Relative in vitro growth rates of duckweeds (Lemnaceae) - the most rapidly growing higher plants.

Relative growth rates (RGR), doubling times (DT) and relative weekly yields (RY) of 39 clones (ecotypes) from 13 species representing all five genera of duckweeds were determined under standardised cultivation conditions. RGR ranged overall from 0.153 to 0.519 day(-1) , DT from 1.34 to 4.54 days and RY from 2.9 to 37.8 week(-1) . The RGR and RY data can be compared directly to other published findings to only a limited extent on account of missing clonal designations for and limited accessibility to previously investigated clones, as well as the use of different data denominators. However, they are consistent with the published results of other comparative duckweed studies of similar scope in showing that RGR does not vary primarily at the level of the genus or species, but rather reflects the adaptation of individual clones to specific local conditions. The RGR data support the widely held assumption that duckweeds can grow faster than other higher plants and that they can thus surpass land-based agricultural crops in productivity. Duckweeds are highly promising for the production of biomass for nutrition and energy, but extensive clonal comparison will be required to identify the most suitable isolates for this purpose.

Introducing a mouse model of brain death.

Experimental animal models of brain death increasing intracranial pressure (ICP) by inflating an intracranial placed balloon-catheter are well established and used in transplant-associated studies. Our aim was to develop an experimental mouse model of brain death (BD) and to compare explosive and gradual brain death induction under ICP monitoring. We therefore induced BD in female OF-1 mice by injecting 40 microl saline every 5 min into an intracranial placed balloon increasing ICP rapidly [BD ex, n=7], or gradually [BD grad, n=7] with 20 microl volume every 5 min under electroencephalogram (EEG) and ICP monitoring until BD occurred. The major criterion for BD was a flat-line-EEG, confirmed by cessation of spontaneous respiration and maximally dilated and fixed pupils. ICP, central activity and heart rate were continuously monitored during the entire 6h follow-up. In sham-operated controls [control, n=7] a burr hole was drilled but no balloon inserted. The BD groups showed equal ICP levels at the time of BD. Both groups had increased heart rates (HR) 15 min after BD, HR decreased to 402+/-29.39 bpm (beats per minute) [BD ex] and 409.33+/-26.46 bpm [BD grad] (n.s. vs. control) by 30 min after the inflation of the balloon, but only BD ex showed a significant decrease in HR compared to control, progressively decreasing thereafter. On the basis of these results, we conclude that the mouse model of brain death can be performed in a standardized, reproducible and successful way.