[1] M. Freebody, "Fiber lasers at the cutting edge of surgery," Biophotonics (2013), Available at http:// www.photonics.com/Article.aspx AID=53575.

[2] F. Beer, W. K€orpert, H. Passow, A. Steidler, A. Meinl, A. G. Buchmair, A. Moritz, "Reduction of collateral thermal impact of diode laser irradiation on soft tissue due to modified application parameters", Lasers Med. Sci. 27, 917–921 (2012).

[3] M. Judy, J. Matthews, B. Aronoff, D. Hults, "Soft tissue studies with 805 nm Diode Laser Radiation: Thermal effects with contact tips and comparison with effects of 1064 nm Nd:YAG laser radiation", Laser Surg. Med. 13, 528–536 (1993).

[4] P. S. Zubeev, A. Rotkov, I. Vaganov, I. Skvortsova, V. A. Kamensky, G. V. Gelikonov, A. M. Sergeev, "Resection of parenchymatous organs using pulse YAG: Nd laser radiation at 1.44-μm and 1.32-μm wavelengths", Proc. SPIE Lasers Surg. 3590, 439–443 (1999).

[5] K. Stock, T. Stegmayer, R. Graser, W. F€orster, R. Hibst, "Comparison of different focusing fiber tips for improved oral diode laser surgery", Lasers Surg. Med. 44, 815–823 (2012).

[6] V. N. Kurlov, Sapphire: Propreties, growth and applications, Encyclopedia of Materials: Science and Technology, pp. 8259–8265, Pergamon, Elsevier Science Ltd (2001).

[7] V. Saadatmanesh, H. M. G. Hussein, M. P. Loeb, S. Sulek, J. A. Milburn, "Method and apparatus for treating a body site with laterally directed laser radiation", Patent US 5242438 (1991).

[8] V. P. Zharov, "New technology in surgery: Combination of laser and ultrasound", Proc. SPIE. 1892, 38–44 (1993).

[9] G. E. Romanos, "Diode Laser Soft-Tissue Surgery: Advancement Aimed at Consistent Cutting, Improved Clinical Outcomes", Compend. Contin. Educ. Dent. 34, 752–757 (2013).

[10] A. V. Shakhov, A. B. Terentjeva, V. A. Kamensky, L. B. Snopova, F. I. Feldstain, A. M. Sergeev, "Optical coherence tomography monitoring for laser surgery of laryngeal carcinoma", J. Surg. Oncol. 77, 253–259 (2001).

[11] M. Amzayyb, R. R. van den Bos, V. M. Kodach,D.M. de Bruin, T. Nijsten, H. A. Neumann, M. J. C. van Gemert, "Carbonized blood deposited on fibres during 810, 940 and 1,470 nm endovenous laser ablation: Thickness and absorption by optical coherence tomography", Lasers Med Sci. 25, 439–447 (2010).

[12] V. I. Yusupov, V. M. Chudnovskii, V. N. Bagratashvili, Laser-Induced Hydrodynamics in Water and Biotissues Nearby Optical Fiber Tip, Hydrodynamics — Advanced Topics, Prof. Harry Schulz (Ed.), InTech, DOI: 10.5772/28517 (2011).

[13] D. Kuznetsova, M. Karabut, V. Elagin, M. Shakhova, V. Bredikhin, O. Baskina, L. Snopova, A. Shakhov, V. Kamensky, "Comparative analysis of biotissue laser resection using strongly absorbing optical fiber tips", Opt. Photon. J. 5, 1–5 (2015).

[14] http://altamls.com/applications/soft-tissue-surgery/ how-top-surgery-works/.

[15] S. Baranoski, E. A. Ayello, Wound Care Essentials: Practice Principles, Lippincott Williams & Wilkins, Philadelphia, PA London, p. 479 (2008).

[16] I. L. Shlivko, M. Y. Kirillin, E. V. Donchenko, D. O. Ellinsky, O. E. Garanina, V. A. Kamensky, "Identifi- cation of layers in optical coherence tomography of skin: Comparative analysis of experimental and Monte Carlo simulated images", Skin Res. Technol. 21, 419–425 (2015).

[17] A. N. Bashkatov, E. A. Genina, V. I. Kochubey, V. V. Tuchin, "Optical properties of human skin, subcutaneous and mucous tissues in the wavelength range from 400 to 2000 nm", J. Phys. D, Appl. Phys. 38, 2543 (2005).

[18] P. Taroni, A. Pifferi, A. Torricelli, L. Spinelli, G. M. Danesini, R. Cubeddu, "Do shorter wavelengths improve contrast in optical mammography " Phys. Med. Biol. 49, 1203–1215 (2004).

[19] A. V. Bykov, M. Y. Kirillin, A. V. Priezzhev, "Monte Carlo simulation of signals from model biological tissues measured by an optical coherence tomograph and an optical coherence doppler tomograph", Opt. Spectrosc. 101, 33–39 (2006).

[20] H. P. Berlien, G. Müller, A. Lasermedizin, "Lehrund Handbuch f€ur Praxis und Klinik", Ecomed, Landsberg München, Zürich (1989).