An Experimental Platform Generating Simulated Blunt Impacts to the Head Due to Rearward Falls.

Impacts to the back of the head due to rearward falls, also referred to as "backfall" events, represent a common source of TBI for athletes and soldiers. A new experimental apparatus is described for replicating the linear and rotational kinematics of the head during backfall events. An anthropomorphic test device (ATD) with a head-borne sensor suite was configured to fall backwards from a standing height, inducing contact between the rear of the head and a ground surface simulant. A pivoting swing arm and release strap were used to generate consistent and realistic head kinematics. Backfall experiments were performed with the ATD fitted with an American football helmet and the resulting linear and rotational head kinematics, as well as calculated injury metrics, compared favorably with those of football players undergoing similar impacts during games or play reconstructions. This test method complements existing blunt impact helmet performance experiments, such as drop tower and pneumatic ram test methods, which may not be able to fully reproduce head-neck-torso kinematics during a backfall event.

Cytoplasmic cleavage in living zoosporangia of Allomyces macrogynus.

We have used the vital fluorescent dye, FM4-64, as a marker of membrane development during zoospore formation in living zoosporangia of Allomyces macrogynus. Membrane development was visualized and documented using standard epifluorescence and laser scanning confocal microscopy. Video-enhanced light microscopy and transmission electron microscopy, using cryopreparation methods, were also employed in this study. In the first 10-12 min after the induction of zoospore formation, only the plasma membrane labelled with FM4-64. During this time, nuclei were strictly located in the cortical cytoplasm with their associated centrosomes positioned immediately adjacent to the plasma membrane (Lowry & Roberson, 1997). Between 12 and 20 min post-induction, increased fluorescence appeared along regions of the plasma membrane adjacent to the nuclei. From these sites, membranes (i.e. cleavage elements) extended laterally within the cortex and then, in conjunction with nuclear migration, rapidly elongated into the sporangial cytoplasm. By 25-35 min post-induction, cleavage elements had ramified throughout the cytoplasm forming a complex, interconnected membranous network. Transmission electron microscopy revealed that cleavage elements were paired membrane sheets with a lumen consisting of an electron opaque, granular matrix. Cleavage elements developed into a highly ordered network by 35-40 min post-induction, which fully delimited zoospore initials into polyhedral-shaped cells. Zoospore discharge occurred between 40 and 50 min post-induction. Our results have shown that cleavage elements undergo four stages of development during zoospore formation in A. macrogynus: (i) development of membrane initials, (ii) cortical extension, (iii) cytoplasmic elongation and ramification and (iv) zoospore initial delimitation.

Tomato chlorosis virus: a new whitefly-transmitted, Phloem-limited, bipartite closterovirus of tomato.

ABSTRACT Tomato chlorosis virus (ToCV) is the second whitefly-transmitted, phloem-limited, bipartite closterovirus described infecting tomato. ToCV is distinct from tomato infectious chlorosis virus (TICV), based on lack of serological and nucleic acid cross-reactions and differences in vector specificity. TICV is transmitted only by the greenhouse whitefly (Trialeurodes vaporariorum), whereas ToCV is transmitted by the greenhouse whitefly, the banded-wing whitefly (T. abutilonea), and Bemisia tabaci biotypes A and B (B. argentifolii). Double-stranded (ds) RNA analyses of ToCV show two prominent dsRNAs of approximately 7,800 and 8,200 bp, with several small dsRNAs. Digoxigenin-11-UTP-labeled riboprobes derived from cDNA clones representing portions of RNAs 1 and 2 were used in Northern blot hybridizations to detect two large nonhomologous dsRNAs and a subset of smaller dsRNAs. These probes were used in dot blot hybridizations to detect ToCV in infected tomato. Inclusion bodies and cytoplasmic vesicles were consistently observed in phloem tissues of ToCV-infected Nicotiana clevelandii. Computer-assisted sequence analysis showed significant homology between ToCV clones that hybridize specifically with RNAs 1 and 2 and the lettuce infectious yellows virus methyltransferase of RNA 1 and the HSP70 heat shock protein homolog of RNA 2, respectively. Thus, ToCV is another member of the growing subgroup of bipartite closteroviruses transmitted by whiteflies.