Optimization and characterization of highly nonlinear fiber for broadband optical time lens applications.

We demonstrate simple and intuitive methods, for dispersion optimization and characterization of highly nonlinear fiber (HNLF) for use in four-wave-mixing (FWM) based time lens applications. A composite dispersion-flattened HNLF is optimized for high bandwidth time lens processing, by segmentation to mitigate FWM impairments due to dispersion fluctuations. The fiber is used for FWM conversion of 32 WDM-channels with 50 GHz spacing in a time lens, with -4.6 dB total efficiency, and <1 dB per-channel efficiency difference. The novel characterization method is based on two tunable continuous-wave lasers. The method is experimentally verified to predict the spectral output profile of time lenses for broadband multicarrier input, with detailed numerical simulations for support.

Mannan-binding lectin recognizes structures on ischaemic reperfused mouse kidneys and is implicated in tissue injury.

Organ damage as a consequence of ischaemia and reperfusion (I/R) is a major clinical problem in an acute renal failure and transplantation. Ligands on surfaces of endothelial cells that are exposed due to the ischaemia may be recognized by pattern recognition molecules such as mannan-binding lectin (MBL), inducing complement activation. We examined the contribution of the MBL complement pathway in a bilateral renal I/R model (45 min of ischaemia followed by 24 h of reperfusion), using transgenic mice deficient in MBL-A and MBL-C [MBL double knockout (MBL DKO)] and in wildtype (WT) mice. Kidney damages, which were evaluated by levels of blood urea nitrogen (BUN) and creatinine, showed that MBL DKO mice were significantly protected compared with WT mice. MBL DKO mice, reconstituted with recombinant human MBL, showed a dose-dependent severity of kidney injury increasing to a comparable level to WT mice. Acute tubular necrosis was evident in WT mice but not in MBL DKO mice after I/R, confirming renal damages in WT mice. MBL ligands in kidneys were observed to be present after I/R but not in sham-operated mice. C3a (desArg) levels in MBL DKO mice were decreased after I/R compared with that in WT mice, indicating less complement activation that was correlated with less C3 deposition in the kidneys of MBL DKO mice. Our data implicate a role of MBL in I/R-induced kidney injury.

On the site of C4 deposition upon complement activation via the mannan-binding lectin pathway or the classical pathway.

The mannan-binding lectin (MBL) pathway and the classical pathway of complement activation are initiated by the binding of the recognition structure of the initiator complexes, MBL and C1q, respectively, to their ligands, i.e. carbohydrate structures or immune complexes. Proenzymes associated with MBL or C1q are then activated and generate C3 convertase through the activation of C4 and C2. The cleavage product of C4, C4b, attaches covalently to nearby hydroxyl or amino groups. The current picture is that C2 must then attach to C4b before being cleaved by the same associated proteases into the enzymatically active fragment, C2b. This suggests a stringent requirement for the deposition of C4b very close to the initiator complex, or indeed onto the initiator complex. We examined the possibility of C4b being bound to the initiator complex by a solid-phase assay, allowing for the selective elution of the initiator complexes, followed by quantification of the C4b being eluted and the C4b remaining on the solid phase. Also, we estimated the generation of complexes between the released initiator complex and C4b. More than 99% of deposited C4b was bound directly to the solid phase rather than to the initiator complex. Our approach cannot answer the question of the whereabouts of the C2 when it is cleaved.