Epidemiological and etiological characteristics of viral meningitis for hospitalized pediatric patients in Yunnan, China.

BACKGROUND: Viral infection is the most common cause of aseptic meningitis. The purpose of this study was to identify the viruses responsible for aseptic meningitis to better understand the clinical presentations of this disease. METHOD: Between March 2009 and February 2010, we collected 297 cerebrospinal fluid specimens from children with aseptic meningitis admitted to a pediatric hospital in Yunnan (China). Viruses were detected by using "in house" real-time quantitative polymerase chain reaction or reverse-transcription real-time quantitative polymerase chain reaction from these samples. Phylogenetic analyses were conducted using the Molecular Evolutionary Genetic Analysis version 7.0 software, with the neighbor-joining method. RESULTS: Viral infection was diagnosed in 35 of the 297 children (11.8%). The causative viruses were identified to be enteroviruses in 25 cases (71.4%), varicella-zoster virus in 5 cases (14.3%), herpes simplex virus 1 in 2 cases (5.7%), and herpes simplex virus 2, Epstein-Barr virus, and human herpesvirus 6 in 1 case each (2.9% each). Of the enteroviruses, coxsackievirus B5 was the most frequently detected serotype (10/25 cases; 40.0%) and all coxsackievirus B5 strains belonged to C group. CONCLUSIONS: In the study, a causative virus was only found in the minority of cases, of them, enteroviruses were the most frequently detected viruses in patients with viral meningitis, followed by varicella-zoster virus and herpes simplex virus. Our findings underscore the need for enhanced surveillance and etiological study of aseptic meningitis.

Characterization of coxsackievirus A10 strains isolated from children with hand, foot, and mouth disease.

Hand, foot, and mouth disease (HFMD) is a contagious disease that threatens the health of children under 5 years of age. Coxsackievirus A10 (CV-A10) is one of the main pathogens of HFMD. Currently, preventive vaccines and specific therapeutic drugs are not available for CV-A10. In this study, a total of 327 stool specimens were collected from pediatric patients from 2009 to 2017 during HFMD surveillance, among which 14 CV-A10 strains could only be isolated from rhabdomyosarcoma cells, but not from KMB17 and Vero cells. Through adaptive culture, 2 and 11 CV-A10 strains were recovered from Vero and KMB17 cell cultures, respectively. The growth of CV-A10 strains in Vero cells was better than that in KMB17 cells. The 14 CV-A10 strains belonged to the F genotype, and the nucleotides and amino acids of their complete genomes shared 92.6%-96.3% and 98.4%-98.9% identities, respectively. The different CV-A10 strains exhibited varying virulence in vivo, but had similar effects on tissue injury, with the hind limb muscles, kidneys, and lungs being severely affected. Additionally, the hind limb muscles had the highest viral loads. CV-A10 was found to exhibit a strong tropism to muscle tissue. The results of this study are critical to developing vaccines against CV-A10 infections.

Characterization of Coxsackievirus A6 Strains Isolated From Children With Hand, Foot, and Mouth Disease.

Coxsackievirus A6 (CVA6) is a key pathogen causing hand, foot and mouth disease (HFMD). However, there are currently no specific antiviral drugs or vaccines for treating infections caused by CVA6. In this study, human rhabdomyosarcoma (RD), African green monkey kidney (Vero), and human embryonic lung diploid fibroblast (KMB17) cells were used to isolate CVA6 from 327 anal swab and fecal samples obtained during HFMD monitoring between 2009 and 2017. The VP1 genes of the isolates were sequenced and genotyped, and the biological characteristics of the representative CVA6 strains were analyzed. A total of 37 CVA6 strains of the D3 gene subtypes were isolated from RD cells, all of which belonged to the epidemic strains in mainland China. Using the adaptive culture method, 10 KMB17 cell-adapted strains were obtained; however, no Vero cell-adapted strains were acquired. Among the KMB17 cell-adapted strains, only KYN-A1205 caused disease or partial death in suckling mice, and its virulence was stronger than its RD cell-adapted strain. The pathogenic KYN-A1205 strain caused strong tropism to the muscle tissue and led to pathological changes, including muscle necrosis and nuclear fragmentation in the forelimb and hindlimb. Sequence analysis demonstrated that the KYN-A1205 strain exhibited multiple amino acid mutations after KMB17 cell adaptation. Moreover, it showed strong pathogenicity, good immunogenicity and genetic stability, and could be used as an experimental CVA6 vaccine candidate.

Instant Self-Assembly Peptide Hydrogel Encapsulation with Fibrous Alginate by Microfluidics for Infected Wound Healing.

Infected wounds caused by persistent inflammation exhibit poor vascularization and cellular infiltration. In order to rapidly control the inflammatory effect and accelerate wound healing, it is necessary to develop a novel drug vehicle addressing the need for infected wounds. Herein, we developed a novel dual-drug delivery system with micrometer-scale alginate fibers encapsulated in instant self-assembly peptide hydrogel. Short peptides with the sequence of Nap-Gly-Phe-Phe-Lys-His (Nap-GFFKH) could self-assemble outside the microfluidic-based alginate microfibers in weak acidic solution (pH ≈ 6.0) within 5 s. The gelation condition is close to the pH environment of the human skin. We further constructed recombinant bovine basic fibroblast growth factor (FGF-2) in fibrous alginate, which was encapsulated in antibiotic-loaded peptide hydrogel. The dual-drug delivery system exhibited good mechanical property and sustained release profiles, where antibiotic could be rapidly released from the peptide hydrogel, while the growth factor could be gradually released within 7 days. Both in vitro antibacterial experiments and in vivo animal experiments confirmed that such a dual-drug delivery system has good antibacterial activity and enhances wound healing property. We suggested that the dual-drug delivery system could be potentially applied for controlled drug release in infected wound healing, drug combination for melanoma therapy, and tissue engineering.