In this work, we numerically study a new means of manipulating single DNA chains in microchannels. The method is based on the effect of finite slip at hydrophobic walls on the hydrodynamics and, consequently, on the dynamics of the DNA in microchannels. We use dissipative particle dynamics to study DNA transport as a function of chain length and the Reynolds number in two dimensional parallel plate channels. We show how an asymmetric velocity profile in a channel with hydrophobic and hydrophilic walls can be used to manipulate the location of the DNA molecules. Using this effect, we propose a simple arrangement of hydrophobic and hydrophilic strips which can be exploited to separate long and short DNA chains. This journal is © the Partner Organisations 2014.

B. S.V. Patnaik

Department of Applied Mechanics

Srikanth Vedantam

Department of Engineering Design

Chains

Hydrophilicity

hydrophobicity

Microchannels

Reynolds number

DISSIPATIVE PARTICLE DYNAMICS

DISSIPATIVE PARTICLE DYNAMICS SIMULATION

DNA MOLECULES

DNA TRANSPORT

HYDROPHOBIC AND HYDROPHILIC

HYDROPHOBIC WALL

PARALLEL-PLATE CHANNELS

Velocity profiles

Bioinformatics

chemical phenomena

chemical structure

chemistry

Computer simulation

metabolism

Hydrophobic and Hydrophilic Interactions

Models, Molecular

IIT Madras is a public technical and research university located in Chennai, Tamil Nadu. Founded in 1959, it is recognised as an Institute of National Importance.

IIT Madras has been ranked as the top engineering institute in India for four years in a row by the National Institutional Ranking Framework of the MHRD

It currently offers undergraduate, postgraduate and research degrees across 16 disciplines in Engineering, Sciences, Humanities and Management. About 596 faculty belonging to science and engineering departments and centres of the Institute are engaged in teaching, research and industrial consultancy.

IIT Madras

Soft Matter

Understanding the dynamics of red blood cell (RBC) motion under in silico conditions is central to the development of cost-effective diagnostic tools. Specifically, unraveling the relationship between the rheological properties and the nature of shape change in the RBC (healthy or infected) can be extremely useful. In case of malarial infection, RBC progressively loses its deformability and tends to occlude the microvessel. In the present study, detailed mesoscopic simulations are performed to investigate the deformation dynamics of an RBC in flow through a constricted channel. Specifically, the manifestation of viscous forces (through flow rates) on the passage and blockage characteristics of a healthy red blood cell (hRBC) vis-á-vis an infected red blood cell (iRBC) are investigated. A finite-sized dissipative particle dynamics framework is used to model plasma in conjunction with a discrete model for the RBC. Instantaneous wall boundary method was used to model no-slip wall boundary conditions with a good control on the near-wall density fluctuations and compressibility effects. To investigate the microvascular occlusion, the RBC motion through 2 types of constricted channels, viz, (1) a tapered microchannel and (2) a stenosed-type microchannel, were simulated. It was observed that the deformation of an infected cell was much less compared with a healthy cell, with an attendant increase in the passage time. Apart from the qualitative features, deformation indices were obtained. The deformation of hRBC was sudden, while the iRBC deformed slowly as it traversed through the constriction. For higher flow rates, both hRBC and iRBC were found to undergo severe deformation. Even under low flow rates, hRBC could easily traverse past the constricted channel. However, for sufficiently slow flow rates (eg, capillary flows), the microchannel was found to be completely blocked by the iRBC. Copyright © 2018 John Wiley & Sons, Ltd.

International Journal for Numerical Methods in Biomedical Engineering

The dynamics of a healthy and infected red blood cell in flow through constricted channels: A DPD simulation

In this paper, we investigate the dynamics of a tethered flexible filament due to fluid flow inside a microchannel. We use the finite sized dissipative particle dynamics (FDPD) approach to model this problem. The flexible filament is modeled as a bead-spring system with both extensional and flexural rigidity. The influence of flow rate and bending stiffness on the filament dynamics is studied in terms of the different conformational modes obtained. The competing effects of the hydrodynamic force and elastic force in the presence of Brownian thermal effects of comparable order influence the mode shapes of the filament. The dynamics of the filament motions are further analyzed using proper orthogonal decomposition. An important consequence of the dynamics of the filament is that it causes cross-flow in the micro-channel, which could potentially be exploited in micro-mixing and pumping applications. The cross stream fluid transport is observed to be more pronounced for higher bending stiffness. © The Royal Society of Chemistry.

A dissipative particle dynamics study of a flexible filament in confined shear flow

Thin deformable membranes are encountered in a number of microfluidics-based applications. These are often employed for enhancing sorting, mixing, cross-diffusion transport, etc. Microfluidic systems with deformable membranes can be better understood by employing simple models and efficient computational procedures. In this paper, we present a dissipative particle dynamics model to simulate the interaction between a deformable membrane and fluid flow in a two-dimensional microchannel. The membrane is modeled as a bead-spring system with both extensional and torsional springs to simulate extensional stiffness and bending rigidity, respectively. By performing detailed simulations on a membrane pinned at both ends and oriented parallel to the flow, we observe different steady state conformations. These membrane deflections are found to be relatively large for low bending stiffnesses and small for high stiffnesses. The membrane was found to exhibit a simple bowing out mode for high stiffness values and more complex conformations at lower stiffnesses. © 2016, Springer-Verlag Berlin Heidelberg.

Microfluidics and Nanofluidics

Dissipative particle dynamics simulation of shear flow in a microchannel with a deformable membrane

The hydrodynamics of flow through two-dimensional parallel-plate microchannels with periodic hydrophobic strips under finite Reynolds numbers is studied using dissipative particle dynamics simulations. The hydrophobic and hydrophilic regions are modeled using partial-slip and no-slip boundary conditions, respectively. We first consider channels with symmetric hydrophobic strips on both walls. It was observed that the volume flow rate through the channel is nonlinearly dependent on the area fraction of the hydrophobic strips. Next, we study flow in an antisymmetric channel in which the hydrophobic strips on the two channel walls are staggered with an axial offset. We observe that, in contrast to the symmetric channels, the presence of antisymmetric strips cause a finite velocity component towards the center of the channel. This cross-stream velocity field may potentially prove useful for separating second-phase particles or enhancing mixing in such microchannels. © 2015, Springer-Verlag Berlin Heidelberg.

Hydrodynamics of flow through microchannels with hydrophobic strips

Transport of DNA in hydrophobic microchannels: A dissipative particle dynamics simulation

Journal	Data powered by TypesetSoft Matter
Publisher	Data powered by TypesetRoyal Society of Chemistry
ISSN	1744683X
Open Access	No