• Title/Summary/Keyword: BioMEMS

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A Simulation Study on Fluid Flowing in Micro Pump (Simulation을 통한 미세 PUMP 내에서의 유체흐름 연구)

  • 김용천;김미진;김진명;김진현;류근걸
    • Journal of the Korea Academia-Industrial cooperation Society
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    • v.3 no.4
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    • pp.233-239
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    • 2002
  • The technology of joining BT (Biotechnology) with NT (Nanotechnology) must be rapidly arranged in 21c. Specially, the technical value is important more and more since the research about MEMS, which synthesizes BT and NT, is variously proceeding on the wide fields. This study by simulation shows the Fluid-Flow within micro Pump used in Bio-MEMS technology through Fluent Program. Namely, this experiment shows the most suitable external conditions and Pump Model within micro Pump by observing the flow of fluids as to the conditions of pressure, temperature and Model when the Fluid flows within micro Pump. We saw the variousness of pressure and temperature as to the existence of Chamber through examining by reference of Fluid-Flow. In the case of the existence of Chamber, the variousness of pressure and temperature is less than in the case of the non-existence of Chamber. By this simulation, we know that the Pump, which has a Chamber, affects the Fluid-Flow less than that. So we can say that it is necessary for us to design the Pump which has a Chamber.

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Flexible Modules Using MEMS Technology (MEMS 기술을 이용한 Flexible Module)

  • 김용준;황은수;김용호;이태희
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2003.06a
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    • pp.223-227
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    • 2003
  • A new flexible electronic packaging technology and its medical applications are presented. Conventional silicon chips and electronic modules can be considered as "mechanically rigid box." which does not bend due to external forces. This mechanically rigid characteristic prohibits its applications to wearable systems or bio-implantable devices. Using current MEMS (Microelectromechanical Systems) technology. a surface micromachined flexible polysilicon sensor array and flexible electrode array fer neural interface were fabricated. A chemical thinning technique has been developed to realize flexible silicon chip. To combine these techniques will result in a realization of truly flexible sensing modules. which are suitable for many medical applications.

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BioMEMS-EARLY DISEASE DETECTION (BioMEMS 기반의 조기 질병 진단 기술에 관한 연구)

  • Singh, Kanika;Kim, Kyung-Chun
    • Proceedings of the KSME Conference
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    • 2007.05b
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    • pp.2781-2784
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    • 2007
  • Early detection of a disease is important to tackle treatment issues in a better manner. Several diagnostic techniques are in use, these days; for such purpose and tremendous research is going on to develop newer and newer methods. However, more work is required to be done to develop cheap and reliable early detection techniques. Micro-fluidic chips are also playing key role to deliver new devices for better health care. The present study focuses on a review of recent developments in the interrogation of different techniques and present state-of-the-art of microfluidic sensor for better, quick, easy, rapid, early, inexpensive and portable POCT (Point of Care testing device) device for a particular study, in this case, bone disease called osteoporosis. Some simulations of the microchip are also made to enable feasibility of the development of a blood-chip-based system. The proposed device will assist in early detection of diseases in an effective and successful manner.

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Flow Visualization in Microchannel Using Confocal Scanning Microscope (공초점 주사현미경을 통한 미세 유로에서의 유동 가시화)

  • Chang Jun Keun;Park Sung-Jin;Kim Jung Kyung;Han Dong Chul
    • Journal of the Korean Society of Visualization
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    • v.1 no.1
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    • pp.28-33
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    • 2003
  • This paper presents the visualization method in which 3-dimensional(3D) microchannel flow can be detected using a confocal scanning microscope. By soft-lithography, we fabricated various Bio-MEMS(Micro Electro-Mechanical System) devices such as a disposable microchip for a flow cytometer and a micro-mixer, which have 3D structures. Injecting aqueous fluorescent solution in the microfluidic devices, we measured the flow in a steady state by the confocal scanning microscope. At first, we explain the principle of the confocal scanning microscope. And then we show the results from 3D visualization of microscopic flow structures using the confocal scanning microscope.

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Cross-sectional radiation type micromixer to mixed interface using PZT (PZT를 이용한 계면 교차 방향 방사형 마이크로믹서)

  • Heo, Pil-Woo;Kim, Deok-Jong;Kim, Jae-Yun;Park, Sang-Jin;Yun, Eui-Soo;Koh, Kwang-Sik
    • 유체기계공업학회:학술대회논문집
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    • 2003.12a
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    • pp.121-125
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    • 2003
  • Micromixer plays an important role in Bio-MEMS or ${\mu}-TAS$. Mixing is generally generated by turbulence and interdiffusion of two fluids. Because of low Reynolds number(Re << 2000) in ${\mu}-channel$, it is difficult to generate turbulence, so mixing mainly depends on interdiffusion. Thus long channel distance is required to mix two different fluids. To reduce the channel length required for mixing, we propose the a new active ${\mu}-mixer$ that two fluids are effectively mixed in ${\mu}-channel$ by the ultrasonic wave which is generated by PZT. The ultrasonic wave is radiated into a chamber in the cross-section directional direction to interface with the two fluids. The two fluids are positioned one on top of the other. Mixing state is measured by the changing of color due to the reaction of NaOH and phenolphtalein.

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BioMEMS 기술을 이용한 바이오 샘플의 정량적 분석방법

  • Kim, Jun-Won;Kim, Ho-Jin
    • Journal of the KSME
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    • v.52 no.8
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    • pp.37-40
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    • 2012
  • 이 글에서는 DNA, 단백질 등과 같은 생체분자(biomolecule)뿐만 아니라 세포 수준에서의 정량적 분석(quantitative analysis)을 위한 강력한 도구로서 마이크로어레이 기반의 바이오멤스 기술에 대해 소개하고자 한다.

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Cross-sectional Radiation Type Mixer into the Boundary Surface using PMN-PT for Micromixing (마이크로믹서에의 응용을 위해 PMN-PT를 이용한 경계면과 수직방향 방사형 믹서)

  • Heo Pil Woo;Yoon Eui Soo;Kho Kwang Sik
    • Journal of the Institute of Electronics Engineers of Korea SC
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    • v.42 no.1
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    • pp.33-37
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    • 2005
  • A micromixer plays an important role in Bio-MEMS or μ-TAS. Mixing is generally generated by turbulence and interdiffusion of two fluids. Because of low Reynolds number values (Re << 2000) within microchannels, it is difficult to generate turbulence, and consequently mixing mainly depends on interdiffusion. So, channel distance is often prohibitively long to mix two different fluids properly. To reduce this mixing length, we proposed a new mixer for micromixing in which two fluids were effectively mixed by an ultrasonic wave generated by PMN-PT. The ultrasonic wave was radiated into a chamber In the cross-sectional direction into the boundary surface formed by two fluids. The two fluids were positioned one on top of the other. The mixing state was measured by observing the color of samples due to the reaction of NaOH and phenolphthalein.

마이크로머시닝 기술의 의학 및 생물학 응용

  • 장준근;김용권
    • The Magazine of the IEIE
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    • v.24 no.10
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    • pp.63-72
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    • 1997
  • Application of MEMS to biologic system mainly categorized into bio-electronics and micro-medical systems, Bio-electronics concerns on the biocompatible electronic device, in-vivo sensors, the sensors based on biological materials, biological materials for electronics and optics, the concepts and materials Inspired by biology and useful for electronics, the algorithm inspired by biology, artificial sense, and the biologic-inorganic hybrids. Micro-medical systems are utilited into the drug delivery systems, micro patient monitoring systems, micro prosthesis and artificial organs, cardiology related prothesis, analysis systems, and the minimal invasive surgery tools based on the m icrom achining technology.

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Structure optimization and characterization of a microbolometer for a CO2 detector (이산화탄소 감지소자를 위한 마이크로볼로미터 구조 최적화 및 특성연구)

  • Seo, Ho-Won;Kim, Tae-Geun;Moon, Sung
    • Journal of Sensor Science and Technology
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    • v.17 no.1
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    • pp.75-80
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    • 2008
  • In this work, we optimized a microbolometer for application of a $CO_2$ detector by using MEMS technology. We fabricated a stable thermal isolation structure by varying the lengths of supporting legs which affect bolometer performance. We could fabricate more stable thermal isolation structure for the microbolometer through the results of ANSYS simulations, and minimize the fabrication processes by using bulk micromachining to use a $CO_2$ detector. The microbolometer shows a detectivity of $2.5{\times}109$ cmHz$^{1/2}$/W at a chopper frequency of 8 Hz and a bias current of $6.25\;{\mu}A$ with a vacuum package of about $3.0{\times}10.3$ torr. Therefore, we put to conclusion that the microbolometer optimized in this experiment could be useful for the application of a $CO_2$ detector.

Development of a Novel Noncontact ECG Electrode by MEMS Fabrication Process

  • Mathias, Dakurah Naangmenkpeong;Park, Jaesoon;Kim, Eungbo;Joung, Yeun-Ho
    • Transactions on Electrical and Electronic Materials
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    • v.17 no.3
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    • pp.150-154
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    • 2016
  • Contact electrodes pose threats like inflammation, metal poisoning, and allergic reaction to the user during long term ECG procedure. Therefore, we present a novel noncontact electrocardiographic electrode designed through microelectromechanical systems (MEMS) process. The proposed ECG electrode consists of small inner and large outer circular copper plates separated by thin insulator. The inner plate enables capacitive transduction of bio-potential variations on a subject’s chest into a voltage that can be processed by a signal processing board, whereas the outer plate shields the inner plate from environmental electromagnetic noise. The electrode lead wires are also coaxially designed to prevent cables from coupling to ground or electronic devices. A prototype ECG electrode has an area of about 2.324 cm2, is very flexible and does not require power to operate. The prototype ECG electrode could measure ECG at about 500 um distance from the subject’s chest.