Supplementary information for the article: Micić, M.; Antonijević, Đ.; Milutinović-Smiljanić, S.; Trisić, D.; Colović, B.; Kosanović, D.; Prokić, B.; Vasić, J.; Zivković, S.; Milašin, J.; Danilović, V.; Đurić, M.; Jokanović, V. Developing a Novel Resorptive Hydroxyapatite-Based Bone Substitute for over-Critical Size Defect Reconstruction: Physicochemical and Biological Characterization and Proof of Concept in Segmental Rabbit’s Ulna Reconstruction. Biomedical Engineering-Biomedizinische Technik 2020, 65 (4), 491–505. https://doi.org/10.1515/bmt-2019-0218.
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Аутори
Micić, MilutinAntonijević, Đorđe
Milutinović-Smiljanić, Sanja
Trisić, Dijana
Colović, Božana
Kosanović, Dejana
Prokić, Bogomir
Vasić, Jugoslav
Zivković, Slavoljub
Milašin, Jelena
Danilović, Vesna
Đurić, Marija
Jokanović, Vukoman
Скуп података (Објављена верзија)
Метаподаци
Приказ свих података о документуАпстракт
Figure 1S. Change of the Ca concentration in the solution containing investigated nHAP granules with time. Figure 2S. Change of the Ca concentration with time in biological apatite (BioOss). Figure 3S. The correlation of the ALBO-OS compressive strenght and the time of the material’s soaking in Hank’s solution. Table 1S. Reference point indentation outcomes of the ALBOOS. MH – microhardness, ID 1st - 1st Cycle Indentation Distance; US 1st - 1st Cycle Unloading Slope; CID 1st -1st Cycle Creep Indentation Distance; TID - Total Indentation Distance; IDI - Indentation Distance Increase; Avg CID - Avg Creep Indentation Distance; Avg US - Average Unloading Slope; Avg US - Average Unloading Slope; Avg LS - Average Loading Slope; Avg ED - Average Energy Dissipated. Table 2S. Ph of nHAP after soaking in simulated body fluid. Figure 4S. Microacrhitectural and structural characteristics of nHAP in vitro and in contact with bone tissue in vivo. Adequate microstructure and surface nanotopography... provide good environment for cells infiltration in vivo. Note the presence of porous paterns within material structure in vivo as well as the lamellar structure of ALBO-OS. Figure 5S. Schematic representation of the extruder design in custom made laboratory 3D printer: from technical reasons, 3D printer was modified to include two extruders: 1 – syringe extruder, 1.1 – glass syringe, 1.2 – external frame of the extruder 1, 1.3 – electrical heater coil, 1.4 –metal piston of the syringe, 1.5 – syringe nozzle (0,8mm in diameter), 1.6 – gears of the piston drive, 1.7 – piston drive motor with reduction, 1.8 – HAP PLA mixture, 2 – PLA extruder, 2.1 – heater block of the PLA extruder, 2.2 – extruder cooler, 2.3 – PLA extruder motor drive with reduction, 2.4 – PLA filament 1.75mm in diameter, 2.5 – PLA extruder nozzle 0,4mm in diameter. Figure 6S. Paste extruder attached to the head of the printer, with removed electrical heater coil, so the syringe with the metal piston can be visible. A) The engineered construct used for the experiments and B) its structure after magnification (X200). C-E) Wettability of the construct. Administration of the reference liquid droplet on the construct surface. F) Histogram showing the time required for reference liquid to completely wet the construct surface. Note that the droplet is absorbed within the part of the second.
Кључне речи:
3D printing / bone reconstruction / personalized medicine / tissue engineeringИзвор:
Biomedical Engineering-Biomedizinische Technik, 2020Издавач:
- Walter De Gruyter Gmbh, Berlin
Финансирање / пројекти:
- Хемијско и структурно дизајнирање наноматеријала за примену у медицини и инжењерству ткива (RS-MESTD-Basic Research (BR or ON)-172026)
- Функционални, функционализовани и усавршени нано материјали (RS-MESTD-Integrated and Interdisciplinary Research (IIR or III)-45005)
Напомена:
- Supplementary material for: https://doi.org/10.1515/bmt-2019-0218
- Related to the published version: https://intor.torlakinstitut.com/handle/123456789/542
Повезане информације:
- Повезани садржај
https://intor.torlakinstitut.com/handle/123456789/660 - Повезани садржај
https://intor.torlakinstitut.com/handle/123456789/542 - Повезани садржај
https://doi.org/10.1515/bmt-2019-0218
Колекције
Институција/група
TorlakTY - DATA AU - Micić, Milutin AU - Antonijević, Đorđe AU - Milutinović-Smiljanić, Sanja AU - Trisić, Dijana AU - Colović, Božana AU - Kosanović, Dejana AU - Prokić, Bogomir AU - Vasić, Jugoslav AU - Zivković, Slavoljub AU - Milašin, Jelena AU - Danilović, Vesna AU - Đurić, Marija AU - Jokanović, Vukoman PY - 2020 UR - http://intor.torlakinstitut.com/handle/123456789/661 AB - Figure 1S. Change of the Ca concentration in the solution containing investigated nHAP granules with time. Figure 2S. Change of the Ca concentration with time in biological apatite (BioOss). Figure 3S. The correlation of the ALBO-OS compressive strenght and the time of the material’s soaking in Hank’s solution. Table 1S. Reference point indentation outcomes of the ALBOOS. MH – microhardness, ID 1st - 1st Cycle Indentation Distance; US 1st - 1st Cycle Unloading Slope; CID 1st -1st Cycle Creep Indentation Distance; TID - Total Indentation Distance; IDI - Indentation Distance Increase; Avg CID - Avg Creep Indentation Distance; Avg US - Average Unloading Slope; Avg US - Average Unloading Slope; Avg LS - Average Loading Slope; Avg ED - Average Energy Dissipated. Table 2S. Ph of nHAP after soaking in simulated body fluid. Figure 4S. Microacrhitectural and structural characteristics of nHAP in vitro and in contact with bone tissue in vivo. Adequate microstructure and surface nanotopography provide good environment for cells infiltration in vivo. Note the presence of porous paterns within material structure in vivo as well as the lamellar structure of ALBO-OS. Figure 5S. Schematic representation of the extruder design in custom made laboratory 3D printer: from technical reasons, 3D printer was modified to include two extruders: 1 – syringe extruder, 1.1 – glass syringe, 1.2 – external frame of the extruder 1, 1.3 – electrical heater coil, 1.4 –metal piston of the syringe, 1.5 – syringe nozzle (0,8mm in diameter), 1.6 – gears of the piston drive, 1.7 – piston drive motor with reduction, 1.8 – HAP PLA mixture, 2 – PLA extruder, 2.1 – heater block of the PLA extruder, 2.2 – extruder cooler, 2.3 – PLA extruder motor drive with reduction, 2.4 – PLA filament 1.75mm in diameter, 2.5 – PLA extruder nozzle 0,4mm in diameter. Figure 6S. Paste extruder attached to the head of the printer, with removed electrical heater coil, so the syringe with the metal piston can be visible. A) The engineered construct used for the experiments and B) its structure after magnification (X200). C-E) Wettability of the construct. Administration of the reference liquid droplet on the construct surface. F) Histogram showing the time required for reference liquid to completely wet the construct surface. Note that the droplet is absorbed within the part of the second. PB - Walter De Gruyter Gmbh, Berlin T2 - Biomedical Engineering-Biomedizinische Technik T1 - Supplementary information for the article: Micić, M.; Antonijević, Đ.; Milutinović-Smiljanić, S.; Trisić, D.; Colović, B.; Kosanović, D.; Prokić, B.; Vasić, J.; Zivković, S.; Milašin, J.; Danilović, V.; Đurić, M.; Jokanović, V. Developing a Novel Resorptive Hydroxyapatite-Based Bone Substitute for over-Critical Size Defect Reconstruction: Physicochemical and Biological Characterization and Proof of Concept in Segmental Rabbit’s Ulna Reconstruction. Biomedical Engineering-Biomedizinische Technik 2020, 65 (4), 491–505. https://doi.org/10.1515/bmt-2019-0218. UR - https://hdl.handle.net/21.15107/rcub_intor_661 ER -
@misc{ author = "Micić, Milutin and Antonijević, Đorđe and Milutinović-Smiljanić, Sanja and Trisić, Dijana and Colović, Božana and Kosanović, Dejana and Prokić, Bogomir and Vasić, Jugoslav and Zivković, Slavoljub and Milašin, Jelena and Danilović, Vesna and Đurić, Marija and Jokanović, Vukoman", year = "2020", abstract = "Figure 1S. Change of the Ca concentration in the solution containing investigated nHAP granules with time. Figure 2S. Change of the Ca concentration with time in biological apatite (BioOss). Figure 3S. The correlation of the ALBO-OS compressive strenght and the time of the material’s soaking in Hank’s solution. Table 1S. Reference point indentation outcomes of the ALBOOS. MH – microhardness, ID 1st - 1st Cycle Indentation Distance; US 1st - 1st Cycle Unloading Slope; CID 1st -1st Cycle Creep Indentation Distance; TID - Total Indentation Distance; IDI - Indentation Distance Increase; Avg CID - Avg Creep Indentation Distance; Avg US - Average Unloading Slope; Avg US - Average Unloading Slope; Avg LS - Average Loading Slope; Avg ED - Average Energy Dissipated. Table 2S. Ph of nHAP after soaking in simulated body fluid. Figure 4S. Microacrhitectural and structural characteristics of nHAP in vitro and in contact with bone tissue in vivo. Adequate microstructure and surface nanotopography provide good environment for cells infiltration in vivo. Note the presence of porous paterns within material structure in vivo as well as the lamellar structure of ALBO-OS. Figure 5S. Schematic representation of the extruder design in custom made laboratory 3D printer: from technical reasons, 3D printer was modified to include two extruders: 1 – syringe extruder, 1.1 – glass syringe, 1.2 – external frame of the extruder 1, 1.3 – electrical heater coil, 1.4 –metal piston of the syringe, 1.5 – syringe nozzle (0,8mm in diameter), 1.6 – gears of the piston drive, 1.7 – piston drive motor with reduction, 1.8 – HAP PLA mixture, 2 – PLA extruder, 2.1 – heater block of the PLA extruder, 2.2 – extruder cooler, 2.3 – PLA extruder motor drive with reduction, 2.4 – PLA filament 1.75mm in diameter, 2.5 – PLA extruder nozzle 0,4mm in diameter. Figure 6S. Paste extruder attached to the head of the printer, with removed electrical heater coil, so the syringe with the metal piston can be visible. A) The engineered construct used for the experiments and B) its structure after magnification (X200). C-E) Wettability of the construct. Administration of the reference liquid droplet on the construct surface. F) Histogram showing the time required for reference liquid to completely wet the construct surface. Note that the droplet is absorbed within the part of the second.", publisher = "Walter De Gruyter Gmbh, Berlin", journal = "Biomedical Engineering-Biomedizinische Technik", title = "Supplementary information for the article: Micić, M.; Antonijević, Đ.; Milutinović-Smiljanić, S.; Trisić, D.; Colović, B.; Kosanović, D.; Prokić, B.; Vasić, J.; Zivković, S.; Milašin, J.; Danilović, V.; Đurić, M.; Jokanović, V. Developing a Novel Resorptive Hydroxyapatite-Based Bone Substitute for over-Critical Size Defect Reconstruction: Physicochemical and Biological Characterization and Proof of Concept in Segmental Rabbit’s Ulna Reconstruction. Biomedical Engineering-Biomedizinische Technik 2020, 65 (4), 491–505. https://doi.org/10.1515/bmt-2019-0218.", url = "https://hdl.handle.net/21.15107/rcub_intor_661" }
Micić, M., Antonijević, Đ., Milutinović-Smiljanić, S., Trisić, D., Colović, B., Kosanović, D., Prokić, B., Vasić, J., Zivković, S., Milašin, J., Danilović, V., Đurić, M.,& Jokanović, V.. (2020). Supplementary information for the article: Micić, M.; Antonijević, Đ.; Milutinović-Smiljanić, S.; Trisić, D.; Colović, B.; Kosanović, D.; Prokić, B.; Vasić, J.; Zivković, S.; Milašin, J.; Danilović, V.; Đurić, M.; Jokanović, V. Developing a Novel Resorptive Hydroxyapatite-Based Bone Substitute for over-Critical Size Defect Reconstruction: Physicochemical and Biological Characterization and Proof of Concept in Segmental Rabbit’s Ulna Reconstruction. Biomedical Engineering-Biomedizinische Technik 2020, 65 (4), 491–505. https://doi.org/10.1515/bmt-2019-0218.. in Biomedical Engineering-Biomedizinische Technik Walter De Gruyter Gmbh, Berlin.. https://hdl.handle.net/21.15107/rcub_intor_661
Micić M, Antonijević Đ, Milutinović-Smiljanić S, Trisić D, Colović B, Kosanović D, Prokić B, Vasić J, Zivković S, Milašin J, Danilović V, Đurić M, Jokanović V. Supplementary information for the article: Micić, M.; Antonijević, Đ.; Milutinović-Smiljanić, S.; Trisić, D.; Colović, B.; Kosanović, D.; Prokić, B.; Vasić, J.; Zivković, S.; Milašin, J.; Danilović, V.; Đurić, M.; Jokanović, V. Developing a Novel Resorptive Hydroxyapatite-Based Bone Substitute for over-Critical Size Defect Reconstruction: Physicochemical and Biological Characterization and Proof of Concept in Segmental Rabbit’s Ulna Reconstruction. Biomedical Engineering-Biomedizinische Technik 2020, 65 (4), 491–505. https://doi.org/10.1515/bmt-2019-0218.. in Biomedical Engineering-Biomedizinische Technik. 2020;. https://hdl.handle.net/21.15107/rcub_intor_661 .
Micić, Milutin, Antonijević, Đorđe, Milutinović-Smiljanić, Sanja, Trisić, Dijana, Colović, Božana, Kosanović, Dejana, Prokić, Bogomir, Vasić, Jugoslav, Zivković, Slavoljub, Milašin, Jelena, Danilović, Vesna, Đurić, Marija, Jokanović, Vukoman, "Supplementary information for the article: Micić, M.; Antonijević, Đ.; Milutinović-Smiljanić, S.; Trisić, D.; Colović, B.; Kosanović, D.; Prokić, B.; Vasić, J.; Zivković, S.; Milašin, J.; Danilović, V.; Đurić, M.; Jokanović, V. Developing a Novel Resorptive Hydroxyapatite-Based Bone Substitute for over-Critical Size Defect Reconstruction: Physicochemical and Biological Characterization and Proof of Concept in Segmental Rabbit’s Ulna Reconstruction. Biomedical Engineering-Biomedizinische Technik 2020, 65 (4), 491–505. https://doi.org/10.1515/bmt-2019-0218." in Biomedical Engineering-Biomedizinische Technik (2020), https://hdl.handle.net/21.15107/rcub_intor_661 .