TY  - JOUR
AU  - Korać Jačić, Jelena
AU  - Dimitrijević, Milena S.
AU  - Bajuk-Bogdanović, Danica V.
AU  - Stanković, Dalibor
AU  - Savić, Slađana D.
AU  - Spasojević, Ivan B.
AU  - MIlenković, Milica R.
PY  - 2023
UR  - http://cherry.chem.bg.ac.rs/handle/123456789/6043
AB  - The interactions of drugs with iron are of interest in relation to the potential effects of iron-rich foods and iron supplements on sorption and bioavailability. Doxycycline (DOX), a member of the tetracycline class of broad-spectrum antibiotics, is frequently administered by oral route. In the digestive tract, DOX can be exposed to iron at different pH values (stomach pH 1.5–4, duodenum pH 5–6, distal jejunum and ileum pH 7–8). In relation to this, we analyzed the impact of pH on Fe3+-DOX complex formation. The optimal conditions for Fe3+-DOX complex formation are pH = 4 and [Fe3+]/[DOX] = 6 molar ratio. HESI-MS showed that Fe3+-DOX complex has 1:1 stoichiometry. Raman spectra of Fe3+-DOX complex indicate the presence of two Fe3+-binding sites in DOX structure: tricarbonylamide group of ring A and phenolic-diketone oxygens of BCD rings. The Fe3+-DOX complex formed at pH = 4 is less susceptible to oxidation than DOX at this pH. The increase of pH induces the decomposition of Fe3+-DOX complex without oxidative degradation of DOX. The pH dependence of Fe3+-DOX complex formation may promote unwanted effects of DOX, impeding the absorption that mainly takes place in duodenum. This could further result in higher concentrations in the digestive tract and to pronounced impact on gut microbiota.
PB  - Springer
T2  - Journal of Biological Inorganic Chemistry
T1  - The formation of Fe3+-doxycycline complex is pH dependent: implications to doxycycline bioavailability
VL  - 28
SP  - 679
EP  - 687
DO  - 10.1007/s00775-023-02018-w
ER  - 

@article{
author = "Korać Jačić, Jelena and Dimitrijević, Milena S. and Bajuk-Bogdanović, Danica V. and Stanković, Dalibor and Savić, Slađana D. and Spasojević, Ivan B. and MIlenković, Milica R.",
year = "2023",
abstract = "The interactions of drugs with iron are of interest in relation to the potential effects of iron-rich foods and iron supplements on sorption and bioavailability. Doxycycline (DOX), a member of the tetracycline class of broad-spectrum antibiotics, is frequently administered by oral route. In the digestive tract, DOX can be exposed to iron at different pH values (stomach pH 1.5–4, duodenum pH 5–6, distal jejunum and ileum pH 7–8). In relation to this, we analyzed the impact of pH on Fe3+-DOX complex formation. The optimal conditions for Fe3+-DOX complex formation are pH = 4 and [Fe3+]/[DOX] = 6 molar ratio. HESI-MS showed that Fe3+-DOX complex has 1:1 stoichiometry. Raman spectra of Fe3+-DOX complex indicate the presence of two Fe3+-binding sites in DOX structure: tricarbonylamide group of ring A and phenolic-diketone oxygens of BCD rings. The Fe3+-DOX complex formed at pH = 4 is less susceptible to oxidation than DOX at this pH. The increase of pH induces the decomposition of Fe3+-DOX complex without oxidative degradation of DOX. The pH dependence of Fe3+-DOX complex formation may promote unwanted effects of DOX, impeding the absorption that mainly takes place in duodenum. This could further result in higher concentrations in the digestive tract and to pronounced impact on gut microbiota.",
publisher = "Springer",
journal = "Journal of Biological Inorganic Chemistry",
title = "The formation of Fe3+-doxycycline complex is pH dependent: implications to doxycycline bioavailability",
volume = "28",
pages = "679-687",
doi = "10.1007/s00775-023-02018-w"
}

Korać Jačić, J., Dimitrijević, M. S., Bajuk-Bogdanović, D. V., Stanković, D., Savić, S. D., Spasojević, I. B.,& MIlenković, M. R.. (2023). The formation of Fe3+-doxycycline complex is pH dependent: implications to doxycycline bioavailability. in Journal of Biological Inorganic Chemistry
Springer., 28, 679-687.
https://doi.org/10.1007/s00775-023-02018-w

Korać Jačić J, Dimitrijević MS, Bajuk-Bogdanović DV, Stanković D, Savić SD, Spasojević IB, MIlenković MR. The formation of Fe3+-doxycycline complex is pH dependent: implications to doxycycline bioavailability. in Journal of Biological Inorganic Chemistry. 2023;28:679-687.
doi:10.1007/s00775-023-02018-w .

Korać Jačić, Jelena, Dimitrijević, Milena S., Bajuk-Bogdanović, Danica V., Stanković, Dalibor, Savić, Slađana D., Spasojević, Ivan B., MIlenković, Milica R., "The formation of Fe3+-doxycycline complex is pH dependent: implications to doxycycline bioavailability" in Journal of Biological Inorganic Chemistry, 28 (2023):679-687,
https://doi.org/10.1007/s00775-023-02018-w . .

TY  - JOUR
AU  - Korać Jačić, Jelena
AU  - Dimitrijević, Milena S.
AU  - Bajuk-Bogdanović, Danica V.
AU  - Stanković, Dalibor
AU  - Savić, Slađana D.
AU  - Spasojević, Ivan B.
AU  - MIlenković, Milica R.
PY  - 2023
UR  - http://cherry.chem.bg.ac.rs/handle/123456789/6044
AB  - The interactions of drugs with iron are of interest in relation to the potential effects of iron-rich foods and iron supplements on sorption and bioavailability. Doxycycline (DOX), a member of the tetracycline class of broad-spectrum antibiotics, is frequently administered by oral route. In the digestive tract, DOX can be exposed to iron at different pH values (stomach pH 1.5–4, duodenum pH 5–6, distal jejunum and ileum pH 7–8). In relation to this, we analyzed the impact of pH on Fe3+-DOX complex formation. The optimal conditions for Fe3+-DOX complex formation are pH = 4 and [Fe3+]/[DOX] = 6 molar ratio. HESI-MS showed that Fe3+-DOX complex has 1:1 stoichiometry. Raman spectra of Fe3+-DOX complex indicate the presence of two Fe3+-binding sites in DOX structure: tricarbonylamide group of ring A and phenolic-diketone oxygens of BCD rings. The Fe3+-DOX complex formed at pH = 4 is less susceptible to oxidation than DOX at this pH. The increase of pH induces the decomposition of Fe3+-DOX complex without oxidative degradation of DOX. The pH dependence of Fe3+-DOX complex formation may promote unwanted effects of DOX, impeding the absorption that mainly takes place in duodenum. This could further result in higher concentrations in the digestive tract and to pronounced impact on gut microbiota.
PB  - Springer
T2  - Journal of Biological Inorganic Chemistry
T1  - The formation of Fe3+-doxycycline complex is pH dependent: implications to doxycycline bioavailability
VL  - 28
SP  - 679
EP  - 687
DO  - 10.1007/s00775-023-02018-w
ER  - 

@article{
author = "Korać Jačić, Jelena and Dimitrijević, Milena S. and Bajuk-Bogdanović, Danica V. and Stanković, Dalibor and Savić, Slađana D. and Spasojević, Ivan B. and MIlenković, Milica R.",
year = "2023",
abstract = "The interactions of drugs with iron are of interest in relation to the potential effects of iron-rich foods and iron supplements on sorption and bioavailability. Doxycycline (DOX), a member of the tetracycline class of broad-spectrum antibiotics, is frequently administered by oral route. In the digestive tract, DOX can be exposed to iron at different pH values (stomach pH 1.5–4, duodenum pH 5–6, distal jejunum and ileum pH 7–8). In relation to this, we analyzed the impact of pH on Fe3+-DOX complex formation. The optimal conditions for Fe3+-DOX complex formation are pH = 4 and [Fe3+]/[DOX] = 6 molar ratio. HESI-MS showed that Fe3+-DOX complex has 1:1 stoichiometry. Raman spectra of Fe3+-DOX complex indicate the presence of two Fe3+-binding sites in DOX structure: tricarbonylamide group of ring A and phenolic-diketone oxygens of BCD rings. The Fe3+-DOX complex formed at pH = 4 is less susceptible to oxidation than DOX at this pH. The increase of pH induces the decomposition of Fe3+-DOX complex without oxidative degradation of DOX. The pH dependence of Fe3+-DOX complex formation may promote unwanted effects of DOX, impeding the absorption that mainly takes place in duodenum. This could further result in higher concentrations in the digestive tract and to pronounced impact on gut microbiota.",
publisher = "Springer",
journal = "Journal of Biological Inorganic Chemistry",
title = "The formation of Fe3+-doxycycline complex is pH dependent: implications to doxycycline bioavailability",
volume = "28",
pages = "679-687",
doi = "10.1007/s00775-023-02018-w"
}

Korać Jačić, J., Dimitrijević, M. S., Bajuk-Bogdanović, D. V., Stanković, D., Savić, S. D., Spasojević, I. B.,& MIlenković, M. R.. (2023). The formation of Fe3+-doxycycline complex is pH dependent: implications to doxycycline bioavailability. in Journal of Biological Inorganic Chemistry
Springer., 28, 679-687.
https://doi.org/10.1007/s00775-023-02018-w

Korać Jačić J, Dimitrijević MS, Bajuk-Bogdanović DV, Stanković D, Savić SD, Spasojević IB, MIlenković MR. The formation of Fe3+-doxycycline complex is pH dependent: implications to doxycycline bioavailability. in Journal of Biological Inorganic Chemistry. 2023;28:679-687.
doi:10.1007/s00775-023-02018-w .

Korać Jačić, Jelena, Dimitrijević, Milena S., Bajuk-Bogdanović, Danica V., Stanković, Dalibor, Savić, Slađana D., Spasojević, Ivan B., MIlenković, Milica R., "The formation of Fe3+-doxycycline complex is pH dependent: implications to doxycycline bioavailability" in Journal of Biological Inorganic Chemistry, 28 (2023):679-687,
https://doi.org/10.1007/s00775-023-02018-w . .

TY  - JOUR
AU  - Korać Jačić, Jelena
AU  - Bajuk-Bogdanović, Danica
AU  - Savić, Slađana D.
AU  - Božić Cvijan, Bojana
AU  - Spasojević, Milica
AU  - MIlenković, Milica R.
PY  - 2023
UR  - http://cherry.chem.bg.ac.rs/handle/123456789/5881
AB  - Hydralazine (HL), a frequently prescribed oral antihypertensive drug, shows redox interactions with transition metals such as copper that are not fully understood. Copper may be present at high concentrations in the digestive tract and can affect oral drugs. An important parameter for such interactions is pH, which changes from acidic in the gastric juice to neutral pH in intestines. In this study, we examined interactions of HL with Cu2+ ions in conditions that mimic pH shift in the digestive tract using UV–Vis, Raman and EPR spectroscopy, cyclic voltammetry and oximetry. In the acidic solution, Cu2+ formed a stable mononuclear complex with two bidentate coordinated HL molecules. On the other hand, at neutral pH, Cu2+ initiated oxidation and degradation of HL. The degradation was more rapid in the HL-Cu2+ system that was initially prepared at acidic pH and then shifted to neutral pH. The formation of the complex at acidic pH increases the availability of Cu2+ for redox reactions after the shift to neutral pH at which Cu2+ is poorly soluble. These results imply that the change of pH along the digestive tract may promote HL degradation by allowing the formation of the complex at gastric pH which makes Cu2+ available for subsequent oxidation of HL at neutral pH.
PB  - Elsevier
T2  - Journal of Inorganic Biochemistry
T1  - Coordination of hydralazine with Cu2+ at acidic pH promotes its oxidative degradation at neutral pH
VL  - 243
SP  - 112181
DO  - 10.1016/j.jinorgbio.2023.112181
ER  - 

@article{
author = "Korać Jačić, Jelena and Bajuk-Bogdanović, Danica and Savić, Slađana D. and Božić Cvijan, Bojana and Spasojević, Milica and MIlenković, Milica R.",
year = "2023",
abstract = "Hydralazine (HL), a frequently prescribed oral antihypertensive drug, shows redox interactions with transition metals such as copper that are not fully understood. Copper may be present at high concentrations in the digestive tract and can affect oral drugs. An important parameter for such interactions is pH, which changes from acidic in the gastric juice to neutral pH in intestines. In this study, we examined interactions of HL with Cu2+ ions in conditions that mimic pH shift in the digestive tract using UV–Vis, Raman and EPR spectroscopy, cyclic voltammetry and oximetry. In the acidic solution, Cu2+ formed a stable mononuclear complex with two bidentate coordinated HL molecules. On the other hand, at neutral pH, Cu2+ initiated oxidation and degradation of HL. The degradation was more rapid in the HL-Cu2+ system that was initially prepared at acidic pH and then shifted to neutral pH. The formation of the complex at acidic pH increases the availability of Cu2+ for redox reactions after the shift to neutral pH at which Cu2+ is poorly soluble. These results imply that the change of pH along the digestive tract may promote HL degradation by allowing the formation of the complex at gastric pH which makes Cu2+ available for subsequent oxidation of HL at neutral pH.",
publisher = "Elsevier",
journal = "Journal of Inorganic Biochemistry",
title = "Coordination of hydralazine with Cu2+ at acidic pH promotes its oxidative degradation at neutral pH",
volume = "243",
pages = "112181",
doi = "10.1016/j.jinorgbio.2023.112181"
}

Korać Jačić, J., Bajuk-Bogdanović, D., Savić, S. D., Božić Cvijan, B., Spasojević, M.,& MIlenković, M. R.. (2023). Coordination of hydralazine with Cu2+ at acidic pH promotes its oxidative degradation at neutral pH. in Journal of Inorganic Biochemistry
Elsevier., 243, 112181.
https://doi.org/10.1016/j.jinorgbio.2023.112181

Korać Jačić J, Bajuk-Bogdanović D, Savić SD, Božić Cvijan B, Spasojević M, MIlenković MR. Coordination of hydralazine with Cu2+ at acidic pH promotes its oxidative degradation at neutral pH. in Journal of Inorganic Biochemistry. 2023;243:112181.
doi:10.1016/j.jinorgbio.2023.112181 .

Korać Jačić, Jelena, Bajuk-Bogdanović, Danica, Savić, Slađana D., Božić Cvijan, Bojana, Spasojević, Milica, MIlenković, Milica R., "Coordination of hydralazine with Cu2+ at acidic pH promotes its oxidative degradation at neutral pH" in Journal of Inorganic Biochemistry, 243 (2023):112181,
https://doi.org/10.1016/j.jinorgbio.2023.112181 . .

TY  - JOUR
AU  - Korać Jačić, Jelena
AU  - Bajuk-Bogdanović, Danica
AU  - Savić, Slađana D.
AU  - Božić Cvijan, Bojana
AU  - Spasojević, Milica
AU  - MIlenković, Milica R.
PY  - 2023
UR  - http://cherry.chem.bg.ac.rs/handle/123456789/5882
AB  - Hydralazine (HL), a frequently prescribed oral antihypertensive drug, shows redox interactions with transition metals such as copper that are not fully understood. Copper may be present at high concentrations in the digestive tract and can affect oral drugs. An important parameter for such interactions is pH, which changes from acidic in the gastric juice to neutral pH in intestines. In this study, we examined interactions of HL with Cu2+ ions in conditions that mimic pH shift in the digestive tract using UV–Vis, Raman and EPR spectroscopy, cyclic voltammetry and oximetry. In the acidic solution, Cu2+ formed a stable mononuclear complex with two bidentate coordinated HL molecules. On the other hand, at neutral pH, Cu2+ initiated oxidation and degradation of HL. The degradation was more rapid in the HL-Cu2+ system that was initially prepared at acidic pH and then shifted to neutral pH. The formation of the complex at acidic pH increases the availability of Cu2+ for redox reactions after the shift to neutral pH at which Cu2+ is poorly soluble. These results imply that the change of pH along the digestive tract may promote HL degradation by allowing the formation of the complex at gastric pH which makes Cu2+ available for subsequent oxidation of HL at neutral pH.
PB  - Elsevier
T2  - Journal of Inorganic Biochemistry
T1  - Coordination of hydralazine with Cu2+ at acidic pH promotes its oxidative degradation at neutral pH
VL  - 243
SP  - 112181
DO  - 10.1016/j.jinorgbio.2023.112181
ER  - 

@article{
author = "Korać Jačić, Jelena and Bajuk-Bogdanović, Danica and Savić, Slađana D. and Božić Cvijan, Bojana and Spasojević, Milica and MIlenković, Milica R.",
year = "2023",
abstract = "Hydralazine (HL), a frequently prescribed oral antihypertensive drug, shows redox interactions with transition metals such as copper that are not fully understood. Copper may be present at high concentrations in the digestive tract and can affect oral drugs. An important parameter for such interactions is pH, which changes from acidic in the gastric juice to neutral pH in intestines. In this study, we examined interactions of HL with Cu2+ ions in conditions that mimic pH shift in the digestive tract using UV–Vis, Raman and EPR spectroscopy, cyclic voltammetry and oximetry. In the acidic solution, Cu2+ formed a stable mononuclear complex with two bidentate coordinated HL molecules. On the other hand, at neutral pH, Cu2+ initiated oxidation and degradation of HL. The degradation was more rapid in the HL-Cu2+ system that was initially prepared at acidic pH and then shifted to neutral pH. The formation of the complex at acidic pH increases the availability of Cu2+ for redox reactions after the shift to neutral pH at which Cu2+ is poorly soluble. These results imply that the change of pH along the digestive tract may promote HL degradation by allowing the formation of the complex at gastric pH which makes Cu2+ available for subsequent oxidation of HL at neutral pH.",
publisher = "Elsevier",
journal = "Journal of Inorganic Biochemistry",
title = "Coordination of hydralazine with Cu2+ at acidic pH promotes its oxidative degradation at neutral pH",
volume = "243",
pages = "112181",
doi = "10.1016/j.jinorgbio.2023.112181"
}

Korać Jačić, J., Bajuk-Bogdanović, D., Savić, S. D., Božić Cvijan, B., Spasojević, M.,& MIlenković, M. R.. (2023). Coordination of hydralazine with Cu2+ at acidic pH promotes its oxidative degradation at neutral pH. in Journal of Inorganic Biochemistry
Elsevier., 243, 112181.
https://doi.org/10.1016/j.jinorgbio.2023.112181

Korać Jačić J, Bajuk-Bogdanović D, Savić SD, Božić Cvijan B, Spasojević M, MIlenković MR. Coordination of hydralazine with Cu2+ at acidic pH promotes its oxidative degradation at neutral pH. in Journal of Inorganic Biochemistry. 2023;243:112181.
doi:10.1016/j.jinorgbio.2023.112181 .

Korać Jačić, Jelena, Bajuk-Bogdanović, Danica, Savić, Slađana D., Božić Cvijan, Bojana, Spasojević, Milica, MIlenković, Milica R., "Coordination of hydralazine with Cu2+ at acidic pH promotes its oxidative degradation at neutral pH" in Journal of Inorganic Biochemistry, 243 (2023):112181,
https://doi.org/10.1016/j.jinorgbio.2023.112181 . .

TY  - JOUR
AU  - Korać Jačić, Jelena
AU  - Milenković, Milica R.
AU  - Bajuk-Bogdanović, Danica
AU  - Stanković, Dalibor
AU  - Dimitrijević, Milena
AU  - Spasojević, Ivan
PY  - 2022
UR  - http://cherry.chem.bg.ac.rs/handle/123456789/5511
AB  - There is a significant interest in understanding coordination and photo-chemistry of tetracycline antibiotics, primarily in relation to the development of advanced oxidation processes for degradation of these pollutants in water processing. Herein we analyzed the pH-dependence of interactions of tetracycline with ferric iron and photosensitivity of tetracycline to UV-A and UV-B, using a set of methods – UV–vis, Raman and electron paramagnetic resonance spectroscopy, MS spectrometry, HPLC, and cyclic voltammetry. Tetracycline and Fe3+ mainly bind through amide and OH groups in tricarbonylamide moiety to form a stable complex with 1:1 stoichiometry at pH ≤ 5. The interaction is reversible and tetracycline is released from the complex with pH increase. Tetracycline in the complex is stabilized and less susceptible than free tetracycline to oxidation by hydroxyl radical that is produced by UV-induced photolysis of Fe3+–OH- complexes. Redox properties of tetracycline were altered with increasing pH and it showed increased susceptibility to UV-induced degradation. In close, the system composed of tetracycline and ferric iron shows coordination and photo-redox chemistry that is dependent of pH in relation to the solubility of Fe3+ species and protonation of tetracycline. The development and optimization of advanced oxidation processes should take into account that iron may bind and stabilize pollutants and that the redox landscape of water changes drastically with pH.
PB  - Elsevier
T2  - Journal of Photochemistry & Photobiology, A: Chemistry
T1  - The impact of ferric iron and pH on photo-degradation of tetracycline in water
VL  - 433
SP  - 114155
DO  - 10.1016/j.jphotochem.2022.114155
ER  - 

@article{
author = "Korać Jačić, Jelena and Milenković, Milica R. and Bajuk-Bogdanović, Danica and Stanković, Dalibor and Dimitrijević, Milena and Spasojević, Ivan",
year = "2022",
abstract = "There is a significant interest in understanding coordination and photo-chemistry of tetracycline antibiotics, primarily in relation to the development of advanced oxidation processes for degradation of these pollutants in water processing. Herein we analyzed the pH-dependence of interactions of tetracycline with ferric iron and photosensitivity of tetracycline to UV-A and UV-B, using a set of methods – UV–vis, Raman and electron paramagnetic resonance spectroscopy, MS spectrometry, HPLC, and cyclic voltammetry. Tetracycline and Fe3+ mainly bind through amide and OH groups in tricarbonylamide moiety to form a stable complex with 1:1 stoichiometry at pH ≤ 5. The interaction is reversible and tetracycline is released from the complex with pH increase. Tetracycline in the complex is stabilized and less susceptible than free tetracycline to oxidation by hydroxyl radical that is produced by UV-induced photolysis of Fe3+–OH- complexes. Redox properties of tetracycline were altered with increasing pH and it showed increased susceptibility to UV-induced degradation. In close, the system composed of tetracycline and ferric iron shows coordination and photo-redox chemistry that is dependent of pH in relation to the solubility of Fe3+ species and protonation of tetracycline. The development and optimization of advanced oxidation processes should take into account that iron may bind and stabilize pollutants and that the redox landscape of water changes drastically with pH.",
publisher = "Elsevier",
journal = "Journal of Photochemistry & Photobiology, A: Chemistry",
title = "The impact of ferric iron and pH on photo-degradation of tetracycline in water",
volume = "433",
pages = "114155",
doi = "10.1016/j.jphotochem.2022.114155"
}

Korać Jačić, J., Milenković, M. R., Bajuk-Bogdanović, D., Stanković, D., Dimitrijević, M.,& Spasojević, I.. (2022). The impact of ferric iron and pH on photo-degradation of tetracycline in water. in Journal of Photochemistry & Photobiology, A: Chemistry
Elsevier., 433, 114155.
https://doi.org/10.1016/j.jphotochem.2022.114155

Korać Jačić J, Milenković MR, Bajuk-Bogdanović D, Stanković D, Dimitrijević M, Spasojević I. The impact of ferric iron and pH on photo-degradation of tetracycline in water. in Journal of Photochemistry & Photobiology, A: Chemistry. 2022;433:114155.
doi:10.1016/j.jphotochem.2022.114155 .

Korać Jačić, Jelena, Milenković, Milica R., Bajuk-Bogdanović, Danica, Stanković, Dalibor, Dimitrijević, Milena, Spasojević, Ivan, "The impact of ferric iron and pH on photo-degradation of tetracycline in water" in Journal of Photochemistry & Photobiology, A: Chemistry, 433 (2022):114155,
https://doi.org/10.1016/j.jphotochem.2022.114155 . .

TY  - DATA
AU  - Korać Jačić, Jelena
AU  - Milenković, Milica R.
AU  - Bajuk-Bogdanović, Danica
AU  - Stanković, Dalibor
AU  - Dimitrijević, Milena
AU  - Spasojević, Ivan
PY  - 2022
UR  - http://cherry.chem.bg.ac.rs/handle/123456789/5511
UR  - http://cherry.chem.bg.ac.rs/handle/123456789/5512
AB  - There is a significant interest in understanding coordination and photo-chemistry of tetracycline antibiotics, primarily in relation to the development of advanced oxidation processes for degradation of these pollutants in water processing. Herein we analyzed the pH-dependence of interactions of tetracycline with ferric iron and photosensitivity of tetracycline to UV-A and UV-B, using a set of methods – UV–vis, Raman and electron paramagnetic resonance spectroscopy, MS spectrometry, HPLC, and cyclic voltammetry. Tetracycline and Fe3+ mainly bind through amide and OH groups in tricarbonylamide moiety to form a stable complex with 1:1 stoichiometry at pH ≤ 5. The interaction is reversible and tetracycline is released from the complex with pH increase. Tetracycline in the complex is stabilized and less susceptible than free tetracycline to oxidation by hydroxyl radical that is produced by UV-induced photolysis of Fe3+–OH- complexes. Redox properties of tetracycline were altered with increasing pH and it showed increased susceptibility to UV-induced degradation. In close, the system composed of tetracycline and ferric iron shows coordination and photo-redox chemistry that is dependent of pH in relation to the solubility of Fe3+ species and protonation of tetracycline. The development and optimization of advanced oxidation processes should take into account that iron may bind and stabilize pollutants and that the redox landscape of water changes drastically with pH.
PB  - Elsevier
T2  - Journal of Photochemistry & Photobiology, A: Chemistry
T1  - Supplementary information for the article: Korać Jačić, J.; Milenković, M. R.; Bajuk-Bogdanović, D.; Stanković, D.; Dimitrijević, M.; Spasojević, I. The Impact of Ferric Iron and PH on Photo-Degradation of Tetracycline in Water. Journal of Photochemistry and Photobiology A: Chemistry 2022, 433, 114155. https://doi.org/10.1016/j.jphotochem.2022.114155.
VL  - 433
SP  - 114155
UR  - https://hdl.handle.net/21.15107/rcub_cherry_5512
ER  - 

@misc{
author = "Korać Jačić, Jelena and Milenković, Milica R. and Bajuk-Bogdanović, Danica and Stanković, Dalibor and Dimitrijević, Milena and Spasojević, Ivan",
year = "2022",
abstract = "There is a significant interest in understanding coordination and photo-chemistry of tetracycline antibiotics, primarily in relation to the development of advanced oxidation processes for degradation of these pollutants in water processing. Herein we analyzed the pH-dependence of interactions of tetracycline with ferric iron and photosensitivity of tetracycline to UV-A and UV-B, using a set of methods – UV–vis, Raman and electron paramagnetic resonance spectroscopy, MS spectrometry, HPLC, and cyclic voltammetry. Tetracycline and Fe3+ mainly bind through amide and OH groups in tricarbonylamide moiety to form a stable complex with 1:1 stoichiometry at pH ≤ 5. The interaction is reversible and tetracycline is released from the complex with pH increase. Tetracycline in the complex is stabilized and less susceptible than free tetracycline to oxidation by hydroxyl radical that is produced by UV-induced photolysis of Fe3+–OH- complexes. Redox properties of tetracycline were altered with increasing pH and it showed increased susceptibility to UV-induced degradation. In close, the system composed of tetracycline and ferric iron shows coordination and photo-redox chemistry that is dependent of pH in relation to the solubility of Fe3+ species and protonation of tetracycline. The development and optimization of advanced oxidation processes should take into account that iron may bind and stabilize pollutants and that the redox landscape of water changes drastically with pH.",
publisher = "Elsevier",
journal = "Journal of Photochemistry & Photobiology, A: Chemistry",
title = "Supplementary information for the article: Korać Jačić, J.; Milenković, M. R.; Bajuk-Bogdanović, D.; Stanković, D.; Dimitrijević, M.; Spasojević, I. The Impact of Ferric Iron and PH on Photo-Degradation of Tetracycline in Water. Journal of Photochemistry and Photobiology A: Chemistry 2022, 433, 114155. https://doi.org/10.1016/j.jphotochem.2022.114155.",
volume = "433",
pages = "114155",
url = "https://hdl.handle.net/21.15107/rcub_cherry_5512"
}

Korać Jačić, J., Milenković, M. R., Bajuk-Bogdanović, D., Stanković, D., Dimitrijević, M.,& Spasojević, I.. (2022). Supplementary information for the article: Korać Jačić, J.; Milenković, M. R.; Bajuk-Bogdanović, D.; Stanković, D.; Dimitrijević, M.; Spasojević, I. The Impact of Ferric Iron and PH on Photo-Degradation of Tetracycline in Water. Journal of Photochemistry and Photobiology A: Chemistry 2022, 433, 114155. https://doi.org/10.1016/j.jphotochem.2022.114155.. in Journal of Photochemistry & Photobiology, A: Chemistry
Elsevier., 433, 114155.
https://hdl.handle.net/21.15107/rcub_cherry_5512

Korać Jačić J, Milenković MR, Bajuk-Bogdanović D, Stanković D, Dimitrijević M, Spasojević I. Supplementary information for the article: Korać Jačić, J.; Milenković, M. R.; Bajuk-Bogdanović, D.; Stanković, D.; Dimitrijević, M.; Spasojević, I. The Impact of Ferric Iron and PH on Photo-Degradation of Tetracycline in Water. Journal of Photochemistry and Photobiology A: Chemistry 2022, 433, 114155. https://doi.org/10.1016/j.jphotochem.2022.114155.. in Journal of Photochemistry & Photobiology, A: Chemistry. 2022;433:114155.
https://hdl.handle.net/21.15107/rcub_cherry_5512 .

Korać Jačić, Jelena, Milenković, Milica R., Bajuk-Bogdanović, Danica, Stanković, Dalibor, Dimitrijević, Milena, Spasojević, Ivan, "Supplementary information for the article: Korać Jačić, J.; Milenković, M. R.; Bajuk-Bogdanović, D.; Stanković, D.; Dimitrijević, M.; Spasojević, I. The Impact of Ferric Iron and PH on Photo-Degradation of Tetracycline in Water. Journal of Photochemistry and Photobiology A: Chemistry 2022, 433, 114155. https://doi.org/10.1016/j.jphotochem.2022.114155." in Journal of Photochemistry & Photobiology, A: Chemistry, 433 (2022):114155,
https://hdl.handle.net/21.15107/rcub_cherry_5512 .

TY  - THES
AU  - Korać Jačić, Jelena K.
PY  - 2020
UR  - http://eteze.bg.ac.rs/application/showtheses?thesesId=7870
UR  - https://fedorabg.bg.ac.rs/fedora/get/o:23173/bdef:Content/download
UR  - http://vbs.rs/scripts/cobiss?command=DISPLAY&base=70036&RID=31031049
UR  - https://nardus.mpn.gov.rs/handle/123456789/17801
UR  - https://cherry.chem.bg.ac.rs/handle/123456789/4365
AB  - Epinefrin je kateholamin sa značajnom fiziološkom ulogom. Konformacija ovog molekulautiče na njegovu interakciju sa drugim molekulima i na njegove biološke efekte. Na fiziološkimpH vrednostima, koordinativne sposobnosti epinefrina prema gvožđu i redoks interakcije epinefrinasa gvožđem su od suštinske važnosti za razumevanje dve veoma različite pojave. Prva pojava ještetno dejstvo koje hronični psihološki/sredinski stres izaziva na nivou kardiovaskularnog sistema.Druga pojava je umrežavanje kateholaminima bogatih biopolimera i struktura. Kako bi se rasvetlileuloge rastvarača i vodoničnih veza u interakcijama epinefrina sa gvožđem, proučavana jekonformacija epinefrina u vodi i polarnom rastvaraču dimetil sulfoksidu (DMSO).U ovoj disertaciji su predstavljeni rezultati proučavanja mehanizama interakcije epinefrinasa Fe2+ i Fe3+ jonima pri različitim koncentracionim odnosima na pH 7,4, odnosno na pH vrednostikoja odgovara fiziološkim uslovima. U svrhu istraživanja bioloških efekata epinefrina, u ovojdisertaciji su predstavljena ispitivanja efekta Epi-Fe3+ kompleksa na ćelije koje konstitutivnoeksprimiraju adrenergičke receptore.Konformacije epinefrina u polarnim rastvaračima, vodi i DMSO, su proučavane metodamaH nuklearne magnetne rezonance (1H NMR) kao i dvodimenzionalnim metodama nuklearnemagnetne rezonance, i to: 1H - 1H COSY, 1H - 15N HSQC i NOESY. Na NH2 i CH2 grupamaepinefrina su uočeni hemijski neekvivalentni protoni prilikom korišćenja DMSO kao rastvarača.Ove pojave nisu uočene kada je rastvarač bila voda. Analizom uticaja korišćenog rastvarača naNMR spektar, i analizom uticaja povećanja temperature uzorka na NMR spektar, dolazi se dozaključka da jedan od protona amino grupe formira jaku intramolekulsku vezu sa alifatičnomhidroksilnom grupom, koja je pak H donor drugoj intermolekularnoj vezi sa DMSO. PomoćuNOESY metode su prikupljeni podaci o prostornoj poziciji protona u bočnom lancu. Na taj način jeformiran 3D model konformacije epinefrina u DMSO. Ukratko, epinefrin formira dodatni petočlaniprsten koji sadrži bifurkovane intramolekulske/intermolekulske vodonične veze i zauzima strukturuoblika škorpiona, gde kateholni prsten predstavlja telo škorpiona, a bočni lanac predstavlja rep kojije povijen u smeru glave škorpiona. U vodi, kao rastvaraču, konformacija epinefrina ne posedujeintramolekulske vodonične veze pa je tada struktura ovog molekula najverovatnije definisanavodoničnim vezama sa molekulima vode.U okviru ove disertacije ispitivanjima je ustanovljeno da epinefrin sa Fe3+ jonima gradistabilne visokospinske komplekse čija je stehiometrija 1:1 ili 3:1. Stehiometrija ovog kompleksazavisi od odnosa koncentracija epinefrina i Fe3+ jona. Na kateholnom prstenu epinefrina atomikiseonika predstavljaju mesto za formiranje koordinacione veze unutar fiziološki relevantnogbidentatnog 1:1 kompleksa. Fe3+ katjon ima slab uticaj na redoks osobine epinefrina. Međutim,epinefrin i Fe2+ joni grade kompleks koji je jak redukcioni agens. Posledica je redukcija O2,proizvodnja vodonik peroksida i formiranje Epi-Fe3+ kompleksa. U ovom procesu epinefrin se neoksiduje, odnosno Fe2+ jon nije prenosilac, već donor elektrona. Oksidacija Fe2+ jona koja jekatalizovana epinefrinom predstavlja moguće hemijsko objašnjenje za stresom izazvana oštećenjaćelija srca. Takođe, rezultati ovih ispitivanja su u skladu sa prethodnim istraživanjima kateholaminau polimerima i njihovih interakcija sa gvožđem, i upućuju na nove strategije za poboljšavanjeefikasnosti umrežavanja kateholaminima bogatih biopolimera i struktura.U stresnim situacijama epinefrin se luči i može interagovati sa labilnim gvožđem koje senalazi u ljudskoj plazmi. Te interakcije mogu prouzrokovati značajne patofiziološke posledice. Uivovoj disertaciji su prikazani rezultati istraživanja prema kojima epinefrin i Fe3+ joni na fiziološkompH grade stabilni 1:1 bidentatni kompleks. Takođe je pokazano da na fiziološkom pH epinefrin nedegradira u prisustvu gvožđa. Utvrđeno je i da epinefrin i Fe2+ joni grade bezbojni kompleks i da jetaj kompleks stabilan pri anaerobnim uslovima. Uočeno je i da epinefrin u prisustvu O2 značajnopromoviše oksidaciju Fe2+ jona i formiranje Epi-Fe3+ kompleksa. Pri eksperimentima rađenimmetodom ciklične voltametrije, Epi-Fe2+ kompleks je pokazao potencijal E1/2 = -582 mV (u odnosuna standardnu vodoničnu elektrodu). Ovakva vrednost E1/2 potencijala objašnjava katalizovanuoksidaciju. Interakcije sa gvožđem mogu uticati na biološke efekte/efikasnost epinefrina. Uticajvezivanja gvožđa na biološko ponašanje epinefrina je ispitivan metodom nametnute voltaže nadeliću membrane u konfiguraciji cela ćelija, u kulturi ćelija koje konstitutivno eksprimirajuadrenergičke receptore. Epinefrin je samostalno, bez značajnog prisustva gvožđa, uzrokovaopovećanje amplitude struja usmerenih ka spoljašnosti ćelija, tj. povećanje izlaznih struja. Kompleksepinefrina sa Fe3+ nije izazivao slične posledice. Ovim se nameće zaključak da formiranjekompleksa sa gvožđem sprečava vezivanje epinefrina za adrenergičke receptore i njihovuposledičnu aktivaciju. Prooksidativna aktivnost Epi-Fe2+ kompleksa možda predstavlja vezu izmeđuhroničnog stresa i kardiovaskularnih problema, a labilno gvožđe u plazmi je potencijalni modulatorbioloških aktivnosti liganda.
AB  - Epinephrine (Epi) is a catecholamine with important physiological roles. Interactions withother molecules and associated biological effects of Epi are controlled by its molecularconformation. Coordinate interactions of epinephrine with iron at physiological pH and their redoxactivity are crucial for understanding two distinct phenomena. First, the adverse effects that chronicstress causes to cardiovascular system. Second, the cross-linking of biopolymers and frameworkswhich are rich in catecholamines. Conformation of epinephrine in polar solvents, namely indimethyl sulfoxide (DMSO) and water, was investigated in order to shed light on effects solventsand hydrogen bonds exert on interactions of epinephrine with iron.Mechanism of epinephrine interactions with Fe2+ and Fe3+ ions was studied at differentconcentration ratios, at physiological pH (pH 7.4), and the results are presented in this dissertation.For the sake of exploration of biological effects of epinephrine, this dissertation also contains theresults of examination of effects Epi-Fe3+ complex has on cell culture with constitutive expressionof adrenergic receptors.Conformation of epinephrine in polar solvents, namely in dimethyl sulfoxide (DMSO) andwater, was investigated using 1H NMR, 1H - 1H COSY, NOESY and 1H - 15N HSQC methods.When DMSO was used as a solvent, chemical and magnetic nonequivalence of protons was spottedat NH2 and CH2 groups on epinephrine. Characteristics of hydrogen bonds in DMSO weredetermined by studying effect which temperature rise has on NMR spectra and also analyzinginfluences of solvent substitution on NMR spectra. Results have shown that epinephrine inducesstrong intramolecular bond between one of the protons of NH2 group and the OH group on the sidechain. On the other hand, the OH group on the side chain, i.e. the aliphatic OH group, presents aproton donor for intermolecular bond between epinephrine and DMSO. This phenomenon was notnoticed when water was used as a solvent. 3D modelling of epinephrine molecule structure wasbased on information about spatial arrangement of protons, which in turn was obtained usingNOESY method. Obtained 3D model shows that epinephrine in DMSO has a rigid structure thatresembles the shape of a scorpion, in which the catechol ring presents the body of the scorpion andthe side chain presents the tail of the scorpion. This structure is a consequence of formation of anadditional five–membered ring limited by inter/intra–molecular bonds. If water is used as a solvent(instead of DMSO), epinephrine takes different and non-rigid conformation which does not possessthe aforementioned intramolecular hydrogen bond. In this case, conformation of epinephrine isdetermined by hydrogen bonds with solvent molecules.Examinations conducted in the scope of this dissertation showed that epinephrine and Fe3+form stable high-spin complexes in 1:1 and 3:1 stoichiometry. Stoichiometry of these depends onconcentration ratio of epinephrine and Fe3+. Results acquired using Raman spectroscopy haveshown that 1:1 bidentate Epi–Fe3+ complex is formed by coordinative bonding of Fe3+ ions toepinephrine molecule through O atoms on the catechol ring. Effect of Fe3+ and Fe2+ ions on redoxproperties of epinephrine was studied using method of cyclic voltammetry. It was observed thatFe3+ ions do not significantly affect redox properties of epinephrine, but epinephrine with Fe2+ ionsforms strong reducing agent. Fe2+ ion presents electron donor that in the presence of epinephrinereduces O2 and causes production of H2O2. Specific hemism of epinephrine, which includesoxidation of Fe2+ ions, may present a mechanism that explains stress-induced cardiotoxicity andheart diseases. Also, these results can be used for improvement of synthesis and development ofbiopolymers.viIn stressful situations epinephrine is released and it may interact with labile iron in humanblood plasma. These interactions can have potentially important (patho)physiological effects. In thisdissertation, it is shown that at physiological pH epinephrine and Fe3+ build stable 1:1 high-spinbidentate complex. It is also shown that in presence of iron, at physiological pH, epinephrine doesnot degrade. It was observed that epinephrine and Fe2+ build colorless complex, which was stableunder anaerobic conditions. In presence of O2, epinephrine significantly catalyzed oxidation of Fe2+ions and formation of Epi-Fe3+ complex. Cyclic voltammetry results showed that the mid-pointpotential of Epi-Fe2+ complex equals -582 mV (vs. standard hydrogen electrode). This value ofmid-point potential explains the oxidation promotion. Biological effects/efficiency of epinephrineare influenced by its interaction with iron. Iron binding effects on biological performance ofepinephrine were examined using patch clamping in cell culture with constitutive expression ofadrenergic receptors. Epinephrine, on its own, induced an increase of outward currents, whereasEpi-Fe3+ complex did not evoke similar phenomenon. These imply that the binding of epinephrineto adrenergic receptors and their activation is inhibited by the formation of the complex of Epi withiron. Oxidative promoting activity of Fe2+ in the presence epinephrine may represent a basis forcardiovascular problems caused by chronic stress. The results obtained in this dissertation indicatethat the labile iron pool may have a new function that represents a modulation of the activity ofbiologically significant ligands/molecules.Epinephrine (Epi) is a catecholamine with important physiological roles. Interactions withother molecules and associated biological effects of Epi are controlled by its molecularconformation. Coordinate interactions of epinephrine with iron at physiological pH and their redoxactivity are crucial for understanding two distinct phenomena. First, the adverse effects that chronicstress causes to cardiovascular system. Second, the cross-linking of biopolymers and frameworkswhich are rich in catecholamines. Conformation of epinephrine in polar solvents, namely indimethyl sulfoxide (DMSO) and water, was investigated in order to shed light on effects solventsand hydrogen bonds exert on interactions of epinephrine with iron.Mechanism of epinephrine interactions with Fe2+ and Fe3+ ions was studied at differentconcentration ratios, at physiological pH (pH 7.4), and the results are presented in this dissertation.For the sake of exploration of biological effects of epinephrine, this dissertation also contains theresults of examination of effects Epi-Fe3+ complex has on cell culture with constitutive expressionof adrenergic receptors.Conformation of epinephrine in polar solvents, namely in dimethyl sulfoxide (DMSO) andwater, was investigated using 1H NMR, 1H - 1H COSY, NOESY and 1H - 15N HSQC methods.When DMSO was used as a solvent, chemical and magnetic nonequivalence of protons was spottedat NH2 and CH2 groups on epinephrine. Characteristics of hydrogen bonds in DMSO weredetermined by studying effect which temperature rise has on NMR spectra and also analyzinginfluences of solvent substitution on NMR spectra. Results have shown that epinephrine inducesstrong intramolecular bond between one of the protons of NH2 group and the OH group on the sidechain. On the other hand, the OH group on the side chain, i.e. the aliphatic OH group, presents aproton donor for intermolecular bond between epinephrine and DMSO. This phenomenon was notnoticed when water was used as a solvent. 3D modelling of epinephrine molecule structure wasbased on information about spatial arrangement of protons, which in turn was obtained usingNOESY method. Obtained 3D model shows that epinephrine in DMSO has a rigid structure thatresembles the shape of a scorpion, in which the catechol ring presents the body of the scorpion andthe side chain presents the tail of the scorpion. This structure is a consequence of formation of anadditional five–membered ring limited by inter/intra–molecular bonds. If water is used as a solvent(instead of DMSO), epinephrine takes different and non-rigid conformation which does not possessthe aforementioned intramolecular hydrogen bond. In this case, conformation of epinephrine isdetermined by hydrogen bonds with solvent molecules.Examinations conducted in the scope of this dissertation showed that epinephrine and Fe3+form stable high-spin complexes in 1:1 and 3:1 stoichiometry. Stoichiometry of these depends onconcentration ratio of epinephrine and Fe3+. Results acquired using Raman spectroscopy haveshown that 1:1 bidentate Epi–Fe3+ complex is formed by coordinative bonding of Fe3+ ions toepinephrine molecule through O atoms on the catechol ring. Effect of Fe3+ and Fe2+ ions on redoxproperties of epinephrine was studied using method of cyclic voltammetry. It was observed thatFe3+ ions do not significantly affect redox properties of epinephrine, but epinephrine with Fe2+ ionsforms strong reducing agent. Fe2+ ion presents electron donor that in the presence of epinephrinereduces O2 and causes production of H2O2. Specific hemism of epinephrine, which includesoxidation of Fe2+ ions, may present a mechanism that explains stress-induced cardiotoxicity andheart diseases. Also, these results can be used for improvement of synthesis and development ofbiopolymers.viIn stressful situations epinephrine is released and it may interact with labile iron in humanblood plasma. These interactions can have potentially important (patho)physiological effects. In thisdissertation, it is shown that at physiological pH epinephrine and Fe3+ build stable 1:1 high-spinbidentate complex. It is also shown that in presence of iron, at physiological pH, epinephrine doesnot degrade. It was observed that epinephrine and Fe2+ build colorless complex, which was stableunder anaerobic conditions. In presence of O2, epinephrine significantly catalyzed oxidation of Fe2+ions and formation of Epi-Fe3+ complex. Cyclic voltammetry results showed that the mid-pointpotential of Epi-Fe2+ complex equals -582 mV (vs. standard hydrogen electrode). This value ofmid-point potential explains the oxidation promotion. Biological effects/efficiency of epinephrineare influenced by its interaction with iron. Iron binding effects on biological performance ofepinephrine were examined using patch clamping in cell culture with constitutive expression ofadrenergic receptors. Epinephrine, on its own, induced an increase of outward currents, whereasEpi-Fe3+ complex did not evoke similar phenomenon. These imply that the binding of epinephrineto adrenergic receptors and their activation is inhibited by the formation of the complex of Epi withiron. Oxidative promoting activity of Fe2+ in the presence epinephrine may represent a basis forcardiovascular problems caused by chronic stress. The results obtained in this dissertation indicatethat the labile iron pool may have a new function that represents a modulation of the activity ofbiologically significant ligands/molecules.
PB  - Универзитет у Београду, Хемијски факултет
T2  - Универзитет у Београду
T1  - Ispitivanje koordinativnih sposobnosti epinefrina prema Fe2+ i Fe3+ katjonima i redoks aktivnost nastalih kompleksa
UR  - https://hdl.handle.net/21.15107/rcub_nardus_17801
ER  - 

@phdthesis{
author = "Korać Jačić, Jelena K.",
year = "2020",
abstract = "Epinefrin je kateholamin sa značajnom fiziološkom ulogom. Konformacija ovog molekulautiče na njegovu interakciju sa drugim molekulima i na njegove biološke efekte. Na fiziološkimpH vrednostima, koordinativne sposobnosti epinefrina prema gvožđu i redoks interakcije epinefrinasa gvožđem su od suštinske važnosti za razumevanje dve veoma različite pojave. Prva pojava ještetno dejstvo koje hronični psihološki/sredinski stres izaziva na nivou kardiovaskularnog sistema.Druga pojava je umrežavanje kateholaminima bogatih biopolimera i struktura. Kako bi se rasvetlileuloge rastvarača i vodoničnih veza u interakcijama epinefrina sa gvožđem, proučavana jekonformacija epinefrina u vodi i polarnom rastvaraču dimetil sulfoksidu (DMSO).U ovoj disertaciji su predstavljeni rezultati proučavanja mehanizama interakcije epinefrinasa Fe2+ i Fe3+ jonima pri različitim koncentracionim odnosima na pH 7,4, odnosno na pH vrednostikoja odgovara fiziološkim uslovima. U svrhu istraživanja bioloških efekata epinefrina, u ovojdisertaciji su predstavljena ispitivanja efekta Epi-Fe3+ kompleksa na ćelije koje konstitutivnoeksprimiraju adrenergičke receptore.Konformacije epinefrina u polarnim rastvaračima, vodi i DMSO, su proučavane metodamaH nuklearne magnetne rezonance (1H NMR) kao i dvodimenzionalnim metodama nuklearnemagnetne rezonance, i to: 1H - 1H COSY, 1H - 15N HSQC i NOESY. Na NH2 i CH2 grupamaepinefrina su uočeni hemijski neekvivalentni protoni prilikom korišćenja DMSO kao rastvarača.Ove pojave nisu uočene kada je rastvarač bila voda. Analizom uticaja korišćenog rastvarača naNMR spektar, i analizom uticaja povećanja temperature uzorka na NMR spektar, dolazi se dozaključka da jedan od protona amino grupe formira jaku intramolekulsku vezu sa alifatičnomhidroksilnom grupom, koja je pak H donor drugoj intermolekularnoj vezi sa DMSO. PomoćuNOESY metode su prikupljeni podaci o prostornoj poziciji protona u bočnom lancu. Na taj način jeformiran 3D model konformacije epinefrina u DMSO. Ukratko, epinefrin formira dodatni petočlaniprsten koji sadrži bifurkovane intramolekulske/intermolekulske vodonične veze i zauzima strukturuoblika škorpiona, gde kateholni prsten predstavlja telo škorpiona, a bočni lanac predstavlja rep kojije povijen u smeru glave škorpiona. U vodi, kao rastvaraču, konformacija epinefrina ne posedujeintramolekulske vodonične veze pa je tada struktura ovog molekula najverovatnije definisanavodoničnim vezama sa molekulima vode.U okviru ove disertacije ispitivanjima je ustanovljeno da epinefrin sa Fe3+ jonima gradistabilne visokospinske komplekse čija je stehiometrija 1:1 ili 3:1. Stehiometrija ovog kompleksazavisi od odnosa koncentracija epinefrina i Fe3+ jona. Na kateholnom prstenu epinefrina atomikiseonika predstavljaju mesto za formiranje koordinacione veze unutar fiziološki relevantnogbidentatnog 1:1 kompleksa. Fe3+ katjon ima slab uticaj na redoks osobine epinefrina. Međutim,epinefrin i Fe2+ joni grade kompleks koji je jak redukcioni agens. Posledica je redukcija O2,proizvodnja vodonik peroksida i formiranje Epi-Fe3+ kompleksa. U ovom procesu epinefrin se neoksiduje, odnosno Fe2+ jon nije prenosilac, već donor elektrona. Oksidacija Fe2+ jona koja jekatalizovana epinefrinom predstavlja moguće hemijsko objašnjenje za stresom izazvana oštećenjaćelija srca. Takođe, rezultati ovih ispitivanja su u skladu sa prethodnim istraživanjima kateholaminau polimerima i njihovih interakcija sa gvožđem, i upućuju na nove strategije za poboljšavanjeefikasnosti umrežavanja kateholaminima bogatih biopolimera i struktura.U stresnim situacijama epinefrin se luči i može interagovati sa labilnim gvožđem koje senalazi u ljudskoj plazmi. Te interakcije mogu prouzrokovati značajne patofiziološke posledice. Uivovoj disertaciji su prikazani rezultati istraživanja prema kojima epinefrin i Fe3+ joni na fiziološkompH grade stabilni 1:1 bidentatni kompleks. Takođe je pokazano da na fiziološkom pH epinefrin nedegradira u prisustvu gvožđa. Utvrđeno je i da epinefrin i Fe2+ joni grade bezbojni kompleks i da jetaj kompleks stabilan pri anaerobnim uslovima. Uočeno je i da epinefrin u prisustvu O2 značajnopromoviše oksidaciju Fe2+ jona i formiranje Epi-Fe3+ kompleksa. Pri eksperimentima rađenimmetodom ciklične voltametrije, Epi-Fe2+ kompleks je pokazao potencijal E1/2 = -582 mV (u odnosuna standardnu vodoničnu elektrodu). Ovakva vrednost E1/2 potencijala objašnjava katalizovanuoksidaciju. Interakcije sa gvožđem mogu uticati na biološke efekte/efikasnost epinefrina. Uticajvezivanja gvožđa na biološko ponašanje epinefrina je ispitivan metodom nametnute voltaže nadeliću membrane u konfiguraciji cela ćelija, u kulturi ćelija koje konstitutivno eksprimirajuadrenergičke receptore. Epinefrin je samostalno, bez značajnog prisustva gvožđa, uzrokovaopovećanje amplitude struja usmerenih ka spoljašnosti ćelija, tj. povećanje izlaznih struja. Kompleksepinefrina sa Fe3+ nije izazivao slične posledice. Ovim se nameće zaključak da formiranjekompleksa sa gvožđem sprečava vezivanje epinefrina za adrenergičke receptore i njihovuposledičnu aktivaciju. Prooksidativna aktivnost Epi-Fe2+ kompleksa možda predstavlja vezu izmeđuhroničnog stresa i kardiovaskularnih problema, a labilno gvožđe u plazmi je potencijalni modulatorbioloških aktivnosti liganda., Epinephrine (Epi) is a catecholamine with important physiological roles. Interactions withother molecules and associated biological effects of Epi are controlled by its molecularconformation. Coordinate interactions of epinephrine with iron at physiological pH and their redoxactivity are crucial for understanding two distinct phenomena. First, the adverse effects that chronicstress causes to cardiovascular system. Second, the cross-linking of biopolymers and frameworkswhich are rich in catecholamines. Conformation of epinephrine in polar solvents, namely indimethyl sulfoxide (DMSO) and water, was investigated in order to shed light on effects solventsand hydrogen bonds exert on interactions of epinephrine with iron.Mechanism of epinephrine interactions with Fe2+ and Fe3+ ions was studied at differentconcentration ratios, at physiological pH (pH 7.4), and the results are presented in this dissertation.For the sake of exploration of biological effects of epinephrine, this dissertation also contains theresults of examination of effects Epi-Fe3+ complex has on cell culture with constitutive expressionof adrenergic receptors.Conformation of epinephrine in polar solvents, namely in dimethyl sulfoxide (DMSO) andwater, was investigated using 1H NMR, 1H - 1H COSY, NOESY and 1H - 15N HSQC methods.When DMSO was used as a solvent, chemical and magnetic nonequivalence of protons was spottedat NH2 and CH2 groups on epinephrine. Characteristics of hydrogen bonds in DMSO weredetermined by studying effect which temperature rise has on NMR spectra and also analyzinginfluences of solvent substitution on NMR spectra. Results have shown that epinephrine inducesstrong intramolecular bond between one of the protons of NH2 group and the OH group on the sidechain. On the other hand, the OH group on the side chain, i.e. the aliphatic OH group, presents aproton donor for intermolecular bond between epinephrine and DMSO. This phenomenon was notnoticed when water was used as a solvent. 3D modelling of epinephrine molecule structure wasbased on information about spatial arrangement of protons, which in turn was obtained usingNOESY method. Obtained 3D model shows that epinephrine in DMSO has a rigid structure thatresembles the shape of a scorpion, in which the catechol ring presents the body of the scorpion andthe side chain presents the tail of the scorpion. This structure is a consequence of formation of anadditional five–membered ring limited by inter/intra–molecular bonds. If water is used as a solvent(instead of DMSO), epinephrine takes different and non-rigid conformation which does not possessthe aforementioned intramolecular hydrogen bond. In this case, conformation of epinephrine isdetermined by hydrogen bonds with solvent molecules.Examinations conducted in the scope of this dissertation showed that epinephrine and Fe3+form stable high-spin complexes in 1:1 and 3:1 stoichiometry. Stoichiometry of these depends onconcentration ratio of epinephrine and Fe3+. Results acquired using Raman spectroscopy haveshown that 1:1 bidentate Epi–Fe3+ complex is formed by coordinative bonding of Fe3+ ions toepinephrine molecule through O atoms on the catechol ring. Effect of Fe3+ and Fe2+ ions on redoxproperties of epinephrine was studied using method of cyclic voltammetry. It was observed thatFe3+ ions do not significantly affect redox properties of epinephrine, but epinephrine with Fe2+ ionsforms strong reducing agent. Fe2+ ion presents electron donor that in the presence of epinephrinereduces O2 and causes production of H2O2. Specific hemism of epinephrine, which includesoxidation of Fe2+ ions, may present a mechanism that explains stress-induced cardiotoxicity andheart diseases. Also, these results can be used for improvement of synthesis and development ofbiopolymers.viIn stressful situations epinephrine is released and it may interact with labile iron in humanblood plasma. These interactions can have potentially important (patho)physiological effects. In thisdissertation, it is shown that at physiological pH epinephrine and Fe3+ build stable 1:1 high-spinbidentate complex. It is also shown that in presence of iron, at physiological pH, epinephrine doesnot degrade. It was observed that epinephrine and Fe2+ build colorless complex, which was stableunder anaerobic conditions. In presence of O2, epinephrine significantly catalyzed oxidation of Fe2+ions and formation of Epi-Fe3+ complex. Cyclic voltammetry results showed that the mid-pointpotential of Epi-Fe2+ complex equals -582 mV (vs. standard hydrogen electrode). This value ofmid-point potential explains the oxidation promotion. Biological effects/efficiency of epinephrineare influenced by its interaction with iron. Iron binding effects on biological performance ofepinephrine were examined using patch clamping in cell culture with constitutive expression ofadrenergic receptors. Epinephrine, on its own, induced an increase of outward currents, whereasEpi-Fe3+ complex did not evoke similar phenomenon. These imply that the binding of epinephrineto adrenergic receptors and their activation is inhibited by the formation of the complex of Epi withiron. Oxidative promoting activity of Fe2+ in the presence epinephrine may represent a basis forcardiovascular problems caused by chronic stress. The results obtained in this dissertation indicatethat the labile iron pool may have a new function that represents a modulation of the activity ofbiologically significant ligands/molecules.Epinephrine (Epi) is a catecholamine with important physiological roles. Interactions withother molecules and associated biological effects of Epi are controlled by its molecularconformation. Coordinate interactions of epinephrine with iron at physiological pH and their redoxactivity are crucial for understanding two distinct phenomena. First, the adverse effects that chronicstress causes to cardiovascular system. Second, the cross-linking of biopolymers and frameworkswhich are rich in catecholamines. Conformation of epinephrine in polar solvents, namely indimethyl sulfoxide (DMSO) and water, was investigated in order to shed light on effects solventsand hydrogen bonds exert on interactions of epinephrine with iron.Mechanism of epinephrine interactions with Fe2+ and Fe3+ ions was studied at differentconcentration ratios, at physiological pH (pH 7.4), and the results are presented in this dissertation.For the sake of exploration of biological effects of epinephrine, this dissertation also contains theresults of examination of effects Epi-Fe3+ complex has on cell culture with constitutive expressionof adrenergic receptors.Conformation of epinephrine in polar solvents, namely in dimethyl sulfoxide (DMSO) andwater, was investigated using 1H NMR, 1H - 1H COSY, NOESY and 1H - 15N HSQC methods.When DMSO was used as a solvent, chemical and magnetic nonequivalence of protons was spottedat NH2 and CH2 groups on epinephrine. Characteristics of hydrogen bonds in DMSO weredetermined by studying effect which temperature rise has on NMR spectra and also analyzinginfluences of solvent substitution on NMR spectra. Results have shown that epinephrine inducesstrong intramolecular bond between one of the protons of NH2 group and the OH group on the sidechain. On the other hand, the OH group on the side chain, i.e. the aliphatic OH group, presents aproton donor for intermolecular bond between epinephrine and DMSO. This phenomenon was notnoticed when water was used as a solvent. 3D modelling of epinephrine molecule structure wasbased on information about spatial arrangement of protons, which in turn was obtained usingNOESY method. Obtained 3D model shows that epinephrine in DMSO has a rigid structure thatresembles the shape of a scorpion, in which the catechol ring presents the body of the scorpion andthe side chain presents the tail of the scorpion. This structure is a consequence of formation of anadditional five–membered ring limited by inter/intra–molecular bonds. If water is used as a solvent(instead of DMSO), epinephrine takes different and non-rigid conformation which does not possessthe aforementioned intramolecular hydrogen bond. In this case, conformation of epinephrine isdetermined by hydrogen bonds with solvent molecules.Examinations conducted in the scope of this dissertation showed that epinephrine and Fe3+form stable high-spin complexes in 1:1 and 3:1 stoichiometry. Stoichiometry of these depends onconcentration ratio of epinephrine and Fe3+. Results acquired using Raman spectroscopy haveshown that 1:1 bidentate Epi–Fe3+ complex is formed by coordinative bonding of Fe3+ ions toepinephrine molecule through O atoms on the catechol ring. Effect of Fe3+ and Fe2+ ions on redoxproperties of epinephrine was studied using method of cyclic voltammetry. It was observed thatFe3+ ions do not significantly affect redox properties of epinephrine, but epinephrine with Fe2+ ionsforms strong reducing agent. Fe2+ ion presents electron donor that in the presence of epinephrinereduces O2 and causes production of H2O2. Specific hemism of epinephrine, which includesoxidation of Fe2+ ions, may present a mechanism that explains stress-induced cardiotoxicity andheart diseases. Also, these results can be used for improvement of synthesis and development ofbiopolymers.viIn stressful situations epinephrine is released and it may interact with labile iron in humanblood plasma. These interactions can have potentially important (patho)physiological effects. In thisdissertation, it is shown that at physiological pH epinephrine and Fe3+ build stable 1:1 high-spinbidentate complex. It is also shown that in presence of iron, at physiological pH, epinephrine doesnot degrade. It was observed that epinephrine and Fe2+ build colorless complex, which was stableunder anaerobic conditions. In presence of O2, epinephrine significantly catalyzed oxidation of Fe2+ions and formation of Epi-Fe3+ complex. Cyclic voltammetry results showed that the mid-pointpotential of Epi-Fe2+ complex equals -582 mV (vs. standard hydrogen electrode). This value ofmid-point potential explains the oxidation promotion. Biological effects/efficiency of epinephrineare influenced by its interaction with iron. Iron binding effects on biological performance ofepinephrine were examined using patch clamping in cell culture with constitutive expression ofadrenergic receptors. Epinephrine, on its own, induced an increase of outward currents, whereasEpi-Fe3+ complex did not evoke similar phenomenon. These imply that the binding of epinephrineto adrenergic receptors and their activation is inhibited by the formation of the complex of Epi withiron. Oxidative promoting activity of Fe2+ in the presence epinephrine may represent a basis forcardiovascular problems caused by chronic stress. The results obtained in this dissertation indicatethat the labile iron pool may have a new function that represents a modulation of the activity ofbiologically significant ligands/molecules.",
publisher = "Универзитет у Београду, Хемијски факултет",
journal = "Универзитет у Београду",
title = "Ispitivanje koordinativnih sposobnosti epinefrina prema Fe2+ i Fe3+ katjonima i redoks aktivnost nastalih kompleksa",
url = "https://hdl.handle.net/21.15107/rcub_nardus_17801"
}

Korać Jačić, J. K.. (2020). Ispitivanje koordinativnih sposobnosti epinefrina prema Fe2+ i Fe3+ katjonima i redoks aktivnost nastalih kompleksa. in Универзитет у Београду
Универзитет у Београду, Хемијски факултет..
https://hdl.handle.net/21.15107/rcub_nardus_17801

Korać Jačić JK. Ispitivanje koordinativnih sposobnosti epinefrina prema Fe2+ i Fe3+ katjonima i redoks aktivnost nastalih kompleksa. in Универзитет у Београду. 2020;.
https://hdl.handle.net/21.15107/rcub_nardus_17801 .

Korać Jačić, Jelena K., "Ispitivanje koordinativnih sposobnosti epinefrina prema Fe2+ i Fe3+ katjonima i redoks aktivnost nastalih kompleksa" in Универзитет у Београду (2020),
https://hdl.handle.net/21.15107/rcub_nardus_17801 .