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Literature DB >> 25346940

Inertial focusing cytometer with integrated optics for particle characterization.

Kenneth T Kotz¹, Anne C Petrofsky¹, Ramin Haghgooie¹, Robert Granier¹, Mehmet Toner¹, Ronald G Tompkins¹.

Abstract

Microfluidic inertial focusing has been shown as a simple and effective method to localize cells and particles within a flow cell for interrogation by an external optical system. To enable portable point of care optical cytometry, however, requires a reduction in the complexity of the large optical systems that are used in standard flow cytometers. Here, we present a new design that incorporates optical waveguides and focusing elements with an inertial focusing flow cell to make a compact robust cytometer capable of enumerating and discriminating beads, cells, and platelets.

Entities: Chemical Disease Species

Year: 2013 PMID： 25346940 PMCID： PMC4206911 DOI： 10.1142/S233954781350009X

Source DB: PubMed Journal: Technology (Singap World Sci)

30 in total

1. Ultra wide-field lens-free monitoring of cells on-chip.

Authors: Aydogan Ozcan; Utkan Demirci
Journal: Lab Chip Date: 2007-11-01 Impact factor: 6.799

2. High speed multi-frequency impedance analysis of single particles in a microfluidic cytometer using maximum length sequences.

Authors: Tao Sun; David Holmes; Shady Gawad; Nicolas G Green; Hywel Morgan
Journal: Lab Chip Date: 2007-06-08 Impact factor: 6.799

3. Equilibrium separation and filtration of particles using differential inertial focusing.

Authors: Dino Di Carlo; Jon F Edd; Daniel Irimia; Ronald G Tompkins; Mehmet Toner
Journal: Anal Chem Date: 2008-02-15 Impact factor: 6.986

4. Scattering detection using a photonic-microfluidic integrated device with on-chip collection capabilities.

Authors: Benjamin R Watts; Zhiyi Zhang; Chang Qing Xu; Xudong Cao; Min Lin
Journal: Electrophoresis Date: 2013-10-07 Impact factor: 3.535

5. Monolithic integration of microfluidic channels and optical waveguides in silica on silicon.

Authors: P Friis; K Hoppe; O Leistiko; K B Mogensen; J Hübner; J P Kutter
Journal: Appl Opt Date: 2001-12-01 Impact factor: 1.980

6. Flow cytometers using optical waveguides in place of lenses for specimen illumination and light collection.

Authors: H M Shapiro; M Hercher
Journal: Cytometry Date: 1986-03

7. Multi-wavelength microflow cytometer using groove-generated sheath flow.

Authors: Joel P Golden; Jason S Kim; Jeffrey S Erickson; Lisa R Hilliard; Peter B Howell; George P Anderson; Mansoor Nasir; Frances S Ligler
Journal: Lab Chip Date: 2009-03-31 Impact factor: 6.799

Review 8. Microfluidics and photonics for Bio-System-on-a-Chip: a review of advancements in technology towards a microfluidic flow cytometry chip.

Authors: Jessica Godin; Chun-Hao Chen; Sung Hwan Cho; Wen Qiao; Frank Tsai; Yu-Hwa Lo
Journal: J Biophotonics Date: 2008-10 Impact factor: 3.207

9. Two-parameter angular light scatter collection for microfluidic flow cytometry by unique waveguide structures.

Authors: Jessica Godin; Yu-Hwa Lo
Journal: Biomed Opt Express Date: 2010-11-22 Impact factor: 3.732

10. Formation and characterization of an ideal excitation beam geometry in an optofluidic device.

Authors: Benjamin R Watts; Thomas Kowpak; Zhiyi Zhang; Chang-Qing Xu; Shiping Zhu
Journal: Biomed Opt Express Date: 2010-09-14 Impact factor: 3.732

5 in total

Review 1. Inertial focusing in microfluidics.

Authors: Joseph M Martel; Mehmet Toner
Journal: Annu Rev Biomed Eng Date: 2014-05-29 Impact factor: 9.590