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Nanoscale Electrokinetics and Microvortices: How Microhydrodynamics Affects Nanofluidic Ion Flux: Supplemental Video 4
A supplemental video from the 2012 review by Hsueh-Chia Chang Gilad Yossifon and Evgeny A. Demekhin "Nanoscale Electrokinetics and Microvortices: How Microhydrodynamics Affects Nanofluidic Ion Flux" from the Annual Review of Fluid Mechanics.
Movie showing the depletion layer and its associated vortex dependence (using 1.2-µm fluorescent microbeads) on the voltage for the widest (2.5-mm) nanoslot.
Nanoscale Electrokinetics and Microvortices: How Microhydrodynamics Affects Nanofluidic Ion Flux: Supplemental Video 5
A supplemental video from the 2012 review by Hsueh-Chia Chang Gilad Yossifon and Evgeny A. Demekhin "Nanoscale Electrokinetics and Microvortices: How Microhydrodynamics Affects Nanofluidic Ion Flux" from the Annual Review of Fluid Mechanics.
Movie showing the depletion layer and its associated vortex dependence (using 1.2-µm fluorescent microbeads) on the voltage for the narrowest (50-µm) nanoslot.
Nanoscale Electrokinetics and Microvortices: How Microhydrodynamics Affects Nanofluidic Ion Flux: Supplemental Video 7
A supplemental video from the 2012 review by Hsueh-Chia Chang Gilad Yossifon and Evgeny A. Demekhin "Nanoscale Electrokinetics and Microvortices: How Microhydrodynamics Affects Nanofluidic Ion Flux" from the Annual Review of Fluid Mechanics.
Movie showing the evolution of the depletion-enrichment phenomenon under reverse 40-V DC bias for a single nanochannel.
Nanoscale Electrokinetics and Microvortices: How Microhydrodynamics Affects Nanofluidic Ion Flux: Supplemental Video 6
A supplemental video from the 2012 review by Hsueh-Chia Chang Gilad Yossifon and Evgeny A. Demekhin "Nanoscale Electrokinetics and Microvortices: How Microhydrodynamics Affects Nanofluidic Ion Flux" from the Annual Review of Fluid Mechanics.
Movie showing the evolution of the depletion-enrichment phenomenon under forward and reverse 30-V DC bias for a nanochannel array (consisting of seven channels) with asymmetric channel separation at the entrances.
Nanoscale Electrokinetics and Microvortices: How Microhydrodynamics Affects Nanofluidic Ion Flux: Supplemental Video 8
A supplemental video from the 2012 review by Hsueh-Chia Chang Gilad Yossifon and Evgeny A. Demekhin "Nanoscale Electrokinetics and Microvortices: How Microhydrodynamics Affects Nanofluidic Ion Flux" from the Annual Review of Fluid Mechanics.
Movie showing the colloid dynamics for different applied voltages in the case of weak electrolyte (0.1 mM) and 1.2-µm beads without fluorescent dye molecules in the background electrolyte solution.
Liquid Rope Coiling: Supplemental Video 1
A supplemental video from the 2012 review by Neil M. Ribe Mehdi Habibi and Daniel Bonn "Liquid Rope Coiling" from the Annual Review of Fluid Mechanics.
Each frame is 1 cm wide and the playback rate is 1/20 real time.
A Conversation with Olle Björkman
The Annual Review of Plant Biology presents a conversation with Dr.Olle Björkman. In this interview Dr. Björkman talks about his research and career in plant biology.
A Conversation with Haldor Topsøe
The Annual Review of Chemical and Biomolecular Engineering presents a conversation with Dr. Haldor Topsøe chairman of Haldor Topsøe. In this interview Dr. Topsøe talks about his career in industry as well as his corporation's work with academic scientists.
A Conversation with Robert M. Solow
Dr. Robert Solow Professor Emeritus of Economics at the Massachusetts Institute of Technology talks about his life and career with Dr. Peter Berck SJ Hall Professor of Agricultural and Resource Economics and Policy at the University of California at Berkeley. In this conversation Dr. Solow discusses growing up in an immigrant family in 1930s Brooklyn being introduced to literature and ideas at James Madison High School attending Harvard University on scholarship and receiving the 1987 Nobel Prize in Economics Laureate.
In Vitro Models of Traumatic Brain Injury: Supplemental Video 1
A supplemental video from the 2011 review by Barclay Morrison III Benjamin S. Elkin Jean-Pierre Dollé and Martin L. Yarmush "In Vitro Models of Traumatic Brain Injury" from the Annual Review of Biomedical Engineering.
Equibiaxial stretch of cultures is achieved through deformation of the culture substrate by pulling the clamped membrane over a hollow cylinder. This video shows the dynamic deformation of a culture being injured with this model.
In Vitro Models of Traumatic Brain Injury: Supplemental Video 2
A supplemental video from the 2011 review by Barclay Morrison III Benjamin S. Elkin Jean-Pierre Dollé and Martin L. Yarmush "In Vitro Models of Traumatic Brain Injury" from the Annual Review of Biomedical Engineering.
Propagation of evoked activity through the neural circuitry.
A Conversation with Karl K. Turekian
The Annual Review of Marine Science presents an interview with Dr. Karl K. Turekian Sterling Professor of Geology and Geophysics at Yale University in conversation with Dr. Kirk Cochran Professor of Marine Science at Stony Brook University.
An Interview with Jeremy Thorner
The Structure of the Nuclear Pore Complex: Supplemental Video 1
A supplemental video from the 2011 review by André Hoelz Erik W. Debler and Günter Blobel "The Structure of the Nuclear Pore Complex" from the Annual Review of Biochemistry.
Overall the nuclear pore complex (NPC) consists of a cylindrical symmetric core which is asymmetrically decorated with filaments and a nuclear basket structure on the cytoplasmic and nucleoplasmic sides respectively. Molecules smaller than ∼40 kDa (small spheres) freely diffuse through the NPC whereas larger noncargo molecules (large spheres) are prevented from crossing the nuclear envelope. Artwork by Joseph Alexander Erik W. Debler and André Hoelz.
The Structure of the Nuclear Pore Complex: Supplemental Video 2
A supplemental video from the 2011 review by André Hoelz Erik W. Debler and Günter Blobel "The Structure of the Nuclear Pore Complex" from the Annual Review of Biochemistry.
Active import and export of cargoes are facilitated by nuclear localization and nuclear export sequences (NLS and NES respectively) that are recognized by transport factors collectively termed karyopherins (Kaps). The NLS of import cargoes (blue) is recognized either directly by an import karyopherin-β (Kap-β; salmon) or via an adapter karyopherin (Kap-α; light green). RanGTP (red) binding inside the nucleus leads to dissociation of the import complex. By contrast the assembly of a NES-cargo Kap-β export complex requires RanGTP binding (represented in blue yellow and red respectively). In the cytosol this export complex is dissociated by GTP hydrolysis which is catalyzed by Ran GTPase-activating protein (RanGAP; dark green) or Ran-binding protein 1 (RanBP1). Artwork by Joseph Alexander Erik W. Debler and André Hoelz.
The Structure of the Nuclear Pore Complex: Supplemental Video 3
A supplemental video from the 2011 review by André Hoelz Erik W. Debler and Günter Blobel "The Structure of the Nuclear Pore Complex" from the Annual Review of Biochemistry.
The transport of large cargoes (blue) is thought to require the dilation of the central channel of the NPC. Artwork by Joseph Alexander Erik W. Debler and André Hoelz.
The Structure of the Nuclear Pore Complex: Supplemental Video 4
A supplemental video from the 2011 review by André Hoelz Erik W. Debler and Günter Blobel "The Structure of the Nuclear Pore Complex" from the Annual Review of Biochemistry.
Inner nuclear membrane (INM) proteins are cotranslationally integrated into the endoplasmic reticulum membrane which is continuous with the outer nuclear membrane and then imported to the INM. Similar to the karyopherin-mediated transport in Movie 2 the transport of INM proteins is also dependent on the Ran cycle and karyopherins that likely travel through the central channel whereas the cargo protein is anchored in the membrane. INM proteins Kap-α Kap-β and RanGTP are illustrated in light purple light green brown and red respectively. Substantial structural changes within the NPC would be necessary to facilitate this transport event. Artwork by Joseph Alexander Erik W. Debler and André Hoelz.
The Extraction of 3D Shape in the Visual System of Human and Nonhuman Primates: Supplemental Video 1
A supplemental video from the 2011 review by Guy A. Orban "The Extraction of 3D Shape in the Visual System of Human and Nonhuman Primates" from the Annual Review of Neuroscience. Second order speed gradient portraying a ridge.
The Extraction of 3D Shape in the Visual System of Human and Nonhuman Primates: Supplemental Video 2
A supplemental video from the 2011 review by Guy A. Orban "The Extraction of 3D Shape in the Visual System of Human and Nonhuman Primates" from the Annual Review of Neuroscience. Second order speed gradient portraying a saddle.
The Extraction of 3D Shape in the Visual System of Human and Nonhuman Primates: Supplemental Video 3
A supplemental video from the 2011 review by Guy A. Orban "The Extraction of 3D Shape in the Visual System of Human and Nonhuman Primates" from the Annual Review of Neuroscience. Rotating random lines portraying a 3D wire figure.