ObjectiveTo study the mechanism of nimodipine combined with electroacupuncture therapeutics protecting rats from cerebral ischemia and reperfusion injury.Methods60 rats were divided randomly into 3 groups, 24 rats in treatment group that accepted nimodipine combined with electroacupuncture therapy after middle cerebral artery occlusion (MCAO) for one hour, and 24 in control group,which acceptd normal saline after ischemia and reperfusion injury, and 12 rats in normal group. One or three days later, all rats were decapitated and their brains were extracted for superoxide dismutase(SOD) activity and malonaldehyde(MDA) concentration assay. And immunohistochemistry was used to detect the expression of growth associated protein 43(GAP-43),microtubule associated protein 2(MAP-2) and cyclin D1 protein.ResultsAfter ischemia and reperfusion injury,SOD activity markedly decreased in both treatment and control group while MDA concentration increased, compared with normal group(P<0.01).Level of MAP-2 expression in treatment and control group was markedly lower than normal group(P<0.01), while levels of GAP-43 and cyclin D1 expression were higher (P<0.01). Contrasted to control group, SOD activity was higher and MDA concentration was lower in treatment group. Level of GAP-43 and MAP-2 expression in treatment group were higher than those in control group, while level of cyclin D1 lower. Differences between treatment group and control group were significent(P<0.01).ConclusionsNimodipine combined with electroacupuncture therapeutics can prevent brains from ischemia and reperfusion injury. It's actions of wiping free radicals out, inhibiting apoptosis and protein hydrolysis and promoting nerve regeneration are involved in the mechanism.

Bivalves are species-rich mollusks with prominent protective roles in coastal ecosystems.Across these ancient lineages,colony-founding larvae anchor themselves either by byssus produc-tion or by cemented attachment.The latter mode of sessile life is strongly molded by left-right shell asymmetry during larval development of Ostreoida oysters such as Crassostrea hongkongensis.Here,we sequenced the genome of C.hongkongensis in high resolution and compared it to reference bivalve genomes to unveil genomic determinants driving cemented attachment and shell asymmetry.Importantly,loss of the homeobox gene Antennapedia(Antp)and broad expansion of lineage-specific extracellular gene families are implicated in a shift from byssal to cemented attachment in bivalves.Comparative transcriptomic analysis shows a conspicuous divergence between left-right asymmetrical C.hongkongensis and symmetrical Pinctada fucata in their expression profiles.Especially,a couple of orthologous transcription factor genes and lineage-specific shell-related gene families including that encoding tyrosinases are elevated,and may cooperatively govern asymmet-rical shell formation in Ostreoida oysters.