Comparing the two curves in Figure 8, the amounts of the effective nanopore numbers can be modulated Lazertinib purchase by adjusting the size of the Si3N4 micropore, which can change the frequency of the current drop signals in the ionic current curve. Conclusions In summary, the transporting properties and detailed translocation information of biomolecules are investigated using an integrated device based on nanopore arrays in PC membranes and micropore in silicon nitride films. The amounts of effective nanopore numbers can be modulated by adjusting the size of Si3N4 micropore, which can change the frequency of signals in ionic current

curve. It is believed that the nanofluidic device based on integrated micropore-nanopore chips possessed comparative potentials in biosensing applications. Authors’ information LL is an associate professor at the Southeast University, PR China. LZ is an undergraduate student at the same university. ZN and YC are professors at the Southeast University, PR China. Acknowledgements This work is financially supported by the Natural Science Foundation of China (51003015 and U1332134); the National Basic Research Program of China (2011CB707601 and 2011CB707605); the Natural Foretinib molecular weight Science Foundation of Suzhou (SYG201329); open fund

offered by the State Key Laboratory of Fire Science (HZ2012-KF09), the Qing Lan Project, and the International Foundation for Science (Stockholm, Sweden); the Organization for the Prohibition of Chemical Weapons, (The Hague, Netherlands), through a grant to Lei Liu (F/4736-1); and the Student Research Training Salubrinal in vitro Programme in Southeast

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