The evolution of bicontinuous polymeric nanospheres in aqueous solution.

Complex polymeric nanospheres in aqueous solution are desirable for their promising potential in encapsulation and templating applications. Understanding how they evolve in solution enables better control of the final structures. By unifying insights from cryoTEM and small angle X-ray scattering (SAXS), we present a mechanism for the development of bicontinuous polymeric nanospheres (BPNs) in aqueous solution from a semi-crystalline comb-like block copolymer that possesses temperature-responsive functionality. During the initial stages of water addition to THF solutions of the copolymer the aggregates are predominantly vesicles; but above a water content of 53% irregular aggregates of phase separated material appear, often microns in diameter and of indeterminate shape. We also observe a cononsolvency regime for the copolymer in THF-water mixtures from 22 to 36%. The structured large aggregates gradually decrease in size throughout dialysis, and the BPNs only appear upon cooling the fully aqueous dispersions from 35 °C to 5 °C. Thus, the final BPNs are ultimately the result of a reversible temperature-induced morphological transition.

Controlled heterocoagulation of platelets and spheres.

We report the controlled heterocoagulation of platelets and spheres, leading to the formation of colloidally stable, anisotropic hybrid particles. Anionically charged, nanosized polymer latex spherical particles were heterocoagulated on the surface of cationically charged hexagonal gibbsite platelets via the adsorption of a single layer of spheres onto both sides of the hexagonal platelets. The latex particles were annealed at a temperature above the Tg of the latex polymer, resulting in a thin polymer layer covering the gibbsite platelets. This heterocoagulation approach enabled the encapsulation of hydrophilic inorganic particles with polymer latexes and the formation of anisotropic hybrid particles.

The observation of intact hepatic endothelial cells by cryo-electron microscopy.

Liver sinusoidal endothelial cells (LSECs) can optimally be imaged by whole mount transmission electron microscopy (TEM). However, TEM allows only investigation of vacuum-resistant specimens and this usually implies the study of chemically fixed and dried specimens. Cryo-electron microscopy (cryo-EM) can be used as a good alternative for imaging samples as whole mounts. Cryo-EM offers the opportunity to study intact, living cells while avoiding fixation, dehydration and drying, at the same time preserving all solubles and water as vitrified ice. Therefore, we compared the different results obtained when LSECs were vitrified using different vitrification conditions. We collected evidence that manual blotting at ambient conditions and vitrification by the guided drop method results in the production of artefacts in LSECs, such as the loss of fenestrae, formation of gaps and lack of structural details in the cytoplasm. We attribute these artefacts to temperature and osmotic effects during sample preparation just prior to vitrification. By contrast, by using an environmentally controlled glove box and a vitrification robot (37 degrees C and 100% relative humidity), these specific structural artefacts were nearly absent, illustrating the importance of controlled sample preparation. Moreover, data on glutaraldehyde-fixed cells and obtained by using different vitrification methods suggested that chemical prefixation is not essential when vitrification is performed under controlled conditions. Conditioned vitrification therefore equals chemical fixation in preserving and imaging cellular fine structure. Unfixed, vitrified LSECs show fenestrae and fenestrae-associated cytoskeleton rings, indicating that these structures are not artefacts resulting from chemical fixation.

Direct observation of dipolar chains in iron ferrofluids by cryogenic electron microscopy.

A key issue in research on ferrofluids (dispersions of magnetic colloids) is the effect of dipolar interactions on their structure and phase behaviour, which is not only important for practical applications but gives fundamental insight in dipolar fluids in general. In 1970, de Gennes and Pincus predicted a Van der Waals-like phase diagram and the presence of linear chains of particles in ferrofluids in zero magnetic field. Despite many experimental studies, no direct evidence of the existence of linear chains of dipoles has been reported in the absence of magnetic field, although simulations clearly show the presence of chain-like structures. Here, we show in situ linear dipolar structures in ferrofluids in zero field, visualized on the particle level by electron cryo-microscopy on thin, vitrified films of organic dispersions of monodisperse metallic iron particles. On systematically increasing the particle size, we find an abrupt transition from separate particles to randomly oriented linear aggregates and branched chains or networks. When vitrified in a permanent magnetic field, these chains align and form thick elongated structures, indicating lateral attraction between parallel dipole chains. These findings show that the experimental model used is well suited to study the structural properties of dipolar particle systems.