Ppler myography: local registration of muscular activity at static loading
Keywords:
acoustic myography, sarcomere, muscular vibrations, Doppler spectrum, monitoring
Abstract
In the present paper, the opportunity of registration of local vibrations of skeletal muscles in vivo by means of the ultrasound Doppler method is researched. The measurements were spent on muscles of the forearm under the action of constant loading as well as at the state of full relaxation. From the analysis of the received spectra of local displacements in the muscle tissues follows that gain-frequency characteristics of oscillatory movements of muscular fibers under loading and at the state of rest differ essentially. The fulfilled analysis and the formulated hypothesis respectively to the physical nature of registered signals reveal the principal opportunity of the usage of ultrasound Doppler myography for diagnostics of the functional state of skeletal muscles.
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References
1. Kitamura К., Tokunaga М., Iwane А.Н., Yanagida Т. A single myosin head moves along an actin filament with regular steps of 5.3 nanometers // Nature. - 1999. - V. 397. - P. 129-134.
2. Katsuyuki Shiroguchi, Kazuhiko Kinosita jr. Miosin V walks by lever action and Brownian motion // Science. - 2007. - V.316. - P. 1208-1212.
3. Reconditi M., Koubassova N., Linari M. et al. The conformation of myosin head domains in rigor muscle determined by X-ray interference // Biophys. J. - 2003. - V. 85. - P. 1098-1110.
4. Linari M., Brunello E., Reconditi M. et al. The structural basis of the increase in isometric force production with temperature in frog skeletal muscle // J. Physiol, - 2005. - V. 567. - P. 459-469.
5. Piazzesi G., Reconditi M., Linari M. et al. Mechanism of force generation by myosin heads in skeletal muscle // Nature. - 2002. - V. 415. - P. 659-662.
6. Rayment I., Rypniewski W., Schmidt-Base K. et al. Three dimensional structure of myosin subfragment-1: a molecular motor//Science. - 1993. - V. 261.-P. 50-58.
7. Rayment I., Holden M.H., Whittaker M. et al. Structure of actin-myosin complex and its implications for muscle contraction // Science. - 1993. - V. 261. - P. 58-65.
8. Wells P.N.T. Doppler studies of the vascular system (Review) // Europ. J. Ultrasound. - 1998 - V 7 -P. 3-8.
9. Kanai H, Sato M., Koiwa Y., Chubachi N. Transcutaneous measurement and spectrum analysis of hart wall vibrations // IEEE Trans. Ultrason., Ferroelectr. Freq. Control. - 1996. -V. 43. - P. 791-810.
10. Mashiyama Т., Hasegava H., Kanai H. Designing beam steering for accurate measurement of intima-media thickness at carotid sinus // Jap. J. Appl. Phys. - 2006. - V. 45, N5B. - P. 4722-4726.
11. de Körte C.L., Pasterkamp G., van der Steen A.F.W, et al. Characterization of plaque components with intravascular ultrasound elastography in human femoral and coronary arteries in vitro // Circulation. - 2000. -V. 102.-P. 617-623.
12. Rubin J.M., Xie H., Kim K. et al. Sonographic elasticity imaging of acute and chronic deep venous thrombosis in humans // J. Ultrasound Med. - 2006.- V. 25, N9. - P. 1179-1186.
13.0phir J., Alam S.K., Garra B.S. et al. Elastography: imaging the elastic properties of soft tissues with ultrasound // J. Med. Ultrason. - 2002. - V. 29, N4. - P. 155-171.
14. Girnyk S., Barannik A., Barannik E. et al. The estimation of elasticity and viscosity of soft tissues in vitro using the data of remote acoustic palpation // Ultrasound Med. Biol. - 2,006. - V. 32, N2. - P. 211-219.
15. Hemmerling TM, et al. Phonomyography and mechanomyography can be used interchangeably to measure neuromuscular block at the adductor pollicis muscle // Anesthesia & Analgesia, 2004. - V. 98. - P. 377-381.
16. Hemmerling T.M., Michaud G., Babin D., Trager G., Donati F. Comparison of phonomyography with balloon pressure mechanomyography to measure contractile force at the corrugator supercilii muscle // Can. J. Anaesth. V. 51. - V. 2. - 2004. - P. 116-121.
17. S.F. Levinson, H. Kanai, H. Hasegawa. Doppler myography - detecting and imaging intrinsic muscle sounds // Proceedings of the Fourth International Conference on the Ultrasonic Measurement and Imaging of Tissue Elasticity. - Lake Travis, Austin, Texas, USA, -2005. - P. 100.
18. Гирнык C.A., Баранник E.A, Баранник A.E., Товстяк В.В., Марусенко А.И, Волохов В.А, Ультразвуковая система для определения вязкоупругих свойств мягких тканей // Вісн. ХНУ № 637. Біофізичний вісник-2004. - Вип. 1-2. - С.94-101.
19. Barannik E.A. Girnyk S.A., Tovsniak V.V., Marusenko А.I., Emilianov S.Y., Sarvazyan А.P. Doppler ultrasound detection of shear waves remotely induced in tissue phantoms and tissue in vitro. //Utrasonics. -2002.- V.40, - P. 849-853.
20. Barannik E.A., Girnyk S.A., Tovsniak V.V., Marusenko A.I., Volkhov V.A., Sarvazyan A.P. The influences of viscosity on the shear remotely induced by focused ultrasound in viscoelastic media // JASA. -2004. V.115.-P.2358-2364.
21. В.И. Дещеревский. Математические модели мышечного сокращения. - М.: Наука, -1977. - 160с.
22. Bagshaw, С. R. Muscle Contraction, 2nd Ed. Chapman and Hall, London, UK, -1993.
23. Cooke, R. The mechanism; of muscle contraction. CRC Crit. Rev. Biochem. -1986. V.21. -P. 53-118.
24. Piazzesi G. and Lombardi V. A cross-bridge model that is able to explain mechanical and energetic properties of shortening muscle // Biophys. J. - 1995. - V. 68. - P. 1966-1979.
25. Ganhui Lan and Sean X. Sun. Dynamics of Myosin-Driven Skeletal Muscle Contraction: I. Steady-State Force Generation // Biophysical Journal. -2005. -V. 88, -P. 4107-4117.
26. Duke T.A.J. Molecular model of muscle contraction // Proc. Natl. Acad. Sei. USA. - 1999. - V.96. - P. 2770-2775.
27. Martyn D.A., Chase P.B., Regnier M., Gordon A.M. A simple model with myofilament compliance predicts activation-dependent crossbridge kinetics in skinned skeletal fibers // Biophys. J. - 2002. - V.83, N6. -P. 3425-3434.
28. Xiumei Liu, Pollack G.H. Stepwise Sliding of single actin and myosin filaments // Biophys. J. - 2004. -V.86.-P. 353-358
29. Э.И. Борзяк, Л.И. Волкова, E.A. Добровольская и др. Анатомия человека: В двух томах, т.1. -М: Медицина. -1996. -544 с.
2. Katsuyuki Shiroguchi, Kazuhiko Kinosita jr. Miosin V walks by lever action and Brownian motion // Science. - 2007. - V.316. - P. 1208-1212.
3. Reconditi M., Koubassova N., Linari M. et al. The conformation of myosin head domains in rigor muscle determined by X-ray interference // Biophys. J. - 2003. - V. 85. - P. 1098-1110.
4. Linari M., Brunello E., Reconditi M. et al. The structural basis of the increase in isometric force production with temperature in frog skeletal muscle // J. Physiol, - 2005. - V. 567. - P. 459-469.
5. Piazzesi G., Reconditi M., Linari M. et al. Mechanism of force generation by myosin heads in skeletal muscle // Nature. - 2002. - V. 415. - P. 659-662.
6. Rayment I., Rypniewski W., Schmidt-Base K. et al. Three dimensional structure of myosin subfragment-1: a molecular motor//Science. - 1993. - V. 261.-P. 50-58.
7. Rayment I., Holden M.H., Whittaker M. et al. Structure of actin-myosin complex and its implications for muscle contraction // Science. - 1993. - V. 261. - P. 58-65.
8. Wells P.N.T. Doppler studies of the vascular system (Review) // Europ. J. Ultrasound. - 1998 - V 7 -P. 3-8.
9. Kanai H, Sato M., Koiwa Y., Chubachi N. Transcutaneous measurement and spectrum analysis of hart wall vibrations // IEEE Trans. Ultrason., Ferroelectr. Freq. Control. - 1996. -V. 43. - P. 791-810.
10. Mashiyama Т., Hasegava H., Kanai H. Designing beam steering for accurate measurement of intima-media thickness at carotid sinus // Jap. J. Appl. Phys. - 2006. - V. 45, N5B. - P. 4722-4726.
11. de Körte C.L., Pasterkamp G., van der Steen A.F.W, et al. Characterization of plaque components with intravascular ultrasound elastography in human femoral and coronary arteries in vitro // Circulation. - 2000. -V. 102.-P. 617-623.
12. Rubin J.M., Xie H., Kim K. et al. Sonographic elasticity imaging of acute and chronic deep venous thrombosis in humans // J. Ultrasound Med. - 2006.- V. 25, N9. - P. 1179-1186.
13.0phir J., Alam S.K., Garra B.S. et al. Elastography: imaging the elastic properties of soft tissues with ultrasound // J. Med. Ultrason. - 2002. - V. 29, N4. - P. 155-171.
14. Girnyk S., Barannik A., Barannik E. et al. The estimation of elasticity and viscosity of soft tissues in vitro using the data of remote acoustic palpation // Ultrasound Med. Biol. - 2,006. - V. 32, N2. - P. 211-219.
15. Hemmerling TM, et al. Phonomyography and mechanomyography can be used interchangeably to measure neuromuscular block at the adductor pollicis muscle // Anesthesia & Analgesia, 2004. - V. 98. - P. 377-381.
16. Hemmerling T.M., Michaud G., Babin D., Trager G., Donati F. Comparison of phonomyography with balloon pressure mechanomyography to measure contractile force at the corrugator supercilii muscle // Can. J. Anaesth. V. 51. - V. 2. - 2004. - P. 116-121.
17. S.F. Levinson, H. Kanai, H. Hasegawa. Doppler myography - detecting and imaging intrinsic muscle sounds // Proceedings of the Fourth International Conference on the Ultrasonic Measurement and Imaging of Tissue Elasticity. - Lake Travis, Austin, Texas, USA, -2005. - P. 100.
18. Гирнык C.A., Баранник E.A, Баранник A.E., Товстяк В.В., Марусенко А.И, Волохов В.А, Ультразвуковая система для определения вязкоупругих свойств мягких тканей // Вісн. ХНУ № 637. Біофізичний вісник-2004. - Вип. 1-2. - С.94-101.
19. Barannik E.A. Girnyk S.A., Tovsniak V.V., Marusenko А.I., Emilianov S.Y., Sarvazyan А.P. Doppler ultrasound detection of shear waves remotely induced in tissue phantoms and tissue in vitro. //Utrasonics. -2002.- V.40, - P. 849-853.
20. Barannik E.A., Girnyk S.A., Tovsniak V.V., Marusenko A.I., Volkhov V.A., Sarvazyan A.P. The influences of viscosity on the shear remotely induced by focused ultrasound in viscoelastic media // JASA. -2004. V.115.-P.2358-2364.
21. В.И. Дещеревский. Математические модели мышечного сокращения. - М.: Наука, -1977. - 160с.
22. Bagshaw, С. R. Muscle Contraction, 2nd Ed. Chapman and Hall, London, UK, -1993.
23. Cooke, R. The mechanism; of muscle contraction. CRC Crit. Rev. Biochem. -1986. V.21. -P. 53-118.
24. Piazzesi G. and Lombardi V. A cross-bridge model that is able to explain mechanical and energetic properties of shortening muscle // Biophys. J. - 1995. - V. 68. - P. 1966-1979.
25. Ganhui Lan and Sean X. Sun. Dynamics of Myosin-Driven Skeletal Muscle Contraction: I. Steady-State Force Generation // Biophysical Journal. -2005. -V. 88, -P. 4107-4117.
26. Duke T.A.J. Molecular model of muscle contraction // Proc. Natl. Acad. Sei. USA. - 1999. - V.96. - P. 2770-2775.
27. Martyn D.A., Chase P.B., Regnier M., Gordon A.M. A simple model with myofilament compliance predicts activation-dependent crossbridge kinetics in skinned skeletal fibers // Biophys. J. - 2002. - V.83, N6. -P. 3425-3434.
28. Xiumei Liu, Pollack G.H. Stepwise Sliding of single actin and myosin filaments // Biophys. J. - 2004. -V.86.-P. 353-358
29. Э.И. Борзяк, Л.И. Волкова, E.A. Добровольская и др. Анатомия человека: В двух томах, т.1. -М: Медицина. -1996. -544 с.
Published
2008-09-29
Cited
How to Cite
Kulibaba, A. A., Girnyk, S. A., Tolstoluzhsky, D. A., & BаrаnniкE. A. (2008). Ppler myography: local registration of muscular activity at static loading. Biophysical Bulletin, 1(20), 79-87. Retrieved from https://periodicals.karazin.ua/biophysvisnyk/article/view/1584
Section
Medical physics
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