Significant development of cells and bioactive compound encapsulation technologies is taking place due to an exceptional possibility of their application in various scientific disciplines, including biomedicine, pharmacy, cosmetology, food and agricultural sciences, beverage production, industrial waste treatment. Despite the broad application of microencapsulation, the literature reviews on dispersion techniques for microcapsule/microbead production, their advantages, restrictions and drawbacks are scarce. The purpose of this paper is to assess the possibilities of electrostatic extrusion for encapsulation of biological material, including living cells in hydrogel microbeads. The paper presents an overview of the mechanisms of droplet formation and controlling experimental parameters for producing microbeads by means of electrostatic extrusion. Electrostatic droplet formation utilizes a special type of physical process taking advantage of electrostatic effects occurring in flowing con...ductive liquids after introduction of an electric field. When an electrostatic field is applied to the metal needle and an electric charge is induced in the liquid flowing out of the needle, the size of droplet detaching from the needle tip decreases as a function of applied electrostatic field. It has been shown that few parameters affect microbead size: applied voltage, electrode geometry, needle size, polarity arrangement and polymer concentration. The electrostatic droplet formation is one of the most precise methods, which enables one to produce spherical and uniform particles ranging from 100 up to 1000 mu m. Most of the authors report that the encapsulated compounds (drugs, enzymes and living cells) remain unaltered after electrostatic extrusion. This technique seems to be particularly promising in biotechnology, pharmaceutical and cosmetics industries, where a low-temperature process, preserving heat-sensitive material is a prerequisite. Future efforts in developing of electrostatic extrusion should be directed towards adequately scaling-up for commercial purpose.
TY - JOUR
AU - Kostić, Ivana
AU - Isailović, Bojana D.
AU - Đorđević Verica B.
AU - Lević, Steva
AU - Nedović, Viktor
AU - Bugarski, Branko
PY - 2012
UR - http://rimi.imi.bg.ac.rs/handle/123456789/396
AB - Significant development of cells and bioactive compound encapsulation technologies is taking place due to an exceptional possibility of their application in various scientific disciplines, including biomedicine, pharmacy, cosmetology, food and agricultural sciences, beverage production, industrial waste treatment. Despite the broad application of microencapsulation, the literature reviews on dispersion techniques for microcapsule/microbead production, their advantages, restrictions and drawbacks are scarce. The purpose of this paper is to assess the possibilities of electrostatic extrusion for encapsulation of biological material, including living cells in hydrogel microbeads. The paper presents an overview of the mechanisms of droplet formation and controlling experimental parameters for producing microbeads by means of electrostatic extrusion. Electrostatic droplet formation utilizes a special type of physical process taking advantage of electrostatic effects occurring in flowing conductive liquids after introduction of an electric field. When an electrostatic field is applied to the metal needle and an electric charge is induced in the liquid flowing out of the needle, the size of droplet detaching from the needle tip decreases as a function of applied electrostatic field. It has been shown that few parameters affect microbead size: applied voltage, electrode geometry, needle size, polarity arrangement and polymer concentration. The electrostatic droplet formation is one of the most precise methods, which enables one to produce spherical and uniform particles ranging from 100 up to 1000 mu m. Most of the authors report that the encapsulated compounds (drugs, enzymes and living cells) remain unaltered after electrostatic extrusion. This technique seems to be particularly promising in biotechnology, pharmaceutical and cosmetics industries, where a low-temperature process, preserving heat-sensitive material is a prerequisite. Future efforts in developing of electrostatic extrusion should be directed towards adequately scaling-up for commercial purpose.
PB - Savez hemijskih inženjera, Beograd
T2 - Hemijska industrija
T1 - Electrostatic extrusion as a dispersion technique for encapsulation of cells and bioactive compounds
EP - 515
IS - 4
SP - 503
VL - 66
DO - 10.2298/HEMIND111209013K
UR - conv_2862
ER -
@article{
author = "Kostić, Ivana and Isailović, Bojana D. and Đorđević Verica B. and Lević, Steva and Nedović, Viktor and Bugarski, Branko",
year = "2012",
abstract = "Significant development of cells and bioactive compound encapsulation technologies is taking place due to an exceptional possibility of their application in various scientific disciplines, including biomedicine, pharmacy, cosmetology, food and agricultural sciences, beverage production, industrial waste treatment. Despite the broad application of microencapsulation, the literature reviews on dispersion techniques for microcapsule/microbead production, their advantages, restrictions and drawbacks are scarce. The purpose of this paper is to assess the possibilities of electrostatic extrusion for encapsulation of biological material, including living cells in hydrogel microbeads. The paper presents an overview of the mechanisms of droplet formation and controlling experimental parameters for producing microbeads by means of electrostatic extrusion. Electrostatic droplet formation utilizes a special type of physical process taking advantage of electrostatic effects occurring in flowing conductive liquids after introduction of an electric field. When an electrostatic field is applied to the metal needle and an electric charge is induced in the liquid flowing out of the needle, the size of droplet detaching from the needle tip decreases as a function of applied electrostatic field. It has been shown that few parameters affect microbead size: applied voltage, electrode geometry, needle size, polarity arrangement and polymer concentration. The electrostatic droplet formation is one of the most precise methods, which enables one to produce spherical and uniform particles ranging from 100 up to 1000 mu m. Most of the authors report that the encapsulated compounds (drugs, enzymes and living cells) remain unaltered after electrostatic extrusion. This technique seems to be particularly promising in biotechnology, pharmaceutical and cosmetics industries, where a low-temperature process, preserving heat-sensitive material is a prerequisite. Future efforts in developing of electrostatic extrusion should be directed towards adequately scaling-up for commercial purpose.",
publisher = "Savez hemijskih inženjera, Beograd",
journal = "Hemijska industrija",
title = "Electrostatic extrusion as a dispersion technique for encapsulation of cells and bioactive compounds",
pages = "515-503",
number = "4",
volume = "66",
doi = "10.2298/HEMIND111209013K",
url = "conv_2862"
}
Kostić, I., Isailović, B. D., Đorđević Verica B., Lević, S., Nedović, V.,& Bugarski, B.. (2012). Electrostatic extrusion as a dispersion technique for encapsulation of cells and bioactive compounds. in Hemijska industrija
Savez hemijskih inženjera, Beograd., 66(4), 503-515.
https://doi.org/10.2298/HEMIND111209013K
conv_2862
Kostić I, Isailović BD, Đorđević Verica B., Lević S, Nedović V, Bugarski B. Electrostatic extrusion as a dispersion technique for encapsulation of cells and bioactive compounds. in Hemijska industrija. 2012;66(4):503-515.
doi:10.2298/HEMIND111209013K
conv_2862 .
Kostić, Ivana, Isailović, Bojana D., Đorđević Verica B., Lević, Steva, Nedović, Viktor, Bugarski, Branko, "Electrostatic extrusion as a dispersion technique for encapsulation of cells and bioactive compounds" in Hemijska industrija, 66, no. 4 (2012):503-515,
https://doi.org/10.2298/HEMIND111209013K .,
conv_2862 .
