Yuki Moritani scite author profile

We consider a confined space molecular communication system, where molecules or information carrying particles are used to transfer information on a microfluidic chip. Considering that information-carrying particles can follow two main propagation schemes: passive transport, and active transport, it is not clear which achieves a better information transmission rate. Motivated by this problem, we compare and analyze both propagation schemes by deriving a set of analytical and mathematical tools to measure the achievable information rates of the on-chip molecular communication systems employing passive to active transport. We also use this toolbox to optimize design parameters such as the shape of the transmission area, to increase the information rate. Furthermore, the effect of separation distance between the transmitter and the receiver on information rate is examined under both propagation schemes, and a guidepost to design an optimal molecular communication setup and protocol is presented.

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Molecular communication: Harnessing biochemical materials to engineer biomimetic communication systems

Hiyama¹,

Moritani²

2010

Nano Communication Networks

117

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Biomolecular-motor-based autonomous delivery of lipid vesicles as nano- or microscale reactors on a chip

Hiyama

Moritani²,

Gojo

et al. 2010

Lab Chip

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We aimed to create an autonomous on-chip system that performs targeted delivery of lipid vesicles (liposomes) as nano- or microscale reactors using machinery from biological systems. Reactor-liposomes would be ideal model cargoes to realize biomolecular-motor-based biochemical analysis chips; however, there are no existing systems that enable targeted delivery of cargo-liposomes in an autonomous manner. By exploiting biomolecular-motor-based motility and DNA hybridization, we demonstrate that single-stranded DNA (ssDNA)-labeled microtubules (MTs), gliding on kinesin-coated surfaces, acted as cargo transporters and that ssDNA-labeled cargo-liposomes were loaded/unloaded onto/from gliding MTs without bursting at loading reservoirs/micropatterned unloading sites specified by DNA base sequences. Our results contribute to the development of an alternative strategy to pressure-driven or electrokinetic flow-based microfluidic devices.

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A Hybrid Hydrogel Biomaterial by Nanogel Engineering: Bottom‐Up Design with Nanogel and Liposome Building Blocks to Develop a Multidrug Delivery System

Sekine

Moritani²,

Ikeda-Fukazawa

et al. 2012

Adv Healthcare Materials

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New hybrid poly(ethylene glycol) (PEG) hydrogels crosslinked with both nanogels and nanogel-coated liposome complexes are obtained by Michael addition of the acryloyl group of a cholesterol-bearing pullulan (CHP) nanogel to the thiol group of pentaerythritol tetra(mercaptoethyl) polyoxyethylene. The nanogel-coated liposome complex is stably retained after gelation and the complexes are well dispersed in the hybrid gel. Microrheological measurements show that the strength and gelation time of the hybrid hydrogel can be controlled by changing the liposome:nanogel ratio. The hydrogel is gradually degraded by hydrolysis under physiological conditions. In this process, the nanogel is released first, followed by the nanogel-coated liposomes. Hybrid hydrogels that can incorporate various molecules into the nanogel and liposomes, and release them in a two-step controllable manner, represent a new functional scaffold capable of delivering multiple drugs, proteins or DNA.

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Direct integration of cell‐free‐synthesized connexin‐43 into liposomes and hemichannel formation

et al. 2010

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Proteoliposomes were directly prepared by synthesizing membrane proteins with the use of minimal protein synthesis factors isolated from Escherichia coli (the PURE system) in the presence of liposomes. Connexin‐43 (Cx43), which is a water‐insoluble integral membrane protein that forms a hexameric complex in membranes, was cotranslationally integrated with an essentially uniform orientation in liposomes. The addition of liposomes following protein expression (post‐translational presence of liposomes) did not lead to the integration of Cx43 into the liposome membranes. The amount of integrated Cx43 increased as the liposome concentration increased. The presence of liposomes did not influence the total amount of synthesized Cx43. The Cx43 integrated into the liposome membranes formed open membrane pores. These results indicate that the liposomes act in a chaperone‐like manner by preventing Cx43 from aggregating in solution, because of integration into the bilayer, and also by functionalization of the integrated Cx43 in the membrane. This is the first report that cell‐free‐synthesized water‐insoluble membrane protein is directly integrated with a uniform orientation as a functional oligomer into liposome membranes. This simple proteoliposome preparation procedure should be a valuable approach for structural and functional studies of membrane proteins. Structured digital abstract http://mint.bio.uniroma2.it/mint/search/interaction.do?interactionAc=MINT-7900670: Cx‐43 (uniprotkb:http://www.uniprot.org/uniprot/P08050) and Cx‐43 (uniprotkb:http://www.uniprot.org/uniprot/P08050) bind (http://www.ebi.ac.uk/ontology-lookup/?termId=MI:0407) by cross‐linking study (http://www.ebi.ac.uk/ontology-lookup/?termId=MI:0030)

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Yuki Moritani

On-Chip Molecular Communication: Analysis and Design

Molecular communication: Harnessing biochemical materials to engineer biomimetic communication systems

Biomolecular-motor-based autonomous delivery of lipid vesicles as nano- or microscale reactors on a chip

A Hybrid Hydrogel Biomaterial by Nanogel Engineering: Bottom‐Up Design with Nanogel and Liposome Building Blocks to Develop a Multidrug Delivery System

Direct integration of cell‐free‐synthesized connexin‐43 into liposomes and hemichannel formation

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