A new model for the determination of limb segment mass in children.

BACKGROUND: The knowledge of limb segment masses is critical for the calculation of joint torques. Several methods for segment mass estimation have been described in the literature. They are either inaccurate or not applicable to the limb segments of children. Therefore, we developed a new cylinder brick model (CBM) to estimate segment mass in children. METHODS: The aim of this study was to compare CBM and a model based on a polynomial regression equation (PRE) to volume measurement obtained by the water displacement method (WDM). We examined forearms, hands, lower legs, and feet of 121 children using CBM, PRE, and WDM. The differences between CBM and WDM or PRE and WDM were calculated and compared using a Bland-Altman plot of differences. FINDINGS: Absolute limb segment mass measured by WDM ranged from 0.16+/-0.04 kg for hands in girls 5-6 years old, up to 2.72+/-1.03 kg for legs in girls 11-12 years old. The differences of normalised segment masses ranged from 0.0002+/-0.0021 to 0.0011+/-0.0036 for CBM-WDM and from 0.0023+/-0.0041 to 0.0127+/-0.036 for PRE-WDM (values are mean+/-2 S.D.). The CBM showed better agreement with WDM than PRE for all limb segments in girls and boys. INTERPRETATION: CBM is accurate and superior to PRE for the estimation of individual limb segment mass of children. Therefore, CBM is a practical and useful tool for the analysis of kinetic parameters and the calculation of resulting forces to assess joint functionality in children.

Phylogeny of 33 ribosomal and six other proteins encoded in an ancient gene cluster that is conserved across prokaryotic genomes: influence of excluding poorly alignable sites from analysis.

Thirty-nine proteins encoded in a large gene cluster that is well-conserved in gene content and gene order across 18 sequenced prokaryotic genomes were extracted, aligned and subjected to phylogenetic analysis. In individual analyses of the alignments, only two probable examples of lateral gene transfer between archaea and eubacteria were detected, involving the genes for ribosomal protein Rpl23 and adenylate kinase. Amino acid sequences for 35 of the 39 proteins were concatenated to yield a data set of 9087 amino acid positions per genome. Many of these proteins, 33 of which are ribosomal proteins, are not highly conserved across distantly related organisms and thus contain many regions that are difficult to align. Phylogenetic analyses were performed with subsets of the concatenated data from which the most highly variable sites had been iteratively removed, using the number of different amino acids that occur at a given site as a criterion of variability. Glycine, which has a strong influence on protein structure, tended to be more frequent at the most conserved (least polymorphic) sites. With most subsets of the data, the proteins from the cyanobacterium Synechocystis tended to branch with their homologues from gram-positive bacteria. The results indicate that excluding only a few percentage of poorly alignable sites from phylogenetic analysis can have a severe impact upon the phylogeny inferred and that bootstrap support for branches can fluctuate substantially, depending upon which sites are excluded.