Analysis of Linear Macromolecule Transport through Aluminum Anodic Oxide Membranes by Pore Model.

“…The transport of long, linear molecules in solution through small pores has relevance for a number of processes including gel permeation chromatography [1-4], ultra filtration [5, 6], protein structural characterization [7, 8], gene transfer and RNA translocation [9-11] or the excretion and assembly of proteins and other molecules through cellular nanopores [12, 13]. The process of polymer translocation through nanoscale pores is also a powerful tool in the development of methods to separate and perhaps organize molecules.…”

“…The use of r H has led to discrepancies between experimentally-observed and theoretically-predicted macromolecular solute diffusivities [5]; and in misleading results from the calculation of the hydrodynamic resistance to solute motion in pores. Theoretically, flexible polymers with radius r H should transport through the pores faster than spheres of radius r H due to decreased predicted hydrodynamic resistances.…”

“…Consequently, numerous efforts to develop hydrodynamic models that more accurately describe the transport problem have been attempted [57, 58, 61-66]. As it turns out, the radius of gyration ( r F ) may be a better parameter to characterize the size of transporting flexible polymers [5]. r F is the radius of an isolated chain in the presence of excluded volume effects, and for a bulk dilute solution it is scaled as: $$r_F\cong a{N}^{\nu }$$…”

“…One model used to estimate the transport of flexible polymers through nanopore membranes is the “open pore model” [5, 73-76]. Originally developed for rigid spherical solutes, the open pore model has also been shown to accurately predict the transport of linear macromolecules of similar weight to collagen through membranes with highly regulated cylindrical pores of dimensions in the 10 1 nm range [5].…”

“…Originally developed for rigid spherical solutes, the open pore model has also been shown to accurately predict the transport of linear macromolecules of similar weight to collagen through membranes with highly regulated cylindrical pores of dimensions in the 10 1 nm range [5]. In the open pore model, r F is reportedly a better characteristic dimension for transport behaviour than r H [5].…”

Optimizing collagen transport through track-etched nanopores

“…The transport of long, linear molecules in solution through small pores has relevance for a number of processes including gel permeation chromatography [1-4], ultra filtration [5, 6], protein structural characterization [7, 8], gene transfer and RNA translocation [9-11] or the excretion and assembly of proteins and other molecules through cellular nanopores [12, 13]. The process of polymer translocation through nanoscale pores is also a powerful tool in the development of methods to separate and perhaps organize molecules.…”

“…The use of r H has led to discrepancies between experimentally-observed and theoretically-predicted macromolecular solute diffusivities [5]; and in misleading results from the calculation of the hydrodynamic resistance to solute motion in pores. Theoretically, flexible polymers with radius r H should transport through the pores faster than spheres of radius r H due to decreased predicted hydrodynamic resistances.…”

“…Consequently, numerous efforts to develop hydrodynamic models that more accurately describe the transport problem have been attempted [57, 58, 61-66]. As it turns out, the radius of gyration ( r F ) may be a better parameter to characterize the size of transporting flexible polymers [5]. r F is the radius of an isolated chain in the presence of excluded volume effects, and for a bulk dilute solution it is scaled as: $$r_F\cong a{N}^{\nu }$$…”

“…One model used to estimate the transport of flexible polymers through nanopore membranes is the “open pore model” [5, 73-76]. Originally developed for rigid spherical solutes, the open pore model has also been shown to accurately predict the transport of linear macromolecules of similar weight to collagen through membranes with highly regulated cylindrical pores of dimensions in the 10 1 nm range [5].…”

“…Originally developed for rigid spherical solutes, the open pore model has also been shown to accurately predict the transport of linear macromolecules of similar weight to collagen through membranes with highly regulated cylindrical pores of dimensions in the 10 1 nm range [5]. In the open pore model, r F is reportedly a better characteristic dimension for transport behaviour than r H [5].…”

Optimizing collagen transport through track-etched nanopores

Diffusion of semi‐flexible polyelectrolyte through nanochannels

Nanoporous materials for biomedical devices