Extensional flow of hyaluronic acid solutions in an optimized microfluidic cross-slot device

Haward, Simon J.; Jaishankar, Aditya; Oliveira, Mónica; Alves, M.A.; McKinley, Gareth H.

doi:10.1063/1.4816708

Cited by 73 publications

(79 citation statements)

References 56 publications

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“…This is partly due to the large mass of the disaccharide HA repeat unit and the inherent rigidity it confers to the HA backbone structure, and also because HA is a polyelectrolyte with a rather expanded coil size under equilibrium conditions. For the HA solutions the relaxation times are determined directly from flow-induced birefringence measurements made in the OSCER device, as described by Haward et al 16 These values are in good agreement with those made on similar solutions in a CaBER device. 51 In Table I we also include the details of the dilute polymer solution studied by Haward et al.…”

Section: A Test Fluidssupporting

confidence: 58%

“…The numerical optimization, design, fabrication and experimental operation of the OSCER device has been described in detail in a number of recent publications [8][9][10]16 and will not be repeated here. To visualize flow instabilities in the device, we use fast polarizing electro-optical modulation techniques to image the full-field flow-induced birefringence (FIB), which arises as polymer molecules unravel in the planar extensional flow field and the polymer solutions become optically anisotropic in local regions of high polymer orientation.…”

Section: B Methodsmentioning

confidence: 99%

“…[11][12][13][14][15] In FIB experiments within the OSCER device (as within conventional cross-slots), a sharply localized birefringent strand can be observed along the outflowing symmetry plane for Wi > 0.5, indicating the development of significant optical anisotropy among macromolecules that pass near the stagnation point. 8,10,16 Moreover, along the symmetry planes of the OSCER device (the x = 0 and y = 0 planes) there is zero shear, and hence the flow field in these regions provides a purely planar extensional deformation to fluid elements. The OSCER device therefore largely satisfies the requirements to be considered as a true extensional rheometer, and we have already demonstrated its use as such in a number of recent publications.…”

Section: Introductionmentioning

confidence: 99%

“…The OSCER device therefore largely satisfies the requirements to be considered as a true extensional rheometer, and we have already demonstrated its use as such in a number of recent publications. 8,10,16 FIG. 1.…”

Section: Introductionmentioning

confidence: 99%

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Instabilities in stagnation point flows of polymer solutions

Haward

McKinley

2013

Physics of Fluids

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A recently-developed microfluidic device, the optimized shape cross-slot extensional rheometer, or OSCER [S.J. Haward, M.S.N. Oliveira, M.A. Alves and G.H. McKinley, Phys. Rev. Lett. 109, 128301 (2012)], is used to investigate the stability of viscoelastic polymer solutions in an idealized planar stagnation point flow. Aqueous polymer solutions, consisting of poly(ethylene oxide) and of hyaluronic acid with various molecular weights and concentrations, are formulated in order to provide fluids with a wide range of rheological properties. Semi-dilute solutions of high molecular weight polymers provide highly viscoelastic fluids with long relaxation times, which achieve a high Weissenberg number (Wi) at flow rates for which the Reynolds number (Re) remains low; hence the elasticity number El = Wi/Re is high. Lower concentration solutions of moderate molecular weight polymers provide only weakly viscoelastic fluids in which inertia remains important and El is relatively low. Flow birefringence observations are used to visualize the nature of flow instabilities in the fluids as the volume flow rate through the OSCER device is steadily incremented. At low Wi and Re, all of the fluids display a steady, symmetric and uniform 'birefringent strand' of highly oriented polymer molecules aligned along the outflowing symmetry axis of the test geometry, indicating the stability of the flow field under such conditions. In fluids of El > 1, we observe steady elastic flow asymmetries beyond a critical Weissenberg number, Wi crit , that are similar in character to those already reported in standard cross-slot geometries [e.g. P.E. Arratia, C.C. Thomas, J. Diorio and J.P. Gollub, Phys. Rev. Lett. 96, 144502 (2006)]. However, in fluids with El < 1 we observe a sequence of timedependent inertio-elastic instabilities beyond a critical Reynolds number, Re crit , characterized by high frequency spatiotemporal oscillations of the birefringent strand. By plotting the critical limits of stability for the various fluids in the Wi-Re operating space, we are able to construct a stability diagram delineating the distinct steady symmetric, steady asymmetric and inertio-elastic flow regimes in this idealized planar elongational flow device.

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Section: A Test Fluidssupporting

confidence: 58%

Section: B Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Instabilities in stagnation point flows of polymer solutions

Haward

McKinley

2013

Physics of Fluids

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“…CaBER measurements are relatively time-efficient and require less sample volume (\1 ml) compared to the techniques such as capillary extrusion (Cogswell 2003), opposed jet flow (Patruyo et al 2002) and filament stretching rheometry (FiSER) (Bhardwaj et al 2007). It is noteworthy that Cross-slot rheometry also offers some of the abovementioned advantages of CaBER, and has been used for cellulosic fluids (Sharma et al 2015) and hyaluronic acid solutions (Haward et al 2013;Haward 2014). From the perspective of processability, breaking up of an initially stable fluid filament is a process which has commercial applications such as spraying and atomization of pesticides, applying paints and adhesives, coating and food processing operations e.g.…”

Section: Introductionmentioning

confidence: 99%

Extensional rheometry of cellulose ether solutions: flow instability

Vadodaria

English

2015

Cellulose

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Capillary breakup extensional rheometry of semi-dilute hydroxyethyl cellulose (HEC) solutions was performed under several step-stretch conditions. The resulting parameters, i.e. terminal steady state extensional viscosity (g E ) and the timescale for viscoelastic stress growth, commonly referred to as the extensional relaxation time (k E ) were found to be sensitive to the step-stretch conditions. The k E decreased with increasing step-strain as opposed to the g E . Prior to the filament break-up, a 'bead-onstring' instability was observed close to the mid-plane. It is believed that this instability originated from the accumulation of viscoelastic stresses near the filament neck leading to the 'elastic recoil' of the extended polymer chains. The reasons for this belief are discussed in detail with the perspective of the past literature. Such type of flow instability has been reported for the first time for a cellulosic system. Various dimensionless numbers were plotted for the HEC solutions and compared with those obtained from past studies for various biopolymers as well as synthetic polymers.

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Characterization of hyaluronic acid and synovial fluid in stagnation point elongational flow

Haward

2013

Biopolymers

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Hyaluronic acid (HA) is an important biomacromolecule, which fulfils a number of vital physiological functions (especially in the joint synovial fluid) and also has consumer and pharmaceutical applications. HA solution properties have already been quite thoroughly characterized in response to steady shear flows but are less well understood in highly deforming extensional flows. In this study, flow-induced birefringence measurements are made as a function of the strain rate in planar elongational flow at the stagnation point of a cross-slot device using HA solutions of a range of molecular weights (0.9×10(6) g mol(-1)≤Mw≤4.8×10(6) g mol(-1)) and at dilute concentrations. The results provide macromolecular relaxation times, molecular weight distributions and the extensional viscosities and Trouton ratios of the fluids. The HA relaxation time is found to vary as τ∼Mw1.8, which is consistent with a partially solvated, expanded coil. An intrinsic Trouton ratio is defined, which varies as [Tr]∼Mw2. The measurement of birefringence with strain rate is shown to be highly sensitive to the molecular weight distribution and can resolve subtle changes due to macromolecular degradation and the presence of fracture products. Mechanical degradation experiments in the cross-slots indicate midchain scission of HA macromolecules, strongly suggesting near full extension of the high-molecular weight fraction in the stagnation point extensional flow field. Taken together the results suggest a possible method for analysis of the HA in synovial fluid, and this concept is tested using synovial fluid obtained from porcine tarsal joint.

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Extensional flow of hyaluronic acid solutions in an optimized microfluidic cross-slot device

Cited by 73 publications

References 56 publications

Instabilities in stagnation point flows of polymer solutions

Instabilities in stagnation point flows of polymer solutions

Extensional rheometry of cellulose ether solutions: flow instability

Characterization of hyaluronic acid and synovial fluid in stagnation point elongational flow

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