Objective To investigate the instant clinical efficacy of intra-arterial infusion of fasudil combined with routine anti-vasospasm for symptomatic cerebral vasospasm (SCVS). Methods The clinical data of 21 patients with subarachnoid hemorrhage (SAH) due to ruptured aneurysm, who were admitted to authors' hospital during the period from May 2010 and February 2014, were retrospectively analyzed. The lesions included Fisher gradeⅡ(n=2), gradeⅢ (n=16) and gradeⅣ (n=3). Endovascular embolization of the aneurysm was carried out within 48 hours after the confirmation of the diagnosis with total cerebral DSA;no bleeding occurred during the operation and routine anti-vasospasm therapy was given. Within 4-9 days after the onset of the disease, all 21 patients presented SCVS. Half dose systemic heparinization, superselective intra-arterial infusion of fasudil (30 mg fasudil+250 ml saline, lasting for 30 min) were adopted. Reexamination of angiography performed at 15 min after fasudil infusion was employed, and the results were evaluated with NIHSS score by comparing the preoperative findings. Results Imaging examination performed after the treatment showed that significant improvement was obtained in 15 patients and no obvious changes in 6 patients. Clinical symptoms were remarkably improved in 11 patients, partially improved in 4 patients and remained unchanged in 6 patients. The mean NIHSS score was improved from preoperative 28.6 to postoperative 21.2. Conclusion For the treatment of symptomatic cerebral vasospasm, superselective intra-arterial infusion of fasudil is effective and safe, and it has good clinical application value.

Isolated vertigo due to vascular mechanisms manifests as vertigo, dizziness or imbalance only. Due to the lack of focal neurological symptoms or signs, it is often misdiagnosed as peripheral vestibular disease, resulting in serious adverse consequences. This article reviews the lesion location, cerebrovascular basis, clinical evaluation, and imaging examination of isolated vertigo caused by vascular mechanisms.

Single-cell RNA sequencing (scRNA-seq) is generally used for profiling transcriptome of individual cells.The droplet-based 10X Genomics Chromium (10X) approach and the plate-based Smart-seq2 full-length method are two frequently used scRNA-seq platforms,yet there are only a few thorough and systematic comparisons of their advantages and limitations.Here,by directly comparing the scRNA-seq data generated by these two platforms from the same samples of CD45-cells,we systematically evaluated their features using a wide spectrum of analyses.Smart-seq2 detected more genes in a cell,especially low abundance transcripts as well as alterna-tively spliced transcripts,but captured higher proportion of mitochondrial genes.The composite of Smart-seq2 data also resembled bulk RNA-seq data more.For 10X-based data,we observed higher noise for mRNAs with low expression levels.Approximately 10％-30％ of all detected tran-scripts by both platforms were from non-coding genes,with long non-coding RNAs (lncRNAs)accounting for a higher proportion in 10X.10X-based data displayed more severe dropout prob-lem,especially for genes with lower expression levels.However,10X-data can detect rare cell types given its ability to cover a large number of cells.In addition,each platform detected distinct groups of differentially expressed genes between cell clusters,indicating the different characteristics of these technologies.Our study promotes better understanding of these two platforms and offers the basis for an informed choice of these widely used technologies.

OBJECTIVE： To investigate the effects of Danhong injection （DHI） on gene expression profile of acute myocardial infarction （AMI） model rats. METHODS： Male SD rats were randomly divided into sham operation group， model group and DHI group （0.76 mL/kg）， with 10 rats in each group. AMI model was established by ligation of left anterior descending coronary artery in model group and DHI group. After modeling， sham operation group and model group were given constant volume of normal saline intramuscularly， and DHI group was given relevant medicine intramuscularly， once a day， for consecutive 14 days. After last administration， myocardial tissue in the marginal zone of infarction was separated. The change of gene expression profile was detected by gene chip technique. Using fold-change of relative expression as index， differentially expressed microRNA （miRNA） were screened. On the basis of retrieving their corresponding genes， gene ontology （GO） and KEGG pathway enrichment analysis were carried out by using DAVID bioinformatics resource database and KEGG pathway database， respectively. TargetScan database was used to predict the target gene messenger RNA （mRNA） corresponding to differentially expressed miRNA. Cytoscape 3.6.1 software was used to construct and analyze the miRNA-mRNA network. Agilent GeneSpring GX v11.5 software was used to screen target genes and miRNA related to inflammation in the above networks. RESULTS： Compared with sham operation group， there were 22 differentially expressed miRNAs in model group， 5 up-regulated and 17 down-regulated. Compared with model group， there were 26 differentially expressed miRNAs in DHI group， and all of them were up-regulated. The differentially expressed miRNAs related to DHI therapy for AMI included rno-let-7a-5p， rno-let-7d-5p， rno-let-7f-5p， rno-miR-26b-5p， rno-miR-29b-3p， cel-miR-39-3p， cel-miR-39-5p， rno-miR-142-5p， rno-miR-191a-5p， rno-miR-409a-3p. Results of GO analysis and KEGG pathway enrichment analysis showed that differentially expressed miRNAs were mainly concentrated in membrane-bound organelles， cytoplasm， endometrial system and other cell components. The molecular functions such as protein binding and ion binding were exerted through biological processes such as anatomical structure development， multicellular tissue development and development process，which were mainly enriched in calcium signaling pathway， PPAR signaling pathway， VEGF signaling pathway， cell apoptosis， glycosylphosphatidylinositol anchored biosynthesis， valine， leucine and isoleucine degradation， etc. miRNA-mRNA network analysis showed that there were 25 target gene mRNAs corresponding to differentially expressed miRNA and 24 miRNAs related to it. There were 6 inflammation-related target genes （IL6， IL1b， TNF， TLR4， CRP， CXCL12） in this network， involving 19 differentially expressed miRNAs. CONCLUSIONS： The therapeutic effect of DHI on AMI may be related to regulating the expression of related miRNA， affecting signal transduction of calcium ion， PPAR and VEGF pathways， and regulating the secretion of inflammatory markers such as interleukin， chemokine and C-reactive protein.