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1  novel, simple and robust method to evaluate myocardial strain.
2 gnificantly reduced assessed by longitudinal myocardial strain (-17.2% +/- 2.8% to -12.3% +/- 3.2%, p
3                                              Myocardial strain abnormalities are prevalent in young D
4 onance imaging (MRI) with 3-dimensional (3D) myocardial strain analysis allows quantitative assessmen
5  dysfunction; however, it is unknown whether myocardial strain analysis at rest in patients with susp
6 dy investigates whether early alterations of myocardial strain and blood biomarkers predict incident
7 ely evaluated for direct imaging of systolic myocardial strain and compared with cross-registered del
8 ession of tumorigenicity-2 is a biomarker of myocardial strain and inflammation.
9 magnetic resonance imaging-derived segmental myocardial strain and markers of myocardial injury could
10 ed a marker that is expressed in response to myocardial strain and possibly fibrosis.
11                                              Myocardial strain and strain rate can detect inducible i
12 dly growing interest in applying measures of myocardial strain and synchrony in clinical investigatio
13 hocardiographic measures of left ventricular myocardial strain and synchrony in healthy adults (n=739
14  We used CMR to consider changes in LV mass, myocardial strain and T1 mapping.
15 tion in young subjects with DMD by measuring myocardial strain and torsion.
16                   Peak systolic longitudinal myocardial strain and ultrasensitive troponin I measured
17 anes, and trastuzumab, systolic longitudinal myocardial strain and ultrasensitive troponin I measured
18 esis induced by VEGF genes improved regional myocardial strain and wall thickening and preserved ejec
19           We aimed at investigating regional myocardial strain and work in post-MI rats with and with
20 e (HARP) imaging for rapid quantification of myocardial strains and for detailed analysis of left ven
21 EF), global longitudinal and circumferential myocardial strain, and diastolic function, graded per Am
22 ular (LV) ejection fraction (EF) and reduced myocardial strain are reported in patients with hypertro
23       Hemodynamic response was monitored and myocardial strain assessed by echocardiography.
24 , a motion-encoding MR imaging technique for myocardial strain assessment with high spatial resolutio
25 than in the septum (P<0.01), but recruitable myocardial strain at peak dobutamine was greater in the
26 nction detected by alterations in transmural myocardial strain, but not by changes in BNP, PRSW, or t
27 e tagging enables noninvasive measurement of myocardial strain, but such strain measurements have not
28                      Shortening fraction and myocardial strain by tissue doppler imaging were quantif
29                               We compared 2D myocardial strains (circumferential shortening, Ecc; max
30 x, global and regional contractile function (myocardial strain), coronary artery flow, and myocardial
31  sought to clarify whether new modalities of myocardial strain Doppler (change in length per unit len
32 f reperfusion, fibrotic tissue increased and myocardial strain echocardiography was significantly com
33   HARP accurately detected subtle changes in myocardial strain fields under increasing doses of dobut
34 3% versus EHM -6.2+/-1.9%; P=0.17), regional myocardial strain from tagged magnetic resonance imaging
35 RP MRI provides fast, accurate assessment of myocardial strains from tagged MR images in normal subje
36 cally relevant, disease-based perspective on myocardial strain imaging in patients with acute myocard
37 rformed, this detection could be improved by myocardial strain imaging that measures regional contrac
38                                              Myocardial strain imaging using echocardiography can be
39                                              Myocardial strain imaging using speckle tracking is more
40 ed (1.5 x 2.5-mm) imaging and measurement of myocardial strain in humans without the need for postpro
41 resonance tagging using SPAMM can quantitate myocardial strain in ischemic and remote myocardium.
42  fat and comprehensive echocardiography with myocardial strain measured by speckle tracking during th
43 men and tissue Doppler echocardiography with myocardial strain measured by speckle tracking.
44 2D) speckle tracking (2DST) echocardiography myocardial strain measurement remain scarce.
45 es contributed to </=12% of the variation in myocardial strain or synchrony in this healthy sample.
46 arotid IMT is associated with alterations of myocardial strain parameters reflecting reduced systolic
47 ft ventricular (LV) hypertrophy and abnormal myocardial strain predict mortality.
48 uscle and fat actively contribute to further myocardial strain, promoting disease progression.
49   Recently, tissue Doppler imaging (TDI) and myocardial strain rate (SR) have emerged as important cl
50  trabeculation was associated with 21% worse myocardial strain (relative to the mean) per unit change
51 e hypothesized that changes in LV transmural myocardial strain represent an early marker of LV dysfun
52                                              Myocardial strain showed differences in each layer (End:
53   This perspective reviews the physiology of myocardial strain, the technical features of strain imag
54 ribution characteristics of left-ventricular myocardial strain using a novel cine MRI based deformati
55 ction was assessed in 12 segments from which myocardial strain was obtained.
56 ic longitudinal, radial, and circumferential myocardial strain were calculated.
57 ation (IR), isovolumic contraction (IC), and myocardial strain were measured in the endocardial (End)
58 n (MLP(-/-), n=6), and wild-type mice (n=8), myocardial strains were measured at 3 cross-sectional le
59                                              Myocardial strains were measured transmurally in the ent

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