Browse > Article
http://dx.doi.org/10.3795/KSME-A.2008.32.10.844

Bio-inspired Cell Deformability Monitoring Chips Based on Strain Dependent Digital Lysis Rates  

Youn, Se-Chan (한국과학기술원 바이오시스템학과, 디지털나노구동연구단)
Lee, Dong-Woo (한국과학기술원 바이오시스템학과, 디지털나노구동연구단)
Cho, Young-Ho (한국과학기술원 바이오시스템학과 및 기계공학과, 디지털나노구동연구단)
Publication Information
Transactions of the Korean Society of Mechanical Engineers A / v.32, no.10, 2008 , pp. 844-849 More about this Journal
Abstract
We present a novel cell deformability monitoring chip based on the digitally measured cell lysis rate which is dependent on the areal strain of the cell membrane. This method offers simple cell deformability monitoring by automated high-throughput testing system. We suggest the filter design considering the areal strain imposed on the cell membrane passing through the filter array having gradually increased orifice length. In the experiment using erythrocytes, we characterized the cell deformability in terms of average fracture areal strain which was $0.24{\pm}0.014\;and\;0.21{\pm}0.002$ for normal and chemically treated erythrocytes, respectively. We also verified that the areal strain of 0.15 effectively discriminates the deformability difference of normal and chemically treated erythrocytes, which can be applied to the clinical situation. We compared the lysis rates and their difference for the samples from different donors and found that the present chips can be commonly used without any calibration process. The experimental results demonstrate the simple structure and high performance of the present cell deformability monitoring chips, applicable to simple and cost-effective cell aging process monitoring.
Keywords
Cell Deformability; Erythrocyte Deformability; Cell Lysis; Red Blood Cell;
Citations & Related Records

Times Cited By SCOPUS : 0
연도 인용수 순위
  • Reference
1 Ogura, E., Abatti, P. J. and Moriizumi, T., 1991, "Measurement of Human Red Blood Cell Deformability Using a Single Micropore on a Thin $Si_3N_4$ Film," IEEE Transactions on Biomedical Engineering, Vol. 38, pp. 721-726   DOI   ScienceOn
2 Abatti, P., 1997, "Determination of the Red Blood Cell Ability to Traverse Cylindrical Pores," IEEE Transactions on Biomedical Engineering, Vol. 44, pp. 209-212   DOI   ScienceOn
3 Allen, T., 1990, Particles Size Measurements, Chapman and Hall
4 Mokken, F. Ch., Kedaria, M., Henny, Ch. P., Harderman, M.R. and Gelb, A.W., 1992, "The Clinical Importance of Erythrocyte Deformability, a Hemorheological Parameter," Ann. Hematology, Vol. 64, pp. 113-122   DOI
5 Caimi, G. and Presti, R. Lo, 2004, "Techniques to Evaluate Erythrocyte Deformability in Diabetes Mellitus," Acta Diabetol, Vol. 41, pp. 99-103   DOI   ScienceOn
6 Waugh, R. and Evans, E., 1979, "Thermoelasticity of Red Blood Cell Membrane," Biophys. J., Vol. 26, pp. 115-132   DOI   ScienceOn
7 Shin, S., 2004, "Laser-Diffraction Slit Rheometer to Measure Red Blood Cell Deformability," Review of the Scientific Instruments, Vol. 75, pp. 559-561   DOI   ScienceOn
8 Dobbe, J.G.G., Streekstra, G.J., Hardeman, M.R., Ince, C. and Grimbergen, C.A., 2002, "The Measurement of the Distribution of Red Blood-Cell Deformability Using an Automated Rheoscope," Cytometry, Vol. 50, pp. 313-325   DOI   ScienceOn
9 Stanley-Wood, N. G. and Lines, R. W., 1992, Particle Size Analysis, The Royal Society of Chemistry
10 Zou, J. and Wong, P.Y., 2004, "Thermal Effects in Plasma Treatment of Patterned PDMS for Bonding Stacked Channels," Materials Research Society Symposium Proceedings, pp. 125-130
11 Schwarts, R.S., Madsen, J.W., Rybicki, A.C. and Nagel, R.L., 1991, "Oxidation of Spectrin and Deformability Defects in Diabetic Erythrocytes," Diabetes, Vol. 30, pp. 701-708   DOI   ScienceOn
12 Hanss, M. F., Guillet, R., Vassauk, D. and Hanss, G., 1989, "Apparatus and Process for Determining the. Deformability of the Red Corpuscles in the Blood," U.S. Patent 4835457, May 30
13 Starzyk, D., Korbut, R. and Gryglewski, R. J., 1999, "Effects of Nitric Oxide and Prostacyclin on. Deformability and Aggregability of Red Blood Cells of Rats ex Vivo and in Vitro," J. Physiol. Pharmacol. Vol. 50, pp. 629-637