MRI-based brain volumes of preterm infants at term: a systematic review and meta-analysis.

BACKGROUND: MRI allows a detailed assessment of brain structures in preterm infants, outperforming cranial ultrasound. Neonatal MR-based brain volumes of preterm infants could serve as objective, quantitative and reproducible surrogate parameters of early brain development. To date, there are no reference values for preterm infants' brain volumes at term-equivalent age. OBJECTIVE: Systematic review of the literature to determine reference ranges for MRI-based brain volumes of very preterm infants at term-equivalent age. METHODS: PubMed Database was searched on 6 April 2020 for studies reporting MR-based brain volumes on representative unselected populations of very preterm and/or very low birthweight infants examined at term equivalent age (defined as 37-42 weeks mean postmenstrual age at MRI). Analyses were limited to volumetric parameters reported in >3 studies. Weighted mean volumes and SD were both calculated and simulated for each parameter. RESULTS: An initial 367 publications were identified. Following application of exclusion criteria, 13 studies from eight countries were included for analysis, yielding four parameters. Weighted mean total brain volume was 379 mL (SD 72 mL; based on n=756). Cerebellar volume was 21 mL (6 mL; n=791), cortical grey matter volume 140 mL (47 mL; n=572) and weighted mean volume of unmyelinated white matter was 195 mL (38 mL; n=499). CONCLUSION: This meta-analysis reports pooled data on several brain and cerebellar volumes which can serve as reference for future studies assessing MR-based volumetric parameters as a surrogate outcome for neurodevelopment and for the interpretation of individual or cohort MRI-based volumetric findings.

Three new species of Scolytoplatypus Schaufuss from China, and notes on the movement and functions of the prosternal processes (Coleoptera: Curculionidae: Scolytinae).

Three new species from China (Yunnan), Scolytoplatypus costatus Gebhardt Beaver, S. geminus Gebhardt Beaver and S. peniculatus Gebhardt Beaver, are described and compared with related species of the genus. The male prosternum of Asian Scolytoplatypus species shows species-specific characters, and frequently bears a pair of processes on or close to the anterior margin. We comment here for the first time on the movement of the processes and their likely functions, and survey their occurrence in Asian species of Scolytoplatypus.

How can two soft bodied animals be precisely connected? a miniature quick-connect system in the slugs, Arion lusitanicus and Arion rufus.

Among stylommatophoran gastropods, many species have simplified or reduced their copulatory organs, for example, within the Arionidae, many species lack penes. In this study, I ask two questions 1) How are soft bodied slugs which do not possess a penis connected during copulation? and 2) Is there a mechanical isolating barrier between related sympatric slug species? Observations on the mating behavior and the functional morphology of the distal genital apparatus were made in a mixed population of Arion lusitanicus and Arion rufus. The investigated Arion species exhibit an elaborate copulation process with a quick genital coupling. Prior to full eversion of the distal genitalia, the genital coupling proceeds inside the atrium cavity of one of the partners. This is in contrast to the symmetrical mutual eversion in penis-bearing species. The donor-recipient channels are tightly connected to one after another and fit precisely. During copulation, the jelly-coated spermatophore of the donor is pressed out into the connected channel of the partner, where it is implanted only with its frontal part. In the field, successful interspecific matings in terms of spermatophore transfer were rarely observed. The observations presented indicate a mechanical barrier which may profoundly influence the intraspecific and interspecific mating success.

A hairy business-periostracal hair formation in two species of helicoid snails (gastropoda, stylommatophora, helicoidea).

In molluscs, the calcareous shell is covered externally by a thin organic layer, the periostracum. The periostracum of some pulmonate species is of special taxonomic interest because it bears distinct microscale architectures. Where and how these structures are formed is as yet unknown. Using histological sections through their shells, gelatin cuts, and live observations I studied the pattern by which the periostracal hair-like projections in two helicoid land snail species are secreted and evenly arranged on the shell. The results indicate a complex mechanism: a hair is formed in the periostracal groove independently of the periostracum, after which it is attached to the edge of the shell, drawn out of the tissue, and finally swivelled to the upper side of the periostracum. Upon further growth of the periostracum, the hairs are finally fixed upright on the shell.

Active camouflage with lichens in a terrestrial snail, Napaeus (N.) barquini Alonso and Ibáñez, 2006 (Gastropoda, Pulmonata, Enidae).

Napaeus barquini Alonso and Ibáñez, 2006, from La Gomera, Canary Islands, lives most commonly on open rock faces covered with crustose lichens. In living specimens, the surface of the shell is covered with a lichen layer that is arranged in the form of protuberances, thereby considerably altering the appearance of the shell. Some of these protuberances may even extend beyond the tip of the shell. The way that these lichens are positioned on the shell and the manner in which they adhere were investigated. The snail grazes lichen material from the substrate and applies it to the surface of its shell in a standardized pattern of movements. The snail uses its mouth to place the moist material onto the shell and to form it into protuberances that adhere as they dry out. To do this, Napaeus barquini extends its body far beyond the shell margin so that it can reach the entire outer surface of the shell and cover it with protuberances, presumably as camouflage.