2021 Candidate degree in physical and mathematical science
Education
2023 Повышение квалификации: Университет ИТМО, "Фронтиры прикладного искуственного интелекта: промышленность, экономика, образование"
2023 Повышение квалификации: Самарский университет, "Информационные системы и цифровые сервисы Самарского университета"
2023 Повышение квалификации: Самарский университет, "Методика создания и использования электронных образовательных ресурсов в LMS Moodle"
2023 Повышение квалификации: Самарский университет, "Основы цифровой дидактики в высшем образовании"
2023 Повышение квалификации: МИРЭА – Российский технологический университет, "Нейронные сети обработки текстов и речи"
2023 Повышение квалификации: Самарский университет, "Цифровые инструменты и сервисы для создания образовательного медиаконтента"
2023 Повышение квалификации: Самарский университет, "Цифровое право в профессиональной деятельности "
2022 Повышение квалификации: Самарский университет, Обучение подготовке и проведению лекционных и практических занятий на английском языке
2022 Повышение квалификации: МИРЭА – Российский технологический университет, «Нейронные сети анализа изображений и аудиоинформации»
2022 Повышение квалификации: Самарский университет, Навыки оказания первой помощи
2021 Повышение квалификации: Самарский университет, Электронная информационно-образовательная среда университета
2021 Повышение квалификации: Самарский университет, по программе "Электронная информационно-образовательная среда университета"
2019 Повышение квалификации: Самарский университет, "Написание научных статей и подготовка презентаций на английском языке"
2013 - 2015 Высшее образование - специалитет, магистратура: Самарский государственный аэрокосмический университет имени академика С.П.Королева
2009 - 2013 Высшее: Самарский государственный аэрокосмический университет имени академика С.П.Королева, факультет Информатика
2022 Повышение квалификации: Самарский университет, Инклюзивное профессиональное образование
2024
1Khristoforova Y.Raman Spectral Features of Human Serum at Different Excitation for Identification of Chronic Heart Failure // 2024 10th International Conference on Information Technology and Nanotechnology, ITNT 2024. — 2024. —
2023
1Grechkin B.V., Vinokurov V.O., Khristoforova Y.A. etc. VGG Convolutional Neural Network Classification of Hyperspectral Images of Skin Neoplasms // Journal of Biomedical Photonics and Engineering 2023. — Vol. 9. Issue 4. № 4.
2Tomnikova Kseniya Evgenevna, Matveeva I.A., Khristoforova Yu.A.MCR-анализ рамановских спектров кожи пациентов с хронической сердечной недостаточностью // IX Международная конференция и молодёжная школа «Информационные технологии и нанотехнологии» (ИТНТ-2023). — 2023. — Vol. 6.
3Khristoforova Y., Bratchenko L., Bratchenko I.Raman-Based Techniques in Medical Applications for Diagnostic Tasks: A Review // International Journal of Molecular Sciences 2023. — Vol. 24. Issue 21. № 21.
4Khristoforova Y.A., Bratchenko L.A., Skuratova M.A. etc. Raman spectroscopy in chronic heart failure diagnosis based on human skin analysis // Journal of Biophotonics 2023. — Vol. 16. Issue 7. № 7.
2022
1Mircheva V.S., Troyanova P.P., Terziev I.N. etc. Near-Infrared and diffuse reflectance spectroscopy of ex vivo and in vivo cutaneous melanin-pigmented neoplasia // 2022 International Conference Laser Optics, ICLO 2022 - Proceedingss. — 2022. —
2Matveeva I.A., Bratchenko I., Khristoforova Y. etc. Multivariate Curve Resolution Alternating Least Squares Analysis of In Vivo Skin Raman Spectra // Sensors (Basel, Switzerland) 2022. — Vol. 22. Issue 24. № 24.
3Bratchenko I.A., Bratchenko L.A., Khristoforova Y.A. etc. Classification of skin cancer using convolutional neural networks analysis of Raman spectra // Computer Methods and Programs in Biomedicine 2022. — Vol. 219.
4Matveeva I.A., Khristoforova Y.A., Bratchenko L.A. etc. Analysis of Raman spectra using the multivariate curve resolution-alternating least squares (MCR-ALS) algorithm // Proceedings of SPIE - The International Society for Optical Engineering. — 2022. — Vol. 12144.
5Khristoforova Y., Bratchenko I., Bratchenko L. etc. Combination of Optical Biopsy with Patient Data for Improvement of Skin Tumor Identification // DIAGNOSTICS 2022. — Vol. 12. Issue 10. № 10.
2Belokonev V.I., Zakharov V.P., Pushkin S.Y. etc. Visualization and spectral analysis of pubic periosteum atrophy // Journal of Biomedical Photonics and Engineering 2021. — Vol. 7. Issue 4.
3Vinokurov V. O. , Khristoforova Yu., Myakinin O. O. etc. Neural network classifier for hyperspectral images of skin pathologies // OMFI-2021. — 2021. — Vol. 2127. Issue 1.
4Bratchenko I.A., Bratchenko L.A., Moryatov A.A. etc. In vivo diagnosis of skin cancer with a portable Raman spectroscopic device // Experimental Dermatology 2021. — Vol. 30. Issue 5. — P. 652-663
5Matveeva I., Khristoforova Y., Moryatov A. etc. Classification of human skin Raman spectra using multivariate curve resolution (MCR) and partial least squares discriminant analysis (PLS-DA) // OMFI-2021. — 2021. — Vol. 2127. Issue 1.
6Mircheva V., Zaharieva L., Ilyov S. etc. Near-infrared autofluorescence spectroscopy and photobleaching detection of melanin-pigmented cutaneous neoplasia // Journal of Physics: Conference Series. — 2021. — Vol. 1859. Issue 1.
8Bratchenko L.A., Khristoforova Y.A., Moryatov A.A. etc. Raman spectroscopy based diagnosis of dermatofibrosarcoma protuberans: Case report // Photodiagnosis and Photodynamic Therapy 2021. — Vol. 35.
9Bratchenko I.A., Khristoforova Y.A., Bratchenko L.A. etc. Optical biopsy of amelanotic melanoma with raman and autofluorescence spectra stimulated by 785 nm laser excitation // Journal of Biomedical Photonics and Engineering 2021. — Vol. 7. Issue 2.
10Vinokurov V. O. , Matveeva I.A., Khristoforova Y.A. etc. Neural network classifier of hyperspectral images of skin pathologies // Computer Optics 2021. — Vol. 45. Issue 6. — P. 879-886
11Khristoforova Y.A., Bratchenko I.A., Bratchenko L.A. etc. DETECTION OF AMELANOTIC MELANOMA ON THE BASIS OF NIR AUTOFLUORESCENCE FEATURES // Progress in Biomedical Optics and Imaging - Proceedings of SPIE. — 2021. — Vol. 11919.
2020
1Matveeva Irina Aleksandrovna, Myakinin O.O., Khristoforova Yu.A.Monte Carlo simulation of Raman light scattering in a human skin // VI Международная конференция и молодежная школа "Информационные технологии и нанотехнологии" (ИТНТ-2020). — 2020. — Vol. 3. — P. 453-459
2Borisova E.G., Bratchenko I.A., Khristoforova Y.A. etc. Near-infrared autofluorescence spectroscopy of pigmented benign and malignant skin lesions // Optical Engineering 2020. — Vol. 59. Issue 6.
3Khristoforova Y., Bratchenko I., Borisova E. etc. The study of ex vivo and in vivo skin neoplasms using near-infrared fluorescence spectroscopy // Proceedings of ITNT 2020 - 6th IEEE International Conference on Information Technology and Nanotechnology. — 2020. —
4Matveeva I.A., Myakinin O. O. , Vinokurov V. O. etc. Additive approach to simulation of malignant neoplasms using the monte carlo method // Journal of Biomedical Photonics and Engineering 2020. — Vol. 6. Issue 3.
5Bashkatov A. N., Zakharov V.P., Bucharskaya A. N. etc. Malignant Tissue Optical PropertiesCham: Springer Nature, 2020. 104p.
6Bratchenko I.A., Bratchenko L.A., Khristoforova Yu.A. etc. Multivariative analysis of Raman and autofluorescence spectra of human tissues // Twelfth Winter Symposium on Chemometrics "Modern Methods of Data Analysis". — 2020. — P. 54-55
7Zakharov V.P., Bratchenko L.A., Khristoforova Y.A. etc. Multiparametric spectral diagnosis of skin cancer // Proceedings of SPIE - The International Society for Optical Engineering. — 2020. — Vol. 11363.
8Matveeva I., Myakinin O. O. , Khristoforova Y. etc. Monte Carlo simulation of Raman light scattering and Multivariate Curve Resolution - Alternating Least Squares for determination of changes in skin tissue during the development of malignant neoplasms // Proceedings of ITNT 2020 - 6th IEEE International Conference on Information Technology and Nanotechnology. — 2020. —
10Khristoforova Y.A., Bratchenko I.A., Bratchenko L.A. etc. Optical biopsy of skin cancer based on Raman and fluorescence spectroscopy // Proceedings of SPIE - The International Society for Optical Engineering. — 2020. — Vol. 11582.
11Borisova E., Genova T., Mircheva V. etc. Multispectral fluorescence detection of pigmented cutaneous tumours // Proceedings of SPIE - The International Society for Optical Engineering. — 2020. — Vol. 11585.
12Matveeva I.A., Myakinin O. O. , Khristoforova Y.A. etc. Possibilities for decomposing Raman spectra of amino acids mixture by Multivariate Curve Resolution (MCR) analysis // Proceedings of SPIE - The International Society for Optical Engineering. — 2020. — Vol. 11582.
13Matveeva I.A., Myakinin O. O. , Khristoforova Y.A. etc. Additive simulation of Raman light scattering from skin cancer using the Monte Carlo method // Proceedings of SPIE - The International Society for Optical Engineering. — 2020. — Vol. 11363.
2019
1Khristoforova Y., Bratchenko I., Myakinin O. O. etc. In vivo multimodal optical biopsy of skin cancer // Proceedings of SPIE - The International Society for Optical Engineering. — 2019. — Vol. 11140.
2Khristoforova Y., Bratchenko I., Bratchenko L. etc. In vivo Raman and autofluorescence study of the pigmented skin neoplasms // Journal of Physics: Conference Series. — 2019. — Vol. 1368. Issue 2.
3Khristoforova Y.A., Bratchenko I.A., Myakinin O. O. etc. Portable spectroscopic system for in vivo skin neoplasms diagnostics by Raman and autofluorescence analysis // Journal of Biophotonics 2019. — Vol. 12. Issue 4.
4Sherendak V.P., Bratchenko I.A., Myakinin O. O. etc. Hyperspectral in vivo analysis of normal skin chromophores and visualization of oncological pathologies // Computer Optics 2019. — Vol. 43. Issue 4. — P. 661-670
5Bratchenko I.A., Artemyev D.N., Khristoforova Y.A. etc. Use of Raman spectroscopy to screen diabetes mellitus with machine learning tools: Comment // BIOMEDICAL OPTICS EXPRESS 2019. — Vol. 10. Issue 9. — P. 4489-4491
2018
1Bratchenko I.A., Myakinin O.O., Sherendak V.P. etc. In vivo hyperspectral analysis of skin hemoglobin and melanin content for neoplasia detection // Journal of Biomedical Photonics & Engineering 2018. — Vol. 4. № 4.
2Khristoforova Y.A., Bratchenko I.A., Myakinin O. O. etc. In vivo NIR Raman and autofluorescence spectroscopies of skin neoplasms // Proceedings of SPIE - The International Society for Optical Engineering. — 2018. — Vol. 10753.
3Shamina L.A., Bratchenko I.A., Artemyev D.N. etc. Analysis of correlation between Raman and autofluorescence human skin response in visible and NIR region // Journal of Physics: Conference Series. — 2018. — Vol. 1096. Issue 1.
2017
1Bratchenko I.A., Khristoforova Y.A., Artemyev D.N. etc. In vivo study of skin cancers with dermoscopy, hyperspectral imaging and Raman spectroscopy // Симпозиум: Оптика и биофотоника 2017. — 2017. — P. 34
2Khristoforova Y.A., Bratchenko I.A., Artemyev D.N. etc. In vivo diagnostics of malignant and benign tumors with low-cost Raman spectrometer // Optics InfoBase Conference Papers. — 2017. — Vol. Part F66-FiO 2017.
3Lykina A. A. , Artemyev D.N., Bratchenko I.A. etc. Raman spectra analysis of human blood protein fractions using the projection on latent structures method // CEUR Workshop Proceedings. — 2017. — Vol. 1900. — P. 64-68
4Raupov D.S., Myakinin O. O. , Bratchenko I.A. etc. Multiple analyze on 3D-OCT images of skin cancer // Optics InfoBase Conference Papers. — 2017. — Vol. Part F66-FiO 2017.
5Bratchenko I.A., Artemyev D.N., Myakinin O. O. etc. Combined Raman and autofluorescence ex vivo diagnostics of skin cancer in near-infrared and visible regions // JOURNAL OF BIOMEDICAL OPTICS 2017. — Vol. 22. Issue 2.
7Gao W., Jin J., Raupov D.S. etc. 2D fourier fractal analysis of skin tumor with spectral domain optical coherence tomography // Optics InfoBase Conference Papers. — 2017. — Vol. Part F66-FiO 2017.
2016
1Lykina A. A. , Artemyev D.N., Khristoforova Y.A. etc. The plasma protein fractions research by Raman spectroscopy method // Proceedings - 2016 International Conference Laser Optics, LO 2016. — 2016. — P. S216
2Artemyev D.N., Bratchenko I.A., Khristoforova Y.A. etc. Blood proteins analysis by Raman spectroscopy method // Proceedings of SPIE - The International Society for Optical Engineering. — 2016. — Vol. 9887.
3Khristoforova Y.A., Bratchenko I.A., Myakinin O. O. etc. Comparison of Raman spectroscopy equipment for tissues and biofluids analysis // Proceedings of SPIE - The International Society for Optical Engineering. — 2016. — Vol. 9887.
4Artemyev D.N., Zakharov V.P., Davydkin I.L. etc. Measurement of human serum albumin concentration using Raman spectroscopy setup // Optical and Quantum Electronics 2016. — Vol. 48. Issue 6.
5Khristoforova Y.A., Bratchenko I.A., Artemyev D.N. etc. NIR autofluorescence skin tumor diagnostics // Proceedings - 2016 International Conference Laser Optics, LO 2016. — 2016. — P. S217
6Bratchenko I.A., Kristoforova Y.A., Myakinin O. O. etc. Fluorescence spectroscopy for neoplasms control // Proceedings of SPIE - The International Society for Optical Engineering. — 2016. — Vol. 9887.
2015
1Zakharov V.P., Bratchenko I.A., Artemyev D.N. etc. Combined autofluorescence and Raman spectroscopy method for skin tumor detection in visible and near infrared regions // Progress in Biomedical Optics and Imaging - Proceedings of SPIE. — 2015. — Vol. 9537.
2Zakharov V.P., Bratchenko I.A., Artemyev D.N. etc. Skin neoplasm diagnostics using combined spectral method in visible and near infrared regions // 2015 International Conference on BioPhotonics, BioPhotonics 2015. — 2015. —
3Bratchenko I.A., Artemyev D.N., Myakinin O. O. etc. Complex optical method of cancer detection and visualization // 2015 International Conference on BioPhotonics, BioPhotonics 2015. — 2015. —
2014
1Zakharov V.P., Bratchenko I.A., Myakinin O. O. etc. Combined Raman spectroscopy and autofluoresence imaging method for in vivo skin tumor diagnosis // Proceedings of SPIE - The International Society for Optical Engineering. — 2014. — Vol. 9198.
2013
1Zakharov V.P., Bratchenko I.A., Khristoforova Yu.A. etc. Diagnostics of skin pathologies based on spectral analysis of backward and Raman scattering // Optics and Spectroscopy (English translation of Optika i Spektroskopiya) 2013. — Vol. 115. Issue 2. — P. 182-186