![]() ![]() Maulucci, G., et al.: Particle size distribution in DMPC vesicles solutions undergoing different sonication times. Koenderink, G.H., Sacanna, S., Pathmamanoharan, C., Rasa, M., Philipse, A.P.: Preparation and properties of optically transparent aqueous dispersions of monodisperse fluorinated colloids. Kaszuba, M., McKnight, D., Connah, M.T., McNeil-Watson, F.K., Nobbmann, U.: Measuring subnanometre sizes using dynamic light scattering. Jarzębski, M., et al.: Particle tracking analysis in food and hydrocolloids investigations Food Hydrocolloids 68, 90–101 (2017b) Jarzębski, M., et al.: Submicron sized fluorescent silica particles characterization. Jarzebski, M., et al.: Core–shell fluorinated methacrylate nanoparticles with Rhodamine-B for confocal microscopy and fluorescence correlation spectroscopy applications. Gapinski, J., Jarzębski, M., Buitenhuis, J., Deptula, T., Mazuryk, J., Patkowski, A.: Structure and dimensions of core-shell nanoparticles comparable to the confocal volume studied by means of fluorescence correlation spectroscopy. Part A 25(3), 241–258 (2008)ĭahneke, B.E.: Measurement of Suspended Particles by Quasi-elastic Light Scattering. Controlled Release 235, 337–351 (2016)Ĭhaudhry, Q., Scotter, M., Blackburn, J., Ross, B., Boxall, A., Castle, L.: Applications and implications of nanotechnologies for the food sector. Dover Publications, Mineola (1976)īhattacharjee, S.: DLS and zeta potential – what they are and what they are not? J. Langmuir 28, 10860–10872 (2012)īerne, B.J., Pecora, R.: Dynamic Light Scattering: With Applications to Chemistry, Biology, and Physics. 41, 770–777 (2006)īell, N.C., Minelli, C., Tompkins, J., Stevens, M.M., Shard, A.G.: Emerging techniques for submicrometer particle sizing applied to Stöber silica. 8, 950 (2018)īai, Y.X., Li, Y.F., Yang, Y., Yi, L.X.: Covalent immobilization of triacylglycerol lipase onto functionalized nanoscale SiO 2 spheres. 67(1–2), 3–11 (2005)Īrenas-Guerrero, P., et al.: Determination of the size distribution of non-spherical nanoparticles by electric birefringence-based methods. Moreover, particle size verification is recommended during long-term storage and when environmental conditions change.Īguilera, J.M.: Why food microstructure? J. Our studies confirmed the hypothesis that more than one particle size determination technique is recommended. Presented results will open discussion about factors other than dilution and concentrations for observing behavior of the nanoparticles and submicron particles in “real conditions”. ![]() The results show that sample behaviours might not only vary with temperature and dispersant changes, but may also fluctuate during the time of measurement (i.e. Furthermore, the studies were performed at both room temperature (20 ☌) and elevated temperature (37 ☌) to simulate various possible applications of nanosystem investigations in the biomedical field. We compared the obtained results in “standard conditions” with non-standard situations, such as using tap water or employing Ringer solution as a dispersant. In this paper, we present the results of monodispersed polystyrene standardized nanobeads, silver and polydispersed submicron-sized fluorinated particles (HFBMA) and silica synthesized by a modified Stöber method. food, emulsions) and nanoparticles dispersion characterization is limited due to particle shape and possible interactions between the sample and the measuring solution. The advantages of DLS for fast and simple colloid systems (i.e. Dynamic light scattering (DLS) is one of the most commonly used for rapid particle size determination. ![]()
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