libtriada.blogg.se - Konishi tai sabaki

Non-equilibrium assembly of microtubules: from molecules to autonomous chemical robots. Design and development of nanoimprint-enabled structures for molecular motor devices. Frida W Lindberg, Till Korten, Anette Löfstrand, Mohammad A Rahman, Mariusz Graczyk, Alf Månsson, Heiner Linke, Ivan Maximov.IEEE Journal of Biomedical and Health Informatics 2019, 23 Deep Learning: Current and Emerging Applications in Medicine and Technology. Collective dynamics of microtubule-based 3D active fluids from single microtubules. Design of Active Nanosystems Incorporating Biomolecular Motors. Toward Intelligent Molecular Machines: Directed Motions of Biological and Artificial Molecules and Assemblies. A Model of Polymeric Nanopropulsion Engine. Toward Single Molecule Detection of Staphylococcal Enterotoxin B: Mobile Sandwich Immunoassay on Gliding Microtubules. Sapsford, Amy Szuchmacher Blum and Banahalli R. Comparing Guiding Track Requirements for Myosin- and Kinesin-Powered Molecular Shuttles. Takahiro Nitta, Akihito Tanahashi, Yu Obara, Motohisa Hirano, Maria Razumova, Michael Regnier and Henry Hess.Biomolecular-Motor-Based Nano- or Microscale Particle Translocations on DNA Microarrays. Satoshi Hiyama, Riho Gojo, Tomohiro Shima, Shoji Takeuchi and Kazuo Sutoh.Improved Surface-Patterned Platinum Microelectrodes for the Study of Exocytotic Events. Khajak Berberian, Kassandra Kisler, Qinghua Fang and Manfred Lindau.Journal of the American Chemical Society 2010, 132 Resolving Rotational Motions of Nano-objects in Engineered Environments and Live Cells with Gold Nanorods and Differential Interference Contrast Microscopy. Gufeng Wang, Wei Sun, Yong Luo, and Ning Fang.Journal of the American Chemical Society 2011, 133 Microbots Swimming in the Flowing Streams of Microfluidic Channels. Orienting Actin Filaments for Directional Motility of Processive Myosin Motors. Jinzhou Yuan, Anand Pillarisetti, Yale E.

Colocalization of Quantum Dots by Reactive Molecules Carried by Motor Proteins on Polarized Microtubule Arrays. Kazuya Fujimoto, Masuto Kitamura, Masatoshi Yokokawa, Isaku Kanno, Hidetoshi Kotera, and Ryuji Yokokawa.Molecular Motor-Powered Shuttles along Multi-walled Carbon Nanotube Tracks.

Aurélien Sikora, Javier Ramón-Azcón, Kyongwan Kim, Kelley Reaves, Hikaru Nakazawa, Mitsuo Umetsu, Izumi Kumagai, Tadafumi Adschiri, Hitoshi Shiku, Tomokazu Matsue, Wonmuk Hwang, and Winfried Teizer.

Highly-Efficient Guiding of Motile Microtubules on Non-Topographical Motor Patterns.

Cordula Reuther, Matthäus Mittasch, Sundar R.

Controlled Surface Silanization for Actin-Myosin Based Nanodevices and Biocompatibility of New Polymer Resists. Rahman, Aseem Salhotra, Hideyo Takatsuki, Sören Jeppesen, Heiner Linke, Alf Månsson. Guided by Light: Optical Control of Microtubule Gliding Assays. Katrukha, Mathijs Vleugel, Maurits Kok, Marileen Dogterom, Anna Akhmanova, Lukas C. Microtubule Detachment in Gliding Motility Assays Limits the Performance of Kinesin-Driven Molecular Shuttles. This article is cited by 119 publications. Because adsorbed kinesin supports motility on top and bottom surfaces of the guiding channels, this guiding mechanism may serve as a first step toward the development of three-dimensional architectures. Microtubules move unencumbered in the undercut, suggesting applications for nanofluidic systems and for in vitro motility assays mimicking the restricted environment characteristic of intracellular transport. This new wall geometry consists of an undercut 200 nm high at the bottom of the channel wall fabricated by image reversal photolithography using AZ5214 photoresist. While it was thought that efficient guiding along these tracks requires a combination of surface chemistry and topography, we show here that channel-like tracks with a particular wall geometry can be created to efficiently guide microtubules in the absence of selectively adsorbed motor proteins. Specifically, we utilize functionalized microtubules as shuttles, which may be transported by kinesin motor proteins along photolithographically defined tracks on a surface. Molecular shuttles represent a nanoscale transport system driven by biomolecular motors that permits the transport of molecular cargo under user-control and along predefined paths. The integration of active transport into nanodevices greatly expands the scope of their applications.