Matrix resistance stress: A key parameter for immobilized cell growth regulation
Samo za registrovane korisnike
2017
Autori
Pajić-Lijaković, IvanaMilivojević, Milan
Lević, Steva
Trifković, Kata T.
Stevanović-Dajić, Zora
Radosević, Radenko
Nedović, Viktor
Bugarski, Branko
Članak u časopisu (Objavljena verzija)
Metapodaci
Prikaz svih podataka o dokumentuApstrakt
Microenvironmentally restricted yeast cell growth within Ca-alginate beads with and without entrapped gas bubbles was considered based on experimental data. Cell growth dynamics was described by (1) the dimensionless cell number density as a function of the cell growth time and (2) the cell distribution per bead cross sections. One of the key control parameters for bioprocess optimization is the matrix resistance stress generated during immobilized cell expansion. The dynamics of the increase in matrix stress was described theoretically based on a multi-scale mathematical model. In order to estimate and reduce the accumulation of matrix stress we considered repeated stress relaxation cycles in separate rheological experiments without immobilized cells. The results revealed that the increase in resistance stress within the Ca-alginate matrix was significant (similar to 7 kPa) after 10 repeated cycles, even under a low compression strain of 2% per cycle. The stress could be reduced by us...ing the Ca-alginate matrix with entrapped gas bubbles. The final cell concentration within the beads with entrapped bubbles was 3.3 times higher in comparison with the beads without bubbles. The bubbles could locally amortize the compression effects within the surrounding cell clusters.
Ključne reči:
Ca-alginate bead with entrapped gas bubbles / Yeast / Matrix resistance stress generation / Matrix rheological properties / Modeling / Microenvironmentally restricted cell growthIzvor:
Process Biochemistry, 2017, 52, 30-43Izdavač:
- Elsevier Sci Ltd, Oxford
Finansiranje / projekti:
- Advancing research in agricultural and food sciences at Faculty of Agriculture, University of Belgrade (EU-FP7-316004)
- Razvoj i primena novih i tradicionalnih tehnologija u proizvodnji konkurentnih prehrambenih proizvoda sa dodatom vrednošću za evropsko i svetsko tržište - Stvorimo bogatstvo iz bogatstva Srbije (RS-MESTD-Integrated and Interdisciplinary Research (IIR or III)-46001)
- Razvoj novih inkapsulacionih i enzimskih tehnologija za proizvodnju biokatalizatora i biološki aktivnih komponenata hrane u cilju povećanja njene konkurentnosti, kvaliteta i bezbednosti (RS-MESTD-Integrated and Interdisciplinary Research (IIR or III)-46010)
DOI: 10.1016/j.procbio.2016.10.017
ISSN: 1359-5113
WoS: 000392774600004
Scopus: 2-s2.0-85002756249
Institucija/grupa
Tehnološko-metalurški fakultetTY - JOUR AU - Pajić-Lijaković, Ivana AU - Milivojević, Milan AU - Lević, Steva AU - Trifković, Kata T. AU - Stevanović-Dajić, Zora AU - Radosević, Radenko AU - Nedović, Viktor AU - Bugarski, Branko PY - 2017 UR - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/3666 AB - Microenvironmentally restricted yeast cell growth within Ca-alginate beads with and without entrapped gas bubbles was considered based on experimental data. Cell growth dynamics was described by (1) the dimensionless cell number density as a function of the cell growth time and (2) the cell distribution per bead cross sections. One of the key control parameters for bioprocess optimization is the matrix resistance stress generated during immobilized cell expansion. The dynamics of the increase in matrix stress was described theoretically based on a multi-scale mathematical model. In order to estimate and reduce the accumulation of matrix stress we considered repeated stress relaxation cycles in separate rheological experiments without immobilized cells. The results revealed that the increase in resistance stress within the Ca-alginate matrix was significant (similar to 7 kPa) after 10 repeated cycles, even under a low compression strain of 2% per cycle. The stress could be reduced by using the Ca-alginate matrix with entrapped gas bubbles. The final cell concentration within the beads with entrapped bubbles was 3.3 times higher in comparison with the beads without bubbles. The bubbles could locally amortize the compression effects within the surrounding cell clusters. PB - Elsevier Sci Ltd, Oxford T2 - Process Biochemistry T1 - Matrix resistance stress: A key parameter for immobilized cell growth regulation EP - 43 SP - 30 VL - 52 DO - 10.1016/j.procbio.2016.10.017 ER -
@article{ author = "Pajić-Lijaković, Ivana and Milivojević, Milan and Lević, Steva and Trifković, Kata T. and Stevanović-Dajić, Zora and Radosević, Radenko and Nedović, Viktor and Bugarski, Branko", year = "2017", abstract = "Microenvironmentally restricted yeast cell growth within Ca-alginate beads with and without entrapped gas bubbles was considered based on experimental data. Cell growth dynamics was described by (1) the dimensionless cell number density as a function of the cell growth time and (2) the cell distribution per bead cross sections. One of the key control parameters for bioprocess optimization is the matrix resistance stress generated during immobilized cell expansion. The dynamics of the increase in matrix stress was described theoretically based on a multi-scale mathematical model. In order to estimate and reduce the accumulation of matrix stress we considered repeated stress relaxation cycles in separate rheological experiments without immobilized cells. The results revealed that the increase in resistance stress within the Ca-alginate matrix was significant (similar to 7 kPa) after 10 repeated cycles, even under a low compression strain of 2% per cycle. The stress could be reduced by using the Ca-alginate matrix with entrapped gas bubbles. The final cell concentration within the beads with entrapped bubbles was 3.3 times higher in comparison with the beads without bubbles. The bubbles could locally amortize the compression effects within the surrounding cell clusters.", publisher = "Elsevier Sci Ltd, Oxford", journal = "Process Biochemistry", title = "Matrix resistance stress: A key parameter for immobilized cell growth regulation", pages = "43-30", volume = "52", doi = "10.1016/j.procbio.2016.10.017" }
Pajić-Lijaković, I., Milivojević, M., Lević, S., Trifković, K. T., Stevanović-Dajić, Z., Radosević, R., Nedović, V.,& Bugarski, B.. (2017). Matrix resistance stress: A key parameter for immobilized cell growth regulation. in Process Biochemistry Elsevier Sci Ltd, Oxford., 52, 30-43. https://doi.org/10.1016/j.procbio.2016.10.017
Pajić-Lijaković I, Milivojević M, Lević S, Trifković KT, Stevanović-Dajić Z, Radosević R, Nedović V, Bugarski B. Matrix resistance stress: A key parameter for immobilized cell growth regulation. in Process Biochemistry. 2017;52:30-43. doi:10.1016/j.procbio.2016.10.017 .
Pajić-Lijaković, Ivana, Milivojević, Milan, Lević, Steva, Trifković, Kata T., Stevanović-Dajić, Zora, Radosević, Radenko, Nedović, Viktor, Bugarski, Branko, "Matrix resistance stress: A key parameter for immobilized cell growth regulation" in Process Biochemistry, 52 (2017):30-43, https://doi.org/10.1016/j.procbio.2016.10.017 . .