasing polyester-chain flexibility as evidenced from difference
74 ed cells were replica plated to two disks of polyester cloth.
75 mutants in which the abundance of cutin, the polyester component of the cuticle, was strongly reduced
76      The stigmatic estolide is a lipid-based polyester constituting the major component of exudate in
77 annel layer between uncoated cover sheets of polyester containing precut access holes.
78                                 For example, polyesters containing 1,2-ethanediol were hydrolyzed fas
79 g 1,2-ethanediol were hydrolyzed faster than polyesters containing 1,8-octanediol.
80 It was found that increasing the hydrophobic polyester content in the hydrogel reduced the swelling v
81 nce the use of synthetic fabrics, especially polyester, continues to increase.
82  carbonate-co-caprolactone), and a cellulose/polyester core.
83                             Here, cotton and polyester-cotton fabrics were sonochemically coated with
84  PVA and chemically modified starch sizes on polyester/cotton fabrics, and had relative weaving effic
85 izes for high-speed weaving of polyester and polyester/cotton yarns to substantially decrease environ
86                                              Polyester cuff retention was recorded when it occurred,
87 astic, and porous crosslinked urethane-doped polyester (CUPE) scaffold sheets that are bonded togethe
88  hexadecanoic acid, a monomer of the cuticle polyester, cutin.
89                              A biocompatible polyester dendrimer composed of the natural metabolites,
90                  An asymmetric biodegradable polyester dendrimer containing 8-10 wt % DOX was prepare
91            The design and preparation of new polyester dendrimer, poly(ethylene oxide) hybrid systems
92                                              Polyester dendrimers are attractive for in vivo delivery
93 ly suitable for the synthesis of custom-made polyester dendrimers.
94 e research activities generated on aliphatic polyester dendritic architectures based on bis-MPA.
95                               Self-assembled polyester dendritic bow-ties with various peripheral gro
96 y(ethylene oxide) and either a polylysine or polyester dendron were prepared and hydrophobic groups w
97 e systems consist of two covalently attached polyester dendrons, where one dendron provides multiple
98 d lipase activity, and seven proteins showed polyester depolymerization activity against polylactic a
99                                              Polyester deposition was followed over Brassica seed dev
100 led the rapid synthesis of >130 lipocationic polyesters directly from functional monomers without pro
101  capture antibody molecules immobilized on a polyester disk to form a sandwich assay.
102 le flat, spiral, coil located just below the polyester disk.
103      The other functionalities in the linear polyester do not participate in the nanoparticle formati
104 the aliphatic load in both suberin and cutin polyesters essentially remained unaffected.
105                  Polybutylate-coated braided polyester (Ethibond* 5-0) suture is a safe and effective
106 tenolol deposited on glass, wood, steel, and polyester fabric.
107                      Over 30 days cotton and polyester fabrics accumulated 3475 and 1950 ng/dm(2) sum
108 d by dip-coating acrylic, cotton, nylon, and polyester fabrics from solutions of diluted rat blood.
109 elative weaving efficiency similar to PVA on polyester fabrics, although with 3- 6% lower add-on.
110 nsulation panel made by hemp fiber (85%) and polyester fiber (15%) in 1 m(2) of wall having a thermal
111 ere, in combination with the stainless steel/polyester fiber blended yarn, the polydimethylsiloxane-c
112 h) and chronic (8 d) effects of microplastic polyester fibers and polyethylene (PE) beads on freshwat
113 ial distribution of local stresses in single polyester fibers under uniaxial strain.
114  from 0.004-in nitinol wire mesh filled with polyester fibers.
115 angiography occurred in 7 of 12 animals (all polyester-filled prostheses).
116                                              Polyester filling was added to enhance thrombogenicity.
117 ere aligned with an intermediary cut-through polyester film and then thermally laminated together at
118 reated by laser photoablation of a 12-microm polyester film, was used to investigate electroassisted
119 phic software package and laser printed on a polyester film.
120  by integrating cellulose paper and flexible polyester films as diagnostic biosensing materials with
121 olymer, and the laser-printing of toner onto polyester films has been shown to be effective for gener
122 tructure on the hydrolysis of nanometer-thin polyester films using a quartz-crystal microbalance with
123 een 20 and 1000 times more formaldehyde than polyester filters under similar RH and airflow condition
124   Formaldehyde emissions from fiberglass and polyester filters used in building heating, ventilation,
125 olyester insulation) and one off-brand (100% polyester fleece).
126 -brand clothing manufacturer (three majority polyester fleece, and one nylon shell with nonwoven poly
127 ampon composed of carboxymethylcellulose and polyester foam increased production of TSST-1 to a large
128 sing a greater diversity of VOCs compared to polyester foam.
129 rs in the commercialization of the bio-based polyesters, for example polyhydroxyalkanoates synthesize
130 s in which a CO2 laser is used to remove the polyester from the channel sections of the internal laye
131 ologically important biodegradable aliphatic polyesters from cyclic esters or lactones.
132  but was similar to that reported with other polyester graft vascular implants and consisted of diffu
133                    The resulting unsaturated polyesters have a high thermal stability and can be read
134                                Biodegradable polyesters have a large potential to replace persistent
135                                Biodegradable polyesters have the potential to replace nondegradable,
136 reening and mechanistic studies of enzymatic polyester hydrolysis.
137  and carboxylesterase structure to enzymatic polyester hydrolysis.
138 . were chosen for in-silico screening toward polyester hydrolyzing enzymes.
139 ysis included increased water solubility and polyester hydrophilicity as well as shorter diol chain l
140 n A, the accumulation of polyhydroxybutyrate polyester in Arabidopsis nuclear transgenic plants (with
141 omplexed PHB is only a minor fraction of the polyester in E. coli.
142 in the extracellular deposition of the cutin polyester in the tomato fruit cuticle.
143 here is much less known on biodegradation of polyesters in natural and artificial anaerobic habitats.
144 iacylglycerol-/diacylglycerol-based estolide polyesters in the petunia stigma.
145 understanding of biodegradation processes of polyesters in WWTPs where the extracellular enzymatic hy
146 er fleece, and one nylon shell with nonwoven polyester insulation) and one off-brand (100% polyester
147                        A series of sulfonate polyester ionomers with well-defined poly(ethylene oxide
148                            Data generated by Polyester is a reasonable approximation to real RNA-seq
149                                              Polyester is an R package designed to simulate RNA-seq d
150  high-molecular-weight metal-free recyclable polyester is reported.
151 d with the outer integument and a cutin-like polyester layer associated with the inner seed coat.
152 noparticles that have a gold core, an apolar polyester layer for drug loading, a polar PEO corona to
153 parel accounts for a large proportion of the polyester market, and synthetic jackets represent the br
154 is DHB, and the best film for the probe is a polyester material commonly used for transparency film.
155 y step during the breakdown of biodegradable polyester materials in natural and engineered systems.
156 functionalized well-defined 3-D nanoparticle polyester materials in targeted nanoscopic ranges with a
157 rious functionalities or by mixing different polyester materials to achieve controlled amounts of spe
158 ty and can be readily cross-linked to robust polyester materials.
159 le, a protective layer composed of the cutin polyester matrix and cuticular waxes.
160 DL), a fluorogenic ester substrate, into the polyester matrix and on monitoring the enzymatic cohydro
161 for hydrolysis of the protective cutin lipid polyester matrix in plants and thus have been exploited
162 y epidermal cells and is composed of a cutin polyester matrix that is embedded and covered with cutic
163 olume, are readily immobilized on a nylon or polyester matrix.
164                        Samples of biomedical polyester (Max-Prene 955) and a fluoropolymer (polyvinyl
165 ased with decreasing differences between the polyester melting temperatures and the experimental temp
166 months after surgical implantation of a thin polyester mesh (cardiac support device [CSD]) that surro
167 al hernia were randomized to a self-gripping polyester mesh or a sutured polyester mesh.
168  a self-gripping polyester mesh or a sutured polyester mesh.
169 hanically fragmented and size filtered using polyester meshes.
170 ted microfluidic system using a multilayered polyester microfluidic disc created through laser print,
171 n the portal trunk of C57BL6 adult mice with polyester microspheres, to ensure a bilateral and distal
172                        A further decrease in polyester molecular weight was observed with increased i
173 aphy coupled with mass spectrometry of lipid polyester monomers confirmed a drastic decrease in aliph
174                              The variance in polyester monomers of these mutants is correlated with d
175                     By contrast, the load of polyester monomers per unit surface area decreases more
176 ent the synthesis of discrete functionalized polyester nanoparticles in selected nanoscale size dimen
177 We report the synthesis and encapsulation of polyester nanosponge particles (NPs) co-loaded with tamo
178 eting ligands are required, these functional polyester NPs provide an exciting alternative approach f
179  cells internalized both coated and uncoated polyester NPs to a similar extent, with uptake observed
180 hemicals used in the production of plastics, polyesters, nylons, fragrances, and medications.
181  structure and formation of this hydrophobic polyester of glycerol and hydroxy/epoxy fatty acids has
182       The plant cuticle consists of cutin, a polyester of glycerol, hydroxyl, and epoxy fatty acids,
183 of apparently all plant cuticles is cutin, a polyester of hydroxy fatty acids; however, despite its u
184              The most intriguing unsaturated polyester of the series is that based on the biomass-der
185                               Acylsugars are polyesters of short- to medium-length acyl chains on suc
186                             In this study, 5 polyesters of similar molar mass were synthesized by rea
187 haracterized, the monomer composition of the polyesters of the cuticular membrane has not been analyz
188 nge of monomer compositions are possible for polyesters of the epidermis.
189 vidual dye-modified copolymers, dye-modified polyesters offer advantages over physical entrapment of
190                  We characterized structured polyester oligomers and products derived from combinator
191                It occurs as an extracellular polyester on the aerial surface of all plants, provides
192 ed from modified Z-stents covered with woven polyester or expanded polytetrafluoroethylene graft mate
193 expanding stainless-steel covered with woven polyester or polytetrafluoroethylene material.
194                                  With Dacron polyester or rayon-tipped swabs, there was no consistent
195  enables the selective preparation of either polyesters or polycarbonates or copoly(ester-carbonates)
196                     Calcium alginate, Dacron polyester, or rayon-tipped swabs were inoculated with pn
197 L, thereby producing exclusively unsaturated polyester P(MBL)ROP with Mn up to 21.0 kg/mol.
198 -poly(ethylene glycol) (PEG) based precision-polyester (P2s) platform, permitting 5-12 periodically s
199 chored to the soft tissues of the chest with polyester patches.
200 ludge to hydrolyze the synthetic compostable polyester PBAT (poly(butylene adipate-co-butylene tereph
201 hate (polyP), and the amphiphilic, solvating polyester, poly-(R)-3-hydroxybutyrate, frequently associ
202 al behavior, and degradability of long-chain polyester, polyamides, polyurethanes, polyureas, polyace
203 vity toward the degradation of the synthetic polyester polycaprolactone.
204   Vaginal fluid specimens were collected via polyester/polyethylene terephthalate swabs every other m
205                                   Suberin, a polyester polymer in the cell wall of terrestrial plants
206 degradable synthetic polymers (polypeptides, polyesters, polyphosphazenes, etc.).
207 orb crude oil microdroplets from water using polyester polyurethane (PESPU) foam.
208 r weight (MW) determination of polyether and polyester polyurethane (PUR) soft blocks.
209                              These aliphatic polyesters possess an acetylene graft density that can b
210 f oligomers indicates the presence of linear polyesters possibly formed via esterfication reactions o
211                                          The polyester powder contained 6 pg/g and 2 pg/g for (232)Th
212 for SGs and acyl SGs in trafficking of lipid polyester precursors.
213                        The amphiphilic graft polyesters prepared in this study are shown to be biocom
214 ster blend (scrub suits and lab coats), 100% polyester (privacy drapes), and 100% polypropylene plast
215 hen depolymerized under conditions to cleave polyesters, produced typical omega-hydroxy fatty acid cu
216  activities of copper-impregnated fibers and polyester products.
217   Therefore, phenylisocyanate is applied for polyester PUR degradation.
218                 Ethanolamine is not used for polyester PUR's degradation because the ester bonds will
219  well-defined and functionalizable aliphatic polyesters remains a key challenge in the advancement of
220 in wax and polycaprolactone, a biodegradable polyester reported for the first time floating in off-sh
221                                              Polyester represents one such polymer, and the laser-pri
222  was observed along weak planes in a brittle polyester resin under far-field asymmetric loading.
223             Maleic anhydride, a precursor to polyester resins, is made by oxidation of n-butane over
224 ed epimerization of the alpha-carbon atom in polyesters resulting in the loss of isotacticity.
225  a CO(2) laser to create the microchannel in polyester sheets containing a uniform layer of printed t
226 nstructed by backfilling small holes made in polyester sheets using a CO2 laser etching system.
227 y screen-printing hydrophilic carbon inks on polyester sheets.
228 abundant and widespread monomer of the cutin polyester, show that the morphology of floral surfaces d
229 e overaccumulation of ferulate in lipophilic polyester significantly increased the tolerance of trans
230 on indium tin oxide-coated substrates (e.g., polyester) simply by solution-casting the ECL gel and br
231  graft model that application of an external polyester stent to the outside of carotid interposition
232 yhydroxyalkanoic acids (PHAs) are a class of polyesters stored in inclusion bodies and found in many
233               These results suggest that the polyester structure of the biodegradable polymers studie
234 nces that we attribute to differences in the polyester structure.
235 ped for the synthesis of dendritic aliphatic polyester structures using an acetal-protected anhydride
236                                 Conventional polyesters such as polylactide (PLA) or its copolymer, p
237                                              Polyester suture was more effective at lower K21 concent
238 cal lengths of surgical suture (chromic gut, polyester suture, silk, and nylon suture) and control un
239  The number of colonies from both the Dacron polyester swabs and medium were significantly lower than
240 culture, rayon swabs are superior and Dacron polyester swabs are inferior.
241 of cutin synthase-like (CUS) proteins act as polyester synthases with negligible hydrolytic activity.
242  as partners of fatty acyl oxidases in lipid polyester synthesis and indicate that their cooverexpres
243 ught molecular bases of alkane formation and polyester synthesis have allowed construction of nearly
244           Traditional chemical catalysts for polyester synthesis have enabled the generation of impor
245                       Recent developments in polyester synthesis have established several systems bas
246 esults reveal a conserved mechanism of cutin polyester synthesis in land plants, and suggest that ela
247 mmobilized enzyme-catalysts for condensation polyester synthesis.
248                                              Polyesters synthesized through the alternating copolymer
249                       Diverse functionalized polyesters, synthesized with pendant functionalities via
250  of the key requirements in semi-crystalline polyesters, synthetic or bio-based, is the control on cr
251 microplastic fibers released from synthetic (polyester) textiles during simulated home washing under
252  WIN1 influences the composition of cutin, a polyester that forms the backbone of the cuticle.
253 lenge, we report the discovery of functional polyesters that are capable of delivering siRNA drugs se
254 lic anhydride comonomer results in amorphous polyesters that exhibit glass transition temperatures (T
255 cturally different ionic phthalic acid based polyesters (the number-average molecular weights (Mn) 17
256 al approach to study enzymatic hydrolysis of polyesters, the key step in their overall biodegradation
257 lthough aromatics are the minor component of polyesters, they play important role in the sealing func
258 n of changes in the masses and rigidities of polyester thin films during enzymatic hydrolysis using a
259             Chemical release from cotton and polyester to laundry water was >80% of aliphatic OPEs (l
260 as been shown to be effective for generating polyester-toner (PeT) microfluidic devices with channel
261     Here, we describe the use of inexpensive polyester-toner, rotation-driven microfluidic devices wi
262 e procedure for the fabrication of thermoset polyester (TPE) microfluidic systems and discusses the p
263 lyethylene glycol (PEG-PBA-PEG) (1.0-4.0 mg) polyester triblock copolymer; food oil, using olive and
264 study was to apply an elastic, biodegradable polyester urethane urea (PEUU) cardiac patch onto subacu
265           The vast majority of tapes contain polyester-urethane as the magnetic particle binder, the
266 he hydrolysis rates and extents of aliphatic polyesters varying in the length of their dicarboxylic a
267 ly(butylene adipate-co-terephthalate) (PBAT) polyesters varying in their terephthalate-to-adipate rat
268  of 1 nmol.min-1 immediately upstream from a polyester vascular graft in the unheparinized baboon cir
269 pylene oxide, we synthesized semicrystalline polyesters via the copolymerization of a range of epoxid
270                     The best DL for blood on polyester was found in the mid-IR spectral window corres
271 the biodegradable lactic/glycolic acid-based polyester, we coincorporated into the polymer an antacid
272                        Activities on all the polyesters were also confirmed with the strains P. pseud
273 h high performing zwitterionic and trehalose polyesters were also degraded, and the polymers and degr
274 ing the corresponding diacid chloride; these polyesters were quantitatively "clicked" with a fluoroal
275 ee types of swabs, flocked-nylon, rayon, and polyester, were evaluated by 3 extraction methods, the s
276 e highest HTP activity and also produced the polyester with the highest Mn, while the Cl-substituted
277 ontrolled coupling of epoxide functionalized polyesters with 2,2'-(ethylenedioxy)bis(ethylamine) to g
278 -based system rapidly converts gamma-BL into polyesters with high monomer conversions (up to 90 %), h
279 is a route to a new class of semicrystalline polyesters with improved properties, produced from readi
280 t with secondary alcohol groups and produces polyesters with lower molecular size.
281                              Novel aliphatic polyesters with pendent acetylene groups were prepared b
282 ide leads to a new class of high-performance polyesters with tunable mechanical properties.
283 ected and assigned to free acids, esters and polyesters with up to eight units.
284 rovides access to a range of new unsaturated polyesters with versatile functionality, as well as the
285 xafluorophosphate using Novozym 435 produced polyesters with weight average molecular weights limited
286                        The location of these polyesters within the seed coat, and their contributions
287 e alkyne groups at high density in aliphatic polyesters without compromising their crystallinity via

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