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.

Association of man-made mineral fibre exposure and sarcoidlike granulomas.

It is assumed that sarcoidosis is caused by inhalation of air borne agents in susceptible persons triggering the inflammatory reaction. The association of metallic dust exposure, such as beryllium and aluminium, and sarcoidlike pulmonary disorders is well known. The ability of man-made mineral fibres (MMMF) to cause granulomatous lung disease has not been appreciated until now. Recently, we observed the association of sarcoidlike granulomatous reaction and occupational history of glass fibre exposure. We hypothesized that there might be a relationship between MMMF exposure and the development of sarcoidlike granulomas. Therefore, the records of 50 sarcoidosis patients-who visited our outpatient clinic between 1996 and 1999 were reviewed. This revealed that 14 cases recalled a history of exposure to either glass fibres or rock wool, both MMMF fibres. The available obtained tissue specimens (n = 12) were reviewed. In six cases electron microscopy qualitative analysis of small fragments of the tissue revealed among others silica, aluminium and sometimes titanium. A distinct relation between fibre deposits fibre deposits and granulomas was found. These findings indicate that in susceptible people MMMF exposure might be related to a chronic granulomatous disease similar to chronic beryllium disease.

Pixe microanalysis of trace elements of normoxic, ischemic and reperfused rat hearts.

With a 3 x 3 mu m(2) proton microbeam spatial distributions of Na, Mg, P, S, K, Ca and Fe were measured via PIXE in 50 x 50 mu m(2) areas of rat heart, sliced into 10-15 mu m thick cryosections. The isolated rat hearts were subjected to normal perfusion, ischemia and reperfusion. Substantial changes in the elemental distribution were found in tissue after 40 min. of reperfusion, particularly indicated by locally elevated Ca and decreased K levels. Electron microscopic examination was used for assessment of artefacts due to sample preparation and handling. Results of stained cryosections analyzed via STIM demonstrated that this latter technique can be employed prior to PIXE analysis to localize individual cells in freeze-dried cryosections.

The procoagulant response of cytomegalovirus infected endothelial cells.

The report describes the effect of an in vitro infection of human umbilical vein endothelial cells with human Cytomegalovirus (CMV). The parameters studied are cellular procoagulant activity, secretion of plasminogen activator inhibitor (PAI-1) and urokinase-type plasminogen activator (u-PA), activation and internalization of factor X and Merocyanine 540 staining. The infection does not result in an increase in PAI-1 and u-PA secretion, but it brings about a procoagulant response, which is relatively rapid compared to the tissue factor mediated response induced by inflammatory mediators. The time course and the coagulation factor dependency suggest a facilitated interaction of coagulation factors on the surface of infected cells. Chromogenic activity measurements after the addition of purified factor X and electron microscopic examination of the cells after addition of colloidal gold-factor X conjugates both point to an internalization of factor X and/or Xa after interaction with the endothelial cell surface. Merocyanine 540 staining suggests that CMV infection leads to membrane perturbations.

Perspective and limitations of cryo-electron microscopy. From model systems to biological specimens.

We investigated the possibility of vitrifying temperature-sensitive lipid phases as well as (small) biological specimens. From a suspension of unilamellar vesicles, prepared from dipalmitoyl-phosphatidylcholine (DPPC), thin aqueous films were formed at various temperatures. With cryo-electron microscopy vesicles were found to be smooth, rippled and faceted or faceted only, depending on the temperature of thin-film formation (318, 312 and 296 K respectively). The morphology and the electron diffraction patterns indicate that membranes can by physically fixed by vitrification in their high-temperature configuration and studied at low temperature by cryo-electron microscopy. This finding suggests that it may also be possible to preserve, in their original state, the more complex membrane systems found in living organisms by initiating rapid-cooling at a physiological temperature. This was explored by vitrification of thin films formed on specimen grids with (human) blood platelets adhering to collagen fibres. Low-temperature observation with an acceleration voltage of 120 kV revealed subcellular details, More details were observed when using higher accelerating voltages (200 and 300 kV) of the electron beam. The results presented in this paper illustrate the great potential of cryo-electron microscopy in the study of membrane dynamics, both in relatively simple model membrane systems and in more complex biological membrane systems.

The ultrastructure of cryo-sections and intact vitrified cells--the effects of cryoprotectants and acceleration voltage on beam induced bubbling.

Chemically fixed pancreas was infiltrated with various cryoprotectants to obtain homogeneously vitrified samples upon cooling. The suitability of these samples for cryoultramicrotomy was tested. Contrast was hardly detectable initially in thin cryo-sections but increased upon irradiation, irrespective of the cryoprotectant (glycerol, propylene glycol, methanol) used. Contrast and beam damage were analyzed in vitrified thin films from collagen, phospholipid vesicles and various concentrations of glycerol. Glycerol increased the beam sensitivity of both collagen and phospholipid vesicles, but diminished the contrast between matrix and lipid vesicles or collagen fibers. The effects of glycerol as observed in thin films explain some of the effects of cryoprotectants in thin cryo-sections. To reduce beam damage in vitrified specimens two approaches are proposed. Firstly, when vitrified films are prepared, dilute suspensions should be used without cryoprotectant. In some cases, such as (thin) intact cells, the composition of the suspended material can only be marginally influenced. Then a second approach can be used involving the application of higher accelerating voltages (e.g. 300 kV). This has two advantages; the increase in mean free path-length of the electrons causes less beam damage on one hand and allows better resolution of thick specimens on the other hand. Micrographs from E. coli bacteria vitrified from suspension illustrate some of the potentials of "intermediate voltage" cryo-electron microscopy.

Phospholipid, nature's own slide and cover slip for cryo-electron microscopy.

Thin films of surface-active compounds, with or without particulate material, can be obtained by immersing and withdrawing a bare specimen grid from a solution/suspension of the compound. Immediately after withdrawing the grid, thinning of the film starts. Thinning is initially powered by gravity and capillary forces and will proceed in thin films (less than 100 nm) driven by intermolecular forces until the London-van der Waals attractive forces come to an equilibrium with electrostatic repulsion of similarly charged surfaces of the film. With small unilamellar vesicles prepared from the phospholipid dimyristoyl phosphatidyl choline (DMPC) the draining behaviour of these films was studied by cryo-electron microscopy. Small unilamellar vesicles were observed within the film as well as the coalescence of these vesicles into sheets ('leaky' membrane fusion). Sheets dominate the images when films are allowed to drain for longer periods (greater than 3 min). Thin films were formed on grids from catalase crystals suspended in a DMPC suspension and vitrified by cooling. High-resolution information was obtained by electron diffraction at low temperature and under low-dose conditions from catalase crystals surrounded by small vesicles as well as from catalase crystals surrounded by sheets of DMPC. In the latter case the water content drops from 99% (DMPC in small vesicles) to less than 30% (DMPC in sheets) during draining. Ferritin was added to a DMPC suspension and thin films were prepared and vitrified. After prolonged draining ferritin molecules were deposited in layers with a stepwise increase in thickness. Draining of thin films has thus a dehydrating effect as well as a sorting and ordering effect. These effects must be considered when using surface-active compounds at air-water interfaces as a slide and cover slip for electron microscopy.

Prothrombinase activity of human platelets is inhibited by beta 2-glycoprotein-I.

In the present paper the influence of beta 2-glycoprotein-I, also known as apolipoprotein H, upon the prothrombinase activity of platelets and phospholipid vesicles was investigated. The results can be summarized as follows. 1. The prothrombinase activity of resting, non-activated platelets, lysed platelets and vesicles composed of phosphatidylserine and phosphatidylcholine at different molar ratios is inhibited by beta 2-glycoprotein-I in a dose-dependent manner. The concentration of glycoprotein which produces marked inhibition is within the physiological plasma concentration range of beta 2-glycoprotein-I. 2. The time dependence of this inhibition is a relatively slow process, which is not fully expressed before 1 h of incubation. 3. The effect of the glycoprotein is not due to a direct interaction with the components of the prothrombinase complex, i.e. factors Xa, Va, Ca2+ or prothrombin, nor is the inhibitory action abolished by increasing concentrations of coagulation factors Xa and Va. This suggests that beta 2-glycoprotein-I causes a reduction of the prothrombinase binding sites of these coagulation factors to platelets or phospholipid vesicles. 4. The prothrombinase activity of platelets stimulated with ionophore A23187 or with collagen plus thrombin is also inhibited by beta 2-glycoprotein-I in a manner similar to that observed for phospholipid vesicles or for lysed platelets. These findings suggest a regulatory role for beta 2-glycoprotein-I in the pathway of blood coagulation.

Vapor fixation for immunocytochemistry and X-ray microanalysis on cryoultramicrotome sections.

Several organic and inorganic vapor fixatives have been tested for their ability to stabilize the ultrastructure of freeze-dried thin cryosections. The vapors from osmium tetroxide and dry formaldehyde gave a good preservation of the ultrastructure. Fixation in formaldehyde vapor preserved the immunoreactivity of alpha-amylase in exocrine pancreas, as was demonstrated with an indirect labeling technique using anti-alpha-amylase and protein A-gold. A major advantage of the use of vapor fixation is that cryosections from a specimen of fresh-frozen tissue can be used for immunocytochemistry as well as for X-ray microanalysis, as was demonstrated for the exocrine pancreas. This opens the possibility of localizing atomic species (X-ray microanalysis) and molecular species (immunocytochemistry) at the subcellular level on thin cryosections from the same tissue block.