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1 ms originates from signal losses due to fast transverse relaxation.
2 In perfused myocardium the field-dependent transverse relaxation analysis of the deoxy Mb proximal
3 of MR signal, the latter contributes to its transverse relaxation and causes the anisotropy of MR si
8 ation data and the Carr-Purcell-Meiboom-Gill transverse relaxation dispersion measurements, suggest t
9 aracterization by more demanding techniques (transverse relaxation dispersion, saturation transfer, a
10 transition, the lipid (1)H signals have slow transverse relaxation, enabling filtering experiments as
13 ribe that the PSR filter is dominated by the transverse relaxation enhancement (R(2p)) experienced by
14 ide chain generates large distance-dependent transverse relaxation enhancements, analogous to those o
17 and alteration of magnetic resonance imaging transverse relaxation in late-life cognitive decline.
18 ncentration-dependent relaxation dispersion, transverse relaxation in the rotating frame, and exchang
20 tter chemical concentrations and altered Cho transverse relaxation, in a pattern distinct from that i
22 ration of ex vivo magnetic resonance imaging transverse relaxation is associated with late-life cogni
23 structure-activity relationship studies and transverse relaxation measurements by nuclear magnetic r
26 Incorporation of the water attenuation by transverse relaxation method for the complete and select
27 t were detected by exchange contributions to transverse relaxation of both C epsilon and C alpha.
32 omplex determined by a combination of methyl-transverse relaxation optimized nuclear magnetic resonan
35 combination of X-ray crystallography, methyl-transverse relaxation optimized spectroscopy (methyl-TRO
39 resonance (NMR) technique based on modified transverse relaxation optimized spectroscopy (TROSY) has
40 ent binder to KRas(G12D) and used (1)H (15)N transverse relaxation optimized spectroscopy (TROSY) het
41 using mutant subunits, we performed a methyl-transverse relaxation optimized spectroscopy (TROSY) NMR
42 e model with biochemical and solution methyl-transverse relaxation optimized spectroscopY (TROSY) NMR
43 abeling technique in combination with methyl-transverse relaxation optimized spectroscopy (TROSY) NMR
44 evisiae Rev1 and demonstrate with the use of transverse relaxation optimized spectroscopy (TROSY) NMR
45 e analyzed its Ca2+-binding properties using transverse relaxation optimized spectroscopy (TROSY)-bas
51 es sparse distance restraints obtained using transverse relaxation optimized spectroscopy experiments
55 ing strategy, biochemical assays, and methyl-transverse relaxation optimized spectroscopy-based NMR s
56 nation of hydrodynamics measurements, methyl-transverse relaxation optimized spectroscopy-based solut
57 sured in both apo- and holo-RXRalpha LBDs by transverse relaxation optimized spectroscopy-Carr-Purcel
59 s, was investigated both by conventional and transverse relaxation optimized spectroscopy-type hetero
67 ry, surface plasmon resonance and (1)H-(15)N transverse relaxation-optimized spectroscopy (TROSY) NMR
69 bservation that high-quality 2D [(15)N,(1)H]-transverse relaxation-optimized spectroscopy (TROSY) spe
73 s observation from MD is supported by methyl-transverse relaxation-optimized spectroscopy NMR data, w
74 ional (1)H-(13)C(F) correlation spectra with transverse relaxation-optimized spectroscopy selection o
75 sperse (19)F resonances in a two-dimensional transverse relaxation-optimized spectroscopy spectrum.
76 e demonstrate the application of (19)F-(13)C transverse relaxation-optimized spectroscopy to investig
78 rties of CA-Ile and -Met methyl groups using transverse-relaxation-optimized NMR spectroscopy to expl
79 ure the effect of conformational exchange on transverse relaxation parameters, namely Carr-Purcell-Me
80 In intrinsically disordered proteins, slow transverse relaxation permits measurement of (3)J(C'C')
81 s, given their high sensitivity and superior transverse relaxation properties, compared to single flu
83 rameters such as diffusion coefficients (D), transverse relaxation (R(2)), and structural similarity.
84 For this, we use advanced methods such as transverse relaxation (R(2)), diffusion measurements, sa
86 in the chemical exchange contribution to the transverse relaxation rate ( R ex) values, relative to t
87 = 171) 14-93 years of age were examined with transverse relaxation rate (R(2)) and four diffusion ten
91 With these data plus the enhancements in transverse relaxation rate (R2) for the other eight prot
93 The target was a composite measure of the transverse relaxation rate (R2) that was associated with
94 rameters [longitudinal relaxation rate (R1), transverse relaxation rate (R2), and heteronuclear nucle
96 between the susceptibility and the effective transverse relaxation rate (R2*) indicated that localize
97 proton density (PD), longitudinal (R1), and transverse relaxation rate (R2*) with 1.6 mm isotropic r
98 xation (R1)) and iron content (via effective transverse relaxation rate (R2*)) was used to track micr
99 The longitudinal relaxation rate (T(1)) and transverse relaxation rate (T(2)) data give mutually con
101 In water NMR (wNMR), the use of the water transverse relaxation rate [R(2)((1)H(2)O)] has been pre
102 axometry (longitudinal relaxation rate [R1], transverse relaxation rate [R2], and proton density [PD]
103 endence of the exchange contributions to the transverse relaxation rate constant shows approximately
104 longitudinal relaxation rate constants (R1), transverse relaxation rate constants (R2), and steady-st
105 easuring pH-dependent (15)N, (13)C, and (1)H transverse relaxation rate constants for 5 nuclei in eac
106 ntifying R2' (reversible contribution to the transverse relaxation rate from local field inhomogeneit
107 les, which induce substantial changes in the transverse relaxation rate of proton nuclear magnetic re
110 ly by examining the dependence of the proton transverse relaxation rate on the spin-locking field str
111 calibration curve (R(2) > 0.999) between the transverse relaxation rate R(2) and iron concentration f
112 he affinity range of low muM to low mM using transverse relaxation rate R(2) as the observable parame
114 nce (15)N longitudinal relaxation rate R(1), transverse relaxation rate R(2), and steady-state {(1)H}
116 longitudinal relaxation rate R1 (1/T1), (2) transverse relaxation rate R2* (1/T2*), and (3) Magnetiz
117 hibit a 20-fold increase in longitudinal and transverse relaxation rate values over the conventional
118 nificant exchange R(ex) contributions to the transverse relaxation rate were detected for most of the
119 which correlates the chemical shift with the transverse relaxation rate, allows for the simultaneous
120 tact bound states with a very fast effective transverse relaxation rate, indicative of side-chain-med
121 , under nonflow conditions, the water proton transverse relaxation rate, R(2)((1)H(2)O), is sensitive
122 dipyridamole-induced change in the apparent transverse relaxation rate, R2*, which correlates with h
124 a measurable change in spin-spin relaxation (transverse relaxation) rate in proton nuclear magnetic r
125 otofibril-bound species in the form of (15)N transverse relaxation rates ((15)N-R(2)) and exchange ki
126 d loop regions and by the enhanced spin-spin transverse relaxation rates (R(2)) observed in the trans
127 e concentration of paramagnetic ions and the transverse relaxation rates (R(2)) of the solvent proton
129 DDADP2-, and Mn(II)PO4(-)) on F- ion 19F NMR transverse relaxation rates (R2 = 1/T2) were studied in
130 ternal motions, reflected in unusually large transverse relaxation rates (R2), was also largely unaff
132 Nepsilon-H resonance and the amide nitrogen transverse relaxation rates (R2s) for varying pH values
133 We have also measured NMR longitudinal and transverse relaxation rates and (15)N-(1)H NOE enhanceme
134 at pH 5.0 and 2.5: 15N NMR longitudinal and transverse relaxation rates and 15N-1H nuclear Overhause
135 e measured and analyzed 15N longitudinal and transverse relaxation rates and [1H]-15N heteronuclear O
136 an analysis of nitrogen-15 longitudinal and transverse relaxation rates and amide nitrogen-proton nu
137 ch enable rapid and reliable measurements of transverse relaxation rates and diffusion coefficients w
138 Using measurement of chemical shifts, (15)N transverse relaxation rates and sedimentation coefficien
139 try measures, including the longitudinal and transverse relaxation rates and the myelin water fractio
142 rates were extracted by examining the (15)N transverse relaxation rates as a function of CPMG delay
143 es of TC14 by measuring 15N longitudinal and transverse relaxation rates as well as [1H-15N] heteronu
144 We measured whole-brain longitudinal and transverse relaxation rates as well as the myelin water
145 ddition, the difference (DeltaR(2)) in (15)N transverse relaxation rates between this sample and a co
148 ng was also suggested by a comparison of the transverse relaxation rates for hRPA70(1-326) and one of
149 hemical shift perturbation mapping and (15)N transverse relaxation rates for intact cardiac troponin
150 ater-exchange rates and various types of 15N transverse relaxation rates for these NH3 groups, reveal
152 me, the extent of the observed variations in transverse relaxation rates is consistent with the prese
154 The Tyr35 --> Gly substitution increased the transverse relaxation rates of more than one third of al
155 concentration, 1H-nuclear magnetic resonance transverse relaxation rates of packed RBCs, and plasma m
156 lution NMR approach in which enhancements of transverse relaxation rates of tail amide and methyl gro
157 can be detected by observing changes in the transverse relaxation rates of the ligand upon binding.
158 ), cerebral blood volume (DeltaCBV/CBV), and transverse relaxation rates of tissue water (T(2)(*) and
159 gens in a liquid mixture have different (1)H transverse relaxation rates R(2)((1)H), forming the basi
162 flexible, exhibiting cross-peak patterns and transverse relaxation rates that are very similar to tho
164 The 15N longitudinal relaxation rates, 15N transverse relaxation rates, and inverted question mark1
165 with measures of longitudinal and effective transverse relaxation rates, proton density and magnetis
166 on axis order parameters, determined by (2)H transverse relaxation rates, suggest that rigidification
167 the magnetic field dependencies of the (13)C transverse relaxation rates, whereas the tensor orientat
173 e NMR spectrum, due to the existence of fast transverse relaxation, related to the large size and exc
175 arge proteins and at very high fields, rapid transverse relaxation severely limits the sensitivity of
176 w-Field Nuclear Magnetic Resonance of proton transverse relaxation signal (T(2)) was monitored in hak
178 solution using (15)N longitudinal (T(1)) and transverse relaxation (T(2)) measurements as well as [(1
179 Gill pulse sequence were used to measure the transverse relaxation (T(2)) of the nucleus and thereby
180 P) including longitudinal relaxation (T(1)), transverse relaxation (T(2)), and (15)N-{(1)H} NOE data
182 near-infrared (NIR) window and enhanced the transverse relaxation (T2 ) contrast effect, as a result
184 TD-NMR spectroscopy was used to measure the transverse relaxation time (T(2)) and intensity of proto
185 E values between 60 ms and 270 ms to measure transverse relaxation time (T(2)) in the basal ganglia.
186 gnificant changes in both chemical shift and transverse relaxation time (T(2)) in the presence of E1p
187 , the free MNP(30) left in solution acted as transverse relaxation time (T(2)) signal reporters for S
188 measurement, water status was assessed from transverse relaxation time (T(2)) weighted signals regis
189 ld, created by microstructure, influence the transverse relaxation time (T2) in an orientation-depend
190 Because the magnetic resonance imaging (MRI) transverse relaxation time (T2) of cartilage is sensitiv
193 netic resonance imaging showed a significant transverse relaxation time (T2) shortening in the pancre
195 s) induced by downhill running (DR) by using transverse relaxation time (T2)-weighted magnetic resona
199 y (aw), freezable water content, (1)H proton transverse relaxation time and water self-diffusivity de
200 mension, 11 mm(3)) were applied to determine transverse relaxation time as affected by magnetic field
202 es of maximal cross-sectional area (CSAmax), transverse relaxation time constant (T2), and lipid frac
203 nd 1-year follow-up quantitative MR imaging (transverse relaxation time constant; MRI-T2 ), MR spectr
205 re were differences between the frequency or transverse relaxation time of signals for the reference
207 We further present 2D images of T1 and the transverse relaxation time T2 of the brain and show that
208 ngle and a time between pulses less than the transverse relaxation time, allowing for thousands of sc
210 omplexity, chemical shift overlap, and short transverse relaxation times (associated with slow tumbli
211 mal analysis at 50-70 C were studied through transverse relaxation times (T(2)) measured after Hahn s
212 ysis at 50-70 degrees C were studied through transverse relaxation times (T(2)) measured after Hahn s
215 mmonly observed increase in the water proton transverse relaxation times (T2) in magnetic resonance i
218 ncluding apparent diffusion coefficients and transverse relaxation times as affected by magnetic fiel
222 in-subject coefficients of variation for the transverse relaxation times of glutamate and glutamine,
223 t interactions, precise determination of the transverse relaxation times of molecules with scalar cou
225 l-based nanostructures have longitudinal and transverse relaxation times that are on par with commonl
227 xperiments when supplemental spin-lattice or transverse relaxation times were employed in the analysi
228 measures changes in spin-spin T(2) magnetic (transverse) relaxation times using a benchtop NMR instru
232 Maps of ex vivo magnetic resonance imaging transverse relaxation were generated using fast spin ech