Ining A. Jou
Cornell University
14 Papers
41 Citations
Ining A. Jou is an academic researcher from Cornell University. The author has contributed to research in topics: Nanopore & Membrane. The author has an hindex of 4, co-authored 12 publications. Previous affiliations of Ining A. Jou include University of Massachusetts Amherst & Clarkson University.
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Papers
Dynamics of driven polymer transport through a nanopore
Kaikai Chen,Ining A. Jou,Niklas Ermann,Murugappan Muthukumar,Ulrich F. Keyser,Nicholas A. W. Bell,Nicholas A. W. Bell +6 more
TL;DR: A study of the dynamics of polymer translocation through synthetic nanopores provides a direct observation of tension propagation—a non-equilibrium description of the process of unfolding that a polymer undergoes during translocation.
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Charged particle separation by an electrically tunable nanoporous membrane.
TL;DR: For the optimal combination of applied electrolyte and membrane biases the same membrane can effectively separate same-sized particles based on charge with a difference of up to 3 times in membrane permeability.
Burkholderia cenocepacia H111 Produces a Water-Insoluble Exopolysaccharide in Biofilm: Structural Determination and Molecular Modelling.
Barbara Bellich,Ining A. Jou,Marco Caterino,Roberto Rizzo,Neil Ravenscroft,Mustafa Fazli,Tim Tolker-Nielsen,John W. Brady,Paola Cescutti +8 more
TL;DR: Molecular modelling and NMR data pointed at restricted dynamics of local conformations which were ascribed to the presence of inter-residue hydrogen bonds and to steric restrictions in the water-insoluble B. cenocepacia biofilm polysaccharide.
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DNA translocation through a nanopore in a single-layered doped semiconductor membrane.
TL;DR: It is shown that the type of semiconductor material used for the membrane has a prominent effect on the biomolecule's translocation time, with DNA exhibiting much longer translocation times through the p-type membrane than through the n type at the same electrolyte and membrane potentials, while the extension of the biomolescule remains practically unchanged.
The biofilm of Burkholderia cenocepacia H111 contains an exopolysaccharide composed of l-rhamnose and l-mannose: Structural characterization and molecular modelling.
Barbara Bellich,Ining A. Jou,Claudia Buriola,Neil Ravenscroft,John W. Brady,Mustafa Fazli,Tim Tolker-Nielsen,Roberto Rizzo,Paola Cescutti +8 more
TL;DR: A water-soluble exopolysaccharide was extracted from B. cenocepacia H111 biofilm, and its structure was determined by GLC-MS, NMR and ESI-MS as discussed by the authors.
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