Modified Couple Stress Theory for Vibration of Embedded Bioliquid-Filled Microtubules under Walking a Motor Protein Including Surface Effects
محورهای موضوعی : EngineeringA Ghorbanpour Arani 1 , M Abdollahian 2 , A.H Ghorbanpour Arani 3
1 - Faculty of Mechanical Engineering, University of Kashan---
Institute of Nanoscience & Nanotechnology, University of Kashan
2 - Faculty of Mechanical Engineering, University of Kashan
3 - Faculty of Mechanical Engineering, University of Kashan
کلید واژه: Modified couple stress theory, Dynamic deflection, Motor protein movement, Bioliquid-filled microtubules, Cytoplasm,
چکیده مقاله :
Microtubules (MTs) are fibrous and tube-like cell substructures exist in cytoplasm of cells which play a vital role in many cellular processes. Surface effects on the vibration of bioliquid MTs surrounded by cytoplasm is investigated in this study. The emphasis is placed on the effect of the motor protein motion on the MTs. The MT is modeled as an orthotropic beam and the surrounded cytoplasm is assumed as an elastic media which is simulated by Pasternak foundation. In order to consider the small scale effects, the modified couple stress theory (MCST) is taken into account. An analytical method is employed to solve the motion equations obtained by energy method and Hamilton’s principle. The influence of surface layers, bioliquid, surrounding elastic medium, motor proteins motion, and small scale parameter are shown graphically. Results demonstrate that the speed of motor proteins is an effective parameter on the vibration characteristics of MTs. It is interesting that increasing the motor proteins speed does not change the maximum and minimum values of MTs dynamic deflection. The presented results might be useful in biomedical and biomechanical principles and applications.
[1] Wang C.Y., Zhang L.C., 2008, Circumferential vibration of microtubules with long axial wavelength, Journal of Theoretical Biology 41: 1892-1896.
[2] Cifra M., Pokorny J., Havelka D., Kucera O., 2010, Electric field generated by axial longitudinal vibration modes of microtubule, Biosystems 100: 122-131.
[3] Mallakzadeh M., Pasha Zanoosi A.A., Alibeigloo A., 2013, Fundamental frequency analysis of microtubules under different boundary conditions using differential quadrature method, Communication in Nonlinear Science and Numerical Simulation 18: 2240-2251.
[4] Li C., Ru C.Q., Mioduchowski A., 2006, Length-dependence of flexural rigidity as a result of anisotropic elastic properties of microtubules, Biochemical and Biophysical Research Communication 349: 1145-1150.
[5] Kucera O., Havelka D., 2012, Mechano-electrical vibrations of microtubules-Link to subcellular morphology, Biosystems 109: 346-355.
[6] Shen H.S., 2013, Nonlocal shear deformable shell model for torsional buckling and postbuckling of microtubules in thermal environments, Mechanics Research Communications 54: 83-95.
[7] Gao Y., Lei F.M., 2009, Small scale effects on the mechanical behaviors of protein microtubules based on the nonlocal elasticity theory, Biochemical and Biophysical Research Communication 387: 467-471.
[8] Demir C., Civalek O., 2013, Torsional and longitudinal frequency and wave response of microtubules based on the nonlocal continuum and nonlocal discrete models, Applied Mathematical Modelling 37: 9355-9367.
[9] Xiang P., Liew K.M., 2012, Free vibration analysis of microtubules based on an atomistic-continuum model, Journal of Sound and Vibration 331: 213-230.
[10] Karimi Zeverdejani M., Tadi Beni Y., 2013, The nano scale vibration of protein microtubules based on modified strain gradient theory, Current Applied Physics 13: 1566-1576.
[11] Akgoz B., Civalek O., 2011, Application of strain gradient elasticity theory for buckling analysis of protein microtubules, Current Applied Physics 11: 1133-1138.
[12] Fu Y., Zhang J., 2010, Modeling and analysis of microtubules based on a modified couple stress theory, Physica E 42: 1741-1745.
[13] Gao Y., An L., 2010, A nonlocal elastic anisotropic shell model for microtubule buckling behaviors in cytoplasm, Physica E 42: 2406-2415.
[14] Shen H.S., 2010, Nonlocal shear deformable shell model for bending buckling of microtubules embedded in an elastic medium, Physics Letter A 374: 4030-4039.
[15] Shen H.S., 2011, Nonlinear vibration of microtubules in living cells, Current Applied Physics 11: 812-821.
[16] Taj M., Zhang J.Q., 2012, Analysis of vibrational behaviors of microtubules embedded within elastic medium by Pasternak model, Biochemical and Biophysical Research Communications 424: 89-93.
[17] Taj M., Zhang J.Q., 2014, Analysis of wave propagation in orthotropic microtubules embedded within elastic medium by Pasternak model, Journal of the Mechanical Behavior Biomedical Materials 30: 300-305.
[18] Farajpour A., Rastgoo A., Mohammadi M., 2014, Surface effects on the mechanical characteristics of microtubule networks in living cells, Mechanics Research Communications 57: 18-26.
[19] Wang X., Yang W.D., Xiong J.T., 2014, Coupling effects of initial stress and scale characteristics on the dynamic behavior of bioliquid-filled microtubules immersed in cytosol, Physica E 56: 342-347.
[20] Li H.B., Xiong J.T., Wang X., 2013, The coupling frequency of bioliquid-filled microtubules considering small scale effects, European Journal of Mechanics-A/Solids 39: 11-16.
[21] Reddy J.N., 2011, Microstructure-dependent couple stress theories of functionally graded beams, Journal of the Mechanics and Physics of Solids 59: 2382-2399.
[22] Ansari R., Mohammadi V., Faghih Shojaei M., Gholami R., Sahmani S., 2013, Postbuckling characteristics of nanobeams based on the surface elasticity theory, Composites Part B: Engineering 55: 240-246.
[23] Shaat M., Mahmoudi F.F., Gao X.L., Faheem A.F., 2014, Size-dependent bending analysis of Kirchhoff nano-plates based on a modified couple-stress theory including surface effects, International Journal of Mechanical Sciences 79: 31-37.
[24] Shaat M., Mohamed S.A., 2014, Nonlinear-electrostatic analysis of micro-actuated beams based on couple stress and surface elasticity theories, International Journal of Mechanical Sciences 84 :208-217.
[25] Mohammad Abadi M., Daneshmehr A.R., 2014, An investigation of modified couple stress theory in buckling analysis of micro composite laminated Euler–Bernoulli and Timoshenko beams, International Journal of Engineering Sciences 75: 40-53.
[26] Daneshmand F., Ghavanloo E., Amabili M., 2011, Wave propagation in protein microtubules modeled as orthotropic elastic shells including transverse shear deformations, Journal of Biomechanics 44: 1960-1966.
[27] Ansari R., Mohammadi V., Faghih Shojaei M., Gholami R., Rouhi H., 2014, Nonlinear vibration analysis of Timoshenko nanobeams based on surface stress elasticity theory, European Journal of Mechanics-A/Solids 45: 143-152.
[28] Abdollahian M., Ghorbanpour Arani A., Mosallaei Barzoki A., Kolahchi R., Loghman A., 2013, Non-local wave propagation in embedded armchair TWBNNTs conveying viscous fluid using DQM, Physica B 418: 1-15.
[29] Amabili M., 2008, Nonlinear Vibrations and Stability of Shells and Plates, Cambridge University Press.
[30] Ghorbanpour Arani A., Roudbari M.A., Amir S., 2012, Nonlocal vibration of SWBNNT embedded in bundle of CNTs under a moving nanoparticle, Physica B 407:3646-3653.
[31] Simsek M., 2011, Nonlocal effects in the forced vibration of an elastically connected double-carbon nanotube system under a moving nanoparticle, Computational Materials Science 50: 2112-2123.
[32] Tuszynski J.A., Luchko T., Portet S., Dixon J.M., 2005, Anisotropic elastic properties of microtubules, The European Physical Journal E 17: 29-35.
[33] Heireche H., Tounsi A., Benhassaini H., Benzair A., Bendahmane M., Missouri M.,Mokadem S., 2010, Nonlocal elasticity effect on vibration characteristics of protein microtubules, Physica E 42: 2375-2379.
[34] Ansari R., Hosseini K., Darvizeh A., Daneshian B., 2013, A sixth-order compact finite difference method for non-classical vibration analysis of nanobeams including surface stress effects, Applied Mathematics and Computation 219: 4977-4991.