Mucosal colonization of gastric endocrine tumors mimicking mixed neoplasms

Two cases of gastric tumors showing mixed composition of endocrine cell clusters and exocrine glands and originally diagnosed as mixed neoplasms are described. In both cases, the exocrine glandular component was restricted to the upper third of the neoplasms being consistently absent in areas of muscular wall invasion and, in case 2, in nodal metastases. These glands were in close anatomical contiguity with the glands of the overlying gastric mucosa or, in case 1, apparently derived from deep pouch-like invaginations of the mucosa. They showed either lack of dysplasia (case 1) or mild dysplasia (case 2) with a Ki67 proliferation index consistently lower than that of the intramucosal glands. The intratumoral glands presented intestinal metaplastic features confirmed by intense Cdx2 immunostaining that, conversely, was absent in the endocrine component of the tumors. The latter showed intense vesicular monoamine transporter 2 immunoreactivity consistent with its origin from the enterochromaffin-like cells of the gastric oxyntic mucosa. On the basis of these findings, it is proposed that the exocrine glands do not represent a true neoplastic component of the tumors. Although mucosal entrapment by the tumor cannot be ruled out, they more likely reflect a hitherto unrecognized mechanism of mucosal colonization of gastric endocrine tumors

Malignancy-associated X chromosome allelic losses in foregut endocrine neoplasms: further evidence from lung tumors

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Occurrence of an intermediate relaxation process in water-in-oil microemulsions below percolation: The electrical modulus formalism

The dielectric and conductometric spectra of water-in-oil microemulsions below percolation in the frequency range from 1 MHz to 1.8 GHz have been analyzed on the basis of the electrical modulus formalism. In the frequency range investigated, this approach clearly evidences the presence of a particular polarization mechanism, resulting in a well-defined dielectric dispersion, located between that due to the orientational polarization of the bulk aqueous phase and that due to the ionic structure of the interface, usually occurring in heterogeneous systems. This polarization mechanism has been attributed to the "in-phase" correlation displacement of surfactant polar head groups surrounding each water droplet dispersed in the oil phase. This mechanism differs from the usual interfacial Maxwell-Wagner effect. The advantage of the electrical modulus formalism, in comparison with the analysis of the directly measured quantities, the permittivity ε′(ω), and the total electrical conductivity σ(ω), are briefly discussed. (c) 2001 Academic Press

On the phase diagram of reentrant condensation in polyelectrolyte-liposome complexation

Complexation of polyions with oppositely charged spherical liposomes has been investigated by means of dynamic light scattering measurements and a well-defined reentrant condensation has been observed. The phase diagram of charge inversion, recently derived [T. T. Nguyen and B. I. Shklovskii, J. Chem. Phys. 115, 7298 (2001)] for the complexation of DNA with charged spherical macroions, has been employed in order to define the boundaries of the region where polyion-liposome complexes begin to condense, forming larger aggregates, and where aggregates dissolve again, towards isolated polyion-coated-liposome complexes. A reasonable good agreement is observed in the case of complexes formed by negatively charged polyacrylate sodium salt polyions and liposomes built up by cationic lipids (dioleoyltrimethylammoniumpropane), in an extended liposome concentration range. (C) 2004 American Institute of Physics