Comparing multiple correspondence and principal component analyses with biomechanical signals. Example with turning the steering wheel.

The purpose of this article is to compare Principal Component Analysis (PCA) and a much less used method, i.e. MCA (Multiple Correspondence Analysis) with data being first changed into membership values to fuzzy space windows. For such a comparison, data from an experimental study about turning the steering wheel is used. In a didactic perspective, this article only considers one multidimensional signal with 5 components: 3 linked to the steering wheel angle and hand positions and 2 to hand effort variables. A discussion weighs out the pros and the cons of both methods with criteria such as the possibility to show complex relational phenomena, the analysis/computing time or the information loss inherent to the averaging stage (in the perspective to analyze several hundreds of large multidimensional signals).

Grouped papules in Hurler-Scheie syndrome.

In a patient with Hurler-Scheie syndrome, a type of mucopolysaccharidosis (I H/S), an initial presentation was grouped papules on the extensor surfaces on the upper portions of the arms and legs. Other physical findings included progressive flexion contractures and mild developmental delay. The patient had deficient alpha-L-induronidase activity, and electron microscopy showed large cytoplasmic vacuoles and lysosomes, consistent with Hurler-Scheie syndrome. Findings of grouped papules have not been previously reported in patients with this syndrome.

Distinct cellular functions mediated by different VLA integrin alpha subunit cytoplasmic domains.

To characterize VLA alpha subunit cytoplasmic domain functions, unaltered alpha 2 cDNA (called X2C2) and two chimeric cDNAs (called X2C5 and X2C4) were constructed with extracellular alpha 2 domains and cytoplasmic alpha 2, alpha 5, and alpha 4 domains respectively. Upon transfection into rhabdomyosarcoma (RD) cells, each construct yielded comparable expression levels, immunoprecipitation profiles, and avidity for collagen and laminin. However, while RDX2C2 and RDX2C5 transfectants mediated collagen gel contraction, RDX2C4 and a mock transfectant (RDpF) did not. Conversely, only RDX2C4 cells (but not RDX2C2 or RDX2C5) showed enhanced cell migration on collagen and laminin compared with RDpF cells. This indicates markedly differing roles for integrin alpha subunit cytoplasmic domains in post-ligand binding events. Furthermore, stable exertion of physical force (collagen gel contraction) may involve fundamentally different cellular machinery than the transient adhesion occurring during cell migration. Finally, these findings provide insight into a functional flexibility perhaps resulting from multiple integrins binding to identical ligands.

Integrin alpha 2 beta 1 (VLA-2) mediates reorganization and contraction of collagen matrices by human cells.

The capacity of cells to organize and contract collagen fibrils is fundamental to processes as diverse as embryogenesis and wound healing. We analyzed different beta 1 integrins on diploid fibroblasts for their role in modifying the tertiary structure of collagen matrices. Using monoclonal antibodies that block the interaction of integrins with their ligands, evidence was obtained that alpha 2 beta 1 integrin is required for the contraction of a type I collagen matrix. Further supporting the role of alpha 2 beta 1, cell lines expressing minimal levels of this integrin uniformly failed to contract collagen matrices. In addition, transfection of a full-length alpha 2 cDNA into one such cell line led to enhanced cell surface expression of alpha 2 beta 1 and conferred the de novo capacity to contract collagen matrices.

Beta-hydroxybutyrate reverses insulin-induced hypoglycemic coma in suckling-weanling mice despite low blood and brain glucose levels.

In normal suckling-weanling mice, DL-beta-hydroxybutyrate (30 mmol/kg ip) stimulated insulin secretion and reduced plasma glucose levels. In the brains of these animals, glucose levels were tripled due to a reduced rate of glucose utilization (determined by deoxyglucose phosphorylation). Other metabolite changes were compatible with inhibition of hexokinase, phosphofructokinase, glyceraldehyde-P-dehydrogenase, and pyruvate dehydrogenase activities. In contrast to the decrease in cerebral glycolysis, metabolite changes were compatible with an increase in the Krebs citric acid metabolic flux. The brain energy charge was also elevated. While it is generally believed that ketone bodies cannot sustain normal brain metabolism and function in the absence of glucose, DL-beta-hydroxybutyrate (20 or 30 mmol/kg ip) reversed insulin (100 U/kg sc)-induced hypoglycemia despite the persistence of a critically reduced plasma glucose concentration and near-zero brain glucose levels. Metabolic correlates of possible significance in the behavioral recovery from coma were reductions of the elevated levels of brain aspartate to below normal and ammonia levels to normal. Levels of acetyl CoA were unchanged both before and after treatment with beta-hydroxybutyrate.

A single therapeutic dose of valproate affects liver carbohydrate, fat, adenylate, amino acid, coenzyme A, and carnitine metabolism in infant mice: possible clinical significance.

We have previously reported that chronic valproate administration reduced ketonemia in suckling mice and fasting epileptic children. The present study demonstrates that even a single dose of valproate in the therapeutic range for man caused a prolonged reduction of plasma beta-hydroxybutyrate levels in normal infant mice; the plasma glucose concentration was also significantly lowered. In the livers of these animals, there were extraordinary decreases in levels of free coenzyme A, acetyl CoA and free carnitine. Concomitantly concentrations of acid-soluble fatty acid (short-chain, non-acetyl) coenzyme A esters and of acid-insoluble (long-chain) fatty acid carnitine esters increased. There was evidence for inhibition of the metabolic flux through the Krebs citric acid cycle at those enzyme reactions which require coenzyme A. While valproate doubled liver alanine levels, concentrations of liver aspartate, glutamate and glutamine were reduced. All of the valproate-induced metabolite changes can be explained by the decrease of coenzyme A due to the accumulation of acid-soluble (non-acetyl) coenzyme A esters (presumably valproyl CoA and further metabolites). Decreased coenzyme A would limit the activities of one or more enzymes in the pathway of fatty acid oxidation and the Krebs citric acid cycle. Secondary decreases in acetyl CoA would limit both ketogenesis and gluconeogenesis. Decreased levels of selected hepatic amino acids could reflect their use as alternative fuels. The effect of clinical doses of valproate in infant mice may relate to the valproate-associated syndrome of hepatic failure and Reye-like encephalopathy in some infants and children and suggest a simple screen for those who may be at particular risk.

Lactate reverses insulin-induced hypoglycemic stupor in suckling-weanling mice: biochemical correlates in blood, liver, and brain.

The recovery of weanling mice from insulin-induced hypoglycemic stupor-coma after injection of sodium -L(+)-lactate (18 mmol/kg) was as rapid (10 min) as in litter-mates treated with glucose (9 mmol/kg). Stimulated by this dramatic action, we studied the effects of lactate injection on brain carbohydrate and energy metabolism in normal and hypoglycemic mice; blood and liver tissue were also studied. Ten minutes after lactate injection in normal mice, plasma lactate levels increased by 15 mmol/L; plasma glucose levels were unchanged, but the beta-hydroxybutyrate concentration fell 59%. In the brains of these animals, glucose levels increased 2.3-fold, and there were significant increases in brain glycogen (10%), glucose-6-phosphate (27%), lactate (68%), pyruvate (37%), citrate (12%), and malate (19%); the increase in alpha-ketoglutarate (32%) was not significant. Lactate injection reduced the cerebral glucose-use rate 40%. These changes were not due to lactate-induced increases in blood [HCO-3] and pH (examined by injection of 15 mmol/kg sodium bicarbonate). Although lactate injection of hypoglycemic mice doubled levels of glucose in plasma and brain (not significant) and most of the cerebral glycolytic intermediates, values were far below normal (still in the range seen in hypoglycemic animals). By contrast, citrate and alpha-ketoglutarate levels returned to normal; the large increase in malate was not significant. Reduced glutamate levels increased to normal, and elevated aspartate levels fell below normal. Thus, recovery from hypoglycemic stupor does not necessarily depend on normal levels of plasma and/or brain glucose (or glycolytic intermediates).(ABSTRACT TRUNCATED AT 250 WORDS)

Routine use of a shunt for carotid endarterectomy.

A temporary inlying shunt used during carotid endarterectomy is the ideal method of cerebral protection. The data presented suggest that if meticulous technique is used, the potential complications of a shunt may be avoided and excellent clinical results expected. When a shunt is used properly, carotid endarterectomy may be performed in a teaching situation with a high degree of safety.