A review of career devoted to Biophotonics – In memoriam to Ekaterina Borisova (1978–2021)

Tsanislava Genova (Login required)
Institute of Electronics, Bulgarian Academy of Sciences, Sofia, Bulgaria

Latchezar Avramov
Institute of Electronics, Bulgarian Academy of Sciences, Sofia, Bulgaria

Boyko Kolev
Institute of Electronics, Bulgarian Academy of Sciences, Sofia, Bulgaria

Alexander Gisbrecht
Institute of Electronics, Bulgarian Academy of Sciences, Sofia, Bulgaria

Irina Bliznakova
Institute of Electronics, Bulgarian Academy of Sciences, Sofia, Bulgaria

Lidiya Zaharieva
Institute of Electronics, Bulgarian Academy of Sciences, Sofia, Bulgaria

Victoria Mircheva
Institute of Electronics, Bulgarian Academy of Sciences, Sofia, Bulgaria

Stoyan Ilyov
Institute of Electronics, Bulgarian Academy of Sciences, Sofia, Bulgaria

Ivan Angelov
Institute of Electronics, Bulgarian Academy of Sciences, Sofia, Bulgaria

Vanya Mantareva
Institute of Organic Chemistry with Centre of Phytochemistry, Bulgarian Academy of Sciences, Sofia, Bulgaria

Petranka Troyanova
Tsaritsa Yoanna-ISUL University Hospital, 8 Byalo More St., Sofia, Bulgaria

Petya Pavlova
Technical University Sofia, Branch Plovdiv, Plovdiv, Bulgaria

Tatiana Novikova
LPICM, CNRS, Ecole Polytechnique, Institut Polytechnique de Paris, Palaiseau, France

Razvigor Ossikovski
LPICM, CNRS, Ecole Polytechnique, Institut Polytechnique de Paris, Palaiseau, France

Deyan Ivanov
LPICM, CNRS, Ecole Polytechnique, Institut Polytechnique de Paris, Palaiseau, France

Viktor Dremin
Research and Development Center of Biomedical Photonics, Orel State University, Orel 302026, Russia
College of Engineering and Physical Sciences, Aston University, Birmingham, UK

Edik U. Rafailov
College of Engineering and Physical Sciences, Aston University, Birmingham, UK

Sergey G. Sokolovsky
College of Engineering and Physical Sciences, Aston University, Birmingham, UK

Alexander Bykov
Optoelectronics and Measurement Techniques Unit, University of Oulu, Oulu, Finland

Igor V. Meglinski
College of Engineering and Physical Sciences, Aston University, Birmingham, UK
Optoelectronics and Measurement Optoelectronics and Measurement Techniques Unit, University of Oulu, Oulu, Finland
Institute of Clinical Medicine N.V. Sklifosovsky, I.M. Sechenov First Moscow State Medical University, Moscow, Russia

Ivan Bratchenko
Department of Laser and Biotechnical Systems, Samara National Research University, Samara, Russia

Oxana Semyachkina-Glushkovskaya
Science Medical Center, Saratov State University, Saratov, Russia
Physics Department, Humboldt University, Berlin, Germany

Elina Genina
Science Medical Center, Saratov State University, Saratov, Russia
Laboratory of Laser Molecular Imaging and Machine Learning, National Research Tomsk State University, Tomsk, Russia

Alexey N. Bashkatov
Science Medical Center, Saratov State University, Saratov, Russia
Laboratory of Laser Molecular Imaging and Machine Learning, National Research Tomsk State University, Tomsk, Russia

Alla B. Bucharskaya
Science Medical Center, Saratov State University, Saratov, Russia
Laboratory of Laser Molecular Imaging and Machine Learning, National Research Tomsk State University, Tomsk, Russia
Saratov State Medical University, Saratov, Russia

Valery Zakharov
Department of Laser and Biotechnical Systems, Samara National Research University, Samara, Russia

Janis Spigulis
Biophotonics Laboratory, Institute of Atomic Physics and Spectroscopy, University of Latvia, Riga, Latvia

Sindhoora Kaniyala Melanthota
Department of Biophysics, Manipal School of Life Sciences, Manipal Academy of Higher Education, Manipal, Karnataka, India

Spandana K. U.
Department of Biophysics, Manipal School of Life Sciences, Manipal Academy of Higher Education, Manipal, Karnataka, India

Nirmal Mazumder
Department of Biophysics, Manipal School of Life Sciences, Manipal Academy of Higher Education, Manipal, Karnataka, India

Shama Prasad K.
Department of Cell and Molecular Biology, Manipal School of Life Sciences, Manipal Academy of Higher Education, Manipal, Karnataka, India

Peter Townsend
University of Sussex, UK

Luís Oliveira
Physics Department, School of Engineering, Polytechnic Institute of Porto, Porto, Portugal
Center of Innovation in Engineering and Industrial Technology, ISEP, Porto, Portugal

Alexander V. Priezzhev
Faculty of Physics, M.V. Lomonosov Moscow State University, Moscow, Russia

Dick (H.J.C.M.) Sterenborg
Department of Biomedical Engineering and Physics of the Academic Medical Centre in Amsterdam, Amsterdam, the Netherlands
Surgical Innovations Group at the Netherlands Cancer Institute, Amsterdam, the Netherlands

Valery V. Tuchin
Science Medical Center, Saratov State University, Saratov, Russia
Laboratory of Laser Molecular Imaging and Machine Learning, National Research Tomsk State University, Tomsk, Russia
Laboratory of Laser Diagnostics of Technical and Living Systems, Precision Mechanics and Control Institute of the Russian Academy of Sciences, Saratov, Russia
А.N. Bach Institute of Biochemistry, Research Center of Biotechnology of the Russian Academy of Sciences, Moscow, Russia




DOI: 10.18287/JBPE21.07.040101

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References


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2. P. Djorev, E. Borisova, and L. Avramov, “Interaction of the IR laser radiation with human skin - Monte-Carlo simulation,” Proceedings of SPIE 5226, 403–407 (2003).

3. E. G. Borisova, P. P. Troyanova, V. P. Stoyanova, and L. A. Avramov, “Laser-induced fluorescence spectroscopy of benign and malignant cutaneous lesions,” Proceedings of SPIE 5830, 394–398 (2005).

4. L. Avramaov, E. Borisova, P. D. Townsend, and L. A. Valberg, “Potential and Current Uses Of Luminescence In Medical Diagnosis,” Materials Science Forum 480–481, 411–416 (2005).

5. E. Borisova, I. Angelov, V. Mantareva, D. Petrova, P. Townsend, L. Valberg, and L. Avramov, “Tumour detection by exogenous fluorescent dyes using new generation photomultiplier tubes,” Proceedings of SPIE 5830, 399–403 (2005).

6. E. Borisova, P. Trojanova, and L. Avramov, “Reflectance measurements of skin lesions – Noninvasive method for diagnostic evaluation of pigmented neoplasia,” Proceedings of SPIE 5862, 58620A (2005).

7. E. Borisova, L. Avramov, and P. Troyanova, “Light-induced fluorescence spectroscopy and optical coherence tomography of basal cell carcinoma,” Journal of Innovative Optical Health Sciences 2(03), 261–268 (2009).

8. E. Borisova, P. Troyanova, and L. Avramov, “Optical biopsy of non-melanin pigmented cutaneous benign and malignant lesions,” Proceedings of SPIE 6257, 62570U (2006).

9. E. Borisova, I. Bliznakova, N. Momchilov, P. Troyanova, and L. Avramov, “Fluorescence spectroscopy investigations of cutaneous tissues,” AIP Conference Proceedings 899, 465–466 (2007).

10. I. Bliznakova, E. Borisova, and L. Avramov, “Laser- and light-induced autofluorescence spectroscopy of human skin in dependence on excitation wavelengths,” Acta Physica Polonica A 112(5), 1131–1136 (2007).

11. E. Borisova, I. Bliznakova, P. Troyanova, and L. Avramov, “Light-induced autofluorescence of animal skin used in tissue optical modeling,” Optics InfoBase Conference Papers 6628, 60 (2007).

12. E. G. Borisova, E. Nikolova, P. P. Troyanova, and L. A. Avramov, “Autofluorescence and diffuse reflectance spectroscopy of pigment disorders in human skin,” Journal of Optoelectronics and Advanced Materials 10(3), 717–722 (2008). ISSN: 14544164.

13. P. Troyanova, E. Borisova, and L. Avramov, “Fluorescence and reflectance properties of hemoglobin-pigmented skin disorders,” Proceedings of SPIE 6734, 673415 (2007).

14. E. Borisova, P. Troyanova, and L. Avramov, “Influence of measurement geometry on the human skin reflectance spectra detection,” Proceedings of SPIE 6734, 673416 (2007).

15. E. Borisova, P. Troyanova, P. Pavlova, and L. Avramov, “Diagnostics of pigmented skin tumors based on laser-induced autofluorescence and diffuse reflectance spectroscopy,” Quantum Electronics 38(6), 597–605 (2008).

16. E. Borisova, P. Troyanova, E. Nikolova, and L. Avramov, “Cutaneous tumors in vivo investigations using fluorescence and diffuse reflectance techniques,” Proceedings of SPIE 6791, 679105 (2008).

17. E. Borisova, D. Dogandjiiska, I. Bliznakova, L. Avramov, E. Pavlova, and P. Troyanova, “Multispectral autofluorescence diagnosis of non-melanoma cutaneous tumors,” Proceedings of SPIE 7368, 736823 (2009).

18. E. Borisova, L. Avramov, P. Pavlova, E. Pavlova, and P. Troyanova, “Qualitative optical evaluation of malignancies related to cutaneous phototype,” Proceedings of SPIE 7563, 75630X (2010).

19. P. Pavlova, E. Borisova, L. Avramov, E. Petkova, and P. Troyanova, “Investigation of Relations between Skin Cancer Lesions’ Images and Their Fluorescent Spectra,” Laser Physics 20(3), 596–603 (2010).

20. E. Borisova, P. Pavlova, E. Pavlova, P. Troyanova, and L. Avramov, “Optical biopsy of human skin – A tool for cutaneous tumours’ diagnosis,” International Journal Bioautomation 16 (1), 53–72 (2012).

21. V. Mantareva, D. Petrova, L. Avramov, I. Angelov, E. Borisova, M. Peeva, and D. Wöhrle, “Long wavelength absorbing cationic Zn(II)-phthalocyanines as fluorescent contrast agents for B16 pigmented melanoma,” Journal of Porphyrins and Phthalocyanines 9(1), 47–53 (2005).

22. E. Drakaki, E. Borisova, M. Makropoulou, L. Avramov, A. A. Serafetinides, and I. Angelov, “Laser induced autofluorescence studies of animal skin used in modeling of human cutaneous tissue spectroscopic measurements,” Skin Research and Technology 13(4), 350–359 (2007).

23. A. Zhelyazkova, E. Borisova, L. Angelova, E. Pavlova, and M. Keremedchiev “Excitation-emission matrices measurements of human cutaneous lesions – Tool for evaluation of fluorescence origin,” Proceedings of SPIE 9032, 90320A (2013).

24. G. Borisova, P. Angelova, and P. Pavlova, “Endogenous and exogenous fluorescence skin cancer diagnostics for clinical applications,” IEEE Journal of Selected Topics in Quantum Electronics 20(2), 6606819 (2014).

25. E. Borisova, P. Pavlova, P. Troyanova, and L. Avramov, “Automation of cancer diagnosis based on colorimetric transformation of cutaneous reflectance spectra,” Optics InfoBase Conference Papers 4386657, 73192 (2007).

26. E. Borisova, E. Pavlova, T. Kundurjiev, P. Troyanova, T. Genova, and L. Avramov, “Light-induced autofluorescence and diffuse reflectance spectroscopy in clinical diagnosis of skin cancer,” Proceedings of SPIE 9129, 91291O (2014).

27. E. Borisova, Al. Jeliazkova, E. Pavlova, P. Troyanova, T. Kundurdjiev, P. Pavlova, and L. Avramov, “Reflectance spectroscopy of pigmented cutaneous benign and malignant lesions,” Proceedings of SPIE 9421, 94210I (2014).

28. Pavlova P., N. Shakev, and E. Borisova, “Comparative analysis of methods for ascertainment the similarity between reflected spectra obtained from skin lesions,” IFAC PapersOnLine 52(25), 365–369 (2019).

29. E. Borisova, T. Genova, P. Troyanova, I. Terziev, V. Zakharov, I. Bratchenko, M. Lomova, D. Gorin, and L. Avramov, “Microscopic and macroscopic spectral peculiarities of cutaneous tumours,” Proceedings of SPIE 10592, 1059202 (2017).

30. E. Borisova, T. Genova-Hristova, P. Troyanova, I. Terziev, E. A. Genina, A. N. Bashkatov, O. Semyachkina-Glushkovskaya, V. Tuchin, and L. Avramov, “Optical UV-VIS-NIR spectroscopy of benign, dysplastic and malignant cutaneous lesions ex vivo,” Proceedings of SPIE 10685, 106853T (2018).

31. E. Borisova, T. Genova-Hristova, P. Troyanova, E. Pavlova, I. Terziev, O. Semyachkina-Glushkovskaya, M. Lomova, E. Genina, G. Stanciu, D. Tranca, and L. Avramov, “Multispectral detection of cutaneous lesions using spectroscopy and microscopy approaches,” Proceedings of SPIE 10467, 104670M (2018).

32. E. Borisova, A. Gisbrecht, T. Genova-Hristova, P. Troyanova, E. Pavlova, N. Penkov, I. Bratchenko, V. Zakharov, I. Lihachova, I. Kuzmina, and J. Spigulis, “Multispectral autoflourescence detection of skin neoplasia using steady-state techniques,” Proceedings of SPIE 11047, 1104704 (2019).

33. E. Borisova, T. Genova, V. Mircheva, P. Troyanova, I. Bratchenko, L. Bratchenko, Y. Khristoforova, V. Zakharov, I. Lihacova, A. Lihacovs, and J. Spigulis, “Multispectral fluorescence detection of pigmented cutaneous tumours,” Proceedings of SPIE 11585, 1158504 (2020).

34. Y. A. Khristoforova, I. A. Bratchenko, L. A. Bratchenko, O. O. Myakinin, D. N. Artemyev, A. A. Moryatov, S. V. Kozlov, E. G. Borisova, T. I. Genova, P. P. Troyanova, and V. P. Zakharov, “Optical biopsy of skin cancer based on Raman and fluorescence spectroscopy,” Proceedings of SPIE 11582, 115821K (2020).

35. V. Mircheva, L. Zaharieva, S. Ilyov, P. Troyanova, I. Lihacova, A. Lihacovs, I. Bratchenko, L. Bratchenko, Y. Khristoforova, and V. Zakharov, “Near-infrared autofluorescence spectroscopy and photobleaching detection of melanin-pigmented cutaneous neoplasia,” Journal of Physics: Conference Series 1859 (1), 012044 (2021).

36. P. Pavlova, E. Borisova, L. Avramov, E. Petkova, and P. Trotanova, “Investigation of Relations between Skin Cancer Lesions’ Images and Their Reflectance and Fluorescent Spectra,” Chapter 6 In Melanoma in the Clinic – Diagnostics, Management and Complications of Malignancy, M. Murph (Ed.), InTech Open Access Publisher, 87–104 (2011). ISBN: 978-953-307-571-6.

37. J. Spigulis, I. Kuzmina, V. Lukinsone, M. Tamošiūnas, I. Oshina, L. Ozolina, A. Maslobojeva, M. Kuzminskis, D. Ivanov, and E. Borisova, “Towards combined multispectral, FLIM and Raman imaging for skin diagnostics,” Proceedings of SPIE 11232, 112320N (2020).

38. L. Bratchenko, E. Abrosimova, S. Stafeev, E. Tupikova, E. Borisova, and I. Bratchenko, “Conventional Raman and surface-enhanced Raman spectroscopy for human skin components analysis,” In 2020 International Conference on Information Technology and Nanotechnology (ITNT), 26–29 May, Samara, Russia (2020).

39. E. Borisova, D. Ivanov, B. Kolev, T. Genova, V. Mircheva, S. Ilyov, L. Zaharieva, I. Lihachova, A. Lihachovs, J. Spigulis, and P. Troyanova, “Autofluorescence spectroscopy of cutaneous neoplasia under ultraviolet, visible and near infrared excitation,” Proceedings of SPIE 11363, 113630Z (2020).

40. E. Borisova, L. Plamenova, M. Keremedchiev, B. Vladimirov, and L. Avramov, “Endogenous and exogenous fluorescence of gastrointestinal tumors-initial clinical observations,” Proceedings of SPIE 8770, 87701C (2013).

41. E. Borisova, L. Angelova, A. Zhelyakova, T. Genova, O. Semyachkina-Glushkovskaya, M. Keremedchiev, N. Penkov, B. Vladimirov, and L. Avramov, “Endogenous and exogenous fluorescence spectroscopy of gastrointestinal tumours – In vitro studies,” Journal of Optoelectronics and Advanced Materials 16(9–10), 1196–1205 (2014). ISSN: 1454-4164.

42. E. Borisova, Ts. Genova, O. Semyachkina-Glushkovskaya, N. Penkov, I. Terziev, and B. Vladimirov, “Excitation-emission matrices (EEMs) of colorectal tumors — tool for spectroscopic diagnostics of gastrointestinal neoplasia,” Frontiers of Optoelectronics 10(3), 292–298 (2017).

43. E. Borisova, T. Genova, A. Zhelyazkova, L. Angelova, M. Keremedchiev, N. Penkov, I. Terziev, B. Vladimirov, O. Semyachkina-Glukhovskaya, and L. Avramov, “Synchronous autofluorescence spectroscopy of gastrointestinal tumours – Tool for endogenous fluorophores evaluation,” Optoelectronics and Advanced Materials, Rapid Communications 9(9–10), 1234–1238 (2015).

44. T. Genova, E. Borisova, A. Zhelyazkova, N. Penkov, B. Vladimirov, I. Terziev, O. Semyachkina-Glushkovskaya, and L. Avramov, “Colorectal cancer stage evaluation using synchronous fluorescence spectroscopy technique,” Optical and Quantum Electronics 48(8), 378 (2016).

45. E. Borisova, O. Semyachkina-Glushkovskaya, T. Genova, N. Penkov, I. Terziev, B. Vladimirov, and L. Avramov, “Synchronous fluorescence spectroscopy of colon neoplasia,” Proceedings of SPIE 10336, 1033602 (2017).

46. E. Borisova, T. Genova-Hristova, N. Penkov, I. Terziev, P. Troyanova, B. Vladimirov, and L. Avramov, “Synchronous fluorescence spectroscopy of soft tissues – Tool for diagnostics of malignant lesions,” Proceedings of 2018 International Conference Laser Optics 8435383, 493 (2018).

47. T. Genova, E. Borisova, N. Penkov, B. Vladimirov, A. Zhelyazkova, and L. Avramov, “Excitation-emission matrices and synchronous fluorescence spectroscopy for cancer diagnostics in gastrointestinal tract,” Quantum Electronics 46(6), 510–514 (2016).

48. E. Borisova, O. Semyachkina-Glushkovskaya, N. Navolokin, V. Mantareva, I. Angelov, I. Agranovich, A. Khorovodov, N. Shushunova, A. Bodrova, I. Fedosov, A. Namykin, A. Abdurashitov, and L. Avramov, “Photodynamic diagnostics of stress-induced gastrointestinal neoplasia in laboratory animals using 5-Aminolevulinic acid and Al-phthalocyanine,” Proceedings of SPIE 10501, 105011E (2018).

49. I. Agranovich, A. Khorovodov, M. Kanevsky, T. Genova-Hristova, A. Gisbrecht, I. Angelov, V. Mantareva, N. Navolokin, O. Semyachkina-Glushkovskaya, and E. Borisova, “Detection of stress-induced gastrointestinal lesions using Al-phythalocynanines in experimental animals,” Proceedings of SPIE 11047, 1104709 (2019).

50. T. Genova, A. Khorovodov, A. Terskov, M. Kanevsky, A. Gisbrecht, L. Avramov, and O. Semyachkina-Glushkovskaya, “Stomach and intestine neoplasia fluorescence detection using 5-ALA/PpIX photosensitization,” Proceedings of SPIE 11047, 1104708 (2019).

51. E. Borisova, T. Genova, A. Khorovodov, I. Agranovich, M. Kanevskiy, S. Konnova, I. Angelov, V. Mantareva, N. Navolokin, and O. Semyachkina-Glushkovskaya, “ALA/PpIX photodiagnosis of stress-induced gastrointestinal primary tumors and metastases in experimental animals,” Proceedings of SPIE 11079, 110790N (2019).

52. I. Agranovich, E. Borisova, N. Navolokin, A. Bucharskaya, G. Maslyakova, A. Shirokov, A. Abdurashitov, I. Angelov, A. Khorovodov, A. Terskov, A. Mamedova, M. Klimova, and O. Semyachkina-Glushkovskaya, “Phenomenon of atypical vascular effects of epinephrine and an increase of photodynamic response by nitroglycerin in rats with colon adenocarcinoma: adrenergic and nitrergic mechanisms and novel applied aspects,” Biomedical Optics Express 10(8), 4115–4125 (2019).

53. E. Borisova, T. Genova, A. Yakimansky, V. Mantareva, I. Angelov, A. Gisbrecht, Al. Khorovodov, I. Agranovich, M. Klimova, and O. Semyachkina-Glushkovskaya, “Conjugation of Zn (II) phthalocyanine with polymeric brushes for improved photodiagnostics and photodynamic therapy of gastric tumours,” Proceedings of SPIE 11457, 114570R (2020).

54. E. Borisova, M. Kanevskiy, S. Konnova, A. Khorovodov, I. Agranovich, T. Genova, L. Avramov, N. Navolokin, and O. Semyachkina-Glushkovskaya, “5-ALA/PpIX photodiagnosis of stress-induced gastrointestinal metastatic tumours in laboratorial animals,” Proceedings of SPIE 11363, 113630U (2020).

55. I. Agranovich, A. Khorovodov, M. Kanevsky, T. Genova, A. Gisbrecht, I. Angelov, V. Mantareva, N. Navolokin, O. Semyachkina-Glushkovskaya, and E. Borisova, “Stress-induced neoplasia detection in the lower part of gastrointestinal tract of rats using phthalocyanines,” Journal of Physics: Conference Series 1859(1), 012038 (2021).

56. V. Mantareva, V. Kussovski, I. Angelov, E. Borisova, L. Avramov, G. Schnurpfeil, and D. Wöhrle, “Photodynamic activity of water-soluble phthalocyanine zinc(II) complexes against pathogenic microorganisms,” Bioorganic & Medicinal Chemistry 15(14), 4829–4835 (2007).

57. V. Kussovski, V. Mantareva, I. Angelov, P. Orozova, D. Wöhrle, G. Schnurpfeil, E. Borisova, and L. Avramov, “Photodynamic inactivation of aeromonas hydrophila by cationic phthalocyanines with different hydrophobicity,” FEMS Microbiology Letters 294(2), 133–140 (2009).

58. A. Pavlov, E. Borisova, O. Pavlova, I. Agranovich, A. Khorovodov, A. Terskov, A. Mamedova, M. Klimova, L. Avramov, and O. Semyachkina-Glushkovskaya, “Photodynamic diagnostics of early gastric cancer: Complexity measures of gastric microcirculation and new model of metastatic adenocarcinoma of rat stomach,” Journal of Innovative Optical Health Sciences 12(2), 1950007 (2019).

59. V. Mantareva, A. Kril, I. Angelov, R. Dimitrov, E. Borisova, and L. Avramov, “Effects of the position of galactose units to Zn(II) phthalocyanine on the uptake and photodynamic activity towards breast cancer cells,” Proceedings of SPIE 8427, 842743 (2012).

60. I. Angelov, V. Mantareva, V. Kussovski, D. Woehrle, E. Borisova, and L. Avramov, “Improved antimicrobial therapy with cationic tetra- and octa-substituted phthalocyanines,” Proceedings of SPIE 7027, 702717 (2008).

61. V. N. Mantareva, I. Angelov, D. Wöhrle, E. Borisova, and V. Kussovski, “Metallophthalocyanines for antimicrobial photodynamic therapy,” Journal of Porphyrins and Phthalocyanines 17(6–7), 399–416 (2013).

62. N. Momchilov, I. Bliznakova, E. Borisova, P. Troyanova, and L. Avramov, “Development of low-cost photodynamic therapy device,” Acta Physica Polonica Series A 112(5), 1125–1130 (2007).

63. E. Borisova, D. Kyurkchiev, K. Tumangelova-Yuzeir, I. Angelov, T. Genova-Hristova, O. Semyachkina-Glushkovskaya, and K. Minkin, “Evaluation of photodynamic treatment efficiency on glioblastoma cells received from malignant lesions: Initial studies,” Proceedings of SPIE 10716, 1071602 (2017).

64. O. Semyachkina-Glushkovskaya, J. Kurths, E. Borisova, S. Sokolovski, V. Mantareva, I. Angelov, A. Shirokov, N. Navolokin, N. Shushunova, A. Khorovodov, M. Ulanova, M. Sagatova, I. Agranivich, O. Sindeeva, A. Gekalyuk, A. Bodrova, and E. Rafailov, “Photodynamic opening of blood-brain barrier,” Biomedical Optics Express 8(11), 5040–5048 (2017).

65. O. Semyachkina-Glushkovskaya, V. Chehonin, E. Borisova, I. Fedosov, A. Namykin, A. Abdurashitov, A. Shirokov, B. Khlebtsov, Y. Lyubun, N. Navolokin, M. Ulanova, N. Shushunova, A. Khorovodov, I. Agranovich, A. Bodrova, M. Sagatova, A. E. Shareef, E. Saranceva, T. Iskra, M. Dvoryatkina, E. Zhinchenko, O. Sindeeva, V. Tuchin, and J. Kurths, “Photodynamic opening of the blood-brain barrier and pathways of brain clearing,” Journal of Biophotonics 11(8), e201700287 (2018).

66. O. Semyachkina-Glushkovskaya, E. Borisova, V. Mantareva, I. Angelov, I. Eneva, A. Terskov, A. Mamedova, A. Shirokov, A. Khorovodov, M. Klimova, I. Agranovich, I. Blokhina, N. Lezhnev, and J. Kurths, “Photodynamic opening of the blood-brain barrier using different photosensitizers in mice,” Applied Sciences (Switzerland) 10(11), 33 (2020).

67. O. V. Semyachkina-Glushkovskaya, A. S. Abdurashitov, E. I. Saranceva, E. G. Borisova, A. A. Shirokov, and N. V. Navolokin, “Blood-brain barrier and laser technology for drug brain delivery,” Journal of Innovative Optical Health Sciences 10(51), 1730011 (2017).

68. O. V. Semyachkina-Glushkovskaya, E. U. Rafailov, S. G. Sokolovsky, E. G. Borisova, V. Mantareva, I. Angelov, A. Shirokov, N. Navolokin, N. A. Shushunova, A. P. Khorovodov, A. V. Terskov, A. A. Bodrova, M. V. Ulanova, E. Shrif, V. V. Tuchin, and J. Kurths, “The laser technologies of targeted opening of blood-brain barrier for drug brain delivery,” Proceedings of 2018 International Conference Laser Optics (ICLO) 8435846, 501 (2018).

69. E. Borisova, L. Angelova, Al. Jeliazkova, Ts. Genova, E. Pavlova, P. Troyanova, and L. Avramov, “Polarization effects in cutaneous autofluorescent spectra,” Proceedings of SPIE 9129, 91292G (2014).

70. E. Borisova, T. Genova, A. Zhelyazkova, L. Angelova, M. Keremedchiev, N. Penkov, and L. Avramov, “Polarization sensitive excitation-emission matrices for detection of colorectal tumours – initial investigations,” Journal of Physics: Conference Series 594, 012031 (2015).

71. D. Ivanov, E. Borisova, T. Genova, L. Nedelchev, and D. Nazarova, “Tissue polarimetric discrimination analysis of skin and colon histological samples,” AIP Conference Proceedings 2075, 170017 (2019).

72. D. Ivanov, V. Strijkova, L. Nedelchev, D. Nazarova, and E. Borisova, “Visualizing Healthy and Malignant Tissues via Polarized Light Imaging and Chemical Staining,” Journal of Physics and Technology 3(1), 14–17 (2019).

73. D. Ivanov, R. Ossikovski, T. Novikova, P. Li, E. Borisova, T. Genova, L. Nedelchev, and D. Nazarova, “Tissue polarimetric study I: In search of reference parameters and depolarizing Mueller matrix model of ex vivo colon samples,” Proceedings of SPIE 11075, 1107514 (2019).

74. D. Ivanov, T. Genova-Hristova, E. Borisova, L. Nedelchev, and D. Nazarova, “Multiwavelength polarimetry of gastrointestinal ex vivo tissues for tumor diagnostic improvement,” Proceedings of SPIE 11047, 1104707 (2019).

75. D. Ivanov, V. Dremin, A. Bykov, E. Borisova, T. Genova, A. Popov, R. Ossikovski, T. Novikova, and I. Meglinski, “Colon cancer detection by using Poincaré sphere and 2D polarimetric mapping of ex vivo colon samples,” Journal of Biophotonics 13(8), e202000082 (2020).

76. D. Ivanov, V. Dremin, E. Borisova, A. Bykov, T. Novikova, I. Meglinski, and R. Ossikovski, “Polarization and depolarization metrics as optical markers in support to histopathology of ex vivo colon tissue,” Biomedical Optics Express 12(7), 4560–4572 (2021).

77. D. Ivanov, V. Dremin, E. Borisova, A. Bykov, I. Meglinski, T. Novikova, and R. Ossikovski, “Symmetric decomposition of Mueller matrices reveals a new parametric space for polarimetric assistance in colon cancer histopathology,” Proceedings of SPIE 11646, 1164614 (2021).

78. S. Ilyov, D. Ivanov, Ts. Genova, V. Mircheva, L. Zaharieva, B. Kolev, B. Vladimirov, H. Valkov, N. Mazumder, K. Sindhoora, O. Semyachkina-Glushkovskaya, L. Avramov, and E. Borisova, “Reflectance polarization ex vivo measurements of gastrointestinal carcinoma lesions for cancer diagnostics,” Journal of Physics: Conference Series 1859, 012041 (2021).

79. K. M. Sindhoora, K. U. Spandana, D. Ivanov, E. Borisova, U. Raghavendra, S. Rai, S. P. Kabekkodu, K. K. Mahato, and N. Mazumder, “Machine-learning-based classification of Stokes-Mueller polarization images for tissue characterization,” Journal of Physics: Conference Series 1859, 012045 (2021).

80. K. M. Sindhoora, Y. Kistenev, E. Borisova, D. Ivanov, O. Zakharova, A. Boyko, D. Vrazhnov, D. Gopal, S. Chakrabarti, S. Prasada K, and N. Mazumder “Types of spectroscopy and microscopy techniques for cancer diagnosis: a review,” Lasers in Medical Sciences [to be published].

81. N. Mazumder, Y. Kistenev, E. Borisova and S. Prasada K. (Eds.), “Optical Polarimetric Modalities for Biomedical Research,” Springer-Nature [to be published].

82. A. Doronin, N. Vera, J. P. Staforelli, P. Coelho, and I. Meglinski, “Propagation of cylindrical vector laser beams in turbid tissue-like scattering medium,” Photonics 6(2), 56 (2019).

83. A. Doronin, N. Vera, J. Staforelli, T. Novikova, and I. Meglinski, “Perspectives of optical diagnosis with vector light beams,” Proceedings of SPIE 10873, 108730K (2019).

84. I. Meglinski, “Spin Angular Momentum of Light in Digital Histopathology,” In International Webinar Conference on Lasers, Optics, Photonics & Sensors (LOPS 2021), 12–13 June, Virtual Conference (2021).

85. I. Meglinski, “Vector Light in Biomedical Diagnosis,” Horizons of Optics, Photonics and Emerging Sciences (HOPES), IEEE Webinar series (2020).

86. I. Meglinski, N. Vera, J. P. Staforelli, and A. Doronin, “Twisted structured light for tissue diagnosis,” In 8th International Conference on Photonics, Optics and Laser Technology – PHOTOPTICS 2020, 27–29 February, Valletta, Malta (2020).

87. O. Semyachkina-Glushkovskaya, A. Pavlov, J. Kurths, E. Borisova, A. Gisbrecht, O. Sindeeva, A. Abdurashitov, A. Shirokov, N. Navolokin, E. Zinchenko, A. Gekalyuk, M. Ulanova, D. Zhu, Q. Luo, and V. Tuchin, “Optical monitoring of stress-related changes in the brain tissues and vessels associated with hemorrhagic stroke in newborn rats,” Biomedical Optics Express 6(10), 4088–4097 (2015).

88. O. Sindeeva, E. Borisova, A. Abdurashitov, E. Zhinchenko, A. Gekalyuk, M. Ulanova, A. E. Sharif, V. Razubaeva, S. Serov, L. Yankovskaya, V. V. Tuchin, and O. Semyachkina-Glushkovskaya, “The stress-related changes in the cerebral blood flow in newborn rats with intracranial hemorrhage: metabolic and endothelial mechanisms,” Journal of Biomedical Photonics & Engineering 1(4), 248–254 (2016).

89. O. Semyachkina-Glushkovskaya, J. Kurths, A. N. Pavlov, E. G. Borisova, A. S. Abdurashitov, D. Zhu, P. Li, Q. Luo, and V. V. Tuchin, “Silent Vascular Catastrophes in the Brain in Term Newborns: Strategies for Optical Imaging,” IEEE Journal of Selected Topics in Quantum Electronics 22(3), 88–101 (2016).

90. O. Semyachkina-Glushkovskaya, E. Borisova, A. Namikin, I. Fedosov, A. Abdurashitov, E. Zhinchenko, A. Gekalyuk, M. Ulanova, V. Rezunbaeva, L. Avramov, D. Zhu, Q. Luo, and V. Tuchin, “Hypoxia and Neonatal Haemorrhagic Stroke: Experimental Study of Mechanisms,” Advances in Experimental Medicine and Biology 923, Oxygen Transport to Tissue XXXVIII, Springer International Publishing Switzerland, 173–179 (2016).

91. O. Semyachkina-Glushkovskaya, E. Borisova, M. Abakumov, D. Gorin, L. Avramov, I. Fedosov, A. Namykin, A Abdurashitov, A. Serov, A. Pavlov, E. Zinchenko, V. Lychagov, N. Navolokin, A. Shirokov, G. Maslyakova, D. Zhu, Q. Luo, V. Chekhonin, V. Tuchin and J. Kurths, “The Stress and Vascular Catastrophes in Newborn Rats: Mechanisms Preceding and Accompanying the Brain Hemorrhages,” Frontiers in Physiology 7, 210 (2016).

92. V. V. Tuchin, E. Borisova, M. Jędrzejewska-Szczerska, M. J. Leahy, F. S. Pavone, J. Popp, and J. Pozo, “A special issue on Biophotonics in Europe,” Frontiers of Optoelectronics 10(3), 203–210 (2017).

93. V. V. Tuchin, Tissue Optics: Light Scattering Methods and Instruments for Medical Diagnostics, 3rd ed., SPIE Press, Bellingham, WA (2015).

94. O. Semyachkina-Glushkovskaya, E. Borisova, S. Sokolovski, V. Mantareva, I. Angelov, A. Shirokov, N. Navolokin, N. Shushunova, A. Khorovodov, M. Ulanova, M. Sagatova, I. Agranivich, A. Bodrova, E. Rafailov, and V. Tuchin, “Laser-induced generation of singlet oxygen: new strategies in the treatment of brain tumor,” In International Conference on Photonics and Imaging in Biology and Medicine, 26–28 September, Suzhou, China (2017). ISBN: 978-1-943580-35-4.

95. O. Semyachkina-Glushkovskaya, E. U. Rafailov, S. G. Sokolovsky, E. G. Borisova, V. Mantareva, I. Angelov, A. Shirokov, N. Navolokin, N. A. Shushunova, A. P. Khorovodov, A. V. Terskov, A. A. Bodrova, M. V. Ulanova, E. Shrif, V. V. Tuchin, and J. Kurths, “The Laser Technologies of Targeted Opening of Blood-Brain Barrier for Drug Brain Delivery,” In IEEE Conference Proceedings: International Conference Laser Optics, 4–8 June, Saint Petersburg, Russia (2018). ISBN: 978-1-5386-3612-1.

96. O. Semyachkina-Glushkovskaya, J. Kurths, E. Borisova, S. Sokolovski, V. Mantareva, I. Angelov, A. Shirokov, N. Navolokin, N. Shushunova, A. Khorovodov, M. Ulanova, M. Sagatova, I. Agranivich, O. Sindeeva, A. Gekalyuk, A. Bodrova, and E. Rafailov, “Photodynamic opening of blood-brain barrier: non-invasive approaches and age differences,” In the 26th International Conference on Advanced Laser Technologies, 9–14 September, Tarragona, Spain (2018).

97. A. N. Bashkatov, V. P. Zakharov, A. B. Bucharskaya, E. G. Borisova, Y. A. Khristoforova, E. A. Genina, and V. V. Tuchin, “Malignant Tissue Optical Properties,” Chapter 1 in Multimodal Optical Diagnostics of Cancer, V. V. Tuchin, J. Popp, and V. Zakharov (Eds.), Springer Nature Switzerland AG, Cham, Switzerland, 3–106 (2020). ISBN 978-3-030-44593-5.

98. O. Semyachkina-Glushkovskaya, D. Postnov, A. Lavrova, I. Fedosov, E. Borisova, V. Nikolenko, T. Penzel, and V. V. Tuchin, “Biophotonic Strategies of Measurement and Stimulation of the Cranial and the Extracranial Lymphatic Drainage Function,” IEEE Journal of Selected Topics in Quantum Electronics 27(4), 7400313 (2021).

99. A. Bucharskaya, G. Maslyakova, M. Chekhonatskaya, S. Pakhomy, D. Mudrak, N. Navolokin, G. Terentyuk, E. Borisova, V. Mantareva, I. Angelov, B. Khlebtsov, N. Khlebtsov, V. Genin, A. Bashkatov, E. Genina, and V. Tuchin, “The assessment of tumor vascularization degree for predicting the effectiveness of plasmonic photothermal and photodynamic therapy,” Proceedings of SPIE 11845, 1184508 (2021).

100. Photoptics 2020, 8th International Conference on Photonics, Optics and Laser Technology [https://photoptics.scitevents.org/?y=2020].

101. E. Borisova, and L. Oliveira (Eds.), “Special Issue “Advanced Laser Technologies for Biophotonics,” Electronics (2021).

102. E. Borisova, I. Bratchenko, Y. Khristoforova, L. Bratchenko, T. I. Genova, A. I. Gisbrecht, A. A. Moryatov, S. V. Kozlov, P. P. Troyanova, and V. P. Zakharov, “Near-infrared autofluorescence spectroscopy of pigmented benign and malignant skin lesions,” Optical Engineering 59(6), 061616 (2020).

103. I. Bratchenko, Y. Khristoforova, L. Bratchenko, A. Moryatov, S. Kozlov, E. Borisova, and V. Zakharov, “Optical Biopsy of Amelanotic Melanoma with Raman and Autofluorescence Spectra Stimulated by 785 nm Laser Excitation,” Journal of Biomedical Photonics & Engineering 7(2), 020308 (2021).

104. J. Spigulis, A. Lihachev, V. Lukinsone, M. Osis, and I. Oshina, “Lasers for in-vivo skin diagnostics: some recent developments,” Proceedings of SPIE 11047, 1104703 (2019).

105. J. Spigulis, V. Lukinsone, I. Oshina, E. Kviesis-Kipge, M. Tamosiunas, and A. Lihachev, “Riga Group’s recent results on laser applications for skin diagnostics,” Journal of Physics: Conference Series 1859, 012033 (2021).

106. The 15th International School on Quantum Electronics “Laser physics and applications”, 2008 (accessed 21 Nov 2021) [http://www.icsqe2020.ie-bas.org/sqe2008/index.htm].

107. 23rd Annual International Laser Physics Workshop – LPHYS’2014. Local Organizing Committee, 2014 (accessed 21 Nov 2021) [https://www.lasphys.com/workshops/lasphys14/local-organizing-committee].

108. 26rd Annual International Laser Physics Workshop – LPHYS’2017. Advisory and Program Committee, 2017. (accessed 21 Nov 2021) [https://www.lasphys.com/workshops/lasphys17/advisory-program-committee].

109. E. Borisova, H. Schneckenburger, and A. Priezzhev, “Special Section on Laser Technologies for Biomedical Applications,” Journal of Biomedical Optics 17 (10), 101501 (2012).

110. R. Robinson, “Ekaterina Borisova on Creativity,” Optics & Photonics News, 28 January 2020 (accessed 21 Nov 2021) [https://www.optica-opn.org/home/career/2020/january/ekaterina_borisova_on_creativity/].




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