The cutaneous microvascular architecture of human diabetic toe studied by corrosion casting and scanning electron microscopy analysis.

In this morphological study, we report on the three-dimensional microvascular architecture constituting the toes of a patient affected by diabetic microangiopathy. We applied corrosion casting (CC) technique to the toes of a patient affected by Type 2 diabetes, who underwent surgery for explantation of inferior left limb due to necrotic processes of soft tissues. The toes of a foot traumatically explanted in a motorcycle accident were kept as controls. According to technical protocols, toes were injected with a low-viscosity acrylic resin (Mercox) through the major digital artery, tissues were corroded in KOH solution (8%), and resulting casts processed for SEM observations. Already at low magnification, in diabetic toes, we found an impairment of the linear track-like disposition of the vessels of plantar side, with signs of vascular disruption and obliterations, stopped resin, and leakages. Capillaries under the nail and a lot of vascular villi in eponychium and nail borders were damaged, and vascular regression phenomena acting on them were clearly visible. Resin leakages and impairment of normal vascular architecture were also observed in the root of the nail. This preliminary report represents only the first step for further investigations regarding morphological three-dimensional appearance of diabetic microangiopathy. CC and scanning electron microscopy technique well documented these morphological modifications, highlighting on both structural and ultrastructural features of diabetic toes microvessels. In conclusion, our qualitative data try to better focus on the pathophysiological mechanisms involved in diabetic dermopathy and microangiopathy, proposing CC as useful method to investigate on them.

In situ hybridization by scanning electron microscopy for painting, centromeric, and YAC localization.

The hybridization site of a DNA probe was detected using a scanning electron microscope (SEM), modifying the standard in situ hybridization (ISH) method. The experiments were performed on human metaphases obtained from lymphocyte cultures of human peripheral blood. The libraries and probes used were: 1-chromosome library for the painting of chromosome 1 (wcp 1), an alphoid centromere-specific probe of chromosome 8 (pZ8.4), and the yeast artificial chromosome (YAC) 964-C10 mapped at band p13 on chromosome 12. These probes were labeled by nick translation with biotin and displayed with a gold-conjugated anti biotin goat antibody. The gold signal was amplified by silver enhancement. The chromatides appeared as packages of thin filaments 120 nm high; some of them collapsed, probably due to ISH procedures. All the probes were clearly detected as small gold particles grouped on the surface of the target chromosomes and chromosome sites. Thus, this procedure is useful to clarify the positional relationship between the chromatin filaments and the probe.

The extracellular matrix of the cuticle of Gordius panigettensis (Gordioiidae, Nematomorpha): observations by TEM, SEM and AFM.

The cuticle of Gordius panigettensis (Sciacchitano, 1955) was studied by scanning electron microscopy (SEM), transmission electron microscopy (TEM) and atomic force microscopy (AFM). The cuticle is composed of 30-50 compact layers. The number of the layers is higher in the central part of the animal's body and decreases at the extremities. Each layer is composed of parallel tightly packed fibres approximately 640 nm in diameter and of indefinite length. The fibres run strictly parallel within each layer, while in adjoining layers they run at a variable angle from 45 degrees in the central body to 90 degrees in the extremities. Each fibre shows a barely detectable filamentous inner structure and is enveloped in a thin highly regular net formed by hexagonal meshes. Our results suggested that these fibres should be proteinaceous although non-collagenous. Thinner radial fibres run among the large fibres and across all the layers and span the whole thickness of the cuticle from the epithelial layer located deep underneath the large fibres up to the epicuticle on the external surface of the animal.

Ultrastructure and functional versatility of hirudinean botryoidal tissue.

In leeches, the botryoidal tissue is composed of two different cell types--granular botryoidal cells and flattened endothelial-like cells--localized in the loose connective tissue between the gut and the body wall sac. We have observed that the botryoidal tissue undergoes functional and structural modifications in response to the different needs arising during the life-cycle of the animal. In healthy, untreated leeches, botryoidal cells are organized in cords or clusters, sometimes surrounding few, small lacunae. Conversely, in wounded animals we have observed the transition of the botryoidal tissue from cluster/cord-like structures to a hollow/tubular architecture, typical of pre-vascular structures. We have documented in botryoidal cell cytoplasm the presence of large calcium storage. Moreover, the cytoplasm of botryoidal cells was filled with granules of different form and size, containing iron or melanin, as tested by classic histochemical methods. The presence of elements like iron and calcium was confirmed by the well-established EDS analysis. In response to a surgical wound, botryoidal tissue cells changed their shape and formed new capillary vessels. Concurrently, botryoidal cells secreted iron from cytoplasmic granules into the new cavity: this secretory activity appeared to be related to intracellular calcium fluctuations. At the end of the angiogenic process, botryoidal cells lost their contact with the basal lamina and moved freely in the circulating fluid towards the lesioned area. Interestingly, circulating botryoidal cells were found to carry melanin in the wounded area. This function is probably involved in defense processes. Thus, we have shown that stimulated botryoidal tissue displays a variety of striking structural, secretory and defensive activities.

Hirudo medicinalis: a new model for testing activators and inhibitors of angiogenesis.

An increasing body of evidence indicates that in the leech Hirudo medicinalis the angiogenic process is finely regulated and coordinated by the botryoidal tissue. In this paper we provide evidence on the involvement of botryoidal tissue cells in angiogenesis induced in H. medicinalis by a variety of stimuli including surgical wounds or the administration of modulators of neovascularization. Interestingly, we show that either human activators of vascular cell growth, or anti-angiogenic peptides like angiostatin and endostatin, or the drug mitomycin, can induce a prompt biological response in H. medicinalis. We show as well that angiogenesis in this invertebrate shares a surprising degree of similarity with neovascularization in vertebrates, both at the biochemical and cellular levels, because it involves similar growth factors/growth factor receptors, and relies on analogous cell-cell or cell-matrix interactions. For these reasons we suggest that H. medicinalis can be used as a reproducible model for testing activators or inhibitors of angiogenesis, and for investigating the biochemical, ultrastructural and cellular processes involved in new vessel formation.