Asymmetric flow field-flow fractionation of superferrimagnetic iron oxide multicore nanoparticles

Chain Formation and Phase Separation in Ferrofluids: The Influence on Viscous Properties

Ferrofluids have attracted considerable interest from researchers and engineers due to their rich set of unique physical properties that are valuable for many industrial and biomedical applications. Many phenomena and features of ferrofluids' behavior are determined by internal structural transformations in the ensembles of particles, which occur due to the magnetic interaction between the particles. An applied magnetic field induces formations, such as linear chains and bulk columns, that become elongated along the field. In turn, these structures dramatically change the rheological and other physical properties of these fluids. A deep and clear understanding of the main features and laws of the transformations is necessary for the understanding and explanation of the macroscopic properties and behavior of ferrofluids. In this paper, we present an overview of experimental and theoretical works on the internal transformations in these systems, as well as on the effect of the internal structures on the rheological effects in the fluids.

Heat Treatment of Poloxamer-Stabilized Triglyceride Nanodispersions: Effects and Underlying Mechanism

Lipid nanoemulsions are being investigated for the parenteral administration of poorly soluble drugs. A narrow particle size distribution in these formulations is a prerequisite for meaningful research and safe administration to patients. Autoclaving a poloxamer-stabilized trimyristin nanoemulsion resulted in moderate particle growth and a strong decrease in particle size distribution width ( Göke , K. ; Roese , E. ; Arnold , A. ; Kuntsche , J. ; Bunjes , H. Mol. Pharmaceutics 2016 , 13 , 3187 . ). In this work, the critical parameters for such a change upon autoclaving poloxamer 188-stabilized lipid nanodispersions were investigated to elucidate the underlying mechanism. Nanodispersions of triglycerides with esterified fatty acid chain lengths from C8 to C18 were treated at different temperatures and for varying durations. The influence of a decrease in poloxamer 188's cloud point was tested by adding potassium chloride to the dispersions prior to autoclaving. The influence of poloxamer 188 concentration and of the type of emulsifier was investigated. The change in particle size and particle size distribution width upon heat treatment was analyzed by dynamic or static light scattering or differential scanning calorimetry. A short esterified fatty acid chain length of the triglycerides, high temperatures, and the addition of potassium chloride were key factors for particle growth up to emulsion break up, whereas the cloud point of poloxamer 188 was irrelevant. Sodium dodecyl sulfate and sucrose laurate had negative effects on emulsion stability during autoclaving. It was concluded that the increase in particle size and the decrease in particle size distribution widths upon heat treatment resulted from heat-accelerated Ostwald ripening and not from a coalescence-based process.

Fractionation of Magnetic Microspheres in a Microfluidic Spiral: Interplay between Magnetic and Hydrodynamic Forces

Magnetic forces and curvature-induced hydrodynamic drag have both been studied and employed in continuous microfluidic particle separation and enrichment schemes. Here we combine the two. We investigate consequences of applying an outwardly directed magnetic force to a dilute suspension of magnetic microspheres circulating in a spiral microfluidic channel. This force is realized with an array of permanent magnets arranged to produce a magnetic field with octupolar symmetry about the spiral axis. At low flow rates particles cluster around an apparent streamline of the flow near the outer wall of the turn. At high flow rates this equilibrium is disrupted by the induced secondary (Dean) flow and a new equilibrium is established near the inner wall of the turn. A model incorporating key forces involved in establishing these equilibria is described, and is used to extract quantitative information about the magnitude of local Dean drag forces from experimental data. Steady-state fractionation of suspensions by particle size under the combined influence of magnetic and hydrodynamic forces is demonstrated. Extensions of this work could lead to new continuous microscale particle sorting and enrichment processes with improved fidelity and specificity.

Magnetic nanoparticles adapted for specific biomedical applications

Magnetic nanoparticles (MNPs) are used in different biomedical applications, whereby each application requires specific particle properties. To fulfill these requirements, particle properties have to be optimized by means of variation of crystal structure, particle size, and size distribution. To this aim, improved aqueous precipitation procedures for magnetic iron oxide nanoparticle synthesis were developed. One procedure focused on the cyclic growth of MNPs without nucleation of new particle cores during precipitation. The second novel particle type are magnetic multicore nanoparticles, which consist of single cores of approximately 10 nm forming dense clusters in the size range from 40 to 80 nm. Their highest potential features these multicore particles in hyperthermia application. In our in vivo experiments, therapeutically suitable temperatures were reached after 20 s of heating for a particle concentration in the tumor of 1% and field parameters of H=24 kA/m and f=410 kHz. This review on our recent investigations for particle optimization demonstrates that tuning magnetic properties of MNPs can be obtained by the alteration of their structure, size, and size distribution. This can be realized by means of control of particle size during synthesis or subsequent size-dependent fractionation. The here-developed particles show high potential for biomedical applications.

Magnetic particle hyperthermia--a promising tumour therapy?

We present a critical review of the state of the art of magnetic particle hyperthermia (MPH) as a minimal invasive tumour therapy. Magnetic principles of heating mechanisms are discussed with respect to the optimum choice of nanoparticle properties. In particular, the relation between superparamagnetic and ferrimagnetic single domain nanoparticles is clarified in order to choose the appropriate particle size distribution and the role of particle mobility for the relaxation path is discussed. Knowledge of the effect of particle properties for achieving high specific heating power provides necessary guidelines for development of nanoparticles tailored for tumour therapy. Nanoscale heat transfer processes are discussed with respect to the achievable temperature increase in cancer cells. The need to realize a well-controlled temperature distribution in tumour tissue represents the most serious problem of MPH, at present. Visionary concepts of particle administration, in particular by means of antibody targeting, are far from clinical practice, yet. On the basis of current knowledge of treating cancer by thermal damaging, this article elucidates possibilities, prospects, and challenges for establishment of MPH as a standard medical procedure.