Development of micro-vibrating flow pumps using MEMS technologies

Osman, Osman Omran; Shintaku, Hirofumi

doi:10.1007/s10404-012-0988-5

Cited by 12 publications

(6 citation statements)

References 31 publications

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“…Recent progress in microfabrication technology has expanded the application of biomedical devices [3][4][5]. Several microdevices that mimic the mechanical cochlear system have been proposed to implement a cochlea-like frequency analyzer [6][7][8][9][10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Electrically Evoked Auditory Brainstem Response by Using Bionic Auditory Membrane in Guinea Pigs

Shintaku

Inaoka

Nakagawa

et al. 2013

JBSE

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Here, we report the measurement of an eABR (electrically evoked auditory brainstem response) by using a custom-developed BAM (bionic auditory membrane) for a novel artificial cochlear system. The BAM is an acoustic sensor designed as a trapezoidal and flexible membrane made of a piezoelectric material to convert acoustic waves to electrical signals with frequency selectivity. The signal from the BAM was used as an electrical source to stimulate the auditory nerves in a cochlea. The stimulating characteristics were investigated by measuring the eABR in guinea pigs. The results showed that the developed system could realize the perception of peak sound pressure levels and frequency of the acoustic wave. Consequently, we accumulated fundamental knowledge for developing a fully implantable artificial cochlea based on the BAM.

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Section: Introductionmentioning

confidence: 99%

Electrically Evoked Auditory Brainstem Response by Using Bionic Auditory Membrane in Guinea Pigs

Shintaku

Inaoka

Nakagawa

et al. 2013

JBSE

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“…Unlike flow through a microchannel, where hydrodynamic transition from laminar to turbulent flow occurs at relatively high Reynolds numbers (Re), a complex flow transition in confined micropin arrays triggers unstable flow phenomena even at low Re. The understanding of the fluid dynamics in micro-total analysis systems (lTAS) and in fluid based microelectromechanical systems (MEMS) relies on the advances in microscale flow visualization and characterization to improve the device efficiency (Osman et al 2012). Also within the growing field of lab-on-chip applications it is important to understand the detailed flow distribution in microchannel networks (Gunther and Jensen 2006).…”

Section: Introductionmentioning

confidence: 99%

Vortex shedding from confined micropin arrays

Renfer

Tiwari

Meyer

et al. 2013

Microfluid Nanofluid

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The hydrodynamics in microcavities populated with cylindrical micropins was investigated using dynamic pressure measurements and fluid pathline visualization. Pressure signals were Fourier-analyzed to extract the flow fluctuation frequencies, which were in the kHz range for the tested flow Reynolds numbers (Re) of up to 435. Three different sets of flow dependent characteristic frequencies were identified, the first due to vortex shedding, the second due to lateral flow oscillation and the third due to a transition between these two flow regimes. These frequencies were measured at different locations along the chip (e.g. inlet, middle and outlet). It is established that vortex shedding initiates at the outlet and then travels upstream with increase in Re. The pathline visualization technique provided direct optical access to the flow field without any intermediate post-processing step and could be used to interpret the frequencies determined through pressure measurements. Microcavities with different micropin height-to-diameter aspect ratios and pitch-to-diameter ratios were tested. The tests confirmed an increase in the Strouhal number (associated with the vortex shedding) with increased confinement (decrease in the aspect ratio or the pitch), in agreement with macroscale measurements. The compact nature of the microscale geometry tested, and the measurement technique demonstrated, readily enabled us to investigate the flow past 4,420 pins with various degrees of confinements; this makes the measurements performed and the techniques developed here an important tool for investigating large arrays of similar objects in a flow field.

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“…Only recently have Liu et al [40] proposed using a 3D extrusion printer to fabricate artificial magnetic cilia with high aspect ratios that are based on PDMS and iron particles. An actuation concept somewhat related to artificial cilia was presented in [41]: A PDMS composite-based cantilever-like structure is fixed to a wall of a microchannel with a slit orifice downstream. Because of the vibrational motion of the valve membrane, the slit orifice is designed to make the flow asymmetric; a net flow in the order of ll/min is thus induced in the microfluidic channel (Fig.…”

Section: Pdms Composite Actuatorsmentioning

confidence: 99%

Stimulus-active polymer actuators for next-generation microfluidic devices

Hilber

2016

Appl. Phys. A

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Microfluidic devices have not yet evolved into commercial off-the-shelf products. Although highly integrated microfluidic structures, also known as lab-on-a-chip (LOC) and micrototal-analysis-system (lTAS) devices, have consistently been predicted to revolutionize biomedical assays and chemical synthesis, they have not entered the market as expected. Studies have identified a lack of standardization and integration as the main obstacles to commercial breakthrough. Soft microfluidics, the utilization of a broad spectrum of soft materials (i.e., polymers) for realization of microfluidic components, will make a significant contribution to the proclaimed growth of the LOC market. Recent advances in polymer science developing novel stimulus-active soft-matter materials may further increase the popularity and spreading of soft microfluidics. Stimulus-active polymers and composite materials change shape or exert mechanical force on surrounding fluids in response to electric, magnetic, light, thermal, or water/solvent stimuli. Specifically devised actuators based on these materials may have the potential to facilitate integration significantly and hence increase the operational advantage for the end-user while retaining costeffectiveness and ease of fabrication. This review gives an overview of available actuation concepts that are based on functional polymers and points out promising concepts and trends that may have the potential to promote the commercial success of microfluidics.

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Development of micro-vibrating flow pumps using MEMS technologies

Cited by 12 publications

References 31 publications

Electrically Evoked Auditory Brainstem Response by Using Bionic Auditory Membrane in Guinea Pigs

Electrically Evoked Auditory Brainstem Response by Using Bionic Auditory Membrane in Guinea Pigs

Vortex shedding from confined micropin arrays

Stimulus-active polymer actuators for next-generation microfluidic devices

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