ABS-SMART (Aortic Balloon Supporting for Superior Mesenteric Artery Recanalization Technique): A New Technical Option for Recanalization of Complete Superior Mesenteric Artery Occlusion in Chronic Mesenteric Ischemia.

OBJECTIVE: To report our experience with a new technique for recanalization of the superior mesenteric artery (SMA)/celiac trunk (CT) with complete occlusion at the origin. TECHNIQUE: We describe our ABS-SMART (Aortic Balloon Supporting for Superior Mesenteric Artery Recanalization Technique) for recanalization of the CT and SMA in cases of complete occlusion of these arteries with a short or inexistent stump, which usually corresponds to chronic lesions with important calcification of the ostium. CONCLUSION: The ABS-SMART is an alternative for the recanalization of visceral arteries in cases where other conventional techniques have failed. It is particularly useful in scenarios characterized by a short occlusion at the origin of the target vessel, with no entry stump or severe calcification at the origin. CLINICAL IMPACT: Catheterization and recanalization of visceral stenoses may pose a challenge in some cases, as for example in the presence of a very narrow angle between the root or origin of the vessel and the aorta, as well as in the case of long and calcified stenoses, or when arteriography is unable to visualize the origin of the vessel. The present study describes our experience with the endovascular revascularization of visceral vessels using an aortic balloon-supported recanalization technique not previously described in the literature, that may be an effective alternative for the treatment of lesions of difficult access, such as total occlusion at the origin of the target vessel, with no entry stump or severe calcification at the origin of the SMA and CT, by improving the chances for technical success.

Study of the electronic and magnetic properties as a function of isoelectronic substitution in SmFe(1-x)RuxAsO0.85F0.15.

We have studied the electronic and magnetic properties of SmFe(1-x)RuxAsO0.85F0.15 (x = 0, 0.05, 0.25, 0.33, 0.5) by high-resolution x-ray absorption and x-ray emission spectroscopy. The local Fe magnetic moment (µ) tends to decrease for a small Ru substitution, but it shows a clear increase with further substitution. It appears that impurity scattering prevails in reducing the µ with small Ru substitution due to an extended Ru d-band. A nanoscale phase separation, that decouples the FeAs layers from the spacer layers, drives the increase of µ at higher Ru substitution. The results provide important information on nanoscale phase separation due to isoelectronic substitution in the active layers of iron-based 1111-superconductors and its effect on the local magnetic properties.

Structural properties and phase diagram of the La(Fe1-xRux)AsO system.

Structural refinement, lattice micro-strain and spontaneous strain analyses have been carried out on selected members of the La(Fe1-xRux)AsO system using high-resolution neutron and synchrotron powder diffraction data. The obtained results indicate that the character of the tetragonal to orthorhombic structural transition changes from first order for x = 0.10, possibly to tricritical for x = 0.20, up to second order for x = 0.30; for x ≥ 0.40 symmetry breaking is suppressed, even though a notable increase of the lattice micro-strain develops at low temperature. By combining structural findings with previous muon spin rotation data, a phase diagram of the La(Fe1-xRux)AsO system has been drawn. Long-range ordered magnetism occurs within the orthorhombic phase (x ≤ 0.30), whereas short-range magnetism appears to be confined within the lattice strained region of the tetragonal phase up to x < 0.60. Direct comparison between the magnetic and structural properties indicates that the magnetic transition is always associated with structural symmetry breaking, although confined to a local scale at high Ru contents.

Theoretical and experimental investigation of magnetotransport in iron chalcogenides.

We explore the electronic, transport and thermoelectric properties of Fe1+y Se x Te1-x compounds to clarify the mechanisms of superconductivity in Fe-based compounds. We carry out first-principles density functional theory (DFT) calculations of structural, electronic, magnetic and transport properties and measure resistivity, Hall resistance and Seebeck effect curves. All the transport properties exhibit signatures of the structural/magnetic transitions, such as discontinuities and sign changes of the Seebeck coefficient and of the Hall resistance. These features are reproduced by calculations provided that antiferromagnetic correlations are taken into account and experimental values of lattice constants are considered in DFT calculations. On the other hand, the temperature dependences of the transport properties can not be fully reproduced, and to improve the agreement between experiment and DFT calculations it is necessary to go beyond the constant relaxation time approximation and take into account correlation effects.

Retention of the tetragonal to orthorhombic structural transition in F-substituted SmFeAsO: a new phase diagram for SmFeAs(O(1-x)F(x)).

In this Letter we propose a new phase diagram for the SmFeAs(O(1-x)F(x)) system, based on careful analysis of synchrotron powder diffraction data, SQUID, and muon spin rotation measurements. The tetragonal to orthorhombic structural transition is slightly affected by F content and is retained for the superconducting samples, even at optimal doping. These findings relate the AFM transition on a different ground with respect to the structural one and suggests that orbital ordering could be the driving force for symmetry breaking.

Energetics and thermodynamic stability of the mixed valence ytterbium germanides.

The results of an experimental study concerning the thermodynamic stability of the Yb germanides, described as intermediate valence compounds, complemented by a computational investigation for the Yb3Ge5 compound are reported. These compounds belong to the rare earth (RE) tetrelides (tetrel = Si, Ge, i.e., group 14 elements), a class of intermetallic materials showing unusual and promising physical properties (giant magnetocaloric effect, magnetostriction, and magnetoresistence). The high-temperature decomposition reactions of the Yb-Ge intermediate phases were studied experimentally by means of the KEMS (Knudsen effusion mass spectrometry) and KEWL (Knudsen effusion weight loss) techniques. From the reaction enthalpies derived by measuring the Yb(g) decomposition pressures as a function of temperature, the heats of formation of five out of six of the intermediate phases in the Yb-Ge system were calculated. From the computational side, the stability of the Yb3Ge5(s) compound has been investigated by DFT-LCAO-B3LYP (density functional theory-linear combination of atomic orbitals-hybrid b3lyp exchange-correlation functional) first principles calculations deriving its equilibrium geometry and the enthalpy of formation at 0 K in relation to the intermediate valence state of Yb in the lattice.

Effect of two gaps on the flux-lattice internal field distribution: evidence of two length scales in Mg(1-x)AlxB2 from muSR.

We have measured the transverse field muon spin precession in the flux-lattice (FL) state of the two-gap superconductor MgB2 and of the electron doped compounds Mg(1-x)AlxB2 in magnetic fields up to 2.8 T. We show the effect of the two gaps on the internal field distribution in the FL, from which we determine two coherence length parameters and the doping dependence of the London penetration depth. This is an independent determination of the complex vortex structure already suggested by the STM observation of large vortices in a MgB2 single crystal. Our data agree quantitatively with STM and we thus validate a new phenomenological model for the internal fields.

Growth, spread, and extracellular localization of herpes simplex virus 1 in Vero cells in the presence of an anti-gD plaque inhibiting monoclonal antibody.

Evidence for a direct cell-to-cell virus transfer could be provided by an agent that inhibits plaque formation without interfering with the processes that determine plaque growth in the exit and reinfection pathway of virus transfer. We studied the process of Vero cell infection by herpes simplex virus type 1 laboratory strain F [HSV-1 (F)] in the presence of monoclonal antibody (mAb) F10, an anti gD mAb that inhibits plaque development but does not neutralize virus infectivity in the absence of complement. In virus growth curves, cell associated virus was inhibited at low (0.01) but not at high (10) MOI when all cells are simultaneously infected, showing that the target of the mAb is the process of progressive cells recruitment and not the rate of virus replication. The mAb slightly inhibited virus exit and delayed virus entry. However these two additional inhibitory activities were not responsible for inhibition of virus spread, at least at early time of infection. In fact inhibition of virus spread, as measured by reduction of infectious centers (IC) from infected monolayers, could be appreciated before the appearance of extracellular virus in control cultures. We obtained electron microscope evidence that, both in the absence and in the presence of mAb, extracellular virus was initially concentrated at the interspaces between adjacent cell membranes, with little or no virus present at free cell surfaces. At more advanced stages of infection, only virus at free cell surfaces was found. The results of the study of virus replication in the presence of the mAb confirmed the hypothesis of the existence of a pathway of virus transfer between adjacent cells independent from extracellular virus. However, no electron microscope evidence for a direct cell-to-cell virus passage or for a modification of virus transfer brought about by the plaque inhibiting mAb was obtained. Interestingly, electron microscope studies suggested a targeting of the virions to different extracellular spaces, intercellular spaces and free cell surfaces, in intact and damaged cells respectively.

Cell-type dependent sensitivity of herpes simplex virus 1 mutants to plaque development inhibition by an anti-gD monoclonal antibody.

Herpes simplex virus 1 (HSV-1) mutants selected in Vero cells either for resistance to plaque development inhibition (PDI) (P1, P2 and P3) or for resistance to neutralization (N1, N2, and N3) against an anti-glycoprotein D (gD) monoclonal antibody (mAb) were characterized both in Vero and BHK cells. In Vero cells P mutants were completely resistant to PDI, while N mutants showed from moderate to good resistance. In BHK cells P mutants lost their resistance to PDI, while N mutants became fully resistant. Cell type influenced the plaque size of the mutants as well. In Vero cells P mutant plaques were larger, and N mutant plaques smaller than wild type virus plaques. In BHK cells all plaques were comparable. With one exception (N2 in BHK) resistance to neutralization could be clearly appreciated at high but not at low mAb:virus particles ratio. For most of the mutants the neutralization values remained approximately the same in Vero and BHK cells. P2 and N2 mutants were more resistant to neutralization in BHK than in Vero cells. However, only for N2 mutant did the change in neutralization resistance go in the same direction as the change in PDI resistance. The results show that it is possible to dissociate the neutralizing and the PDI activities of a mAb and that the sensitivity of a virus to plaque inhibition by an anti-gD mAb is cell-type dependent.

Passive immune protection by herpes simplex virus-specific monoclonal antibodies with different plaque development inhibition activity.

A series of herpes simplex viruses type 1 (HSV-1) neutralizing monoclonal antibodies (mAbs) with different plaque development inhibition (PDI) activity were tested for passive protection in mice. When virus was inoculated intracranially, mAbs with PDI activity were not more protective than mAbs without PDI activity. However, when virus was inoculated percutaneously, there was a trend indicating that neutralizing mAbs with PDI power were more active in protecting mice from the cutaneous lesion than mAbs without PDI power. The results are discussed in relation to the possible involvement of PDI activity in in vivo protection and to the fact that this mechanism of protection might operate in cutaneous, but not in nervous tissue.