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1 hich in turn triggers hydrolysis to uncage a target molecule.
2 which the majority contain only zero or one target molecule.
3 be selectively created and integrated in the target molecule.
4 proving the stereospecific formation of the target molecule.
5 d domino reaction and ultimately yielded the target molecule.
6 ions of the aptamer chain in presence of the target molecule.
7 s interrupted and not easily accessible to a target molecule.
8 ntrol can be achieved for sensing of the new target molecule.
9 and capable of rebinding selectively to this target molecule.
10 ich can recognize and specifically bind to a target molecule.
11 folded conformation around the small neutral target molecule.
12 ynthesis of the acyclic dienyl moiety of the target molecule.
13 od that, in principle, can be applied to any target molecule.
14 ng alpha- and beta-glycoside moieties of the target molecule.
15 to match the vibrational fingerprint of the target molecule.
16 source with the electronic absorption of the target molecule.
17 nalized with DNA probes complementary to the target molecule.
18 protein in the free-energy landscape of the target molecule.
19 It is a polymerization method around the target molecule.
20 ns, including benzylic oxidation, led to the target molecule.
21 capable of selectively and tightly binding a target molecule.
22 functional decorations to reach the desired target molecule.
23 while maintaining high concentrations of the target molecule.
24 itative measure of the population profile of target molecules.
25 nriched organosilanes, an important class of target molecules.
26 eporter for the presence of nonelectroactive target molecules.
27 that can be used in the synthesis of complex target molecules.
28 magnetic field and stabilized by multivalent target molecules.
29 ification of extremely low concentrations of target molecules.
30 s hydrated form, bicarbonate (HCO3(-)), into target molecules.
31 g their affinity and specificity towards the target molecules.
32 in proportion to the chemical nature of the target molecules.
33 man fingerprint spectrum with trace level of target molecules.
34 g events between purified bacteria- and host-target molecules.
35 ementarity of base-pairing between probe and target molecules.
36 n our diversity oriented approach toward the target molecules.
37 (MIPs) for the specific recognition of NMP22 target molecules.
38 caused reduction in atherothrombosis-related target molecules.
39 ial defect in the linear deubiquitination of target molecules.
40 for the synthesis of a variety of bioactive target molecules.
41 e unreliable for samples containing very few target molecules.
42 and resolution for the detection of specific target molecules.
43 d/or binding affinity of oligonucleotides to target molecules.
44 re to afford nitriles, an important class of target molecules.
45 and can be generated against a wide array of target molecules.
46 o-recognition elements for a wide variety of target molecules.
47 e cavities to increase their affinity to the target molecules.
48 the highest imprinting effectiveness for the target molecules.
49 pler broadening due to spatial motion of the target molecules.
50 with respect to specificity and affinity for target molecules.
51 ommodities, moving away from simple fuels as target molecules.
52 to levels of low femtomolar concentration of target molecules.
53 with the removal of the carbamoyl moiety in target molecules.
54 tic alternative to access complex structural target molecules.
55 different scaffold proteins for a variety of target molecules.
56 s but also accelerated decay of short-tailed target molecules.
57 ing into their overall approach to accessing target molecules.
58 ntibodies to amplify signals of low-abundant target molecules.
59 al described herein may be extended to other target molecules.
60 e applied to the bonds between the probe and target molecules.
61 assays indicate the involvement of multiple target molecules.
62 e the development of novel immunotherapeutic target molecules.
63 seful biochemical derivatization of intended target molecules.
64 ations to mass-limited and aggregation-prone target molecules.
65 very of both activities within one precisely targeted molecule.
66 eaction to generate initial chirality in the targeted molecule.
67 inted polymers are synthetic receptors for a targeted molecule.
68 nergy profiles of eight systems for the four targeted molecules.
69 mbined with X-rays and conjugated to a tumor-targeting molecule.
70 for the first time as late-stage gametocyte-targeting molecules.
71 nd highlights the significance of HIF-1alpha-targeting molecules.
72 he genome that are inaccessible to other DNA-targeting molecules.
73 cytic C-type lectin receptors are attractive targeting molecules.
74 the lungs, and some bacteria produce neuron-targeting molecules.
75 gments with a detection limit down to 20 DNA target molecules (1.5aM range), making it suitable for a
76 etection from 1microL(-1) to 10(5)microL(-1) target molecules (20 to 2 million targets), making it su
77 the stem P1 and inhibited recognition of the target molecule 7-methylamino-7-deazaguanine (preQ 1 ).
79 his device was used to detect the low weight target molecule adenosine triphosphate (ATP), a common b
80 enables to map the detected intensity of the target molecule against an external calibration curve.
81 can be used to probe the specificity of pHLA-targeting molecules, aiding the development of future re
82 ing a solid-state host matrix containing the target molecule, allowing the observation of phosphoresc
85 s (DC), but almost all available systems use target molecules also expressed on other cells and thus
86 neous capture rates of a mixture of both the target molecule and an internal calibrator of precisely
87 nate from various precursor ions for a given target molecule and may be acquired at varying energies
88 ecause they allow for the rapid capture of a target molecule and the removal of non-specific interact
92 pment as it interferes with the detection of target molecules and may give rise to false positive sig
94 idated the thrombin-directed activity of all target molecules and revealed that posttranslational sul
96 of CD40L into rAd5-based MERS-CoV S1 vaccine targeting molecule and molecular adjuvants not only enha
97 of principle, we chose a dendritic cell (DC)-targeting molecule and specific model antigens to genera
98 nanogate, which could selectively respond to target molecules, and control enzymatic reaction for ele
99 difficulties in identifying the appropriate target molecules, and more importantly, by the phenotypi
100 dicated that our sensor binds selectively to target molecules, and the non-specific binding where ads
101 One of them can be neutralized by SR-BI-targeting molecules, and it is critical only for wild-ty
102 Herein, interaction between DNA probes and target molecule are also investigated and result reveale
103 n binding sites that specifically identify a target molecule are essential for life science research,
106 s, reliable methods to incorporate BCPs into target molecules are in high demand, as reflected by a f
107 damage in HD neurons, and these mitochondria-targeted molecules are potential therapeutic molecules f
108 sculature has opened the possibility of PSMA-targeted molecules as generalizable cancer imaging and t
109 bserving the real-time binding events of the target molecule at nanomolar concentration levels and co
110 including the (a) selection against various target molecules; (b) modulation of protein function in
111 AB sensors provide quantitative detection of target molecules based on the rate of color change of an
113 change of impedance caused by the receptors-target molecules binding at the sample/electrode interfa
114 e changes in streaming current, first when a target molecule binds to the capture probes immobilized
116 rsion is used to determine the number of PSA target molecules bound to the receptors in both selectiv
117 ecific rILSA, Nluc-ABD, selectively bound to target-molecule-bound mouse IgG1 and rabbit IgG primary
118 luate the interaction between aggregates and target molecules but also offers new insight for underst
119 derivatization reactions widens the scope of targeted molecules but also clearly points out mineral m
120 enable to the preparation of the carbocyclic target molecule by suitable postrearrangement transforma
122 tunities to redesign synthetic strategies to target molecules by incorporating a key enzymatic step i
123 noassays to sensitively detect low-abundance target molecules by just mixing their detection antibodi
124 re polymerized in the presence of a specific target molecule called the 'template' and capable of reb
125 owever, the presence of a nitrogen atom in a target molecule can complicate its chemical synthesis be
126 ids autofluorescence and photobleaching, and target molecules can be detected specifically and sensit
128 cross-linker, radical initiator, along with target molecule (cephalexin) in a porogenic material.
129 the mechanisms driving bacterial sepsis, the target molecules controlling vascular leakage are still
130 he remaining single-stranded portion of each target molecule could subsequently hybridize to compleme
135 mplate and demonstrate high affinity for the target molecule (e.g., melamine and trypsin in our publi
138 ind simultaneously to different sites on the target molecule, enabling highly sensitive and specific
139 es in aqueous solution for these hydrophobic target molecules, exceeding the values of known syntheti
140 Starting with citronellal, the quest for the target molecule featured a novel bis-transannular Diels-
141 intestinal infection or IBS is adsorption of target molecules followed by removal from the body.
143 in HUVECs and that CXCR7 may be a potential target molecule for endothelial regeneration and repair
144 function of Noxa, this could be a potential target molecule for future treatment approaches for H. p
151 toolkit of frameworks for capturing specific target molecules for their structure determination.
152 pose that SM/Cer and SMPD1 are new potential target molecules for therapeutic strategies to overcome
153 families, and demonstrate that its presence targets molecules for TLR detection, while its absence e
154 n the strengths of SERS for the detection of target molecules from complex mixtures and the clinical
155 cartridge allows for selective enrichment of target molecules from larger sample volumes and removal
156 atrix of the cell wall that partially shield target molecules from the immediate environment and also
157 was able to consistently detect and quantify target molecules from the most abundant species (Atlanti
158 is nanocomposite enable simple separation of targeted molecules from a complex matrix while the silve
159 ide the chemical identity of the capture and targeted molecules from their vibrational Raman fingerpr
160 ir structure and interactions with potential target molecules have only recently been investigated in
163 ithin a few minutes for determination of the target molecule in low sample volume at disposable cost-
164 cted several research groups to work on this target molecule in search of novel antibiotics with new
167 roach can be easily adopted to monitor other target molecules in a simple, low-cost, sensitive and se
168 at form crystalline inclusion compounds with target molecules in a single-step crystallization, compl
169 ver, the technique is limited when measuring target molecules in aqueous solution by strong water abs
174 es of some notable SLPs required for binding target molecules in hosts and how this information can b
178 approaches can sense a very small amount of target molecules in the blood and cerebrospinal fluids s
181 quently, the effects of concentration of the targeted molecules in the sample, installation position
183 erbium into a form suitable for chelation to targeting molecules in diagnostic nuclear medicine is pr
185 ated secondary antibodies, regardless of the target molecules, in various immunoassay formats, such a
186 physiological process of fibrogenesis; these target molecules include collagen types I, III, and IV,
188 Illustrative examples are provided for some target molecules, including terminal alkynes, strained r
189 lusively by lysozyme and not other cell wall-targeting molecules, including the peptidoglycan deacety
191 electronic pre-resonance conditions to image target molecules inside living cells with very high vibr
192 f miR-92 in CSCs led to higher expression of target molecules integrin alpha(V) and alpha(5) subunits
193 ed biosensors to transduce the presence of a target molecule into a dose-dependent fluorescence signa
194 ular imaging that can visualize the specific target molecules involved in immune-checkpoint pathways.
196 s to the construction of fluorine-containing target molecules is important for a variety of scientifi
197 ce (SPR) based label-free detection of small targeted molecules is a great challenge and require subs
199 elective detection of a low molecular weight target molecule (less than 200 Da) by aptamer-based sens
200 -radiative modes in the matrix surrounding a target molecule may also have broader applications in li
201 of binding to distinct epitopes on the same target molecule may enable fine-tuning of intracellular
203 These findings suggest that mitochondria-targeted molecules MitoQ and SS31 are protective against
204 e the protective effects of the mitochondria-targeted molecules MitoQ and SS31 in striatal neurons th
205 we use the beta-lactam ampicillin to predict target molecule occupancy at MIC from antimicrobial acti
206 presence in cellulosic materials makes it a target molecule of the pulp and paper industry's bleachi
207 appropriate validation, ultimately identify target molecules of diagnostic, prognostic, or therapeut
208 re-programmed sequential release of multiple target molecules of opposite solubility (hydrophobic and
209 Extracellular matrix protein 1, a direct targeting molecule of parathyroid hormone-related peptid
211 mechanism of adhesion by covalent bonding to target molecules on host cells that mimics that used by
214 AgAb action paralleled the abundance of the targeted molecules on lymphoma cells as well as their HL
216 lin (apoCaM) often appears inert, modulating target molecules only upon conversion to its Ca(2+)-boun
218 tics requires molecular amplification of the target molecules or molecular signal amplification after
219 logical ability of nucleic acids to identify target molecules or silence genes involved in disease pa
224 al tool where obtaining single crystals of a target molecule presents a significant challenge and it
228 set of receptors that have adapted to detect target molecules relating to numerous cellular pathways.
229 iting increased in vitro resistance to SR-BI-targeting molecules remain responsive to anti-SR-BI mAb
230 stationary supports for effective binding of target molecules requires understanding of the relations
231 at dsDNA react differently than ssDNA to the targeted molecules, requiring more energy to move the mo
232 dual binders, by bringing together different target molecules, restricting their conformational flexi
233 gene, capable of orchestrating a variety of target molecules, resulting in the activation of several
235 ylboron compounds are an important family of target molecules, serving as useful intermediates, as we
236 stem has the merits of wide applicability to target molecules, small sample volume, and a low detecti
237 e same mAb for an almost unlimited number of target molecule specificities, reducing manufacturing co
238 ptasensors capable of specifically sensing a target molecule such as ATP, HIV, ochratoxin, potassium
239 is designed to detect a potpourri of complex target molecules such as cell surface antigens, allergen
241 gut, and interfering with gut trafficking by targeting molecules such as alpha4beta7 in IBD can lead
242 er, attempts to develop anti-chaperone drugs targeting molecules such as Hsp70 have been hampered by
243 to replace antibodies for the recognition of target molecules (such as antigens), and have been integ
244 selectivity to CRP when compared with other target molecules, such as urea or creatinine, while main
248 nderlie the development of immunotherapeutic target molecules that augment the function of immune eff
249 that fertoprotectants against cisplatin must target molecules that control cell death pathways in the
251 namely to alpha-tocopheryl succinate, an SDH-targeting molecule that induced RIP1/PARP1-mediated necr
255 A origami nanoassembly, wherein binding of a target molecule to any of these probes leads to mechanoc
257 ders that recognize specific epitopes on the target molecule to exert a desired modulation of biologi
259 signaling in the hippocampus and a possible target molecule to limit brain damage during hemorrhagic
260 molecule assays (dSimoa), that enables more target molecules to be counted through increased samplin
261 ny medical and chemical applications require target molecules to be delivered in a controlled manner
262 e of fluorochrome labelled probes allows the target molecules to be detected by measuring the fluores
264 heir binding specificity and affinity to the target molecules to interfere with designated molecular
265 flow, which facilitates the transport of the target molecules to the binding region located in the mi
268 ing of one (multivalent) or two (monovalent) target molecules to these elements opens the stem, enhan
269 actions between different DNA sequences with targeted molecules to rank the nucleobase sensing perfor
270 GCs or a novel generation of nonsteroidal GR-targeting molecules, to meet the increasing clinical nee
271 ular mechanism, along with the identity of a target molecule, underlying the evasion of the macrophag
272 lecular recognition of one enantiomer of the target molecule using a DNA aptamer, and the ability of
273 posites can be used to simultaneously purify target molecules using external magnetic field and produ
274 gation of an approach toward the challenging target molecules via a key guanylation step employing di
275 and blends and (ii) a lower O:C ratio in the target molecules via electrochemical decarboxylation/deo
277 showed that the diastereomeric purity of the target molecule was >91 %, the highest obtained to date.
279 Specific staining and immobilization of the target molecules was achieved via a double hybridization
280 hly symmetric quaternary stereocenter of the target molecules was controlled through a matched combin
281 teractions between the cyclodextrins and the target molecule, we observe these gradients can serve to
282 Using xanthene dyes and organophosphates as target molecules, we found the transport metrics, e.g.,
284 approaches to the unusual amino acids in the target molecules were developed on the basis of a Negish
286 ates from association of completely atomized target molecules, whereas in the late plasma, the increa
287 ical environment, while allowing coupling to target molecules, which can be biological in nature (e.g
288 ed the accumulation of detection antibody to target molecules, which dramatically enhanced the sensit
289 es enables the simultaneous detection of two target molecules, which exhibit the same affinity intera
290 ion of TGF-beta synthesis by those TNF-alpha-targeting molecules, which are able to trigger mTNF-alph
291 bling selective chemical imaging of specific target molecules, while simultaneously providing topogra
293 sitates the simultaneous binding of a single target molecule with two affinity ligands each conjugate
294 e chemical receptors that recognize and bind target molecules with a high affinity and selectivity.
296 stoichiometric inclusion of a wide range of target molecules with full occupancy, typically without
297 are 'synthetic antibodies' that can bind to target molecules with high affinity and specificity.
299 g diffusivity of an unknown concentration of target molecules with that of a reference solution.
300 also from asymmetric chemical bonding of the target molecules with the framework that is able to prov