TY  - CONF
AU  - Nešić, M. D.
AU  - Filipović Tričković, Jelena
AU  - Valenta Šobot, Ana
AU  - Žakula, Jelena
AU  - Korićanac, Lela
AU  - Popović, I.
AU  - Soto, J.
AU  - Algarra, M.
AU  - Ralić, V.
AU  - Abu el Rub, Anamarija
AU  - Matijević, M.
AU  - Stepić, Milutin
AU  - Petković, M.
PY  - 2023
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/11809
AB  - Carbon Dots (CDs) are biocompatible, fluorescent, water-soluble, and stable nanoparticles with a high potential to be used for vast biomedical applications [1,2]. We explore the application of CDs produced from natural sources, black carrots, as anti-cancer and imaging agents. These nanoparticles suppress cell growth of three different cancer cell lines, cervical (HeLa), pancreatic (PANC-1), and melanoma (A375) cell lines in vitro. However, the cytotoxic effect against A375 cells stands out, with only 20% of viable cells left after treatment (Fig.1(a)), antimetastatic potential, and a selectivity index higher than two, which indicates that the efficacy against melanoma cells is significantly greater than the toxicity against non-malignant cells (MRC-5). Furthermore, after the cellular uptake, green fluorescence was visible in the cytosol of A375 cells (Fig. 1 (b)). On the other hand, the DAPI stain for DNA was visible as a blue light in the cell nucleus. Moreover, cells with a higher intensity of green fluorescence in the nucleus, Fig. 1 (c) indicated with arrows, were the cells with condensed chromatin in the mitotic phase of the cell cycle (Fig. 1 (d) and (e)), which indicates that CDs interact with chromatin and that they could be used as a marker of cells mitosis and proliferation. In summary, we have demonstrated the great anti-cancer potential of black carrot CDs, for image-guided anti-cancer therapy of melanoma that can be used to recognize cell proliferation.
PB  - Belgrade : Vinča Institute of Nuclear Sciences
C3  - PHOTONICA2023 : 9th International School and Conference on Photonics : book of abstracts; August 28 - September 1, 2023; Belgrade
T1  - Anti-cancer and imaging potential of fluorescent black carrot Carbon Dot nanoparticles
SP  - 79
EP  - 79
UR  - https://hdl.handle.net/21.15107/rcub_vinar_11809
ER  - 

@conference{
author = "Nešić, M. D. and Filipović Tričković, Jelena and Valenta Šobot, Ana and Žakula, Jelena and Korićanac, Lela and Popović, I. and Soto, J. and Algarra, M. and Ralić, V. and Abu el Rub, Anamarija and Matijević, M. and Stepić, Milutin and Petković, M.",
year = "2023",
abstract = "Carbon Dots (CDs) are biocompatible, fluorescent, water-soluble, and stable nanoparticles with a high potential to be used for vast biomedical applications [1,2]. We explore the application of CDs produced from natural sources, black carrots, as anti-cancer and imaging agents. These nanoparticles suppress cell growth of three different cancer cell lines, cervical (HeLa), pancreatic (PANC-1), and melanoma (A375) cell lines in vitro. However, the cytotoxic effect against A375 cells stands out, with only 20% of viable cells left after treatment (Fig.1(a)), antimetastatic potential, and a selectivity index higher than two, which indicates that the efficacy against melanoma cells is significantly greater than the toxicity against non-malignant cells (MRC-5). Furthermore, after the cellular uptake, green fluorescence was visible in the cytosol of A375 cells (Fig. 1 (b)). On the other hand, the DAPI stain for DNA was visible as a blue light in the cell nucleus. Moreover, cells with a higher intensity of green fluorescence in the nucleus, Fig. 1 (c) indicated with arrows, were the cells with condensed chromatin in the mitotic phase of the cell cycle (Fig. 1 (d) and (e)), which indicates that CDs interact with chromatin and that they could be used as a marker of cells mitosis and proliferation. In summary, we have demonstrated the great anti-cancer potential of black carrot CDs, for image-guided anti-cancer therapy of melanoma that can be used to recognize cell proliferation.",
publisher = "Belgrade : Vinča Institute of Nuclear Sciences",
journal = "PHOTONICA2023 : 9th International School and Conference on Photonics : book of abstracts; August 28 - September 1, 2023; Belgrade",
title = "Anti-cancer and imaging potential of fluorescent black carrot Carbon Dot nanoparticles",
pages = "79-79",
url = "https://hdl.handle.net/21.15107/rcub_vinar_11809"
}

Nešić, M. D., Filipović Tričković, J., Valenta Šobot, A., Žakula, J., Korićanac, L., Popović, I., Soto, J., Algarra, M., Ralić, V., Abu el Rub, A., Matijević, M., Stepić, M.,& Petković, M.. (2023). Anti-cancer and imaging potential of fluorescent black carrot Carbon Dot nanoparticles. in PHOTONICA2023 : 9th International School and Conference on Photonics : book of abstracts; August 28 - September 1, 2023; Belgrade
Belgrade : Vinča Institute of Nuclear Sciences., 79-79.
https://hdl.handle.net/21.15107/rcub_vinar_11809

Nešić MD, Filipović Tričković J, Valenta Šobot A, Žakula J, Korićanac L, Popović I, Soto J, Algarra M, Ralić V, Abu el Rub A, Matijević M, Stepić M, Petković M. Anti-cancer and imaging potential of fluorescent black carrot Carbon Dot nanoparticles. in PHOTONICA2023 : 9th International School and Conference on Photonics : book of abstracts; August 28 - September 1, 2023; Belgrade. 2023;:79-79.
https://hdl.handle.net/21.15107/rcub_vinar_11809 .

Nešić, M. D., Filipović Tričković, Jelena, Valenta Šobot, Ana, Žakula, Jelena, Korićanac, Lela, Popović, I., Soto, J., Algarra, M., Ralić, V., Abu el Rub, Anamarija, Matijević, M., Stepić, Milutin, Petković, M., "Anti-cancer and imaging potential of fluorescent black carrot Carbon Dot nanoparticles" in PHOTONICA2023 : 9th International School and Conference on Photonics : book of abstracts; August 28 - September 1, 2023; Belgrade (2023):79-79,
https://hdl.handle.net/21.15107/rcub_vinar_11809 .

TY  - CONF
AU  - Matijević, M.
AU  - Korićanac, Lela
AU  - Nakarada, Đ.
AU  - Žakula, Jelena
AU  - Stepić, M.
AU  - Radoičić, Marija
AU  - Mojović, M.
AU  - Petković, M.
AU  - Nešić, M. D.
PY  - 2023
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/11799
AB  - Treating cancer remains a major challenge, despite the development of many therapies and advances in general knowledge about the disease. The treatments commonly used are invasive and non-selective, leading to severe side effects and unsatisfactory long-term outcomes. Nevertheless, external stimuli activating therapeutic agents in the affected area can be more beneficial than these aggressive therapies. Photodynamic therapy (PDT) is a minimally invasive, selective treatment that uses photosensitizer (PS) to damage cancer cells. The PS is activated by light, triggering a series of processes that produce reactive oxygen species (ROS), ultimately leading to cancer cell death. Numerous types of nanomaterial possess the capability to act as PS, one of which is TiO2 [1]. Although nanostructured TiO2 is biocompatible in the absence of light, its valence band electrons can be stimulated only by ultraviolet (UV) light irradiation. Since the penetration of UV light into tissue is limited, for application in PDT, nanostructured TiO2 can be doped with heteroatoms like N or C to allow visible light responsiveness [2,3]. This work evaluated the PS properties of unmodified nanostructured TiO2 (spherical nanoparticles TiO2 NPs and prolate nanospheroids, TiO2 PNSs) and doped TiO2 (N- and C-TiO2 NPs). After the synthesis, the size of TiO2 was confirmed to be in the nanoscale range (5-104 nm) by transmission electron microscopy [3,4]. The doped TiO2 was found to absorb visible light, as demonstrated by UV-Vis spectroscopy and bandgap calculations. Additionally, hydroxyl radicals were detected in water suspensions of TiO2 PNSs by electron paramagnetic resonance (EPR) spectroscopy, both with and without UV light illumination [4]. However, this radical was observed only with blue light stimulation of the water suspensions of N- and C-TiO2 NPs [3]. Cell experiments further revealed the internalization process of nanostructured TiO2 within cells, their cytotoxicity profiles, and the different death modalities triggered by their uptake. After confocal microscopy indicated the successful internalization of the investigated TiO2, viability tests on different cell lines confirmed their good biocompatibility without light [3,4]. The PDT's efficacy using nanostructured TiO2 and appropriate light stimuli was evaluated on various cancer cell lines. The most significant viability reduction (60 %) was observed in the HeLa cell line with the combined treatment of C-TiO2 NPs-blue light. In addition to EPR results, blue light-induced C-TiO2 NPs-catalyzed generation of ROS was confirmed intracellularly, implying that oxidative stress was the leading cause of HeLa cell death. Fluorescent labeling allowed distinguishing morphological changes inside the cells after the C-TiO2 NPs, blue light, and the combined C-TiO2 NPs-blue light treatment. Blue light exposure led to the appearance of large necrotic cells with deformed nuclei, cytoplasm swelling, and membrane blebbing. In contrast, the combined therapy with C-TiO2 NPs-blue light resulted in controlled cell death, such as autophagy. Since programmed cell death is the desired cancer cell death mechanism, the combined treatment presented here can provide a better outcome of local anticancer therapy.
PB  - Belgrade : Vinča Institute of Nuclear Sciences
C3  - PHOTONICA2023 : 9th International School and Conference on Photonics : book of abstracts; August 28 - September 1, 2023; Belgrade
T1  - Photosensitizer potential of doped and undoped nanostructured TiO2
SP  - 36
EP  - 36
UR  - https://hdl.handle.net/21.15107/rcub_vinar_11799
ER  - 

@conference{
author = "Matijević, M. and Korićanac, Lela and Nakarada, Đ. and Žakula, Jelena and Stepić, M. and Radoičić, Marija and Mojović, M. and Petković, M. and Nešić, M. D.",
year = "2023",
abstract = "Treating cancer remains a major challenge, despite the development of many therapies and advances in general knowledge about the disease. The treatments commonly used are invasive and non-selective, leading to severe side effects and unsatisfactory long-term outcomes. Nevertheless, external stimuli activating therapeutic agents in the affected area can be more beneficial than these aggressive therapies. Photodynamic therapy (PDT) is a minimally invasive, selective treatment that uses photosensitizer (PS) to damage cancer cells. The PS is activated by light, triggering a series of processes that produce reactive oxygen species (ROS), ultimately leading to cancer cell death. Numerous types of nanomaterial possess the capability to act as PS, one of which is TiO2 [1]. Although nanostructured TiO2 is biocompatible in the absence of light, its valence band electrons can be stimulated only by ultraviolet (UV) light irradiation. Since the penetration of UV light into tissue is limited, for application in PDT, nanostructured TiO2 can be doped with heteroatoms like N or C to allow visible light responsiveness [2,3]. This work evaluated the PS properties of unmodified nanostructured TiO2 (spherical nanoparticles TiO2 NPs and prolate nanospheroids, TiO2 PNSs) and doped TiO2 (N- and C-TiO2 NPs). After the synthesis, the size of TiO2 was confirmed to be in the nanoscale range (5-104 nm) by transmission electron microscopy [3,4]. The doped TiO2 was found to absorb visible light, as demonstrated by UV-Vis spectroscopy and bandgap calculations. Additionally, hydroxyl radicals were detected in water suspensions of TiO2 PNSs by electron paramagnetic resonance (EPR) spectroscopy, both with and without UV light illumination [4]. However, this radical was observed only with blue light stimulation of the water suspensions of N- and C-TiO2 NPs [3]. Cell experiments further revealed the internalization process of nanostructured TiO2 within cells, their cytotoxicity profiles, and the different death modalities triggered by their uptake. After confocal microscopy indicated the successful internalization of the investigated TiO2, viability tests on different cell lines confirmed their good biocompatibility without light [3,4]. The PDT's efficacy using nanostructured TiO2 and appropriate light stimuli was evaluated on various cancer cell lines. The most significant viability reduction (60 %) was observed in the HeLa cell line with the combined treatment of C-TiO2 NPs-blue light. In addition to EPR results, blue light-induced C-TiO2 NPs-catalyzed generation of ROS was confirmed intracellularly, implying that oxidative stress was the leading cause of HeLa cell death. Fluorescent labeling allowed distinguishing morphological changes inside the cells after the C-TiO2 NPs, blue light, and the combined C-TiO2 NPs-blue light treatment. Blue light exposure led to the appearance of large necrotic cells with deformed nuclei, cytoplasm swelling, and membrane blebbing. In contrast, the combined therapy with C-TiO2 NPs-blue light resulted in controlled cell death, such as autophagy. Since programmed cell death is the desired cancer cell death mechanism, the combined treatment presented here can provide a better outcome of local anticancer therapy.",
publisher = "Belgrade : Vinča Institute of Nuclear Sciences",
journal = "PHOTONICA2023 : 9th International School and Conference on Photonics : book of abstracts; August 28 - September 1, 2023; Belgrade",
title = "Photosensitizer potential of doped and undoped nanostructured TiO2",
pages = "36-36",
url = "https://hdl.handle.net/21.15107/rcub_vinar_11799"
}

Matijević, M., Korićanac, L., Nakarada, Đ., Žakula, J., Stepić, M., Radoičić, M., Mojović, M., Petković, M.,& Nešić, M. D.. (2023). Photosensitizer potential of doped and undoped nanostructured TiO2. in PHOTONICA2023 : 9th International School and Conference on Photonics : book of abstracts; August 28 - September 1, 2023; Belgrade
Belgrade : Vinča Institute of Nuclear Sciences., 36-36.
https://hdl.handle.net/21.15107/rcub_vinar_11799

Matijević M, Korićanac L, Nakarada Đ, Žakula J, Stepić M, Radoičić M, Mojović M, Petković M, Nešić MD. Photosensitizer potential of doped and undoped nanostructured TiO2. in PHOTONICA2023 : 9th International School and Conference on Photonics : book of abstracts; August 28 - September 1, 2023; Belgrade. 2023;:36-36.
https://hdl.handle.net/21.15107/rcub_vinar_11799 .

Matijević, M., Korićanac, Lela, Nakarada, Đ., Žakula, Jelena, Stepić, M., Radoičić, Marija, Mojović, M., Petković, M., Nešić, M. D., "Photosensitizer potential of doped and undoped nanostructured TiO2" in PHOTONICA2023 : 9th International School and Conference on Photonics : book of abstracts; August 28 - September 1, 2023; Belgrade (2023):36-36,
https://hdl.handle.net/21.15107/rcub_vinar_11799 .

TY  - CONF
AU  - Miler, I. D.
AU  - Nešić, M. D.
AU  - Žakula, Jelena
AU  - Korićanac, Lela
AU  - Radoičić, Marija B.
AU  - Korićanac, A.
AU  - Petković, M.
AU  - Stepić, Milutin
PY  - 2021
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/10909
AB  - Melanoma is one of the most severe life-threatening diseases with a highly aggressive biologic behavior. Despite all improvements in diagnosis and therapy, most deaths from melanoma are due to metastases that are resistant to conventional treatment modalities [1]. Photodynamic therapy (PDT) is a relatively new treatment modality that has been successfully applied to many diseases and disorders, including skin cancers. PDT uses a combination of a light-sensitive substance (known as a photosensitizer, PS) and light of an appropriate wavelength. After the activation by light, PS reacts with molecular oxygen producing reactive oxygen species (ROS) and radicals, which cause intracellular biochemical changes leading to cell death [2]. Titanium dioxide nanoparticles (TiO2 NPs) are commonly used PSs in PDT [3], but they absorb strongly in the UV light range. Doping TiO2 NPs with ions leads to an increase in the absorption edge wavelength and a decrease in the bandgap energy, enabling the application of a less damaging visible light for the NP activation. However, to our best knowledge, metal-doped TiO2 has not been extensively tested as PSs. This study aimed to investigate the effects of colloidal TiO2 NPs and prolate nanospheroids (PNSs) doped with Cu and Ni on melanoma cell lines (A375) in the dark and under blue light irradiation. In general, doped TiO2 NPs show higher photocatalytic activity than undoped analog. Among them, the best photocatalytic activity showed TiO2 NPs doped with Cu [4]. However, colloidal TiO2 NPs have a diameter of 5 nm, whereas PNSs are around 20 nm long. Therefore, the cytotoxicity of cells was dependent on the dopant and the size of NPs. Still, in all cases, it is augmented by the light illumination, implying the potential use of doped TiO2 NPs with Cu and Ni as a light-sensitive drug in PDT of melanoma. In summary, our results can contribute to the development of more efficient skin cancer treatment modalities.
PB  - Belgrade : Institute of Physics Belgrade
C3  - PHOTONICA2021 : 8th International School and Conference on Photonics and HEMMAGINERO workshop : Abstracts of Tutorial, Keynote, Invited Lectures, Progress Reports and Contributed Papers; August 23-27, 2021; Belgrade
T1  - The metal-doped TiO2 nanoparticles as photosensitizers in photodynamic therapy of melanoma
SP  - 103
UR  - https://hdl.handle.net/21.15107/rcub_vinar_10909
ER  - 

@conference{
author = "Miler, I. D. and Nešić, M. D. and Žakula, Jelena and Korićanac, Lela and Radoičić, Marija B. and Korićanac, A. and Petković, M. and Stepić, Milutin",
year = "2021",
abstract = "Melanoma is one of the most severe life-threatening diseases with a highly aggressive biologic behavior. Despite all improvements in diagnosis and therapy, most deaths from melanoma are due to metastases that are resistant to conventional treatment modalities [1]. Photodynamic therapy (PDT) is a relatively new treatment modality that has been successfully applied to many diseases and disorders, including skin cancers. PDT uses a combination of a light-sensitive substance (known as a photosensitizer, PS) and light of an appropriate wavelength. After the activation by light, PS reacts with molecular oxygen producing reactive oxygen species (ROS) and radicals, which cause intracellular biochemical changes leading to cell death [2]. Titanium dioxide nanoparticles (TiO2 NPs) are commonly used PSs in PDT [3], but they absorb strongly in the UV light range. Doping TiO2 NPs with ions leads to an increase in the absorption edge wavelength and a decrease in the bandgap energy, enabling the application of a less damaging visible light for the NP activation. However, to our best knowledge, metal-doped TiO2 has not been extensively tested as PSs. This study aimed to investigate the effects of colloidal TiO2 NPs and prolate nanospheroids (PNSs) doped with Cu and Ni on melanoma cell lines (A375) in the dark and under blue light irradiation. In general, doped TiO2 NPs show higher photocatalytic activity than undoped analog. Among them, the best photocatalytic activity showed TiO2 NPs doped with Cu [4]. However, colloidal TiO2 NPs have a diameter of 5 nm, whereas PNSs are around 20 nm long. Therefore, the cytotoxicity of cells was dependent on the dopant and the size of NPs. Still, in all cases, it is augmented by the light illumination, implying the potential use of doped TiO2 NPs with Cu and Ni as a light-sensitive drug in PDT of melanoma. In summary, our results can contribute to the development of more efficient skin cancer treatment modalities.",
publisher = "Belgrade : Institute of Physics Belgrade",
journal = "PHOTONICA2021 : 8th International School and Conference on Photonics and HEMMAGINERO workshop : Abstracts of Tutorial, Keynote, Invited Lectures, Progress Reports and Contributed Papers; August 23-27, 2021; Belgrade",
title = "The metal-doped TiO2 nanoparticles as photosensitizers in photodynamic therapy of melanoma",
pages = "103",
url = "https://hdl.handle.net/21.15107/rcub_vinar_10909"
}

Miler, I. D., Nešić, M. D., Žakula, J., Korićanac, L., Radoičić, M. B., Korićanac, A., Petković, M.,& Stepić, M.. (2021). The metal-doped TiO2 nanoparticles as photosensitizers in photodynamic therapy of melanoma. in PHOTONICA2021 : 8th International School and Conference on Photonics and HEMMAGINERO workshop : Abstracts of Tutorial, Keynote, Invited Lectures, Progress Reports and Contributed Papers; August 23-27, 2021; Belgrade
Belgrade : Institute of Physics Belgrade., 103.
https://hdl.handle.net/21.15107/rcub_vinar_10909

Miler ID, Nešić MD, Žakula J, Korićanac L, Radoičić MB, Korićanac A, Petković M, Stepić M. The metal-doped TiO2 nanoparticles as photosensitizers in photodynamic therapy of melanoma. in PHOTONICA2021 : 8th International School and Conference on Photonics and HEMMAGINERO workshop : Abstracts of Tutorial, Keynote, Invited Lectures, Progress Reports and Contributed Papers; August 23-27, 2021; Belgrade. 2021;:103.
https://hdl.handle.net/21.15107/rcub_vinar_10909 .

Miler, I. D., Nešić, M. D., Žakula, Jelena, Korićanac, Lela, Radoičić, Marija B., Korićanac, A., Petković, M., Stepić, Milutin, "The metal-doped TiO2 nanoparticles as photosensitizers in photodynamic therapy of melanoma" in PHOTONICA2021 : 8th International School and Conference on Photonics and HEMMAGINERO workshop : Abstracts of Tutorial, Keynote, Invited Lectures, Progress Reports and Contributed Papers; August 23-27, 2021; Belgrade (2021):103,
https://hdl.handle.net/21.15107/rcub_vinar_10909 .