Publications

  • Pasias D., Koutsokeras L., Passos A., G. Constantinides, Balabani S. and Kaliviotis E. (2022). Effects of biomechanical properties of blood on surface tension driven flows in superhydrophilic channels. Physics of Fluids, Submitted February 2022, Under Review.
  • Koutinas, M., M. Kyriakou, K. Andreou, M. Hadjicharalambous, E. Kaliviotis, D. Pasias, G. Kazamias, C. Varavvas, and I. Vyrides. (2021). Enhanced Biodegradation and Valorization of Drilling Wastewater Via Simultaneous Production of Biosurfactants and Polyhydroxyalkanoates by Pseudomonas Citronellolis SJTE-3. Bioresource Technology doi:10.1016/j.biortech.2021.125679.
  • Louka, M. and Kaliviotis, E. Development of an Optical Method for the Evaluation of Whole Blood Coagulation. Biosensors, 11(4), (2021). DOI: 10.3390/bios11040113
  • Pasias D., Passos A., G. Constantinides, Balabani S. and Kaliviotis E. (2020). Surface tension driven flow of blood in a rectangular microfluidic channel: effect of erythrocyte aggregation. Physics of Fluids, 32, 071903 (2020); https://doi.org/10.1063/5.0008939.
  • Passos A., Sherwood J.M., Kaliviotis E., Agrawa l. R., Pavesio C., Balabani S. (2019). The effect of deformability on the microscale flow behavior of red blood cell suspensions. Physics of Fluids, 31 (9), 091903.
  • Kapnisis, K., Seidner, H., Prokopi, M., Pasias, D., Pitsillides, C., Anayiotos, A. and Kaliviotis E., (2019). The effects of stenting on hemorheological parameters: an in vitro investigation under various blood flow conditions. Clinical Hemorheology and Microcirculation, Accepted Feb. 2019.
  • Ermolinskiy P. B., Semenov A. N., Lugovtsov A. E., Poeschl C., Windberger U., Kaliviotis E. and Priezzhev A. V. (2019). Effect of different macromolecules on viscous and microrheologic properties of blood at various temperatures. Proceedings of SPIE. Accepted Jan. 2019.
  • Kaliviotis E., (2018). Erythrocyte deformability measurements in high viscosity mediums. Clinical Hemorheology and Microcirculation, Accepted February 2018.
  • Kaliviotis E., Sherwood J., and Balabani S. (2018). Local viscosity distribution in bifurcating microfluidic blood flows. Physics of Fluids, Doi.org/10.1063/1.5011373.
  • Xu, D., Ji, C., Avital, E., Kaliviotis, E., Munjiza, A., Williams, J. (2017). An Investigation on the Aggregation and Rheodynamics of Human Red Blood Cells Using High Performance Computations. Scientifica, art. no. 6524156.
  • Kaliviotis E., Sherwood J., and Balabani S. (2017). Partitioning of red blood cell aggregates in bifurcating microscale flows. Scientific Reports, DOI: 10.1038/srep44563.
  • Kaliviotis E., Pasias D., Sherwood J., and Balabani S. (2016). Red blood cell aggregate flux in a bifurcating microchannel. Medical Engineering and Physics, https://doi.org/10.1016/j.medengphy.2017.04.007.
  • Kaliviotis E., Sherwood J.M., Dusting J. and Balabani S. (2016). Quantification of local blood flow characteristics in microfluidic applications. Series on Biomechanics, 30(1), pp.5-14.
  • Kaliviotis E., Dusting J., Sherwood J.M. and Balabani S. (2015). Quantifying local characteristics of velocity, aggregation and hematocrit of human erythrocytes in a microchannel flow. Clinical Hemorheology and Microcirculation, DOI10.3233 /CH-151980
  • Kaliviotis, E. (2015). Mechanics of the red blood cell network. Journal of Cellular Biotechnology, DOI: 10.3233/JCB-15004.
  • Antonova, N., Xu, D., Velcheva, I., Kaliviotis, E. and Tosheva, P. (2015). Stenosis effects on the fluid mechanics of the common carotid artery bifurcation for unsteady flows. Journal of Mechanics in Medicine and Biology, 15.
  • Sherwood, J. M., Kaliviotis, E., Dusting, J. and Balabani, S. (2014) Hematocrit, viscosity and velocity distributions of aggregating and non-aggregating blood in a bifurcating microchannel. Journal of Biomechanics Modelling in Mechanobiology, 13, pp.259-273.
  • Sherwood, J. M., Holmes, D., Kaliviotis, E. and Balabani, S. (2014). Spatial distributions of red blood cells significantly alter local haemodynamics. PLOS ONE, 9. doi.org/10.1371/journal.pone.0100473
  • Antonova, N., Dong, X., Tosheva, P., Kaliviotis, E. and Velcheva, I. (2014) Numerical analysis of 3D blood flow and common carotid artery hemodynamics in the carotid artery bifurcation with stenosis. Clinical Hemorheology and Microcirculation, 57, pp.159-173.
  • Xu, D., Kaliviotis, E., Munjiza, A., Avital, E., Ji, C. and Williams, J. (2013). Large scale simulation of red blood cell aggregation in shear flows. Biomechanics, 46, pp.1810-1817.
  • Hanson B., Cox B., Kaliviotis E. and Smith C.H. (2012). Effects of Saliva on Starch-Thickened Drinks with Acidic and Neutral pH. Dysphagia, 27(3), pp.427-435.
  • Sherwood, J. M., Dusting, J., Kaliviotis, E. and Balabani, S. (2012) The effect of red blood cell aggregation on velocity and cell-depleted layer characteristics of blood in a bifurcating microchannel, Biomicrofluidics, 6(2), 241119.
  • Kaliviotis E. and Yianneskis M. (2011). Blood viscosity modelling: Influence of aggregate network dynamics under transient conditions. Biorheology, 48, pp.127-147.
  • Kaliviotis E., Dusting J. and Balabani S. (2011). Spatial variation of blood viscosity: Modelling using shear fields measured by a μPIV based technique. Medical Engineering and Physics, 33, pp.824-831.
  • Kaliviotis E., Ivanov I., Antonova N. and Yianneskis M. (2010). Erythrocyte aggregation at non-steady flow conditions: A comparison of characteristics measured with electrorheology and image analysis. Clinical Hemorheology and Microcirculation, 44, pp.43-54.
  • Dusting J., Kaliviotis E., Balabani S. and Yianneskis M. (2009). Coupled human erythrocyte velocity field and aggregation measurements at physiological haematocrit levels. Journal of Biomechanics, 42, pp.1438-1443.
  • Kaliviotis E. and Yianneskis M. (2009). An energy-rate based blood viscosity model incorporating aggregate network dynamics. Biorheology, 46, pp.639-649.
  • Kaliviotis E. and Yianneskis M. (2008b). Fast response characteristics of red blood cell aggregation. Biorheology, 45, pp.639-649.
  • Kaliviotis E. and Yianneskis M. (2008a). On the Effect of Microstructural Changes of Blood on Energy Dissipation in Couette Flow. Clinical Hemorheology and Microcirculation, 39, pp.235-242.
  • Kaliviotis E. and Yianneskis M. (2007). On the Effect of Dynamic Flow Conditions on Blood Microstructure Investigated with Optical Shearing Microscopy and Rheometry. Journal of Engineering in Medicine, 221, pp.887-897.