华东和华南地区商品猪戊型肝炎病毒携带率和基因分型分析

Objective To determine the prevalence and genotype of hepatitis E virus (HEV)among commercial swine population in Eastern and Southern China. Methods Six hundred specimens of swine bile collected from 5 slaughterhouses in Eastern and Southern China from 2007 to 2009 were tested for HEV RNA using nested RT-PCR. PCR products were sequenced for phylogenetic analysis. Results Forty-seven out of the 600 samples (7.83%) were positive for HEV RNA. Based on the 150 nt fragment within HEV ORF2, data from phylogenetic analysis revealed that all the 47 HEV isolates were identified to be genotype Ⅳ, sharing 75.0%-83.4%, 75.0%-84.6%, 71.9%-80.7% and 88.1%-91.5% nucleotide identities with prototype Ⅰ,Ⅱ,Ⅲ and Ⅳ HEV strains respectively while majority of the isolates clustered within their respective isolation sites. Conclusion HEV was widespread in commercial swine population in Eastern and Southern China that raised a serious concern about the safety regarding the consumption of pork products.     

甲型H1N1流行性感冒病毒血凝素蛋白基因进化研究

Objective To determine the evolutionary rate and divergence time of influenza A virus HA gene isolated recently worldwide pandemic and explore the origin and its transmission. Methods A total of 344 HI sequences available in the GenBank (including 248 isolated from human, 84 from swine, 11 from avian, and 1 from ferret) and 7 isolated in Shanghai were collected. The nucleotide substitution rate and time to most recent common ancestor (tMRCA) was calculated using molecular clock theory and Bayesian Skyline Plot (BSP) based on Markov chain Monte Carlo. Then genetic phylogeny was constructed referring to posterior distribution. Results It was found that H1 sequences in the US from human, swine and avian were clustered significantly with swine H1 ones from Asia phylogenetieally (Cluster US). The second cluster (Cluster Eurasian Human) nearly consisted of human H1 sequences isolated in other regions. The third cluster (Cluster Eurasian Animal) consisted of swine and avian H1 sequences from China and Italy respectively. As for all the H1 sequences, the evolutionary rate was of 2.57×10-3substitutions/site per year averagely (95% Highest Posterior Density: 1.96×10-3-3.03×10-3/site per year). The estimated dates for tMRCA of human H1 in Europe and swine H1 in the mainland of China were the earliest, with the corresponding rates of 6.46×10-3/site per year and 0.97×10-3/site per year respectively. The tMRCAs of human and swine H1 sequences from the US were similar, with the rates of 5.86×10-3/site per year and 5.02×10-3/site per year. Conclusion The present flu outbreak was possibly induced by long-term circulation of influenza A virus (H1 N1) in human population and swine herds in America. There was no evidence proving that influenza virus in China involved in the present outbreak.     

甲型H1N1流行性感冒病毒血凝素蛋白基因进化研究

Objective To determine the evolutionary rate and divergence time of influenza A virus HA gene isolated recently worldwide pandemic and explore the origin and its transmission. Methods A total of 344 HI sequences available in the GenBank (including 248 isolated from human, 84 from swine, 11 from avian, and 1 from ferret) and 7 isolated in Shanghai were collected. The nucleotide substitution rate and time to most recent common ancestor (tMRCA) was calculated using molecular clock theory and Bayesian Skyline Plot (BSP) based on Markov chain Monte Carlo. Then genetic phylogeny was constructed referring to posterior distribution. Results It was found that H1 sequences in the US from human, swine and avian were clustered significantly with swine H1 ones from Asia phylogenetieally (Cluster US). The second cluster (Cluster Eurasian Human) nearly consisted of human H1 sequences isolated in other regions. The third cluster (Cluster Eurasian Animal) consisted of swine and avian H1 sequences from China and Italy respectively. As for all the H1 sequences, the evolutionary rate was of 2.57×10-3substitutions/site per year averagely (95% Highest Posterior Density: 1.96×10-3-3.03×10-3/site per year). The estimated dates for tMRCA of human H1 in Europe and swine H1 in the mainland of China were the earliest, with the corresponding rates of 6.46×10-3/site per year and 0.97×10-3/site per year respectively. The tMRCAs of human and swine H1 sequences from the US were similar, with the rates of 5.86×10-3/site per year and 5.02×10-3/site per year. Conclusion The present flu outbreak was possibly induced by long-term circulation of influenza A virus (H1 N1) in human population and swine herds in America. There was no evidence proving that influenza virus in China involved in the present outbreak.     

甲型H1N1流行性感冒病毒血凝素蛋白基因进化研究

Objective To determine the evolutionary rate and divergence time of influenza A virus HA gene isolated recently worldwide pandemic and explore the origin and its transmission. Methods A total of 344 HI sequences available in the GenBank (including 248 isolated from human, 84 from swine, 11 from avian, and 1 from ferret) and 7 isolated in Shanghai were collected. The nucleotide substitution rate and time to most recent common ancestor (tMRCA) was calculated using molecular clock theory and Bayesian Skyline Plot (BSP) based on Markov chain Monte Carlo. Then genetic phylogeny was constructed referring to posterior distribution. Results It was found that H1 sequences in the US from human, swine and avian were clustered significantly with swine H1 ones from Asia phylogenetieally (Cluster US). The second cluster (Cluster Eurasian Human) nearly consisted of human H1 sequences isolated in other regions. The third cluster (Cluster Eurasian Animal) consisted of swine and avian H1 sequences from China and Italy respectively. As for all the H1 sequences, the evolutionary rate was of 2.57×10-3substitutions/site per year averagely (95% Highest Posterior Density: 1.96×10-3-3.03×10-3/site per year). The estimated dates for tMRCA of human H1 in Europe and swine H1 in the mainland of China were the earliest, with the corresponding rates of 6.46×10-3/site per year and 0.97×10-3/site per year respectively. The tMRCAs of human and swine H1 sequences from the US were similar, with the rates of 5.86×10-3/site per year and 5.02×10-3/site per year. Conclusion The present flu outbreak was possibly induced by long-term circulation of influenza A virus (H1 N1) in human population and swine herds in America. There was no evidence proving that influenza virus in China involved in the present outbreak.     

甲型H1N1流行性感冒病毒血凝素蛋白基因进化研究

Objective To determine the evolutionary rate and divergence time of influenza A virus HA gene isolated recently worldwide pandemic and explore the origin and its transmission. Methods A total of 344 HI sequences available in the GenBank (including 248 isolated from human, 84 from swine, 11 from avian, and 1 from ferret) and 7 isolated in Shanghai were collected. The nucleotide substitution rate and time to most recent common ancestor (tMRCA) was calculated using molecular clock theory and Bayesian Skyline Plot (BSP) based on Markov chain Monte Carlo. Then genetic phylogeny was constructed referring to posterior distribution. Results It was found that H1 sequences in the US from human, swine and avian were clustered significantly with swine H1 ones from Asia phylogenetieally (Cluster US). The second cluster (Cluster Eurasian Human) nearly consisted of human H1 sequences isolated in other regions. The third cluster (Cluster Eurasian Animal) consisted of swine and avian H1 sequences from China and Italy respectively. As for all the H1 sequences, the evolutionary rate was of 2.57×10-3substitutions/site per year averagely (95% Highest Posterior Density: 1.96×10-3-3.03×10-3/site per year). The estimated dates for tMRCA of human H1 in Europe and swine H1 in the mainland of China were the earliest, with the corresponding rates of 6.46×10-3/site per year and 0.97×10-3/site per year respectively. The tMRCAs of human and swine H1 sequences from the US were similar, with the rates of 5.86×10-3/site per year and 5.02×10-3/site per year. Conclusion The present flu outbreak was possibly induced by long-term circulation of influenza A virus (H1 N1) in human population and swine herds in America. There was no evidence proving that influenza virus in China involved in the present outbreak.     

甲型H1N1流行性感冒病毒血凝素蛋白基因进化研究

Objective To determine the evolutionary rate and divergence time of influenza A virus HA gene isolated recently worldwide pandemic and explore the origin and its transmission. Methods A total of 344 HI sequences available in the GenBank (including 248 isolated from human, 84 from swine, 11 from avian, and 1 from ferret) and 7 isolated in Shanghai were collected. The nucleotide substitution rate and time to most recent common ancestor (tMRCA) was calculated using molecular clock theory and Bayesian Skyline Plot (BSP) based on Markov chain Monte Carlo. Then genetic phylogeny was constructed referring to posterior distribution. Results It was found that H1 sequences in the US from human, swine and avian were clustered significantly with swine H1 ones from Asia phylogenetieally (Cluster US). The second cluster (Cluster Eurasian Human) nearly consisted of human H1 sequences isolated in other regions. The third cluster (Cluster Eurasian Animal) consisted of swine and avian H1 sequences from China and Italy respectively. As for all the H1 sequences, the evolutionary rate was of 2.57×10-3substitutions/site per year averagely (95% Highest Posterior Density: 1.96×10-3-3.03×10-3/site per year). The estimated dates for tMRCA of human H1 in Europe and swine H1 in the mainland of China were the earliest, with the corresponding rates of 6.46×10-3/site per year and 0.97×10-3/site per year respectively. The tMRCAs of human and swine H1 sequences from the US were similar, with the rates of 5.86×10-3/site per year and 5.02×10-3/site per year. Conclusion The present flu outbreak was possibly induced by long-term circulation of influenza A virus (H1 N1) in human population and swine herds in America. There was no evidence proving that influenza virus in China involved in the present outbreak.     

甲型H1N1流行性感冒病毒血凝素蛋白基因进化研究

Objective To determine the evolutionary rate and divergence time of influenza A virus HA gene isolated recently worldwide pandemic and explore the origin and its transmission. Methods A total of 344 HI sequences available in the GenBank (including 248 isolated from human, 84 from swine, 11 from avian, and 1 from ferret) and 7 isolated in Shanghai were collected. The nucleotide substitution rate and time to most recent common ancestor (tMRCA) was calculated using molecular clock theory and Bayesian Skyline Plot (BSP) based on Markov chain Monte Carlo. Then genetic phylogeny was constructed referring to posterior distribution. Results It was found that H1 sequences in the US from human, swine and avian were clustered significantly with swine H1 ones from Asia phylogenetieally (Cluster US). The second cluster (Cluster Eurasian Human) nearly consisted of human H1 sequences isolated in other regions. The third cluster (Cluster Eurasian Animal) consisted of swine and avian H1 sequences from China and Italy respectively. As for all the H1 sequences, the evolutionary rate was of 2.57×10-3substitutions/site per year averagely (95% Highest Posterior Density: 1.96×10-3-3.03×10-3/site per year). The estimated dates for tMRCA of human H1 in Europe and swine H1 in the mainland of China were the earliest, with the corresponding rates of 6.46×10-3/site per year and 0.97×10-3/site per year respectively. The tMRCAs of human and swine H1 sequences from the US were similar, with the rates of 5.86×10-3/site per year and 5.02×10-3/site per year. Conclusion The present flu outbreak was possibly induced by long-term circulation of influenza A virus (H1 N1) in human population and swine herds in America. There was no evidence proving that influenza virus in China involved in the present outbreak.     

甲型H1N1流行性感冒病毒血凝素蛋白基因进化研究

Objective To determine the evolutionary rate and divergence time of influenza A virus HA gene isolated recently worldwide pandemic and explore the origin and its transmission. Methods A total of 344 HI sequences available in the GenBank (including 248 isolated from human, 84 from swine, 11 from avian, and 1 from ferret) and 7 isolated in Shanghai were collected. The nucleotide substitution rate and time to most recent common ancestor (tMRCA) was calculated using molecular clock theory and Bayesian Skyline Plot (BSP) based on Markov chain Monte Carlo. Then genetic phylogeny was constructed referring to posterior distribution. Results It was found that H1 sequences in the US from human, swine and avian were clustered significantly with swine H1 ones from Asia phylogenetieally (Cluster US). The second cluster (Cluster Eurasian Human) nearly consisted of human H1 sequences isolated in other regions. The third cluster (Cluster Eurasian Animal) consisted of swine and avian H1 sequences from China and Italy respectively. As for all the H1 sequences, the evolutionary rate was of 2.57×10-3substitutions/site per year averagely (95% Highest Posterior Density: 1.96×10-3-3.03×10-3/site per year). The estimated dates for tMRCA of human H1 in Europe and swine H1 in the mainland of China were the earliest, with the corresponding rates of 6.46×10-3/site per year and 0.97×10-3/site per year respectively. The tMRCAs of human and swine H1 sequences from the US were similar, with the rates of 5.86×10-3/site per year and 5.02×10-3/site per year. Conclusion The present flu outbreak was possibly induced by long-term circulation of influenza A virus (H1 N1) in human population and swine herds in America. There was no evidence proving that influenza virus in China involved in the present outbreak.     

甲型H1N1流行性感冒病毒血凝素蛋白基因进化研究

Objective To determine the evolutionary rate and divergence time of influenza A virus HA gene isolated recently worldwide pandemic and explore the origin and its transmission. Methods A total of 344 HI sequences available in the GenBank (including 248 isolated from human, 84 from swine, 11 from avian, and 1 from ferret) and 7 isolated in Shanghai were collected. The nucleotide substitution rate and time to most recent common ancestor (tMRCA) was calculated using molecular clock theory and Bayesian Skyline Plot (BSP) based on Markov chain Monte Carlo. Then genetic phylogeny was constructed referring to posterior distribution. Results It was found that H1 sequences in the US from human, swine and avian were clustered significantly with swine H1 ones from Asia phylogenetieally (Cluster US). The second cluster (Cluster Eurasian Human) nearly consisted of human H1 sequences isolated in other regions. The third cluster (Cluster Eurasian Animal) consisted of swine and avian H1 sequences from China and Italy respectively. As for all the H1 sequences, the evolutionary rate was of 2.57×10-3substitutions/site per year averagely (95% Highest Posterior Density: 1.96×10-3-3.03×10-3/site per year). The estimated dates for tMRCA of human H1 in Europe and swine H1 in the mainland of China were the earliest, with the corresponding rates of 6.46×10-3/site per year and 0.97×10-3/site per year respectively. The tMRCAs of human and swine H1 sequences from the US were similar, with the rates of 5.86×10-3/site per year and 5.02×10-3/site per year. Conclusion The present flu outbreak was possibly induced by long-term circulation of influenza A virus (H1 N1) in human population and swine herds in America. There was no evidence proving that influenza virus in China involved in the present outbreak.     

甲型H1N1流行性感冒病毒血凝素蛋白基因进化研究

Objective To determine the evolutionary rate and divergence time of influenza A virus HA gene isolated recently worldwide pandemic and explore the origin and its transmission. Methods A total of 344 HI sequences available in the GenBank (including 248 isolated from human, 84 from swine, 11 from avian, and 1 from ferret) and 7 isolated in Shanghai were collected. The nucleotide substitution rate and time to most recent common ancestor (tMRCA) was calculated using molecular clock theory and Bayesian Skyline Plot (BSP) based on Markov chain Monte Carlo. Then genetic phylogeny was constructed referring to posterior distribution. Results It was found that H1 sequences in the US from human, swine and avian were clustered significantly with swine H1 ones from Asia phylogenetieally (Cluster US). The second cluster (Cluster Eurasian Human) nearly consisted of human H1 sequences isolated in other regions. The third cluster (Cluster Eurasian Animal) consisted of swine and avian H1 sequences from China and Italy respectively. As for all the H1 sequences, the evolutionary rate was of 2.57×10-3substitutions/site per year averagely (95% Highest Posterior Density: 1.96×10-3-3.03×10-3/site per year). The estimated dates for tMRCA of human H1 in Europe and swine H1 in the mainland of China were the earliest, with the corresponding rates of 6.46×10-3/site per year and 0.97×10-3/site per year respectively. The tMRCAs of human and swine H1 sequences from the US were similar, with the rates of 5.86×10-3/site per year and 5.02×10-3/site per year. Conclusion The present flu outbreak was possibly induced by long-term circulation of influenza A virus (H1 N1) in human population and swine herds in America. There was no evidence proving that influenza virus in China involved in the present outbreak.     

Europe and hospitals--strengths and requirements

Hospitals all over Europe must get ready to face the important challenge of 1993 at all levels: micro-economic, macro-economic, local, regional and European. Despite the liberalization trends which will inevitably appear with the increased freedom of exchange and movement, hospitals must strive to remain havens of peace to patients.     

护士职业礼仪与整体护理研究

整体护理强调的是以病人为中心，以护理程序为核心，有系统的对病人进行身心整体护理。整体护理是否见效，在很大程度上取决于护士的职业素质。从我院开展的整体护理模式病房工作成效分析，在学习新模式，转变传统护理观念的同时，同样要重视护士职业礼仪的教育，这样既提高整体护理的理论知识，     

Overweight and obesity in children and adolescents and preventative measures

The prevalence of overweight and obesity in children is increasing rapidly. This is alarming because obesity is associated with severe chronic diseases, such as type 2 diabetes mellitus. Obesity at young age is related to obesity at adult age. Consequently, the prevention of overweight from childhood onwards is an important issue. Apart from diabetes mellitus type 2 there is an increased risk of orthopaedic complications, respiratory problems, fertility problems, cardiovascular diseases and psychosocial consequences in the form of a negative self-image, emotional and behavioural problems and depression. Environmental and behavioural factors are regarded as the most important causes of the rapid increase in the prevalence of overweight and as the most important starting points for prevention. Most prevention programmes are still in the initial stages. Prevention programmes aimed at stimulating breast feeding and daily physical activity (playing outside) and the restriction of sweetened drinks and watching TV are very promising. With such preventive measures the involvement of both the school and the parents is important.