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1 act with the surface of a metastable aqueous microdroplet.
2  assembly is greatly improved when using gel microdroplets.
3 ch impedes a more universal applicability of microdroplets.
4 f the internal configurations of LC emulsion microdroplets.
5 quence of approximately 40-600 encapsulating microdroplets.
6  to 5100 resulting from the stable QD-loaded microdroplets.
7 gregates and is contaminated by silicone oil microdroplets.
8 elopment of an enzyme assay inside picoliter microdroplets.
9  2-100 ng of protein was added to amino acid microdroplets.
10 ted for the first time in "optically sliced" microdroplets.
11 sed for monitoring the growth of bacteria in microdroplets.
12  surface textures can be applied to transfer microdroplets.
13 chanisms that drive reaction acceleration in microdroplets.
14 in lipid-stabilized, phase-separated aqueous microdroplets.
15 r single cells encapsulated into an array of microdroplets.
16 copolymer molecules on biopolymer coacervate microdroplets.
17 le cells and reagents in independent aqueous microdroplets (1 pL to 10 nL volumes) dispersed in an im
18 ng the mixing dynamics of colliding airborne microdroplets (40 +/- 5 mum diameter) using a streak-bas
19                               The coacervate microdroplets act as killer protocells for the obliterat
20 sed on the light-induced generation of water microdroplets acting as reversible stirrers of two conti
21                  The contrasting features of microdroplet and bulk-solution reactions are described t
22 y the degree of solute entrapment within the microdroplet and further describes the dynamics of dropl
23 dividual cells are encapsulated into aqueous microdroplets and assayed directly for the release of an
24  enables simultaneous creation of drug-laden microdroplets and encapsulation of stem cells in photopo
25             The combined utilization of PDMS microdroplets and microspheres not only enables the real
26  community of protease-containing coacervate microdroplets and protein-polymer microcapsules (protein
27 roach by comparing sequencing results of gel microdroplets and single cells following MDA.
28 chemical reactions between the charged spray microdroplets and surface molecules can be exploited to
29  coefficients can be quantified using merged microdroplets and that merged droplets can be used to st
30  small volumes such as intracellular fluids, microdroplets, and microfluidic chips also requires nano
31 tion and germination, plasmid stability, gel microdroplets, and the production of double-stranded RNA
32 ximately 23%) and suspended petroleum liquid microdroplets ( approximately 0.8%).
33                           Complex coacervate microdroplets are finding increased utility in synthetic
34 RM images is achieved by applying a chemical microdroplet array to the sample surface which is used t
35 ning surface-wettability-guided assembly and microdroplet-array-based operations.
36 mpatible, magnetically responsive ferrofluid microdroplets as local mechanical actuators and allows q
37 posed molecules detected by our enhanced gel microdroplet assay.
38  overcome this limitation, we have developed microdroplet assays enabling us to detect single primary
39                                  The charged microdroplets associated with incompletely dried ions co
40 these attributes through Raman excitation in microdroplets-but microdroplets have not been used in pr
41 emitter to control the reactivity of charged microdroplets by varying their exposure time with acid v
42 e have examined the same reaction in aqueous microdroplets (ca. 5 mum diameter) and find that the cyc
43  our results suggest that peptide-nucleotide microdroplets can be considered as a new type of protoce
44                           Using this module, microdroplets can be sorted based on absorbance readout
45 ively charged microbubble/positively charged microdroplet clusters are injected i.v., activated withi
46         Self-organized hexagonally patterned microdroplet clusters over locally heated water surfaces
47 influenced not only by the velocity at which microdroplets collide but also the geometry of the colli
48 ound loaded with a lipophilic NIR dye to the microdroplet component was shown to facilitate local rel
49 he electric field energization of coacervate microdroplets comprising polylysine and short single str
50 the encounter of 40 ppbv-6.0 ppmv O3(g) with microdroplets containing [catechol] = 1-150 muM.
51 dic channel in which were injected composite microdroplets containing a solution of an azidocoumarin
52  in biomass between populations of picoliter microdroplets containing different species of cyanobacte
53 itions, followed by flow cytometry to detect microdroplets containing microcolonies.
54 rystallization patterns (DCP) of an array of microdroplets containing solutions of different reporter
55 ng such superlattices that involves moulding microdroplets containing the nanoparticles and spatially
56  water surrounded by silicone oil where each microdroplet contains <1 enzyme on average.
57  reaction is also undertaken at liquid metal microdroplets created via sonication to produce Ag- and
58                                      Organic microdroplet deposits of DDPD in HDOP at basal plane pyr
59                                       Single microdroplets (diameter approximately 50 mum, 65 pL) fal
60 tark contrast to the observation that NH4NO3 microdroplets do not homogeneously effloresce, even when
61 -matter composite consisting of liquid metal microdroplets embedded in a soft elastomer matrix is pre
62 e kinetics of aqueous chemistry occurring in microdroplet environments require experimental technique
63 trations and other chemical manipulations in microdroplets even if they need to be kept alkaline.
64 leagues were replicated in the corresponding microdroplet experiments.
65 ) gas-mixture was passed through a suspended microdroplet flow, where the residence time in the dynam
66 nique combines encapsulation of cells in gel microdroplets for massively parallel microbial cultivati
67                                              Microdroplet formation plays a role in a variety effects
68 ume solutions sets up an apparent conundrum: Microdroplets formed by spray ionization can be used to
69 lar interfaces, including those generated at microdroplets formed in dilute hexafluoro-2-propanol (HF
70 This property is invoked to adsorb crude oil microdroplets from water using polyester polyurethane (P
71                                              Microdroplets generated in microfluidic channels hold gr
72   Also, two commonly used carrier fluids for microdroplet generation (FC-70 Fluorinert oil and silico
73 ingle microdroplets is afforded by on-demand microdroplet generation coupled to a commercial ion-trap
74 icle (NP) introduction using nebulization or microdroplet generation systems.
75 pectrometer (ICPTOFMS) in combination with a microdroplet generator (MDG) for simultaneous mass quant
76         Individual droplets generated from a microdroplet generator (MDG) were merged into an aerosol
77 termination of ENPs employing a monodisperse microdroplet generator (MDG) with transport efficiencies
78                                          Our microdroplet generator can be effectively applied to a d
79                We developed a drop-on-demand microdroplet generator for the discrete dispensing of bi
80 nsisting of a biomolecule concentrator and a microdroplet generator, which enhances the limited sensi
81 on of single-captured bacterial cells in gel microdroplets (GMDs) to improve full genomic sequence re
82 asic electrode system compared to the random microdroplet/graphite system.
83 hrough Raman excitation in microdroplets-but microdroplets have not been used in practical applicatio
84 The mixing dynamics of unconfined (airborne) microdroplets have yet to be studied in detail, which is
85 BQT)-which can be used to study reactions in microdroplets in a controlled environment.
86 on effect does not occur for certain organic microdroplets in aqueous solutions.
87 pe (reaction product) is the basis for using microdroplets in directed evolution studies, and the app
88                                 Water-in-oil microdroplets in microfluidics are well-defined individu
89 and nanoparticles, within individual aqueous microdroplets in oil.
90 nalyte concentrations from within individual microdroplets in real time using SERRS spectroscopy.
91 ions of a device for generating monodisperse microdroplets in two distinct size regimes and in a high
92 e methods to fabricate QD-stabilized toluene microdroplets in water as whispering gallery mode micros
93                                              Microdroplets interfaced by lipid monolayers were employ
94           By incorporating liquid metal (LM) microdroplets into a soft elastomer, we achieve a approx
95 any experiments, the precise volume of these microdroplets is a critical parameter which can be influ
96 nt of laser-induced photochemistry in single microdroplets is afforded by on-demand microdroplet gene
97  of I(-) by O3 at the air-water interface of microdroplets is evidenced by the appearance of hypoiodo
98                     The average speed of the microdroplets is measured using microparticle image velo
99   A method to monitor the level of oxygen in microdroplets is presented.
100      The spontaneous formation of coacervate microdroplet-laden photo-crosslinked hydrogels derived f
101                             Vitamin B2-doped microdroplet lasers are generated and trapped on a super
102 rate a polydisperse source of highly charged microdroplets, leading to multiple confounding factors p
103               It is demonstrated that single microdroplet mass spectra are recordable, one at a time,
104                                              Microdroplet NMR is a droplet microfluidic NMR loading m
105  microscale analysis, nanoSplitter LC-MS and microdroplet NMR, for the identification of unknown comp
106 n binding site conceptually represented as a microdroplet of ligands confined to a small volume is ex
107 se of a reactant encapsulated in a composite microdroplet of liquid perfluorohexane.
108                                      Merging microdroplets of different reactants is one such approac
109                           Crystallization of microdroplets of molten alloys could, in principle, pres
110 ger a phase transition and the nucleation of microdroplets of one of the components of the mixture.
111 ringes, and it is difficult to differentiate microdroplets of silicone oil from particles formed by a
112 ments suggest the possibility of emission of microdroplets of solution due to the intense fields at t
113 highest reported efflorescence RH values for microdroplets of these salts.
114                                          Gel microdroplets offer a powerful and high-throughput techn
115                                              Microdroplets offer unique compartments for accommodatin
116 lowed by the repeated condensation of liquid microdroplets on the fragmented tissue, allows for maxim
117  0.4 ms and spray the mixture in the form of microdroplets onto an electron microscopy grid, yielding
118         We sequenced six samples enriched by microdroplet or traditional singleplex PCR using primers
119                                        Thus, microdroplet PCR reactions require additional polymerase
120                                We scaled the microdroplet PCR to 3,976 amplicons totaling 1.49 Mb of
121 ch combining bisulfite treatment followed by microdroplet PCR with next-generation sequencing to assa
122  we describe an enrichment approach based on microdroplet PCR, which enables 1.5 million amplificatio
123  approach to enrich the target gene panel by microdroplet PCR.
124 hy genes in 12 MKS pedigrees using RainDance microdroplet-PCR enrichment and IlluminaGAIIx next-gener
125 sorting of cyanobacteria and microalgae in a microdroplet platform.
126 brane at the surface of preformed coacervate microdroplets prepared from cationic peptides/polyelectr
127                                              Microdroplets present several unique characteristics of
128 tituted quinolines were conducted in charged microdroplets produced by an electrospray process at amb
129  similar to reaction acceleration in charged microdroplets produced by electrospray ionization.
130 en pumping to accurately control the size of microdroplets produced in a microfluidic device.
131 s is the beginning of phase II, in which oil microdroplets quickly nucleate in the whole drop, leadin
132 pared to those in the corresponding bulk and microdroplet reactions and it is concluded that the rate
133 Complementary to cavitational chemistry, the microdroplet reactors created by USP facilitate the form
134 ature on SERRS-based detection of individual microdroplets remains lacking.
135                       Stability of pH in the microdroplets required for different determinations and
136  In this way, Zn(II) can also be titrated in microdroplets, requiring a pH around 10.
137             The highly QD-stabilized toluene microdroplet resonators in the all-liquid phase would be
138 alysis of treponemes embedded in agarose gel microdroplets revealed that only minor portions of Msp a
139 ntal physical and chemical processes such as microdroplet role in reaction catalysis in nature as wel
140                                Moreover, the microdroplets selectively sequester porphyrins, inorgani
141 method for performing two-phase reactions in microdroplets sheared by sheath gas without using a phas
142                                  The toluene microdroplets show size-dependently high Q-factors up to
143  performance depend on the properties of the microdroplet spray, sample, and surface.
144  both oxygen and LLL12 in stimuli responsive microdroplets (SRMs) by a gas-driven coaxial flow focusi
145 to generate two well-controlled monodisperse microdroplet streams and collide (and thus mix) the micr
146                                 In DESI-MSI, microdroplets strike the tissue sample, the resulting sp
147 estimated from times of coalescing ballistic microdroplets, suggest that complete mixing occurs withi
148 ation of SO2(g) on the interfacial layers of microdroplet surfaces was investigated using a spray-cha
149                                  Each of the microdroplets suspended on the surface of fluorinated li
150                 Our results demonstrate that microdroplet technology is well suited for processing DN
151 tides spontaneously accumulate in water into microdroplets that are stable to changes in temperature
152 ent variation of the well content results in microdroplets that represent time capsules of the compos
153 e, the ion and ligands behave as a "confined microdroplet" that is free to fluctuate and adapt to ion
154 om the original large ESI droplets and these microdroplets then desolvate without a significant decre
155  intercept intermediates of this reaction in microdroplets to validate a mechanism proposed herein.
156 g can be achieved when using airborne merged microdroplets to, e.g., study reaction kinetics when rea
157 ing micropillars from pipette-dispensed PDMS microdroplets using vacuum-chucked microspheres.
158  copolymers showed coacervate-like spherical microdroplets (varphi approximately 1-5 mum at pH approx
159  The rapid oxidation of SO2(g) on the acidic microdroplets was estimated as 1.5 x 10(6) [S(IV)] (M s(
160           Using spatially extended arrays of microdroplets, we study the diffusion of both AHL and IP
161                             The DNA-enriched microdroplets were manipulated by application of a magne
162 ssay in which treponemes encapsulated in gel microdroplets were probed with syphilitic sera in parall
163 irochetes encapsulated in agarose beads (gel microdroplets) were incubated with antibodies to these s
164 ) is trafficked into the attached coacervate microdroplets, which are then released as functionally m
165 hod can instantaneously tune the size of the microdroplets, which has applications in composites, cat
166 w capability of studying electrochemistry in microdroplets, which offers an opportunity to understand
167 lso rapidly growing interest in the field of microdroplets, which promises to offer the analyst many
168  entrapment of the solutes within an aqueous microdroplet, while the water molecules from the droplet
169 e analysis of treponemes encapsulated in gel microdroplets, while opsonization assays failed to detec
170 mits the analysis of mixing phenomena within microdroplets with a temporal resolution of 1 mus.
171 c tissues, using fluorescent, cell-sized oil microdroplets with defined mechanical properties and coa
172 oplet streams and collide (and thus mix) the microdroplets with high spatial and temporal control whi
173 mical microscope (SECM) were accomplished in microdroplets with solution volumes of less than 1 nL.
174             Spherical cap-shaped polystyrene microdroplets, with nonequilibrium contact angle, are pl
175  on the millisecond timescale in the charged microdroplets without the addition of any external acid.

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