• الصفحة الرئيسية
  • The Effect of Magnetic Nanoparticles on Dynamic Behavior of Aorta Artery with Atherosclerosis Under the Action of Pulsating Blood Velocity

شارک

عنوان URL للمقالة


رقم المقالة : JSM-2106-1700 (R1) زيارة : 156 الصفحة: 477 - 490

10.22034/jsm.2021.1933470.1700

20.1001.1.20083505.2022.14.4.6.2

نوع المخطوط: ابحاث

The Effect of Magnetic Nanoparticles on Dynamic Behavior of Aorta Artery with Atherosclerosis Under the Action of Pulsating Blood Velocity

الموضوعات :

M.R Motaghedifar 1 ( Department of Mechanical Engineering, Kashan Branch, Islamic Azad University, Kashan, Iran )
A Fakhar 2 ( Department of Mechanical Engineering, Kashan Branch, Islamic Azad University, Kashan, Iran )
H Tabatabaei 3 ( Department of Mechanical Engineering, Kashan Branch, Islamic Azad University, Kashan, Iran )
M Mazochi 4 ( Department of Cardiology, School of Medicine, Kashan University of Medical Sciences, Kashan, Iran )

تاريخ الإرسال : 27 الثلاثاء , ذو الحجة, 1443 تاريخ التأكيد : 05 السبت , ربيع الأول, 1444 تاريخ الإصدار : 07 الخميس , جمادى الأولى, 1444

الکلمات المفتاحية: Atherosclerosis, Numerical Method, Aorta artery, Pharmaceutical nanoparticles, Pulsating blood flow,

ملخص المقالة :

In this article, a biomechanical model is presented for dynamic instability behavior of aorta arteries with atherosclerosis conveying pulsating blood including pharmaceutical nanoparticles. Utilizing Mindlin theory of cylindrical shell, the aorta artery is simulated mathematically. The atherosclerosis is assumed symmetric with lipid tissue. The pharmaceutical nanoparticles are subjected to magnetic field for attract to the lipid tissue in artery. Applying energy method and numerical method of differential quadrature (DQ), the final equations are solved for obtaining the dynamic instability region (DIR). The DIR is curve of dynamic blood velocity with respect to artery frequency. The influences of various variables of magnetic field, magnetic nanoparticle’s volume percent, tissue, lipid’s height and length upon dynamic behavior of aorta artery are investigated. Based on the results, the existence of magnetic nanoparticle in the blood enhances the artery frequency and consequently can lead to better heart performance and reduce the risk of heart attack.

المصادر:


  1. Bhardwaj V., Hariharan S., Balasubramanian I., Lamprecht A., 2005, Pharmaceutical aspects of polymeric nanoparticles for oral drug delivery, Journal of Biomedical Nanotechnology 1: 235-258.
    2.
  2. Adibkia K., Nokhodchi A., Siah-Shadbad M., Omidi Y., Javadzadeh Y., Mohammadi G., 2009, A review on the methods of preparation of pharmaceutical nanoparticles, Journal Pharmaceutical Sciences 15: 303-314.
    3.
  3. Hedayatnasab Z., Abnisa F., Daud W., 2017, Review on magnetic nanoparticles for magnetic nanofluid hyperthermia application, Materials and Design 123: 174-196.
    4.
  4. Mohammed L., Gomaa H. G., Ragab D., Zhu J., 2017, Magnetic nanoparticles for environmental and biomedical applications: A review, Particuology 30: 1-14.
    5.
  5. Zhou Z., Yang L., Gao J., Chen X., 2019, Structure–relaxivity relationships of magnetic nanoparticles for magnetic resonance imaging, Advanced Materials 31:
    6.
  6. Raffa V., 2020, Engineering magnetic nanoparticles for repairing nerve injuries, Advances in Nanostructured Materials and Nanopatterning Technologies 2020: 167-200.
    7.
  7. Gloag L., Mehdipour M., Chen D., Tilley R. D., Gooding J. J., 2020, Advances in the application of magnetic nanoparticles for sensing, Advanced Materials 31: 1904385.
    8.
  8. Thomas D., Mathew N., Nath Megha S., 2021, Starch modified alginate nanoparticles for drug delivery application, International Journal of Biological Macromolecules 173: 277-284.
    9.
  9. Yaghmur A., Mu H., 2021, Recent advances in drug delivery applications of cubosomes, hexosomes, and solid lipid nanoparticles, Acta Pharmaceutica Sinica B 11: 871-885.
    10.
  10. Maiti S., Shaw S., Shit G. C., 2021, Fractional order model of thermo-solutal and magnetic nanoparticles transport for drug delivery applications, Colloids and Surfaces B: Biointerfaces 203:
    11.
  11. Okeyo P.O., Rajendran S.T., Boisen A., 2021, Sensing technologies and experimental platforms for the characterization of advanced oral drug delivery systems, Advanced Drug Delivery Reviews 176: 113850.
    12.
  12. Li X., Zhao Y., Zhao C., 2021, Applications of capillary action in drug delivery, IScience 24: 102810.
    13.
  13. Cui J., Xu Y., Tu H., Zhou H., Wang H., Di L., Wang R., 2021, Gather wisdom to overcome barriers: Well-designed nano-drug delivery systems for treating gliomas, Acta Pharmaceutica Sinica B 12: 1100-1125.
    14.
  14. Zhu Y.Sh., Tang K., Lv J., 2021, Peptide–drug conjugate-based novel molecular drug delivery system in cancer, Trends in Pharmacological Sciences 42: 857-869.
    15.
  15. Tubaldi E., Ferrari G., Balasubramanian P., Amabili M., 2019, Dynamic behavior of a Dacron aortic graft, ASME 2019 International Mechanical Engineering Congress and Exposition.
    16.
  16. Ferrari G., Balasubramanian P., Tubaldi E., Giovanniello F., Amabili M., 2019, Experiments on dynamic behavior of a Dacron aortic graft in a mock circulatory loop, Journal of Biomechanics 86: 132-140.
    17.
  17. Sharzehee M., Fatemifar F., Han H-C., 2019, Computational simulations of the helical buckling behavior of blood vessels, Numerical Methods in Biomedical Engineering 35:
    18.
  18. Liu Q., Han H-C., 2012, Mechanical buckling of artery under pulsatile pressure, Journal of Biomechanics 45: 1192-1198.
    19.
  19. Kim E., Okamoto T., Song J., Lee K., 2020, The acute effects of different frequencies of whole-body vibration on arterial stiffness, Clinical and Experimental Hypertension 42: 345-351.
    20.
  20. Ling Y., Tang J., Liu H., 2021, Numerical investigation of two-phase non-Newtonian blood flow in bifurcate pulmonary arteries with a flow resistant using Eulerian multiphase model, Chemical Engineering Science 233: 116426.
    21.
  21. Kumar D., Satyanarayana B., Deo N., 2021, Application of heat source and chemical reaction in MHD blood flow through permeable bifurcated arteries with inclined magnetic field in tumor treatments, Results in Applied Mathematics 10: 100151.
    22.
  22. Fatin Jamil D., Saleem S., Ud Din S., 2021, Analysis of non-Newtonian magnetic Casson blood flow in an inclined stenosed artery using Caputo-Fabrizio fractional derivatives, Computer Methods and Programs in Biomedicine 203: 106044.
    23.
  23. Das S., Pal T. K., Janan R.N., Giri B., 2021, Significance of Hall currents on hybrid nano-blood flow through an inclined artery having mild stenosis: Homotopy perturbation approach, Microvascular Research 137:104192.
    24.
  24. Sarwar L., Hussain A., 2021, Flow characteristics of Au-blood nanofluid in stenotic artery, International Communications in Heat and Mass Transfer 127: 105486.
    25.
  25. Teimouri K., Tavakoli M.R., Kim K.Ch., 2021, Investigation of the plaque morphology effect on changes of pulsatile blood flow in a stenosed curved artery induced by an external magnetic field, Computers in Biology and Medicine 135: 104600.
    26.
  26. Stamou A.C., Radulovic J., Buick J.M., 2021, Effect of stenosis growth on blood flow at the bifurcation ofthe carotid artery, Journal of Computational Science 54: 101435.
    27.
  27. Reddy J. N., 2004, Mechanics of Laminated Composite Plates and Shells, Washington, CRC press.
    28.
  28. Bose S., Banerjee M., 2015, Effect of non-Newtonian characteristics of blood on magnetic particle capture in occluded blood vessel, Journal of Magnetism and Magnetic Materials 374: 611-623.
    29.
  29. Reddy J. N., Wang C. M., 2004, Dynamics of Fluid-Conveying Beams: Governing Equations and Finite Element Models, Singapore: Centre for Offshore Research and Engineering.
    30.
  30. Johnston M., Johnston P.R., Corney S., Kilpatrick D., 2004, Non-Newtonian blood flow in human right coronary arteries: steady state simulations, Journal of Biomechanics 37: 709-720.
    31.
  31. Civalek Ö., 2004, Application of differential quadrature (DQ) and harmonic differential quadrature (HDQ) for buckling analysis of thin isotropic plates and elastic columns. Engineering Structures 26: 171-186.
    32.
  32. Chen W., 1996, Differential Quadrature Method and its Applications in Engineering, Department of Mechanical Engineering, Shanghai Jiao Tong University.
    33.
  33. Shu C., 1999, Differential Quadrature and its Application in Engineering, Springer.
    34.
  34. Bolotin V.V., 1964, The Dynamic Stability of Elastic Systems, Holden-Day, San Francisco.
    35.
  35. Liu Q., Han H.C., 2012, Mechanical buckling of artery under pulsatile pressure, Journal of Biomechanics 45: 1192-1198.
    36.
  36. Jozwik K., Obidowski D., 2010, Numerical simulations of the blood flow through vertebral arteries, Journal of Biomechanics 43: 177-185.
    37.
  37. Han H.C., 2008, Nonlinear buckling of blood vessels: A theoretical study, Journal of Biomechanics 41: 2708-2713.
    38.

سند

Sanad is a platform for managing Azad University publications

الروابط

المراكز ذات الصلة

دعامة

الصفحات الرسمية

حقوق هذا الموقع الإلكتروني مملوكة لنظام SANAD Press Management. © 1442-1446

الصفحة الرئيسية| دخول| معلومات عنا| اتصل بنا|
[English] [فارسی] [en] [fa]