Publications
"Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). 
supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular Dynamics Simulation of DNA Capture and Transport in Heated Nanopores." ACS Applied Materials and Interfaces 8:12599-12608 (2016). supporting.pdf (461.04 KB)
supporting.pdf (461.04 KB) "Molecular mechanics of DNA bricks: in situ structure, mechanical properties and ionic conductivity." New Journal of Physics 18:055012 (2016). supporting_information.pdf (7.84 MB)
supporting_information.pdf (7.84 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "DNA sequence-dependent ionic currents in ultra-small solid-state nanopores." Nanoscale 18:9600-9613 (2016). supp_triplet.pdf (98.62 KB)
supp_triplet.pdf (98.62 KB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB) "De Novo Reconstruction of DNA Origami Structures through Atomistic Molecular Dynamics Simulation." Nucleic Acids Research 44:3013-3019 (2016).
"Water Mediates Recognition of DNA Sequence via Ionic Current Blockade in a Biological Nanopore." ACS Nano 10:4644-4651 (2016). supporting_mspa.pdf (3.61 MB)
supporting_mspa.pdf (3.61 MB)