The loss of topography in the microbial communities of the upper respiratory tract in the elderly.
about
Age-Associated Microbial Dysbiosis Promotes Intestinal Permeability, Systemic Inflammation, and Macrophage Dysfunction.The effects of inhaled aztreonam on the cystic fibrosis lung microbiome.Kisameet Glacial Clay: an Unexpected Source of Bacterial Diversity.Dendritic Cell-Airway Epithelial Cell Cross-Talk Changes with Age and Contributes to Chronic Lung Inflammatory Diseases in the ElderlyBacterial microbiome in the nose of healthy cats and in cats with nasal diseaseComposition and immunological significance of the upper respiratory tract microbiota.Defective NOD2 peptidoglycan sensing promotes diet-induced inflammation, dysbiosis, and insulin resistance.Human pharyngeal microbiome may play a protective role in respiratory tract infections.Culture and molecular-based profiles show shifts in bacterial communities of the upper respiratory tract that occur with age.Ecobiotherapy Rich in Firmicutes Decreases Susceptibility to Colitis in a Humanized Gnotobiotic Mouse Model.The role of the local microbial ecosystem in respiratory health and disease.Microbiota and host determinants of behavioural phenotype in maternally separated mice.The Microbiome: The Trillions of Microorganisms That Maintain Health and Cause Disease in Humans and Companion Animals.Pregnancy-related changes in the maternal gut microbiota are dependent upon the mother's periconceptional dietIntestinal microbiota modulates gluten-induced immunopathology in humanized mice.The development and application of a molecular community profiling strategy to identify polymicrobial bacterial DNA in the whole blood of septic patientsStreptococcus pneumoniae Colonization Disrupts the Microbial Community within the Upper Respiratory Tract of Aging MiceAssessment of the Microbial Constituents of the Home Environment of Individuals with Cystic Fibrosis (CF) and Their Association with Lower Airways Infections.A multidimensional approach to the management of severe asthma: Inflammometry, molecular microbiology and bronchial thermoplastySHP-2 Phosphatase Prevents Colonic Inflammation by Controlling Secretory Cell Differentiation and Maintaining Host-Microbiota Homeostasis.Capturing the diversity of the human gut microbiota through culture-enriched molecular profilingA comparison of intestinal microbiota in a population of low-risk infants exposed and not exposed to intrapartum antibiotics: The Baby & Microbiota of the Intestine cohort study protocolLongitudinal sampling of the lung microbiota in individuals with cystic fibrosis.Milk Fat Globule Membrane Supplementation in Formula Modulates the Neonatal Gut Microbiome and Normalizes Intestinal Development.The human microbiome: opportunities and challenges for clinical care.Immune ageing and susceptibility to Streptococcus pneumoniae.Ethnic and diet-related differences in the healthy infant microbiome.The respiratory tract microbiome and lung inflammation: a two-way street.Differential responses of human dendritic cells to metabolites from the oral/airway microbiome.The Evolving Cystic Fibrosis Microbiome: A Comparative Cohort Study Spanning 16 Years.Streptococcus pneumoniae colonization is required to alter the nasal microbiota in cigarette smoke-exposed mice.Changes in Composition of the Gut Bacterial Microbiome after Fecal Microbiota Transplantation for Recurrent Clostridium difficile Infection in a Pediatric Heart Transplant Patient.The Nasopharyngeal Microbiota of Children With Respiratory Infections in Botswana.Reemergence of Lower-Airway Microbiota in Lung Transplant Patients with Cystic Fibrosis.Comparison of the Microbiota of Older Adults Living in Nursing Homes and the Community.Non-digestible oligosaccharides directly regulate host kinome to modulate host inflammatory responses without alterations in the gut microbiota.Inflammaging and the Lung.Association of high-risk sexual behaviour with diversity of the vaginal microbiota and abundance of Lactobacillus.Acetylcholine-producing T cells in the intestine regulate antimicrobial peptide expression and microbial diversity.Intrapartum antibiotics for GBS prophylaxis alter colonization patterns in the early infant gut microbiome of low risk infants.
P2860
Q33567407-A9A3DC94-61E1-4502-ADC5-ABAECD2228CCQ33644835-C949D5B7-CF76-487C-9043-C0071FB20101Q33721337-4F5A121F-AD71-4C44-B12E-B594678BE426Q33838704-F5C1E927-D466-451E-B1DC-212EF5A37C26Q33853557-DCBE1BC4-FBEA-4C19-BF32-B830A2CB06DEQ34542383-78726E3F-19CE-4854-B35A-38D205EB41F2Q35192440-43C0FFC7-5C9D-4021-975B-D201F870D8BAQ35192938-EBE684E4-33C8-40B5-BCD7-F37190912B11Q35536029-B7BA078C-A78F-4457-8524-2E2CB45F7FE9Q35659344-8179B970-C6A0-4B2F-9AC8-6749B3BD1F07Q35684946-0AC78A5B-7BC7-4BC9-8697-2679E0495425Q35720168-5BB3C7A4-4121-4C99-ACBF-E8D0B7B1A8DCQ35721841-C54F0AEC-5495-4753-BE66-F2855C688173Q35760173-539C9CD5-5A82-4C09-8A6A-2A97DFA7093EQ35803031-C8F7132E-E1A3-464D-B06E-5E401AF6E61DQ35810781-53EB88FF-5DCE-4B4D-BC6C-A60B022D15C5Q35898594-E1017C10-B747-424A-9B58-BD870985116EQ35918209-0A94EA83-7635-49FC-BF1F-4D5C5E92D1E6Q35934380-8C0C995D-8475-45B2-A52E-7F17A2791079Q35995768-D6659F7C-C46C-4B23-837E-CDDB8E430884Q36065363-F5F22809-154A-417C-ACBE-38340D4B186AQ36189178-AB3E4A45-04A4-4D50-8518-385FB737E85AQ36295243-AFABCFE0-D631-4042-ADA9-437152571B08Q37723925-B82EC271-0093-4DE8-A274-510046DF0816Q38274423-C7584A6A-8F41-4692-AC0E-85067D5ACEADQ38608479-A0565369-6F02-48ED-9DFA-B7C911CE54DFQ38737986-46A69D4A-A188-4594-80EC-9B0C5FAD164FQ38783008-65D8428C-B98C-4FAA-BA41-74B782035EBDQ38962869-9DC121BA-F5ED-425B-864A-8619A94B16D3Q39328796-4E83B938-FE78-4B00-BEB5-3EC56FA46B87Q40112489-1D717124-3FA5-44F4-A7F2-E2B6C4D742FFQ40246055-89F3D0AE-136A-4DE2-B198-F0CE44B47EEEQ40255983-06A99E7C-2ADF-430D-AA0B-7A0F1BBB8056Q40420487-255A7A45-7C01-4309-B7A9-84A78C24BC27Q41110647-31273CB7-D11D-4102-9A23-793B65F906CAQ41987607-8BEF0EA6-0EBA-4E77-A7D8-6837D10500D7Q41989657-F39C74C4-D051-433B-9015-98438220AE89Q46270150-BE7E0CFB-749C-4916-8675-06C5B7031129Q46465650-EFE3A269-9C0D-4FB0-9818-6A0E126EF96AQ47402966-A6266F5E-8CAE-4233-A75D-A36D0553C879
P2860
The loss of topography in the microbial communities of the upper respiratory tract in the elderly.
description
2014 nî lūn-bûn
@nan
2014 թուականի Մայիսին հրատարակուած գիտական յօդուած
@hyw
2014 թվականի մայիսին հրատարակված գիտական հոդված
@hy
2014年の論文
@ja
2014年論文
@yue
2014年論文
@zh-hant
2014年論文
@zh-hk
2014年論文
@zh-mo
2014年論文
@zh-tw
2014年论文
@wuu
name
The loss of topography in the ...... piratory tract in the elderly.
@ast
The loss of topography in the ...... piratory tract in the elderly.
@en
type
label
The loss of topography in the ...... piratory tract in the elderly.
@ast
The loss of topography in the ...... piratory tract in the elderly.
@en
prefLabel
The loss of topography in the ...... piratory tract in the elderly.
@ast
The loss of topography in the ...... piratory tract in the elderly.
@en
P2093
P2860
P1476
The loss of topography in the ...... spiratory tract in the elderly
@en
P2093
Chris P Verschoor
Jennie Johnstone
Jennifer C Stearns
Kathy Luinstra
Laura Rossi
Marek Smieja
Michael G Surette
P2860
P304
P356
10.1513/ANNALSATS.201310-351OC
P577
2014-05-01T00:00:00Z