Diatom Microscopy. Группа авторов

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Название Diatom Microscopy
Автор произведения Группа авторов
Жанр Медицина
Серия
Издательство Медицина
Год выпуска 0
isbn 9781119711551



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A concept for breaking the diffraction resolution limit. Appl Phys B 60(5), 495–497.

      [1.26] Hell, S.W. and Wichmann, J. (1994) Breaking the diffraction resolution limit by stimulated emission: stimulated-emission-depletion fluorescence microscopy. Opt Lett 19(11), 780–782.

      [1.27] Horton, N.G., Wang, K., Kobat, D., Clark, C.G., Wise, F.W., Schaffer, C.B. and Xu, C. (2013) In vivo three-photon microscopy of subcortical structures within an intact mouse brain. Nat photonics 7(3), 205–209.

      [1.28] Huang, B., Babcock, H. and Zhuang, X. (2010) Breaking the diffraction barrier: super-resolution imaging of cells. Cell 143(7), 1047–1058.

      [1.29] Köhler, J. (1997) Use of algae for monitoring rivers II. - Innsbruck. Int Revue ges Hydrobiol 82(3), 340.

      [1.30] Kieu, K., Mehravar, S., Gowda, R., Norwood, R.A. and Peyghambarian, N. (2013) Label-free multi-photon imaging using a compact femtosecond fiber laser mode-locked by carbon nanotube saturable absorber. Biomed Opt Express 4(10), 2187–2195.

      [1.31] Korte, V.L. and Blinn, D.W. (1983) Diatom Colonization on Artificial Substrata in Pool and Riffle Zones Studied by Light and Scanning Electron Microscopy. J Phycol 19(3), 332–341.

      [1.32] Kotzsch, A., Gröger, P., Pawolski, D., Bomans, P.H.H., Sommerdijk, N.A.J.M., Schlierf, M. and Kröger, N. (2017) Silicanin-1 is a conserved diatom membrane protein involved in silica biomineralization. BMC Biol 15(1), 65–65.

      [1.33] Kröger, N. and Poulsen, N. (2008) Diatoms-from cell wall biogenesis to nanotechnology. Annu Rev Genet 42, 83–107.

      [1.34] Kremers, G.-J., Gilbert, S.G., Cranfill, P.J., Davidson, M.W. and Piston, D.W. (2011) Fluorescent proteins at a glance. J Cell Sci 124, 157–160.

      [1.35] Leblanc, K. and Hutchins, D.A. (2005) New applications of a biogenic silica deposition fluorophore in the study of oceanic diatoms. Limnology and Oceanography: Methods 3(10), 462–476.

      [1.36] Lin, H.-Y., Yen, S.-C., Kuo, P.-C., Chung, C.-Y., Yeh, K.-L., Huang, C.-H., Chang, J. and Lin, H.-J. (2017) Alkaline phosphatase promoter as an efficient driving element for exogenic recombinant in the marine diatom Phaeodactylum tricornutum. Algal Res 23, 58–65.

      [1.37] Marter, P., Schmidt, S., Kiontke, S. and Moog, D. (2020) Optimized mRuby3 is a Suitable Fluorescent Protein for in vivo Co-localization Studies with GFP in the Diatom Phaeodactylum tricornutum. Protist 171(1), 125715.

      [1.38] Mazumder, N., Balla, N.K., Zhuo, G.-Y., Kistenev, Y.V., Kumar, R., Kao, F.-J., Brasselet, S., Nikolaev, V.V. and Krivova, N.A. (2019) Label-Free Non-linear Multimodal Optical Microscopy—Basics, Development, and Applications. Frontiers in Physics 7, 170.

      [1.39] McNair, H.M., Brzezinski, M.A. and Krause, J.W. (2015) Quantifying diatom silicification with the fluorescent dye, PDMPO. Limnology and Oceanography: Methods 13(10), 587–599.

      [1.40] Minsky, M. (1988) Memoir on inventing the confocal scanning microscope. Scanning 10(4), 128–138.

      [1.41] Moerner, W.E. (2006) Single-molecule mountains yield nanoscale cell images. Nat Methods 3(10), 781–782.

      [1.42] Montazer, Z., Habibi Najafi, M.B. and Levin, D.B. (2019) Microbial degradation of low-density polyethylene and synthesis of polyhydroxyalkanoate polymers. Can J Microbiol 65(3), 224–234.

      [1.43] Nieuwenhuizen, R.P.J., Lidke, K.A., Bates, M., Puig, D.L., Grünwald, D., Stallinga, S. and Rieger, B. (2013) Measuring image resolution in optical nanoscopy. Nat Methods 10(6), 557–562.

      [1.44] Noga, T., Stanek-Tarkowska, J., Kochman, N., Peszek, Ł., Pajączek, A. and Woźniak, K. (2013) Application of diatoms to assess the quality of the waters of the baryczka stream, left-side tributary of the river san. J Ecol Eng 14(3), 8–23.

      [1.45] Onesto, V., Villani, M., Coluccio, M.L., Majewska, R., Alabastri, A., Battista, E., Schirato, A., Calestani, D., Coppedé, N., Cesarelli, M., Amato, F., Di Fabrizio, E. and Gentile, F. (2018) Silica diatom shells tailored with Au nanoparticles enable sensitive analysis of molecules for biological, safety and environment applications. Nanoscale Res Lett 13(1), 94.

      [1.46] Patrascu, E., Melinte, P. and Dragoi, G. (2014) Optimized morphologic evaluation of biostructures by examination in polarized light and differential interference contrast microscopy. Romanian J Leg Med 22, 275–282.

      [1.47] Patterson, G.H. (2009) Fluorescence microscopy below the diffraction limit. Semin Cell Dev Biol 20(8), 886–893.

      [1.48] Pawley, J. (2006) Handbook of Biological Confocal Microscopy. Springer US.

      [1.49] Pletikapić, G., Žutić, V., Vinković Vrček, I. and Svetličić, V. (2012) Atomic force microscopy characterization of silver nanoparticles interactions with marine diatom cells and extracellular polymeric substance. J Mol Recognit 25(5), 309–317.

      [1.50] Poulsen, N., Scheffel, A., Sheppard, V.C., Chesley, P.M. and Kröger, N. (2013) Pentalysine clusters mediate silica targeting of silaffins in Thalassiosira pseudonana. J Biol Chem 288(28), 20100–20109.

      [1.51] Prasad, P.N. (2004) Introduction to Biophotonics. Wiley.

      [1.52] Qin, T., Gutu, T., Jiao, J., Chang, C.H. and Rorrer, G.L. (2008) Photoluminescence of silica nanostructures from bioreactor culture of marine diatom Nitzschia frustulum. J Nanosci Nanotechnol 8(5), 2392–2398.

      [1.53] Rakowska, B. and Szczepocka, E. (2011) Demonstration of the Bzura River restoration using diatom indices. Biologia 66, 411–417.

      [1.54] Rea, I., Martucci, N.M., De Stefano, L., Ruggiero, I., Terracciano, M., Dardano, P., Migliaccio, N., Arcari, P., Taté, R., Rendina, I. and Lamberti, A. (2014) Diatomite biosilica nanocarriers for siRNA transport inside cancer cells. Biochim Biophys Acta 1840(12), 3393–3403.

      [1.55] Romann, J., Valmalette, J.-C., Chauton, M.S., Tranell, G., Einarsrud, M.-A. and Vadstein, O. (2015) Wavelength and orientation dependent capture of light by diatom frustule nanostructures. Sci Rep 5(1), 17403.

      [1.56] Rosenholm, J.M., Meinander, A., Peuhu, E., Niemi, R., Eriksson, J.E., Sahlgren, C. and Lindén, M. (2009) Targeting of Porous Hybrid Silica Nanoparticles to Cancer Cells. ACS Nano 3(1), 197–206.

      [1.57] Ruggiero, I., Terracciano, M., Martucci, N.M., De Stefano, L., Migliaccio, N., Tatè, R., Rendina, I., Arcari, P., Lamberti, A. and Rea, I. (2014) Diatomite silica nanoparticles for drug delivery. Nanoscale Res Lett 9(1), 329.

      [1.58] Rust, M.J., Bates, M. and Zhuang, X. (2006) Sub-diffraction-limit imaging by stochastic optical reconstruction microscopy (STORM). Nat Methods 3(10), 793–796.

      [1.59] Salmon, E.D. and Tran, P. (1998) Chapter 9 High-Resolution Video-Enhanced Differential Interference Contrast (VE-DIC) Light Microscopy. In: Methods in Cell Biology. G. Sluder and D.E. Wolf, (eds.) Academic Press. 56: 153–184.

      [1.60] Salta, M., Dennington, S.P. and Wharton, J.A. (2018) Biofilm Inhibition by Novel Natural Product- and Biocide-Containing Coatings Using High-Throughput Screening. Int J Mol Sci 19(5), 1434.

      [1.61] Sansone, C., Braca, A., Ercolesi, E., Romano, G., Palumbo, A., Casotti, R., Francone, M. and Ianora, A. (2014) Diatom-derived polyunsaturated aldehydes activate cell death in human cancer cell lines but not normal cells. PLoS One 9(7), e101220.

      [1.62] Schlundt, C., Mark Welch, J.L., Knochel, A.M., Zettler, E.R. and Amaral-Zettler, L.A. (2020) Spatial structure in the “Plastisphere”: Molecular resources for imaging microscopic communities on plastic marine debris. Mol Ecol Resour 20(3), 620–634.

      [1.63]