TY  - JOUR
AU  - Willaert, Ronnie
AU  - Vanden, Boer, Pieterjan
AU  - Malovichko, Anton
AU  - Alioscha-Perez, Mitchel
AU  - Radotić, Ksenija
AU  - Bartolić, Dragana
AU  - Kalauzi, Aleksandar
AU  - Villalba, Maria Ines
AU  - Sanglard, Dominique
AU  - Dietler, Giovanni
AU  - Sahli, Hichem
AU  - Kasas, Sandor
PY  - 2020
UR  - http://rimsi.imsi.bg.ac.rs/handle/123456789/1335
AB  - Living single yeast cells show a specific cellular motion at the nanometer scale with a magnitude that is proportional to the cellular activity of the cell. We characterized this cellular nanomotion pattern of nonattached single yeast cells using classical optical microscopy. The distribution of the cellular displacements over a short time period is distinct from random motion. The range and shape of such nanomotion displacement distributions change substantially according to the metabolic state of the cell. The analysis of the nanomotion frequency pattern demonstrated that single living yeast cells oscillate at relatively low frequencies of around 2 hertz. The simplicity of the technique should open the way to numerous applications among which antifungal susceptibility tests seem the most straightforward.
PB  - Amer Assoc Advancement Science, Washington
T2  - Science Advances
T1  - Single yeast cell nanomotions correlate with cellular activity
IS  - 26
VL  - 6
DO  - 10.1126/sciadv.aba3139
ER  - 

@article{
author = "Willaert, Ronnie and Vanden, Boer, Pieterjan and Malovichko, Anton and Alioscha-Perez, Mitchel and Radotić, Ksenija and Bartolić, Dragana and Kalauzi, Aleksandar and Villalba, Maria Ines and Sanglard, Dominique and Dietler, Giovanni and Sahli, Hichem and Kasas, Sandor",
year = "2020",
abstract = "Living single yeast cells show a specific cellular motion at the nanometer scale with a magnitude that is proportional to the cellular activity of the cell. We characterized this cellular nanomotion pattern of nonattached single yeast cells using classical optical microscopy. The distribution of the cellular displacements over a short time period is distinct from random motion. The range and shape of such nanomotion displacement distributions change substantially according to the metabolic state of the cell. The analysis of the nanomotion frequency pattern demonstrated that single living yeast cells oscillate at relatively low frequencies of around 2 hertz. The simplicity of the technique should open the way to numerous applications among which antifungal susceptibility tests seem the most straightforward.",
publisher = "Amer Assoc Advancement Science, Washington",
journal = "Science Advances",
title = "Single yeast cell nanomotions correlate with cellular activity",
number = "26",
volume = "6",
doi = "10.1126/sciadv.aba3139"
}

Willaert, R., Vanden, B. P., Malovichko, A., Alioscha-Perez, M., Radotić, K., Bartolić, D., Kalauzi, A., Villalba, M. I., Sanglard, D., Dietler, G., Sahli, H.,& Kasas, S.. (2020). Single yeast cell nanomotions correlate with cellular activity. in Science Advances
Amer Assoc Advancement Science, Washington., 6(26).
https://doi.org/10.1126/sciadv.aba3139

Willaert R, Vanden BP, Malovichko A, Alioscha-Perez M, Radotić K, Bartolić D, Kalauzi A, Villalba MI, Sanglard D, Dietler G, Sahli H, Kasas S. Single yeast cell nanomotions correlate with cellular activity. in Science Advances. 2020;6(26).
doi:10.1126/sciadv.aba3139 .

Willaert, Ronnie, Vanden, Boer, Pieterjan, Malovichko, Anton, Alioscha-Perez, Mitchel, Radotić, Ksenija, Bartolić, Dragana, Kalauzi, Aleksandar, Villalba, Maria Ines, Sanglard, Dominique, Dietler, Giovanni, Sahli, Hichem, Kasas, Sandor, "Single yeast cell nanomotions correlate with cellular activity" in Science Advances, 6, no. 26 (2020),
https://doi.org/10.1126/sciadv.aba3139 . .