7 research outputs found
Biomimetic Engineering of a Generic Cell-on-Membrane Architecture by Microfluidic Engraving for On-Chip Bioassays
We develop a biomimetic cell-on-membrane architecture
in close-volume
format which allows the interfacial biocompatibility and the reagent
delivery capability for on-chip bioassays. The key concept lies in
the microfluidic engraving of lipid membranes together with biological
cells on a supported substrate with topographic patterns. The simultaneous
engraving process of a different class of fluids is promoted by the
front propagation of an air–water interface inside a flow-cell.
This highly parallel, microfluidic cell-on-membrane approach opens
a door to the natural biocompatibility in mimicking cellular stimuli-response
behavior essential for diverse on-chip bioassays that can be precisely
controlled in the spatial and temporal manner
Self-Organized Anisotropic Wrinkling of Molecularly Aligned Liquid Crystalline Polymer
Anisotropic wrinkling which utilizes the anisotropic
nature of
liquid crystalline polymer (LCP) is demonstrated as a means of physical
self-assembly to produce periodic microstructures. Through the plasma
treatment on the molecularly aligned LCP film surface, one-dimensionally
ordered wrinkle pattern was spontaneously formed on glass substrates
without employing external thin-film deposition or prestrain control
of the system. Experimental results indicate that the directionality
of the wrinkle pattern can be tailored by the structural ordering
of LCP molecules in the bilayer system of a hard skin layer on a soft
substrate. Studies on process variables, such as the plasma treatment
time and the film thickness, were conducted to figure out the effect
on the wrinkling morphology. Due to its spatial periodicity over a
large area and undemanding requirement of the process, this approach
can be a candidate for the microfabrication in various applications
Self-Organized Anisotropic Wrinkling of Molecularly Aligned Liquid Crystalline Polymer
Anisotropic wrinkling which utilizes the anisotropic
nature of
liquid crystalline polymer (LCP) is demonstrated as a means of physical
self-assembly to produce periodic microstructures. Through the plasma
treatment on the molecularly aligned LCP film surface, one-dimensionally
ordered wrinkle pattern was spontaneously formed on glass substrates
without employing external thin-film deposition or prestrain control
of the system. Experimental results indicate that the directionality
of the wrinkle pattern can be tailored by the structural ordering
of LCP molecules in the bilayer system of a hard skin layer on a soft
substrate. Studies on process variables, such as the plasma treatment
time and the film thickness, were conducted to figure out the effect
on the wrinkling morphology. Due to its spatial periodicity over a
large area and undemanding requirement of the process, this approach
can be a candidate for the microfabrication in various applications
Lipid Membrane Deformation Accompanied by Disk-to-Ring Shape Transition of Cholesterol-Rich Domains
During
vesicle budding or endocytosis, biomembranes undergo a series
of lipid- and protein-mediated deformations involving cholesterol-enriched
lipid rafts. If lipid rafts of high bending rigidities become confined
to the incipient curved membrane topology such as a bud-neck interface,
they can be expected to reform as ring-shaped rafts. Here, we report
on the observation of a disk-to-ring shape morpho-chemical transition
of a model membrane in the absence of geometric constraints. The raft
shape transition is triggered by lateral compositional heterogeneity
and is accompanied by membrane deformation in the vertical direction,
which is detected by height-sensitive fluorescence interference contrast
microscopy. Our results suggest that a flat membrane can become curved
simply by dynamic changes in local chemical composition and shape
transformation of cholesterol-rich domains
Visualization 3: F-number matching method in light field microscopy using an elastic micro lens array
Reconstructed perspective views (R=2). Originally published in Optics Letters on 15 June 2016 (ol-41-12-2751
Lipid Membrane Deformation Accompanied by Disk-to-Ring Shape Transition of Cholesterol-Rich Domains
During
vesicle budding or endocytosis, biomembranes undergo a series
of lipid- and protein-mediated deformations involving cholesterol-enriched
lipid rafts. If lipid rafts of high bending rigidities become confined
to the incipient curved membrane topology such as a bud-neck interface,
they can be expected to reform as ring-shaped rafts. Here, we report
on the observation of a disk-to-ring shape morpho-chemical transition
of a model membrane in the absence of geometric constraints. The raft
shape transition is triggered by lateral compositional heterogeneity
and is accompanied by membrane deformation in the vertical direction,
which is detected by height-sensitive fluorescence interference contrast
microscopy. Our results suggest that a flat membrane can become curved
simply by dynamic changes in local chemical composition and shape
transformation of cholesterol-rich domains
Visualization 2: F-number matching method in light field microscopy using an elastic micro lens array
Reconstructed perspective views (R=1). Originally published in Optics Letters on 15 June 2016 (ol-41-12-2751