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Literature DB >> 26459443

Point-of-care (POC) devices by means of advanced MEMS.

Stanislav L Karsten¹, Mehmet C Tarhan², Lili C Kudo³, Dominique Collard², Hiroyuki Fujita⁴.

Abstract

Microelectromechanical systems (MEMS) have become an invaluable technology to advance the development of point-of-care (POC) devices for diagnostics and sample analyses. MEMS can transform sophisticated methods into compact and cost-effective microdevices that offer numerous advantages at many levels. Such devices include microchannels, microsensors, etc., that have been applied to various miniaturized POC products. Here we discuss some of the recent advances made in the use of MEMS devices for POC applications.

Entities: CellLine Chemical Disease Species

Mesh：

Year: 2015 PMID： 26459443 PMCID： PMC4607928 DOI： 10.1016/j.talanta.2015.04.032

Source DB: PubMed Journal: Talanta ISSN： 0039-9140 Impact factor: 6.057

68 in total

1. Portable filter-based microdevice for detection and characterization of circulating tumor cells.

Authors: Henry K Lin; Siyang Zheng; Anthony J Williams; Marija Balic; Susan Groshen; Howard I Scher; Martin Fleisher; Walter Stadler; Ram H Datar; Yu-Chong Tai; Richard J Cote
Journal: Clin Cancer Res Date: 2010-09-28 Impact factor: 12.531

2. Design of a front-end integrated circuit for 3D acoustic imaging using 2D CMUT arrays.

Authors: Ihsan Ciçek; Ayhan Bozkurt; Mustafa Karaman
Journal: IEEE Trans Ultrason Ferroelectr Freq Control Date: 2005-12 Impact factor: 2.725

3. Monitoring the dynamics of primary T cell activation and differentiation using long term live cell imaging in microwell arrays.

Authors: Irina Zaretsky; Michal Polonsky; Eric Shifrut; Shlomit Reich-Zeliger; Yaron Antebi; Guy Aidelberg; Nir Waysbort; Nir Friedman
Journal: Lab Chip Date: 2012-12-07 Impact factor: 6.799

4. Handheld ultrahigh speed swept source optical coherence tomography instrument using a MEMS scanning mirror.

Authors: Chen D Lu; Martin F Kraus; Benjamin Potsaid; Jonathan J Liu; Woojhon Choi; Vijaysekhar Jayaraman; Alex E Cable; Joachim Hornegger; Jay S Duker; James G Fujimoto
Journal: Biomed Opt Express Date: 2013-12-20 Impact factor: 3.732

5. Label-free viscosity measurement of complex fluids using reversal flow switching manipulation in a microfluidic channel.

Authors: Yang Jun Kang; Jeongeun Ryu; Sang-Joon Lee
Journal: Biomicrofluidics Date: 2013-07-26 Impact factor: 2.800

6. A microfluidic device for simultaneous measurement of viscosity and flow rate of blood in a complex fluidic network.

Authors: Yang Jun Kang; Eunseop Yeom; Sang-Joon Lee
Journal: Biomicrofluidics Date: 2013-10-01 Impact factor: 2.800

7. Capacitive micromachined ultrasonic transducers for medical imaging and therapy.

Authors: Butrus T Khuri-Yakub; Omer Oralkan
Journal: J Micromech Microeng Date: 2011-05 Impact factor: 1.881

8. High-purity and label-free isolation of circulating tumor cells (CTCs) in a microfluidic platform by using optically-induced-dielectrophoretic (ODEP) force.

Authors: Song-Bin Huang; Min-Hsien Wu; Yen-Heng Lin; Chia-Hsun Hsieh; Chih-Liang Yang; Hung-Chih Lin; Ching-Ping Tseng; Gwo-Bin Lee
Journal: Lab Chip Date: 2013-04-07 Impact factor: 6.799

Point-of-care (POC) devices by means of advanced MEMS.

1. Portable filter-based microdevice for detection and characterization of circulating tumor cells.

2. Design of a front-end integrated circuit for 3D acoustic imaging using 2D CMUT arrays.

3. Monitoring the dynamics of primary T cell activation and differentiation using long term live cell imaging in microwell arrays.

4. Handheld ultrahigh speed swept source optical coherence tomography instrument using a MEMS scanning mirror.

5. Label-free viscosity measurement of complex fluids using reversal flow switching manipulation in a microfluidic channel.

6. A microfluidic device for simultaneous measurement of viscosity and flow rate of blood in a complex fluidic network.

7. Capacitive micromachined ultrasonic transducers for medical imaging and therapy.

8. High-purity and label-free isolation of circulating tumor cells (CTCs) in a microfluidic platform by using optically-induced-dielectrophoretic (ODEP) force.

9. On-line blood viscosity monitoring in vivo with a central venous catheter, using electrical impedance technique.

Review 10. Recent advances in paper-based sensors.

1. Integrated Artificial Intelligence Approaches for Disease Diagnostics.

Review 2. Small-volume detection: platform developments for clinically-relevant applications.