COMPUTER-ASSISTED SPIM-LIKE METHODS (SPIM, MSPIM, MUVISPIM & PIV/ LDV/ LDA/ LDF BASED ON SPIM-LIKE SETUPS) AS NOVEL TOOLS FOR DYNAMIC ANALYSIS OF SUPERCRITICAL FLUID FLUXES AND ORIENTED COMPLEX FLUIDS WITH SOFT MATTER STRUCTURES
( Pp. 17-24)
More about authors
Gradov Oleg Valeryevich
research fellow, Photobionics Laboratory (0412), Department of Dynamics of Biological and Chemical Processes; senior researcher / senior research fellow, Laboratory of Biological Effects of Nanostructures (005)
N.N. Semenov Institute of Chemical Physics, Russian Academy of Sciences; V.L. Talrose Institute for Energy Problems of Chemical Physics (Russian Academy of Sciences) Orehov Theodor Konstantinovich otdel dinamiki himicheskih i biologicheskih processov
N.N. Semenov Institute of Chemical Physics (Russian Academy of Sciences)
N.N. Semenov Institute of Chemical Physics, Russian Academy of Sciences; V.L. Talrose Institute for Energy Problems of Chemical Physics (Russian Academy of Sciences) Orehov Theodor Konstantinovich otdel dinamiki himicheskih i biologicheskih processov
N.N. Semenov Institute of Chemical Physics (Russian Academy of Sciences)
Abstract:
We propose a novel procedure for the supercritical fluid behavior visualization and measurements based on SPIM or similar microscopic techniques in the rotational micro-capillary tubes. We propose to replace a time-lapse registration by a superfast registration (using high-speed cameras) for in situ fixation of supercritical fluid dynamics and for slow-motion representations of physical states and transitions, distinguishable using mathematical morphology tools. An elegant version of this method for our purposes includes also a cross-correlation spectroscopy for supercritical fluid behavior analysis Also we propose to use SPIM-like (Selective Plane Illumination Microscopy) setups with 2-objective, 3-objective or 4-objective registration schemes for this purpose in order to perform PIV (Particle Image Velocimetry), LDV (Laser Doppler Velocimetry) / LDA (Laser Doppler Anemometry) / LDF (Laser Doppler Flowmetry) and similar measurements using the above configuration.
How to Cite:
Gradov O.V., Orehov T.K., (2018), COMPUTER-ASSISTED SPIM-LIKE METHODS (SPIM, MSPIM, MUVISPIM & PIV/ LDV/ LDA/ LDF BASED ON SPIM-LIKE SETUPS) AS NOVEL TOOLS FOR DYNAMIC ANALYSIS OF SUPERCRITICAL FLUID FLUXES AND ORIENTED COMPLEX FLUIDS WITH SOFT MATTER STRUCTURES. Computational Nanotechnology, 4 => 17-24.
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Kazarian S.G., Chan K.L. Confocal Raman microscopy of supercritical fluid dyeing of polymers // Analyst. 2003. Vol. 128, No. 5. Rp. 499-503.
Wang Y., Yang C., Tomasko D. Confocal Microscopy Analysis of Supercritical Fluid Impregnation of Polypropylene // Ind. Eng. Chem. Res. 2002. Vol. 41. Rp. 1780-1786.
Arey B.W. et al. Identification of fragile microscopic structures during mineral transformations in wet supercritical CO2// Micros. Microanal. 2013. Vol. 19. Rp. 268-275.
Cella Zanacchi F. et al. Live-cell 3D super-resolution imaging in thick biological samples // Nat. Meth. 2011. Vol. 8, No. 12. Rp. 1047-1049.
Krieger J.W. et al. Dual-color fluorescence crosscorrelation spectroscopy on a single plane illumination microscope (SPIM-FCCS) // Opt. Expr. 2014. Vol. 22. Rp. 2358-2375.
Thompson W.R., Geery E.L. Heat Transfer to Cryogenic Hydrogen at Supercritical Pressures // Adv. Cryogen. Engin. 1962. Vol. 7. Rp. 391-400.
Chen I.M., Anderson R.E. A Thermal Stratification Model of a Cryogenic Tank at Supercritical Pressures // Adv. Cryogen. Engin. 1972. Vol. 17. Rp. 475-486.
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Kim T., Kim Y., Kim S.-K. Numerical study of cryogenic liquid nitrogen jets at supercritical pressures // Journ. Supercrit. Fluids. 2011. Vol. 56, No. 2. Rp. 152-163.
Terashima H., Koshi M. Strategy for simulating supercritical cryogenic jets using high-order schemes // Computers Fluids. 2013. Vol. 85. Rp. 39-46.
Hendricks R.C., Boldman D.R., Neumann H.E., Vlcek B.L. Qualitative Investigation of Cryogenic Fluid Injection Into a Supersonic Flow Field // Adv. Cryogen. Engin. 1990. Vol. 35. Rp. 469-476.
Rogers T.L., Johnston K.P., Williams R.O. Solution-based particle formation of pharmaceutical powders by supercritical or compressed fluid CO 2 and cryogenic spray-freezing technologies // Drug Dev. Ind. Pharm. 2001. Vol. 27, No. 10. Rp. 1003-1015.
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Gradov O.V. Experimental Setups for Ozonometric Microscopy // Biomedical Engineering. 2013. Vol. 46, Is. 6. Rp. 260-264.
Oganessian V.A., Notchenko A.V., Gradov O.V. Multispectral topological laser speckle analyzers of proliferation and differentiation activity during morphogenesis based on tunable laser diodes and spectrometric fingerprinting of the cell cycle stages // Journal of Physical Chemistry Biophysics. 2015. Vol. 5. No. 3. R. 75.
Gradov O.V., Notchenko A.V., Oganessian V.A. The neurogoniometry: Applied optical analysis for neural structure directogramm/ radiation pattern measurements // Optics. 2016. Vol. 4. No. 6. Rp. 37-42.
Notchenko A.V., Oganessian V.A., Gradov O.V. A novel tunable laser diode microrefractometric and goniometric spectrotomography based on multiaxis robotized feodorov stage and the multi-wavelength spectrorefrctometric technology of the data analysis // II Int. Conf. PhysTech-Med 2015: Physics of Living Systems. MIPT. 2015. Rp. 10-11.
Gradov O.V., Skrynnik A.A., Notchenko A.V., Oganessian V.A. Label-free angle-selective molecular imaging and spectrorefractometric microtomography-on-a-chip using goniometric stages and tunable laser systems with acousto-optic filters // ADFLIM (12-14.12.2016). The Federal Research Centre Fundamentals of Biotechnology of the Russian Academy of Sciences (Research Center of Biotechnology RAS) Moscow, 2016. R. 4.
Borra C., Andreolini F., Novotny M. Use of capillary supercritical fluid chromatography and microcolumn liquid chromatography for the determination of nonvolatile organics in aqueous environmental samples // Anal. Chem. 1989. Vol. 61. No. 11. Rp. 1208-1210.
Kazarian S.G., Chan K.L. Confocal Raman microscopy of supercritical fluid dyeing of polymers // Analyst. 2003. Vol. 128, No. 5. Rp. 499-503.
Wang Y., Yang C., Tomasko D. Confocal Microscopy Analysis of Supercritical Fluid Impregnation of Polypropylene // Ind. Eng. Chem. Res. 2002. Vol. 41. Rp. 1780-1786.
Arey B.W. et al. Identification of fragile microscopic structures during mineral transformations in wet supercritical CO2// Micros. Microanal. 2013. Vol. 19. Rp. 268-275.
Cella Zanacchi F. et al. Live-cell 3D super-resolution imaging in thick biological samples // Nat. Meth. 2011. Vol. 8, No. 12. Rp. 1047-1049.
Krieger J.W. et al. Dual-color fluorescence crosscorrelation spectroscopy on a single plane illumination microscope (SPIM-FCCS) // Opt. Expr. 2014. Vol. 22. Rp. 2358-2375.
Thompson W.R., Geery E.L. Heat Transfer to Cryogenic Hydrogen at Supercritical Pressures // Adv. Cryogen. Engin. 1962. Vol. 7. Rp. 391-400.
Chen I.M., Anderson R.E. A Thermal Stratification Model of a Cryogenic Tank at Supercritical Pressures // Adv. Cryogen. Engin. 1972. Vol. 17. Rp. 475-486.
Ashraf-Khorassani M., Houck R.K., Levy J.M. Cryogenically Cooled Adsorbent Trap for Off-Line Supercritical Fluid Extraction // Journ. Chromatogr. Sci. 1992. Vol. 30, No. 9. Rp. 361-366.
Branam R., Mayer W. Length scales in cryogenic injection at supercritical pressure // Experiments in Fluids. 2002. Vol. 33, No. 3. Rp. 422-428.
Branam R., Mayer W. Characterization of Cryogenic Injection at Supercritical Pressure // Journal of Propulsion and Power. 2003. Vol. 19, No. 3. Rp. 342-355.
Kim T., Kim Y., Kim S.-K. Numerical study of cryogenic liquid nitrogen jets at supercritical pressures // Journ. Supercrit. Fluids. 2011. Vol. 56, No. 2. Rp. 152-163.
Terashima H., Koshi M. Strategy for simulating supercritical cryogenic jets using high-order schemes // Computers Fluids. 2013. Vol. 85. Rp. 39-46.
Hendricks R.C., Boldman D.R., Neumann H.E., Vlcek B.L. Qualitative Investigation of Cryogenic Fluid Injection Into a Supersonic Flow Field // Adv. Cryogen. Engin. 1990. Vol. 35. Rp. 469-476.
Rogers T.L., Johnston K.P., Williams R.O. Solution-based particle formation of pharmaceutical powders by supercritical or compressed fluid CO 2 and cryogenic spray-freezing technologies // Drug Dev. Ind. Pharm. 2001. Vol. 27, No. 10. Rp. 1003-1015.
Lemenovskij D.A. et al. // Priroda Nature . 2006. № 6. in Russian, electronic resource .
Gradov O.V. Experimental Setups for Ozonometric Microscopy // Biomedical Engineering. 2013. Vol. 46, Is. 6. Rp. 260-264.
Oganessian V.A., Notchenko A.V., Gradov O.V. Multispectral topological laser speckle analyzers of proliferation and differentiation activity during morphogenesis based on tunable laser diodes and spectrometric fingerprinting of the cell cycle stages // Journal of Physical Chemistry Biophysics. 2015. Vol. 5. No. 3. R. 75.
Gradov O.V., Notchenko A.V., Oganessian V.A. The neurogoniometry: Applied optical analysis for neural structure directogramm/ radiation pattern measurements // Optics. 2016. Vol. 4. No. 6. Rp. 37-42.
Notchenko A.V., Oganessian V.A., Gradov O.V. A novel tunable laser diode microrefractometric and goniometric spectrotomography based on multiaxis robotized feodorov stage and the multi-wavelength spectrorefrctometric technology of the data analysis // II Int. Conf. PhysTech-Med 2015: Physics of Living Systems. MIPT. 2015. Rp. 10-11.
Gradov O.V., Skrynnik A.A., Notchenko A.V., Oganessian V.A. Label-free angle-selective molecular imaging and spectrorefractometric microtomography-on-a-chip using goniometric stages and tunable laser systems with acousto-optic filters // ADFLIM (12-14.12.2016). The Federal Research Centre Fundamentals of Biotechnology of the Russian Academy of Sciences (Research Center of Biotechnology RAS) Moscow, 2016. R. 4.
Keywords:
SPIM (Selective Plane Illumination Microscopy), MSPIM, Supercritical Fluid Laser Optics, PIV (Particle Image Veloci- metry), LDV (Laser Doppler Velocimetry), LDA (Laser Doppler Anemometry) / LDF (Laser Doppler Flowmetry).
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