BACKGROUND: In a number of recently published studies comparing measurements from patients with those from control subjects, a decreased magnitude of the systematic variation of backscattered energy over the heart cycle (cyclic variation) is accompanied by an increased level of overall myocardial backscatter (calibrated myocardial image brightness) when measured at a specific phase of the heart cycle (eg, end systole or end diastole). The goal of this study was to investigate whether this observation is consistent with predictions based on a model of the mechanisms of cyclic variation incorporating changes in relative intracellular and extracellular acoustic impedance over the heart cycle. METHODS: A previously described 3-component Maxwell-type model of muscle mechanics representing cardiac cell mechanical behavior was utilized to predict the systematic variation in the relative acoustic impedance differences between intracellular and extracellular elastic properties over the heart cycle and hence the observed magnitude of cyclic variation and overall myocardial scattering level. Predictions were obtained for a series of specific values of relative intracellular and extracellular acoustic impedance. RESULTS: Results indicate that the predicted magnitude of cyclic variation can be directly related to the overall myocardial backscatter level. For example, specific changes in the acoustic impedance (stiffness properties) of the extracellular matrix without any change in the intracellular acoustic impedance result in predicted values of -43.5 dB, -38.5 dB, and -33.5 dB for end-diastolic myocardial backscatter levels with corresponding values of 5.0 dB, 2.5 dB, and 1.3 dB for the predicted magnitude of cyclic variation, respectively. CONCLUSION: This study suggests that observed decreases in the magnitude of cyclic variation with concomitant increases in the measured overall myocardial backscatter level are consistent with predictions from a model based on the relative acoustic impedance differences between intracellular and extracellular elastic properties over the heart cycle. These results suggest that ultrasonic backscatter measurements may provide a noninvasive approach for assessing some relationships among myocardial stiffness, degree of fibrosis, and contractile performance.
BACKGROUND: In a number of recently published studies comparing measurements from patients with those from control subjects, a decreased magnitude of the systematic variation of backscattered energy over the heart cycle (cyclic variation) is accompanied by an increased level of overall myocardial backscatter (calibrated myocardial image brightness) when measured at a specific phase of the heart cycle (eg, end systole or end diastole). The goal of this study was to investigate whether this observation is consistent with predictions based on a model of the mechanisms of cyclic variation incorporating changes in relative intracellular and extracellular acoustic impedance over the heart cycle. METHODS: A previously described 3-component Maxwell-type model of muscle mechanics representing cardiac cell mechanical behavior was utilized to predict the systematic variation in the relative acoustic impedance differences between intracellular and extracellular elastic properties over the heart cycle and hence the observed magnitude of cyclic variation and overall myocardial scattering level. Predictions were obtained for a series of specific values of relative intracellular and extracellular acoustic impedance. RESULTS: Results indicate that the predicted magnitude of cyclic variation can be directly related to the overall myocardial backscatter level. For example, specific changes in the acoustic impedance (stiffness properties) of the extracellular matrix without any change in the intracellular acoustic impedance result in predicted values of -43.5 dB, -38.5 dB, and -33.5 dB for end-diastolic myocardial backscatter levels with corresponding values of 5.0 dB, 2.5 dB, and 1.3 dB for the predicted magnitude of cyclic variation, respectively. CONCLUSION: This study suggests that observed decreases in the magnitude of cyclic variation with concomitant increases in the measured overall myocardial backscatter level are consistent with predictions from a model based on the relative acoustic impedance differences between intracellular and extracellular elastic properties over the heart cycle. These results suggest that ultrasonic backscatter measurements may provide a noninvasive approach for assessing some relationships among myocardial stiffness, degree of fibrosis, and contractile performance.
Authors: Christopher W Lloyd; Leonid Shmuylovich; Mark R Holland; James G Miller; Sándor J Kovács Journal: Ultrasound Med Biol Date: 2011-06-16 Impact factor: 2.998
Authors: Mark R Holland; Allyson A Gibson; Adam Q Bauer; Linda R Peterson; Jean E Schaffer; Richard G Bach; Sharon Cresci; James G Miller Journal: Ultrasound Med Biol Date: 2010-10 Impact factor: 2.998
Authors: Christian C Anderson; Allyson A Gibson; Jean E Schaffer; Linda R Peterson; Mark R Holland; James G Miller Journal: Ultrasound Med Biol Date: 2011-03-25 Impact factor: 2.998
Authors: Mark R Holland; Allyson A Gibson; Carol A Kirschner; Deborah Hicks; Achiau Ludomirsky; Gautam K Singh Journal: J Am Soc Echocardiogr Date: 2009-01-08 Impact factor: 5.251
Authors: V Di Bello; F Aghini-Lombardi; F Monzani; E Talini; L Antonangeli; C Palagi; A Di Cori; N Caraccio; M G Delle Donne; A Dardano; A Pinchera; M Mariani Journal: J Endocrinol Invest Date: 2007 Jul-Aug Impact factor: 4.256
Authors: Imre Csige; Dóra Ujvárosy; Zoltán Szabó; István Lőrincz; György Paragh; Mariann Harangi; Sándor Somodi Journal: J Diabetes Res Date: 2018-11-04 Impact factor: 4.011