TY  - CONF
AU  - Zvicer, Jovana
AU  - Stojkovska, Jasmina
AU  - Milošević, Mia
AU  - Veljović, Đorđe
AU  - Obradović, Bojana
PY  - 2023
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/6956
AB  - Development of novel biomaterials for use in biomedical applications requires careful assessment due to the intended interactions with cells and tissues. Understanding biocompatibility, non-toxicity, and capability of promoting desired biological responses requires thorough characterization of biomaterial, including its chemical composition, surface properties, mechanical strength, degradation rate, etc. Traditional in vitro methods for evaluating biomaterials in cell monolayers are convenient but limited by the lack of specific biophysical signals found in vivo, which can lead to unreliable results. This in vitro-in vivo gap can result in the unnecessary sacrifice of a large number of animals for testing purposes. Therefore, there is a need for alternative approaches that beter mimic the in vivo environment and accurately predict the behavior of the biomaterial after implantation. Biomimetic bioreactors are primarily developed for tissue engineering to provide the key biochemical (e.g., nutrients, gases, growth factors) and biophysical signals (e.g., shear stress, hydrostatic pressure, mechanical strains) found in vivo and thus could be indispensable tools in physiologically relevant biomaterial assessment. Our group introduced the application of two biomimetic bioreactors for the physiologically relevant characterization of two types of composite biomaterials aimed for bone and osteochondral tissue engineering. In specific, macroporous composite scaffolds were produced using two natural polymers (gellan gum and alginate) as matrices imitating organic phase of bone tissue with incorporated particulate bioactive glass (BAG) and β-tricalcium phosphate (β-TCP) as hydroxyapatite (HAp) precursors. In addition, in osteochondral scaffolds, gellan gum hydrogel served as a cartilaginous layer on top of the porous composite base. Integrity and mechanical properties of all prepared scaffolds were monitored for 14 days under physiological levels of mechanical compression (up to 10% strain, compression rate 337.5 µm s-1) in a bioreactor with dynamic compression and medium perfusion. Bioactivity and HAp formation within the scaffolds were investigated in a perfusion bioreactor under the flow of simulated body fluid for up to 28 days. The scaffolds were assessed by SEM, EDS, and XRD analyses indicating a significant increase in HAp formation under bioreactor conditions as compared to static controls in all investigated samples. Moreover, the formed HAp crystals were more uniformly distributed throughout the scaffolds showing a more cauliflower-like morphology and thus, indicating potentials for bone/osteochondral tissue engineering applications. The obtained results confirm the high influence of experimental conditions on the outcomes of biomaterial characterization and importance of closely mimicking physiological conditions, thus puting forward biomimetic bioreactors as a means in this direction.
PB  - Davos : AO Research Institute
C3  - ARI Abstracts Periodical
T1  - BIOMIMETIC BIOREACTORS AS A TOOL FOR MORE RELEVANT BIOMATERIAL ASSESSMENT
IS  - Collection 3
SP  - 313
UR  - https://hdl.handle.net/21.15107/rcub_technorep_6956
ER  - 

@conference{
author = "Zvicer, Jovana and Stojkovska, Jasmina and Milošević, Mia and Veljović, Đorđe and Obradović, Bojana",
year = "2023",
abstract = "Development of novel biomaterials for use in biomedical applications requires careful assessment due to the intended interactions with cells and tissues. Understanding biocompatibility, non-toxicity, and capability of promoting desired biological responses requires thorough characterization of biomaterial, including its chemical composition, surface properties, mechanical strength, degradation rate, etc. Traditional in vitro methods for evaluating biomaterials in cell monolayers are convenient but limited by the lack of specific biophysical signals found in vivo, which can lead to unreliable results. This in vitro-in vivo gap can result in the unnecessary sacrifice of a large number of animals for testing purposes. Therefore, there is a need for alternative approaches that beter mimic the in vivo environment and accurately predict the behavior of the biomaterial after implantation. Biomimetic bioreactors are primarily developed for tissue engineering to provide the key biochemical (e.g., nutrients, gases, growth factors) and biophysical signals (e.g., shear stress, hydrostatic pressure, mechanical strains) found in vivo and thus could be indispensable tools in physiologically relevant biomaterial assessment. Our group introduced the application of two biomimetic bioreactors for the physiologically relevant characterization of two types of composite biomaterials aimed for bone and osteochondral tissue engineering. In specific, macroporous composite scaffolds were produced using two natural polymers (gellan gum and alginate) as matrices imitating organic phase of bone tissue with incorporated particulate bioactive glass (BAG) and β-tricalcium phosphate (β-TCP) as hydroxyapatite (HAp) precursors. In addition, in osteochondral scaffolds, gellan gum hydrogel served as a cartilaginous layer on top of the porous composite base. Integrity and mechanical properties of all prepared scaffolds were monitored for 14 days under physiological levels of mechanical compression (up to 10% strain, compression rate 337.5 µm s-1) in a bioreactor with dynamic compression and medium perfusion. Bioactivity and HAp formation within the scaffolds were investigated in a perfusion bioreactor under the flow of simulated body fluid for up to 28 days. The scaffolds were assessed by SEM, EDS, and XRD analyses indicating a significant increase in HAp formation under bioreactor conditions as compared to static controls in all investigated samples. Moreover, the formed HAp crystals were more uniformly distributed throughout the scaffolds showing a more cauliflower-like morphology and thus, indicating potentials for bone/osteochondral tissue engineering applications. The obtained results confirm the high influence of experimental conditions on the outcomes of biomaterial characterization and importance of closely mimicking physiological conditions, thus puting forward biomimetic bioreactors as a means in this direction.",
publisher = "Davos : AO Research Institute",
journal = "ARI Abstracts Periodical",
title = "BIOMIMETIC BIOREACTORS AS A TOOL FOR MORE RELEVANT BIOMATERIAL ASSESSMENT",
number = "Collection 3",
pages = "313",
url = "https://hdl.handle.net/21.15107/rcub_technorep_6956"
}

Zvicer, J., Stojkovska, J., Milošević, M., Veljović, Đ.,& Obradović, B.. (2023). BIOMIMETIC BIOREACTORS AS A TOOL FOR MORE RELEVANT BIOMATERIAL ASSESSMENT. in ARI Abstracts Periodical
Davos : AO Research Institute.(Collection 3), 313.
https://hdl.handle.net/21.15107/rcub_technorep_6956

Zvicer J, Stojkovska J, Milošević M, Veljović Đ, Obradović B. BIOMIMETIC BIOREACTORS AS A TOOL FOR MORE RELEVANT BIOMATERIAL ASSESSMENT. in ARI Abstracts Periodical. 2023;(Collection 3):313.
https://hdl.handle.net/21.15107/rcub_technorep_6956 .

Zvicer, Jovana, Stojkovska, Jasmina, Milošević, Mia, Veljović, Đorđe, Obradović, Bojana, "BIOMIMETIC BIOREACTORS AS A TOOL FOR MORE RELEVANT BIOMATERIAL ASSESSMENT" in ARI Abstracts Periodical, no. Collection 3 (2023):313,
https://hdl.handle.net/21.15107/rcub_technorep_6956 .

TY  - CONF
AU  - Zvicer, Jovana
AU  - Stojkovska, Jasmina
AU  - Veljović, Đorđe
AU  - Milošević, Mia
AU  - Obradović, Bojana
PY  - 2023
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/6957
AB  - Comprehensive preclinical studies are essential for the development of novel biomaterials that can be used in biomedical applications. However, traditional methods used for the evaluation of biomaterials have certain limitations. In vitro testing in cell monolayers is fast and easily accessible, but the 2D environment can affect cell metabolism and morphology, leading to unreliable results. On the other hand, in vivo animal studies are complex, time-consuming, expensive, and raise ethical concerns. Biomimetic bioreactors, primarily developed for tissue engineering to provide a physiologically relevant, strictly controlled environment that mimics the conditions in specific tissues or organs, could be indispensable tools in physiologically relevant biomaterial characterization and step between in vitro and in vivo studies. They offer the majority or all the necessary biochemical (e.g. pH, nutrients, gases, growth factors) and biophysical signals (e.g., shear stress, hydrostatic pressure, mechanical strains) highly relevant for biomaterial assessment and prediction of material behavior after implantation. Our group has developed two types of potential biomaterials aimed for bone and osteochondral tissue engineering based on bioactive glass (BAG), β-tricalcium phosphate (β-TCP), and different natural polymers (gellan gum and alginate). Scaffolds' integrity and mechanical properties were monitored continuously under the physiological level of mechanical compression using a dynamic compression bioreactor coupled with medium perfusion during 14 days. Formation of hydroxyapatite (HAp) within the scaffolds was investigated in a perfusion bioreactor, in the presence of simulated body fluid (SBF) during 14 and 28 days for scaffolds based on BAG and β-TCP, respectively. SEM, EDS, and XRD results have shown a significant increase in the formation of HAp under bioreactor conditions compared to static control conditions. Beyond that, formed HAp crystals were more uniformly distributed throughout scaffolds and presented more cauliflower-like morphology. The obtained results demonstrated the utilization potential of biomimetic bioreactors in physiologically relevant biomaterial characterization.
C3  - Book of Abstract / 3rd YCN Workshop, 19th to 21st April 2023, Aveiro, Portugal
T1  - HOW NOVEL BIOMATERIALS BASED ON BIOACTIVE GLASS AND β-TRICALCIUM PHOSPHATE CAN BE EVALUATED UNDER PHYSIOLOGICALLY RELEVANT CONDITIONS?
SP  - 23
UR  - https://hdl.handle.net/21.15107/rcub_technorep_6957
ER  - 

@conference{
author = "Zvicer, Jovana and Stojkovska, Jasmina and Veljović, Đorđe and Milošević, Mia and Obradović, Bojana",
year = "2023",
abstract = "Comprehensive preclinical studies are essential for the development of novel biomaterials that can be used in biomedical applications. However, traditional methods used for the evaluation of biomaterials have certain limitations. In vitro testing in cell monolayers is fast and easily accessible, but the 2D environment can affect cell metabolism and morphology, leading to unreliable results. On the other hand, in vivo animal studies are complex, time-consuming, expensive, and raise ethical concerns. Biomimetic bioreactors, primarily developed for tissue engineering to provide a physiologically relevant, strictly controlled environment that mimics the conditions in specific tissues or organs, could be indispensable tools in physiologically relevant biomaterial characterization and step between in vitro and in vivo studies. They offer the majority or all the necessary biochemical (e.g. pH, nutrients, gases, growth factors) and biophysical signals (e.g., shear stress, hydrostatic pressure, mechanical strains) highly relevant for biomaterial assessment and prediction of material behavior after implantation. Our group has developed two types of potential biomaterials aimed for bone and osteochondral tissue engineering based on bioactive glass (BAG), β-tricalcium phosphate (β-TCP), and different natural polymers (gellan gum and alginate). Scaffolds' integrity and mechanical properties were monitored continuously under the physiological level of mechanical compression using a dynamic compression bioreactor coupled with medium perfusion during 14 days. Formation of hydroxyapatite (HAp) within the scaffolds was investigated in a perfusion bioreactor, in the presence of simulated body fluid (SBF) during 14 and 28 days for scaffolds based on BAG and β-TCP, respectively. SEM, EDS, and XRD results have shown a significant increase in the formation of HAp under bioreactor conditions compared to static control conditions. Beyond that, formed HAp crystals were more uniformly distributed throughout scaffolds and presented more cauliflower-like morphology. The obtained results demonstrated the utilization potential of biomimetic bioreactors in physiologically relevant biomaterial characterization.",
journal = "Book of Abstract / 3rd YCN Workshop, 19th to 21st April 2023, Aveiro, Portugal",
title = "HOW NOVEL BIOMATERIALS BASED ON BIOACTIVE GLASS AND β-TRICALCIUM PHOSPHATE CAN BE EVALUATED UNDER PHYSIOLOGICALLY RELEVANT CONDITIONS?",
pages = "23",
url = "https://hdl.handle.net/21.15107/rcub_technorep_6957"
}

Zvicer, J., Stojkovska, J., Veljović, Đ., Milošević, M.,& Obradović, B.. (2023). HOW NOVEL BIOMATERIALS BASED ON BIOACTIVE GLASS AND β-TRICALCIUM PHOSPHATE CAN BE EVALUATED UNDER PHYSIOLOGICALLY RELEVANT CONDITIONS?. in Book of Abstract / 3rd YCN Workshop, 19th to 21st April 2023, Aveiro, Portugal, 23.
https://hdl.handle.net/21.15107/rcub_technorep_6957

Zvicer J, Stojkovska J, Veljović Đ, Milošević M, Obradović B. HOW NOVEL BIOMATERIALS BASED ON BIOACTIVE GLASS AND β-TRICALCIUM PHOSPHATE CAN BE EVALUATED UNDER PHYSIOLOGICALLY RELEVANT CONDITIONS?. in Book of Abstract / 3rd YCN Workshop, 19th to 21st April 2023, Aveiro, Portugal. 2023;:23.
https://hdl.handle.net/21.15107/rcub_technorep_6957 .

Zvicer, Jovana, Stojkovska, Jasmina, Veljović, Đorđe, Milošević, Mia, Obradović, Bojana, "HOW NOVEL BIOMATERIALS BASED ON BIOACTIVE GLASS AND β-TRICALCIUM PHOSPHATE CAN BE EVALUATED UNDER PHYSIOLOGICALLY RELEVANT CONDITIONS?" in Book of Abstract / 3rd YCN Workshop, 19th to 21st April 2023, Aveiro, Portugal (2023):23,
https://hdl.handle.net/21.15107/rcub_technorep_6957 .