Embryological transport features a very interesting and complex application of peristaltic fluid dynamics. Electro-osmotic phenomena are also known to arise in embryo transfer location. The fluid dynamic environment in embryological systems is also known to be non-Newtonian and exhibits strong viscoelastic properties. Motivated by these applications, the present article develops a new mathematical model for simulating two-dimensional peristaltic transport of a viscoelastic fluid in a tapered channel under the influence of electro-osmosis induced by asymmetric zeta potentials at the channel walls. The robust Jeffrey viscoelastic model is utilized. The finite Debye layer electro-kinetic approximation is deployed. The moving boundary problem is transformed to a steady boundary problem in the wave frame. The current study carries significant physiological relevance to an ever-increasing desire to study intrauterine fluid flow motion in an artificial uterus. The consequences of this model may introduce a new mechanical factor for embryo transport to a successful implantation site. Hydrodynamic characteristics are shown to be markedly influenced by the electro-osmosis, the channel taper angle, and the phase shift between the channel walls. Furthermore, it is demonstrated that volumetric flow rates and axial flow are both enhanced when the electro-osmotic force aids the axial flow for specific values of zeta potential ratio. Strong trapping of the bolus (representative of the embryo) is identified in the vicinity of the channel central line when the electro-osmosis opposes axial flow. The magnitude of the trapped bolus is observed to be significantly reduced with increasing tapered channel length whereas embryo axial motility is assisted with aligned electro-osmotic force.
Skip Nav Destination
Article navigation
February 2019
Research-Article
Electro-Osmosis Modulated Viscoelastic Embryo Transport in Uterine Hydrodynamics: Mathematical Modeling
V. K. Narla,
V. K. Narla
Department of Mathematics,
GITAM (Deemed to be University),
Hyderabad 502329, India
e-mail: vknarla@gmail.com
GITAM (Deemed to be University),
Hyderabad 502329, India
e-mail: vknarla@gmail.com
Search for other works by this author on:
Dharmendra Tripathi,
Dharmendra Tripathi
Department of Sciences and Humanities,
National Institute of Technology,
Uttarakhand 246174, India
e-mail: dtripathi@nituk.ac.in
National Institute of Technology,
Uttarakhand 246174, India
e-mail: dtripathi@nituk.ac.in
Search for other works by this author on:
O. Anwar Bég
O. Anwar Bég
Aeronautical and Mechanical Engineering,
University of Salford,
Manchester M54WT, UK
e-mail: O.A.Beg@salford.ac.uk
University of Salford,
Manchester M54WT, UK
e-mail: O.A.Beg@salford.ac.uk
Search for other works by this author on:
V. K. Narla
Department of Mathematics,
GITAM (Deemed to be University),
Hyderabad 502329, India
e-mail: vknarla@gmail.com
GITAM (Deemed to be University),
Hyderabad 502329, India
e-mail: vknarla@gmail.com
Dharmendra Tripathi
Department of Sciences and Humanities,
National Institute of Technology,
Uttarakhand 246174, India
e-mail: dtripathi@nituk.ac.in
National Institute of Technology,
Uttarakhand 246174, India
e-mail: dtripathi@nituk.ac.in
O. Anwar Bég
Aeronautical and Mechanical Engineering,
University of Salford,
Manchester M54WT, UK
e-mail: O.A.Beg@salford.ac.uk
University of Salford,
Manchester M54WT, UK
e-mail: O.A.Beg@salford.ac.uk
Manuscript received June 13, 2018; final manuscript received October 24, 2018; published online November 30, 2018. Assoc. Editor: Ching-Long Lin.
J Biomech Eng. Feb 2019, 141(2): 021003 (10 pages)
Published Online: November 30, 2018
Article history
Received:
June 13, 2018
Revised:
October 24, 2018
Citation
Narla, V. K., Tripathi, D., and Anwar Bég, O. (November 30, 2018). "Electro-Osmosis Modulated Viscoelastic Embryo Transport in Uterine Hydrodynamics: Mathematical Modeling." ASME. J Biomech Eng. February 2019; 141(2): 021003. https://doi.org/10.1115/1.4041904
Download citation file:
Get Email Alerts
Related Articles
High-Order Solution of Viscoelastic Fluids Using the Discontinuous Galerkin Method
J. Fluids Eng (March,2015)
Thermodynamic Evaluation of Electro-Osmotic Peristaltic Pumping for Shear-Thinning Fluid Flow
J. Micro Nano-Manuf (September,2022)
Electrokinetic-Driven Flow and Heat Transfer of a Non-Newtonian Fluid in a Circular Microchannel
J. Heat Transfer (February,2013)
Unsteady Electrokinetic Flow in a Microcapillary: Effects of Periodic Excitation and Geometry
J. Fluids Eng (November,2019)
Related Proceedings Papers
Related Chapters
Introduction
Axial-Flow Compressors
Introduction
Introduction to Finite Element, Boundary Element, and Meshless Methods: With Applications to Heat Transfer and Fluid Flow
Electrokinetic Dewatering and Sedimentation of Dredged Contaminated Sediment
Contaminated Sediments: Evaluation and Remediation Techniques