Force measurements during posterior calvarial vault osteodistraction: A novel measurement method.

Posterior calvarial vault osteodistraction (PCVO) has become increasingly popular in the correction of craniosynostosis. When compared to cranioplasty, PCVO offers a shorter, less invasive operation, greater intracranial volume advancement and a lower rate of relapse. In general, distraction protocols are based primarily on clinical observations rather than systematic research. Faster distraction protocols may reduce complications. However, distraction protocols producing higher forces can increase complications. Thus, we need to understand these forces in order to improve distraction protocols and devices. We developed a force measurement method that can be used on PCVO devices. Here, we present preliminary data about the forces developed during PCVO. We measured the forces in four bicoronal craniosynostosis patients during PCVO. We observed a linear-like trend between the force increase and the distraction distance within distraction sessions. We also observed a step-wise force increase between distraction sessions and found that the distraction force relaxed rapidly shortly after the distraction session. The mean maximum pre-distraction force for one distracter was 20.4 N, while the mean maximum end-distraction force for one distracter was 57.6 N. Our data suggests that current treatment protocols might be re-evaluated favouring shorter distraction distances and more frequent distraction sessions.

The Fe-only nitrogenase from Rhodobacter capsulatus: identification of the cofactor, an unusual, high-nuclearity iron-sulfur cluster, by Fe K-edge EXAFS and 57Fe Mössbauer spectroscopy.

Samples of the dithionite-reduced FeFe protein (the dinitrogenase component of the Fe-only nitrogenase) from Rhodobacter capsulatus have been investigated by 57Fe Mössbauer spectroscopy and by Fe and Zn EXAFS as well as XANES spectroscopy. The analyses were performed on the basis of data known for the FeMo cofactor and the P cluster of Mo nitrogenases. The prominent Fourier transform peaks of the Fe K-edge spectrum are assigned to Fe-S and Fe-Fe interactions at distances of 2.29 A and 2.63 A, respectively. A significant contribution to the Fe EXAFS must be assigned to an Fe backscatterer shell at 3.68 A, which is an unprecedented feature of the trigonal prismatic arrangement of iron atoms found in the FeMo cofactor of nitrogenase MoFe protein crystal structures. Additional Fe...Fe interactions at 2.92 A and 4.05 A clearly indicate that the principal geometry of the P cluster is also conserved. Mössbauer spectra of 57Fe-enriched FeFe protein preparations were recorded at 77 K (20 mT) and 4.2 K (20 mT, 6.2 T), whereby the 4.2 K high-field spectrum clearly demonstrates that the cofactor of the Fe-only nitrogenase (FeFe cofactor) is diamagnetic in the dithionite-reduced ("as isolated") state. The evaluation of the 77 K spectrum is in agreement with the assumption that this cofactor contains eight Fe atoms. In the literature, several genetic and biochemical lines of evidence are presented pointing to a significant structural similarity of the FeFe, the FeMo and and the FeV cofactors. The data reported here provide the first spectroscopic evidence for a structural homology of the FeFe cofactor to the heterometal-containing cofactors, thus substantiating that the FeFe cofactor is the largest iron-sulfur cluster so far found in nature.

The prismane protein resolved--Mössbauer investigation of a 4Fe cluster with an unusual mixture of bridging ligands and metal coordinations.

The prismane protein of Desulfovibrio vulgaris, in its isolated, its one-electron-reduced and its oxidized states, was the subject of a detailed Mössbauer investigation. Measurements were recorded in the range 0.295-77 K and in the field range 0-6.2 T (parallel and perpendicular to the gamma beam). The paramagnetic parts of the magnetically split Mössbauer spectra were analyzed with the spin-Hamiltonian formalism, including the nuclear Hamiltonian; the diamagnetic parts result from the nuclear Hamiltonian only. The field-dependent spectra at 295 mK and 4.2 K indicate that the paramagnetic part of the isolated protein represents a spin-coupled 4Fe unit with the spin of one Fe site (5/2) oriented antiparallel to the spins of the other three Fe sites (5/2, 5/2 and 2), yielding a total cluster spin, Stot of 9/2. The Mössbauer parameters of the individual Fe sites indicated that this unit represents a 4Fe cluster with an unusual mixture of bridging and terminal ligands and metal coordinations (hybrid cluster). The diamagnetic part of the isolated protein represents an additional 4Fe unit, which, according to its Mössbauer parameters, is a [4Fe2.5+-4S] cubane. The parameter changes upon one-electron oxidation or reduction and the magnetic properties of the two clusters in the three oxidation states of the protein investigated here reveal that the redox behavior of the prismane protein is exclusively related with the hybrid cluster. [structures: see text] These findings are contrary to the former hypothesis of one or two [6Fe-6S] cluster(s) as the prosthetic group of this protein [Hagen, W. R., Pierik, A. J. & Veeger, C. (1989) J. Chem. Soc. Faraday Trans. 185, 4083-4090; Moura, I., Tavares, P., Moura, J. J. G., Ravi, N., Huynh, B. H., Liu, M.-Y. & LeGall, J. (1992) J. Biol. Chem. 287, 4487-4496]. However, they are in full agreement with the crystal structure of the isolated protein, which, concurrent with our Mössbauer investigation, has been solved.