Computational simulation of spontaneous bone straightening in growing children

Periosteal surface pressures have been shown to inhibit bone formation and induce bone resorption, while tensile strains perpendicular to the periosteal surface have been shown to inhibit bone resorption and induce new bone deposition. A new computational model was developed to incorporate these experimental findings into simulations of spontaneous bone straightening in children with congenital posteromedial bowing of the tibia. Three-dimensional finite element models of the periosteum were used to determine the relationships between the defect angle and the distribution of bone surface pressures and strains due to growth-generated tensile strains in the periosteum. These relationships were incorporated into an iterative simulation to model development of a growing, bowed tibia with an initial defect angle of 27°. When periosteal loads were included in the simulation, the defect angle decreased to 10° after 2 years, and the bone straightened by an age of 25 years. When periosteal loads were not included in the simulation, the defect angle decreased to 23° after 2 years, and a defect angle of 9° remained at an age of 25 years. A “modeling drift” bone apposition/resorption pattern appeared only when periosteal loads were included. The results suggest that periosteal pressures and tensile strains induced by bone bowing can accelerate the process of bone straightening and lead to more complete correction of congenital bowing defects. Including the mechanobiological effects of periosteal surface loads in the simulations produced results similar to those seen clinically, with rapid straightening during the first few years of growth.     

Ammonium excretion and glutamate dehydrogenase activity of zooplankton in Great South Bay, New York

In Great South Bay, nanoplankton, (<20 sµm) accountedfor the largest fraction (56%) of zooplankton glutamate dehydrogenase(GDH) activity over a one year period. Microzooplankton (20–200µm) and macrozooplankton (>200 µm) accountedfor 20% and 24%, respectively. Total zooplankton ammonium regenerationin Great South Bay could account for 74% of the ammonium requirementby phytoplankton in winter, but in summer when phytoplanktondemand was greater, and zooplankton population was low, it suppliedless than 5%. This study suggests that the smallest zooplanktonfraction, less than 20 µm, can be the most important asregards nitrogen regeneration in estuarine environments. MacrozooplanktonGDH activity in Great South Bay ranged from 0.18 mg atoms NH⁺₄-Nm^–3 d^–1 in winter to 3.34 mg atoms NH⁺₄-N m^–3d^–1 in spring. Over an annual period, the averaged GDH/excretionratio was 20.4 3.5 (n = 10), and this ratio agrees well withobservations by other investigators. Observed macrozooplanktonexcretion rates showed a strong correlation with the excretionrates indirectly estimated from GDH activities. The GDH/excretionratio seems to vary depending on the internal physiologicalstates of zooplankton as well as food availability.     

Action of lead on glutamate-activated chloride currents inHelix pomatia L. neurons

Summary 1. In molluscan neurons glutamate may, on different neurons, evoke either excitation or inhibition. We studied neurons ofHelix pomatia which have hyperpolarizing responses to glutamate and determined the effects of lead on these responses.2. In voltage clamp experiments, the reversal potentials of these glutamate responses indicate that they are due to a conductance increase to chloride ions. Further evidence for this conclusion was obtained by the demonstration that responses to glutamate remained unaffected in experiments with intracellular dialysis with K-free saline in the presence of Na- and K-free extracellular media. In these circumstances, there is effectively no other ion than chloride to carry the current. In isolated neurons the glutamate-evoked chloride current is concentration dependent between 25 and 2500 µM. The current rises over 200 msec and declines in the continued presence of glutamate over a period of about 3 sec.3. Lead (0.5–1.0 µM) potentiated the glutamate-evoked chloride current provided that the channels were not maximally activated. The potentiation was greater if lead was added 30–60 sec before glutamate application.4. These results suggest that potentiation of transmitter-evoked responses by lead must be considered as yet another possible site of action of lead on neurons, and thus this effect must be considered as a part of the mechanism responsible for the neurotoxicity of this heavy metal.     

Inclusion bodies in several species of Ceratium Schrank (Dinophyceae) from the Caribbean Sea examined with DNA-specific staining

Several dinoflagellate species in the genus Ceraiium Schrankwere examined, with the help of a DNA-specific dye, for thepresence of a nucleus, chloroplasts and inclusion bodies. Theabundance of Ceratium in the Caribbean Sea in April 1990 wasbetween 1.3 and 4.9 x 10⁵ cells m^–3 Most Ceratium teresKofoid contained 5–10 small chloroplasts and among 529C.teres cells. 8% possessed an inclusion body. The shape andsize of inclusion bodies varied, and 7% of the inclusions hada DNA-containing particle inside. Similar inclusion bodies werealso observed in Ceratium declinatum f. normale Jörgensen,Ceratium furca (Ehrenberg) Claparede and Lachmann, and Ceratiumfusus (Ehrenberg) Dujardin. Our observations indicated thatinclusion bodies are common in oceanic Ceratium. ¹Present address: Institute of Marine Biology, National TaiwanOcean University, Keelung 20224, Taiwan, ROC     

CHEMICAL COMPOSITION AND PHOTOSYNTHETIC CHARACTERISTICS OF ETHMODISCUS REX (BACILLARIOPHYCEAE): EVIDENCE FOR VERTICAL MIGRATION1

Ethmodiscus rex (Rattray) Wiseman and Hendey cells from near surface net tows in the Southwest Atlantic Ocean and Caribbean Sea were examined for chemical composition, internal nutrient pool concentrations, and oxygen evolution characteristics. Elemental ratios indicated nitrogen limitation with C:N:P ratios of 125:9:1 (atoms), and carbon: chlorophyll (chl) ratios of 129:1 (weight). However, internal nitrate pools (1.4–27.1 mM) suggested that cells were not N-limited. Intracellular NO₃^? accounted for up to 54% (range = 3–54%) of the total N quota in some samples. Photosynthetic parameters were consistent with a high-light-adapted population and suggested an instantaneous maximum chl-specific photosynthetic rate (P^B_max) of 4.8–12.4 nmol O₂·μg chl^?1· h^?1. Respiration rates varied ten-fold and were inversely related to P^B_max Ethmodiscus chemical composition and buoyancy characteristics are similar to vertically migrating Rhizosolenia mats and the non-motile dinoflagellate Pyrocystis noctiluca Murray (Schuett). The presence of internal NO₃^? pools in Ethmodiscus suggests that this genus is also vertically migrating to exploit sub-surface nitrogen pools. Such behavior may be widespread in large, non-motile oceanic phytoplankton. Based on ascent rate data, chemical composition, and photosynthetic rates, we estimate that the entire division–migration cycle for Ethmodiscus requires at least 7–12 days.     

Effect of curare on responses to different putative neurotransmitters in Aplysia neurons

We have studied the effects of curare on responses resulting from iontophoretic application of several putative neurotransmitters onto Aplysia neurons. These neurons have specific receptors for acetylcholine (ACh), dopamine, octopamine, phenylethanolamine, histamine, γ-aminobutyric acid (GABA), aspartic acid, and glutamic acid. Each of these substances may on different specific neurons elicit at least three types of response, caused by a fast depolarizing Na⁺, a fast hyperpolarizing Cl^?, or a slow hyperpolarizing K⁺ conductance increase. All responses resulting from either Na⁺ or Cl^? conductance increases, irrespective of which putative transmitter activated the response, were sensitive to curare. Most were totally blocked by ≤ 10^?4 M curare. GABA responses were less sensitive and were often only depressed by 10^?3 M curare. K⁺ conductance responses, irrespective of the transmitter, were not curare sensitive. These results are consistent with a model of receptor organization in which one neurotransmitter receptor may be associated with any of at least three ionophores, mediating conductance increase responses to Na⁺, Cl^?, and K⁺, respectively. In Aplysia nervous tissue, curare appears not to be a specific antagonist for the nicotinic ACh receptor, but rather to be a specific blocking agent for a class of receptor-activated Na⁺ and Cl^? responses.     

Size fractionation of algal chlorophyll, carbon fixation and phosphatase activity: relationships with species-specific size distributions and zooplankton community structure

Algal chlorophyll, carbon fixation and alkaline phosphataseactivity were net-fractionated using 22-µm, and 75-µmscreens in three lakes with contrasting zooplankton communities.Size distributions of algal biovolume were also determined throughmicroscopic examination. Relatively good correspondence wasfound between size distributions obtained through net fractionationand those determined by microscopic examination. Biovolume-specificcarbon fixation and chlorophyll decreased with increasing fractionsize but no differences were observed among fractions for chlorophyll-specificcarbon fixation. High algal standing stocks and low phosphorusdeficiency in Tuesday Lake were attributed to low grazing pressureby small, inefficient zooplankton and possible limitation bynutrients other than phosphorus. Algal standing stocks werelow and phosphorus deficiency was high in Peter and Paul Lakes,in which the zooplankton was dominated by large grazers. Differentalgal size fractions experienced differing degrees of phosphorusdeficiency. These size fraction differences in P-deficiencyin Peter and Paul Lakes were attributed to differences in algalspecies composition and to differing levels of zooplankton grazingpressure and nutrient regeneration. A unimodal relationshipbetween relative nanoplankton biovolume and zooplankton biomasswas found and reflects the positive (nutrient regeneration)and negative (grazing mortality) effects of zooplankton on thealgal community.