Rajan E. Banerjee scite author profile

Rajan E. Banerjee

3Publications

34Citation Statements Received

150Citation Statements Given

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Columbia University

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Validation of theoretical framework explaining active solute uptake in dynamically loaded porous media

Albro

Banerjee

et al. 2010

Journal of Biomechanics

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Solute transport in biological tissues is a fundamental process necessary for cell metabolism. In connective soft tissues, such as articular cartilage, cells are embedded within a dense extracellular matrix that hinders the transport of solutes. However, according to a recent theoretical study (Mauck et al., 2003, J. Biomech. Eng. 125, 602-614), the convective motion of a dynamically loaded porous solid matrix can also impart momentum to solutes, pumping them into the tissue and giving rise to concentrations which exceed those achived under passive diffusion alone. In this study, the theoretical predictions of this model are verified against experimental measurements. The mechanical and transport properties of an agarose-dextran model system were characterized from independent measurements and substituted into the theory to predict solute uptake or desorption under dynamic mechanical loading for various agarose concentrations and dextran molecular weights, as well as different boundary and initial conditions. In every tested case, agreement was observed between experiments and theoretical predictions as assessed by coefficients of determination ranging from R 2 =0.61 to 0.95. These results provide strong support for the hypothesis that dynamic loading of a deformable porous tissue can produce active transport of solutes via a pumping mechanisms mediated by momentum exchange between the solute and solid matrix.

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Dynamic loading of immature epiphyseal cartilage pumps nutrients out of vascular canals

Albro

Banerjee

et al. 2011

Journal of Biomechanics

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The potential influence of mechanical loading on transvascular transport in vascularized soft tissues has not been explored extensively. This experimental investigation introduced and explored the hypothesis that dynamic mechanical loading can pump solutes out of blood vessels and into the surrounding tissue, leading to faster uptake and higher solute concentrations than could otherwise be achieved under unloaded conditions. Immature epiphyseal cartilage was used as a model tissue system, with fluorescein (332 Da), dextran (3, 10 and 70 kDa) and transferrin (80 kDa) as model solutes. Cartilage disks were either dynamically loaded (±10% compression over a 10% static offset strain, at 0.2 Hz) or maintained unloaded in solution for up to 20 hours. Results demonstrated statistically significant solute uptake in dynamically loaded (DL) explants relative to passive diffusion (PD) controls for all solutes except unbound fluorescein, as evidenced by the DL:PD concentration ratios after 20 hours (1.0 ± 0.2, 2.4 ± 1.1, 6.1 ± 3.3, 9.0 ± 4.0, and 5.5±1.6 for fluorescein, 3, 10, and 70 kDa dextran, and transferrin). Significant uptake enhancements were also observed within the first 30 seconds of loading. Termination of dynamic loading produced dissipation of enhanced solute uptake back to PD control values. Confocal images confirmed that solute uptake occurred from cartilage canals into their surrounding extracellular matrix. The incidence of this loading-induced transvascular solute pumping mechanism may significantly alter our understanding of the interaction of mechanical loading and tissue metabolism.

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Direct Validation of Active Solute Transport Induced by Dynamic Loading of Porous Hydrated Media

Albro

Banerjee

et al. 2009

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Transport pathways play a key role in maintaining cellular metabolic activity in biological tissues. Efforts to maintain or enhance the transport of nutrients may prove beneficial to the maintenance of native or development of engineered tissue. Various studies have investigated the potential of dynamic mechanical loading to increase the uptake and desorption rates of solutes in articular cartilage [1, 2]. Recently, a novel concept has been theoretically suggested that such dynamic loading of porous deformable media may additionally yield higher steady state concentrations of solutes, beyond those achieved by passive diffusion [3]. The first experimental evidence that dynamic loading can significantly enhance solute uptake over passive diffusion was recently reported for a model system of dextran in agarose hydrogels [4]. The results of this experimental study [4] were interpreted in the context of the earlier theoretical predictions [3], though a direct validation of theory with experiments has not yet been attempted. Therefore, the current study focuses on directly validating the theoretical framework by independently measuring the mechanical and transport properties of agarose hydrogels and dextran solutions experimentally, and substituting these values into the theory to evaluate the predicted solute uptake. These predictions are then compared to the previously reported experimental measurements of uptake of dextran in agarose under dynamic loading [4], for several gel concentrations and solute molecular weights.

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Rajan E. Banerjee

Validation of theoretical framework explaining active solute uptake in dynamically loaded porous media

Dynamic loading of immature epiphyseal cartilage pumps nutrients out of vascular canals

Direct Validation of Active Solute Transport Induced by Dynamic Loading of Porous Hydrated Media

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