Effect of Polarization and Coherence of Optical Radiation on Sturgeon Sperm Motility
This work contains information about the influence low-level optical irradiation on sperm motility of sturgeon fish. On the basis of given and earlier received data the following conclusion has been made. Among the photophysical processes of a resonant and not resonant nature (oriented action of light; action of gradient forces; dipole-dipole interaction; termooptical processes), which are capable to cause the photobiological effects depended on such laserspecific characteristics as polarization and coherency, determining influence belongs to oriented action of light and dipole-dipole interactions among the processes studied in the present work.
[1] V.Yu. Plavskii et al. (2007). Apparatus for low-level laser therapy:
modern status and development trends. J Opt Technol. 74 (4), 246-257.
[2] E. Mester (1966). The use of the laser beam in therapy. Orv. Hetil., 107
(22), 1012-1016.
[3] M. Fenyö (1984). Theoretical and experimental basis of biostimulation
by laser irradiation. Opt. Laser Technol., 16 (4), 209-215.
[4] K. Yokoyama, K. Sugiyama, (2001). Temporomandibular joint pain
analgesia by linearly polarized near-infrared irradiation. Clinical J.
Pain., 17 (1), 47-51.
[5] L. Medenica, M. Lens, (2003). The use of polarized polychromatic noncoherent
light alone as a therapy for venous leg ulceration. J. Wound
Care, 12 (1), 37-40.
[6] K. Yokoyama, K. Sugiyama (2003). Influence of linearly polarized nearinfrared
irradiation on deformability of human stored erythrocytes. J.
Clin. Laser Med. Surg., 21 (1), 19-22.
[7] J. Verbelen (2007). Use of polarised light as a method of pressure ulcer
prevention in an adult intensive care unit. J. Wound Care., 16 (4), 145-
150.
[8] A.V. Budagovsky (2005). On the ability of cells to distinguish the
coherence of optical radiation. Quantum Electronics, 35 (4), 369-374.
[9] A.N. Rubinov, A.A. Afanas-ev (2005). Nonresonance mechanisms of
biological effects of coherent and incoherent light. Opt. Spectr., 98 (6),
943-948.
[10] T. Karu (1999). Primary and secondary mechanisms of action of visible
to near-IR radiation on cells. J. Photochem. Photobiol. B: Biol., 49 (1),
1-17.
[11] M. Fenyö, J. Mandl, & A. Falus (2002). Opposite effect of linearly
polarized light on biosynthesis of interleukin-6 in a human B lymphoid
cell line and peripheral human monocytes. Cell Biol. Intern., 26 (3),
265-269.
[12] V.A. Mostovnikov et al. (1994). Primary photophysical processes
which define the biological and therapeutic effect of low-intensity laser
radiation. Proc. SPIE, 2370, 541-548.
[13] .Yu. Plavskii et al. (2007). Apparatus for low-level laser therapy:
modern status and development trends. J Opt Technol. 74 (4), 246-257.
[14] J. Kubota, T. Ohshiro (1989). The effects of diode laser low reactivelevel
laser therapy (LLLT) on flap survival in a rat model. Laser
Therapy, 1 (3), 127-134.
[15] I. Onac, L. Pop, & I. Onac (1999). Implications of low-power He-Ne
laser and monochromatic red light biostimulation in protein and
glycoside metabolism. Laser Therapy, 11 (1) 130-137.
[16] T. Qadri et al. 2007The importance of coherence length in laser
phototherapy of gingival inflammation - a pilot study. Lasers Surg.
Med., 22 (4), 245-251.
[17] V.A. Tolkachev (2004). Role of Light Polarization in the Optothermal
Effect. J. Appl. Spectrosc., 71, (1), 139-142.
[18] Yu.A. Vladimirov et al. (2004). Molecular and cellular mechanisms
triggered by low-level laser irradiation. Biophysics (Moscow), 49 (2),
325-336.
[19] V.Yu. Plavskii & N.V. Barulin (2008). Effect of polarization and
coherence of low-intensity optical radiation on fish embryos. J Appl
Spectrosc, Vol. 75, No. 6, pp 843-856.
[20] V.V. Tuchin (1997). Light scattering study of tissues. Physics-Uspekhi,
40 (5), 495-515.
[21] T.I. Karu, L.V. Pyatibrat & T.P. Ryabykh, (1997). Nonmonotonic
behavior of the dose dependence of the radiation effect on cells in vitro
exposed to pulsed laser radiation at λ = 820 nm. Lasers Surg. Med. 21
(5), 485-492.
[22] S.M. Zubkova (1978). Mechanism of biological effect of helium-neon
laser irradiation Nauchnye Dokl. Vyss. Shkoly. Biol. Nauki (Moscow),
No 7, 30-37 (in Russian)
[23] G.A. Zalesskaya et al. (2006). Effect of intravenous laser irradiation
on the molecular structure of blood and blood components. J. Appl.
Spectrosc., 73 (1), 115-122.
[24] V.Yu. Plavskii, & N.V. Barulin (2008). Effect of polarization and
coherence of low-intensity optical radiation on fish embryos. J Appl
Spectrosc, Vol. 75, No. 6, pp 843-856.
[25] V.Yu. Plavskii, & N.V. Barulin (2008). Effect of exposure of sturgeon
roe to low-intensity laser radiation on the hardiness of juvenile sturgeon.
J Appl Spectrosc, 75 (2), 241-250.
[26] V.Yu. Plavskii, & N.V. Barulin (2008). How the biological activity of
low-intensity laser radiation depends on its modulation frequency. J Opt
Technol., 75 (9), 546-552.
[1] V.Yu. Plavskii et al. (2007). Apparatus for low-level laser therapy:
modern status and development trends. J Opt Technol. 74 (4), 246-257.
[2] E. Mester (1966). The use of the laser beam in therapy. Orv. Hetil., 107
(22), 1012-1016.
[3] M. Fenyö (1984). Theoretical and experimental basis of biostimulation
by laser irradiation. Opt. Laser Technol., 16 (4), 209-215.
[4] K. Yokoyama, K. Sugiyama, (2001). Temporomandibular joint pain
analgesia by linearly polarized near-infrared irradiation. Clinical J.
Pain., 17 (1), 47-51.
[5] L. Medenica, M. Lens, (2003). The use of polarized polychromatic noncoherent
light alone as a therapy for venous leg ulceration. J. Wound
Care, 12 (1), 37-40.
[6] K. Yokoyama, K. Sugiyama (2003). Influence of linearly polarized nearinfrared
irradiation on deformability of human stored erythrocytes. J.
Clin. Laser Med. Surg., 21 (1), 19-22.
[7] J. Verbelen (2007). Use of polarised light as a method of pressure ulcer
prevention in an adult intensive care unit. J. Wound Care., 16 (4), 145-
150.
[8] A.V. Budagovsky (2005). On the ability of cells to distinguish the
coherence of optical radiation. Quantum Electronics, 35 (4), 369-374.
[9] A.N. Rubinov, A.A. Afanas-ev (2005). Nonresonance mechanisms of
biological effects of coherent and incoherent light. Opt. Spectr., 98 (6),
943-948.
[10] T. Karu (1999). Primary and secondary mechanisms of action of visible
to near-IR radiation on cells. J. Photochem. Photobiol. B: Biol., 49 (1),
1-17.
[11] M. Fenyö, J. Mandl, & A. Falus (2002). Opposite effect of linearly
polarized light on biosynthesis of interleukin-6 in a human B lymphoid
cell line and peripheral human monocytes. Cell Biol. Intern., 26 (3),
265-269.
[12] V.A. Mostovnikov et al. (1994). Primary photophysical processes
which define the biological and therapeutic effect of low-intensity laser
radiation. Proc. SPIE, 2370, 541-548.
[13] .Yu. Plavskii et al. (2007). Apparatus for low-level laser therapy:
modern status and development trends. J Opt Technol. 74 (4), 246-257.
[14] J. Kubota, T. Ohshiro (1989). The effects of diode laser low reactivelevel
laser therapy (LLLT) on flap survival in a rat model. Laser
Therapy, 1 (3), 127-134.
[15] I. Onac, L. Pop, & I. Onac (1999). Implications of low-power He-Ne
laser and monochromatic red light biostimulation in protein and
glycoside metabolism. Laser Therapy, 11 (1) 130-137.
[16] T. Qadri et al. 2007The importance of coherence length in laser
phototherapy of gingival inflammation - a pilot study. Lasers Surg.
Med., 22 (4), 245-251.
[17] V.A. Tolkachev (2004). Role of Light Polarization in the Optothermal
Effect. J. Appl. Spectrosc., 71, (1), 139-142.
[18] Yu.A. Vladimirov et al. (2004). Molecular and cellular mechanisms
triggered by low-level laser irradiation. Biophysics (Moscow), 49 (2),
325-336.
[19] V.Yu. Plavskii & N.V. Barulin (2008). Effect of polarization and
coherence of low-intensity optical radiation on fish embryos. J Appl
Spectrosc, Vol. 75, No. 6, pp 843-856.
[20] V.V. Tuchin (1997). Light scattering study of tissues. Physics-Uspekhi,
40 (5), 495-515.
[21] T.I. Karu, L.V. Pyatibrat & T.P. Ryabykh, (1997). Nonmonotonic
behavior of the dose dependence of the radiation effect on cells in vitro
exposed to pulsed laser radiation at λ = 820 nm. Lasers Surg. Med. 21
(5), 485-492.
[22] S.M. Zubkova (1978). Mechanism of biological effect of helium-neon
laser irradiation Nauchnye Dokl. Vyss. Shkoly. Biol. Nauki (Moscow),
No 7, 30-37 (in Russian)
[23] G.A. Zalesskaya et al. (2006). Effect of intravenous laser irradiation
on the molecular structure of blood and blood components. J. Appl.
Spectrosc., 73 (1), 115-122.
[24] V.Yu. Plavskii, & N.V. Barulin (2008). Effect of polarization and
coherence of low-intensity optical radiation on fish embryos. J Appl
Spectrosc, Vol. 75, No. 6, pp 843-856.
[25] V.Yu. Plavskii, & N.V. Barulin (2008). Effect of exposure of sturgeon
roe to low-intensity laser radiation on the hardiness of juvenile sturgeon.
J Appl Spectrosc, 75 (2), 241-250.
[26] V.Yu. Plavskii, & N.V. Barulin (2008). How the biological activity of
low-intensity laser radiation depends on its modulation frequency. J Opt
Technol., 75 (9), 546-552.
@article{"International Journal of Biological, Life and Agricultural Sciences:55708", author = "Nikolai V. Barulin and Vitaly Yu. Plavskii", title = "Effect of Polarization and Coherence of Optical Radiation on Sturgeon Sperm Motility", abstract = "This work contains information about the influence low-level optical irradiation on sperm motility of sturgeon fish. On the basis of given and earlier received data the following conclusion has been made. Among the photophysical processes of a resonant and not resonant nature (oriented action of light; action of gradient forces; dipole-dipole interaction; termooptical processes), which are capable to cause the photobiological effects depended on such laserspecific characteristics as polarization and coherency, determining influence belongs to oriented action of light and dipole-dipole interactions among the processes studied in the present work.
", keywords = "sturgeon, aquaculture, fish sperm, laser, optical
irradiation, sperm motility", volume = "6", number = "7", pages = "465-5", }
