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PLOS ONE 2014

Synovial Fluid Response to Extensional Flow: Effects of Dilution and Intermolecular Interactions

DOI: 10.1371/journal.pone.0092867

Simon J. Haward

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Abstract:

In this study, a microfluidic cross-slot device is used to examine the extensional flow response of diluted porcine synovial fluid (PSF) samples using flow-induced birefringence (FIB) measurements. The PSF sample is diluted to 10× 20× and 30× its original mass in a phosphate-buffered saline and its FIB response measured as a function of the strain rate at the stagnation point of the cross-slots. Equivalent experiments are also carried out using trypsin-treated PSF (t-PSF) in which the protein content is digested away using an enzyme. The results show that, at the synovial fluid concentrations tested, the protein content plays a negligible role in either the fluid's bulk shear or extensional flow behaviour. This helps support the validity of the analysis of synovial fluid HA content, either by microfluidic or by other techniques where the synovial fluid is first diluted, and suggests that the HA and protein content in synovial fluid must be higher than a certain minimum threshold concentration before HA-protein or protein-protein interactions become significant. However a systematic shift in the FIB response as the PSF and t-PSF samples are progressively diluted indicates that HA-HA interactions remain significant at the concentrations tested. These interactions influence FIB-derived macromolecular parameters such as the relaxation time and the molecular weight distribution and therefore must be minimized for the best validity of this method as an analytical technique, in which non-interaction between molecules is assumed.

References

[1]	Palfrey AJ, Davies DV (1968) Immediate viscosity of synovial fluid. J Appl Physiol 25: 672–678.
[2]	Al-Assaf S, Meadows J, Phillips GO, Williams PA (1996) The application of shear and extensional viscosity measurements to assess the potential of hylan in viscosupplementation. Biorheology 33: 319–332. doi: 10.1016/0006-355x(96)00025-x
[3]	Bing？l A？, Lohmann D, Püschel K, Kulicke W-M (2010) Characterization and comparison of shear and extensional flow of sodium hyaluronate and human synovial fluid. Biorheology 47: 205–224.
[4]	Backus C, Carrington SP, Fisher LR, Odell JA, Rodrigues DA (2002) The roles of extensional and shear flows of synovial fluid and replacement systems in joint protection. In: Kennedy JF, Phillips GO, Williams PA, Hascall VC, editors. Hyaluronan Volume 1: Chemical, Biochemical and Biological Aspects. Cambridge, Woodhead Publishing Ltd. pp. 209–218.
[5]	Haward SJ, Jaishankar A, Oliveira MSN, Alves MA, McKinley GH (2013) Extensional flow of hyaluronic acid solutions in an optimized microfluidic cross-slot device. Biomicrofluidics 7: 044108. doi: 10.1063/1.4816708
[6]	Balasz EA, Denlinger JL (1993) Viscosupplementation: a new concept in the treatment of osteoarthritis. J Rheumatol Suppl 39: 3–9.
[7]	McCarty DJ (1997) Synovial fluid. In: McCarty DJ, Koopman WJ, editors. Arthritis and Allied Conditions. A Textbook of Rheumatology. Baltimore, Williams & Wilkins. pp. 81–99.
[8]	Oates KMN, Krause WE, Colby RH (2002) Using rheology to probe the mechanism of joint lubrication: polyelectrolyte/protein interactions in synovial fluid. Mat Res Soc Symp Proc 711: 53. doi: 10.1557/proc-711-ff4.7.1
[9]	Oates KMN, Krause WE, Jones RL, Colby RH (2006) Rheopexy of synovial fluid and protein aggregation. J R Soc Interface 3: 167–174. doi: 10.1098/rsif.2005.0086
[10]	Sharma V, Jaishankar A, Wang Y-C, McKinley GH (2011) Rheology of globular proteins: apparent yield stress, high shear rate viscosity and interfacial viscoelasticity of bovine serum albumin solutions. Soft Matter 7: 5150–5160. doi: 10.1039/c0sm01312a
[11]	Elsaid KA, Jay GD, Warman ML, Rhee DK, Chichester CO (2005) Association of articular cartilage degradation and loss of boundary-lubricating ability of synovial fluid following injury and inflammatory arthritis. Arthritis Rheum 52: 1746–1755. doi: 10.1002/art.21038
[12]	Jay GD, Torres JR, Warman ML, Laderer MC, Breuer KS (2007) The role of lubricin in the mechanical behaviour of synovial fluid. P Natl Acad Sci USA 104: 6194–6199. doi: 10.1073/pnas.0608558104
[13]	Haward SJ (2014) Characterization of hyaluronic acid and synovial fluid in stagnation point elongational flow. Biopolymers 101: 287–305. doi: 10.1002/bip.22357
[14]	De Gennes PG (1974) Coil-stretch transition of dilute flexible polymers under ultrahigh velocity gradients. J Chem Phys 60: 5030–5042. doi: 10.1063/1.1681018
[15]	Larson RG, Magda JJ (1989) Coil-stretch transition in mixed shear and extensional flows of dilute polymer solutions. Macromolecules 22: 3004–3010. doi: 10.1021/ma00197a022
[16]	Meyer F, Lohmann D, Kulicke W-M (2009) Determination of the viscoelastic behaviour of sodium hyaluronate in phosphate buffered saline with rheo-mechanical and rheo-optical methods. J Rheol 53: 799–818. doi: 10.1122/1.3122985
[17]	Keller A, Odell JA (1985) The extensibility of macromolecules in solution; a new focus for macromolecular science. Colloid Polym Sci 263: 181–201. doi: 10.1007/bf01415506
[18]	Haward SJ, Sharma V, Odell JA (2011) Extensional opto-rheometry with biofluids and ultra-dilute polymer solutions. Soft Matter 7: 9908–9921. doi: 10.1039/c1sm05493g
[19]	Haward SJ, Ober TJ, Oliveira MSN, Alves MA, McKinley GH (2012) Extensional rheology and elastic instabilities of a wormlike micellar solution in a microfluidic cross-slot device. Soft Matter 8: 536–555. doi: 10.1039/c1sm06494k
[20]	Odell JA, Carrington SP (2006) Extensional flow oscillatory rheometry. J Non-Newtonian Fluid Mech 137: 110–120. doi: 10.1016/j.jnnfm.2006.03.010
[21]	Riddiford CL, Jerrard HG (1970) Limitations on the measurement of relaxation times using a pulsed Kerr effect method. J Phys D: Appl Phys 3: 1314–1321. doi: 10.1088/0022-3727/3/9/311
[22]	Arratia PE, Thomas CC, Diorio J, Gollub JP (2006) Elastic instabilities of polymer solutions in cross-channel flow. Phys Rev Lett 96: 144502. doi: 10.1103/physrevlett.96.144502
[23]	Poole RJ, Alves MA, Oliveira PJ (2007) Purely elastic flow asymmetries. Phys Rev Lett 99: 164503. doi: 10.1103/physrevlett.99.164503
[24]	Haward SJ, McKinley GH (2012) Stagnation point flow of wormlike micellar solutions in a microfluidic cross-slot device: Effects of surfactant concentration and ionic environment. Phys Rev E 85: 031502. doi: 10.1103/physreve.85.031502
[25]	Haward SJ, McKinley GH (2013) Instabilities in stagnation point flows of polymer solutions. Phys Fluids 25: 083104. doi: 10.1063/1.4818151
[26]	Haward SJ, Oliveira MSN, Alves MA, McKinley GH (2012) Optimized cross-slot flow geometry for microfluidic extensional rheometry. Phys Rev Lett 109: 128301. doi: 10.1103/physrevlett.109.128301
[27]	Mendichi R, ？oltés L, Schieroni AG (2003) Evaluation of Radius of gyration and intrinsic viscosity molar mass dependence and stiffness of hyaluronan. Biomacromolecules 4: 1805–1810. doi: 10.1021/bm0342178
[28]	Odell JA, Keller A, Müller AJ (1989) Extensional flow behaviour of macromolecules in solution. In: Glass JE, editor. Polymers in Aqueous Media. Washington, American Chemical Society. pp. 193–244.
[29]	Clasen C, Plog JP, Kulicke W-M, Owens M, Macosko C, et al. (2006) How dilute are dilute solutions in extensional flows? J Rheol 50: 849–881. doi: 10.1122/1.2357595
[30]	Fouissac E, Milas M, Rinaudo M (1993) Shea-rate, concentration, molecular weight, and temperature viscosity dependences of hyaluronate, a wormlike polyelectrolyte. Macromolecules 26: 6945–6951. doi: 10.1021/ma00077a036
[31]	Gilson MK, Rashin A, Fine R, Honig B (1985) On the calculation of electrostatic interactions in proteins. J Mol Biol 184: 503–516. doi: 10.1016/0022-2836(85)90297-9
[32]	Moon YU, Curtis RA, Anderson CO, Blanch HW, Prausnitz JM (2000) Protein–protein interactions in aqueous ammonium sulphate solutions. Lysozyme and bovine serum albumin (BSA) J Sol Chem 29: 699–718.

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