Detection of adsorbed cytochrome c on hydroxyapatite thick films using a microwave sensor

1.Koutsopoulos, S., Synthesis and characterization of hydroxyapatite crystals: A review study on the analytical methods. Journal of Biomedical Materials Research, 2002. 62(4): p. 600-612. Search in Google Scholar

2.Tofail, S., et al., Direct and ultrasonic measurements of macroscopic piezoelectricity in sintered hydroxyapatite. Journal of Applied Physics, 2009. 105(6): p. 064103. Search in Google Scholar

3.Lang, S.B., et al., Pyroelectric, piezoelectric, and photoeffects in hydroxyapatite thin films on silicon. Applied Physics Letters, 2011. 98(12): p. 123703-3. Search in Google Scholar

4.Tofail, S., et al., Pyroelectric surface charge in hydroxyapatite ceramics. Journal of Applied Physics, 2009. 106(10): p. 106104. Search in Google Scholar

5.Robin, S., et al., Charge Specific Protein Placement at Submicrometer and Nanometer Scale by Direct Modification of Surface Potential by Electron Beam. Langmuir, 2011. 27(24): p. 14968-14974. Search in Google Scholar

6.Lampin, M., et al., Correlation between substratum roughness and wettability, cell adhesion, and cell migration. Journal of biomedical materials research, 1997. 36(1): p. 99-108. Search in Google Scholar

7.Rechendorff, K., et al., Enhancement of Protein Adsorption Induced by Surface Roughness. Langmuir, 2006. 22(26): p. 10885-10888. Search in Google Scholar

8.Dorozhkin, S.V., Bioceramics of calcium orthophosphates. Biomaterials, 2010. 31(7): p. 1465- 1485. Search in Google Scholar

9.Korostynska, O., et al. High temperature induced pyroelectricity in screen-printed Hydroxyapatite thick films. in Electrets (ISE), 2011 14th International Symposium on. 2011. IEEE. Search in Google Scholar

10.Konaka, T., et al., Relative permittivity and dielectric loss tangent of substrate materials for high-T c superconducting film. Journal of Superconductivity, 1991. 4(4): p. 283-288. Search in Google Scholar

11.Kim, H.T., et al., Low‐Temperature Sintering and Microwave Dielectric Properties of Zinc Metatitanate‐Rutile Mixtures Using Boron. Journal of the American Ceramic Society, 1999. 82(11): p. 3043-3048. Search in Google Scholar

12.Korostynska, O., et al., Novel method for vegetable oil type verification based on real-time microwave sensing. Sens. Actuator A-Phys., 2013. 202(0): p. 211-216. Search in Google Scholar

13.Mason, A., et al., A resonant co-planar sensor at microwave frequencies for biomedical applications. Sens. Actuator A-Phys., 2013. 202(0): p. 170-175. Search in Google Scholar

14.Krupka, J., Frequency domain complex permittivity measurements at microwave frequencies. Measurement Science and Technology, 2006. 17(6): p. R55. Search in Google Scholar

15.Sheen, J., Study of microwave dielectric properties measurements by various resonance techniques. Measurement, 2005. 37(2): p. 123-130. Search in Google Scholar

16.Nyfors, E. and P. Vainikainen. Industrial microwave sensors. in Microwave Symposium Digest, 1991., IEEE MTT-S International. 1991. IEEE. Search in Google Scholar

17.Korostynska, O., et al. Planar electromagnetic wave sensor for instantaneous assessment of pesticides in water. in Sensing Technology (ICST), 2013 Seventh International Conference on. 2013. Search in Google Scholar

18.Völgyi, F., Microstrip Transmission- and Reflection- Type Sensors Used in Microwave Aquametry, in Electromagnetic Aquametry, K. Kupfer, Editor. 2005, Springer Berlin Heidelberg. p. 243-256. Search in Google Scholar

19.Korostynska, O., et al., Biomedical Sensing with Hydroxyapatite Ceramics in GHz Frequency Range. Key Engineering Materials, 2013. 543: p. 26-29. Search in Google Scholar

20.Ow, Y.-L.P., et al., Cytochrome c: functions beyond respiration. Nature Reviews Molecular Cell Biology, 2008. 9(7): p. 532-542.Search in Google Scholar