Project description:Microbiome of lower respiratory tract with infection of influenza virus

Project description:Human metapneumovirus (HMPV) is a primary causative agent of acute lower respiratory tract infections. We used single cell RNA-sequencing (scRNA-seq) to assess lung immune profiles in a mouse model of HMPV infection.

Project description:This project was a prospective translational study aimed at evaluating gene expression profiles (GEP) of patients with ventilator-associated pneumonia (VAP) . GEP of VAP were compared with a control group of patients which did not developed ventilator-associated lower respiratory tract infection despite being subjected to mechanical ventilation.

Project description:The respiratory epithelium is the body’s first line of defense to pathogens, pollutants, and other potentially injurious agents that can be inhaled. Sampling the upper respiratory tract is becoming a widely used technique in the clinic to examine the molecular changes in the diseased airway; however, it is unclear as to whether the responses in the upper respiratory tract (i.e. the nasal turbinates) reflect the changes that occur in the lower respiratory tract (i.e. trachea and lungs). Here, we assessed the responses to poly I:C, a synthetic double-stranded RNA molecule that is meant to mimic the acute effects of a viral infection, in both the upper and lower respiratory tracts of cynomolgus macaques. To do this, we compared the in vivo response after a nasal poly I:C challenge in a nasal scrape samples (performed using a nasal curette) to responses that occurred after ex vivo poly I:C stimulation in nasal scrapes, tracheal epithelial brushings, and lung tissue explants in non-human primates.

Project description:The respiratory epithelium is the body’s first line of defense to pathogens, pollutants, and other potentially injurious agents that can be inhaled. Sampling the upper respiratory tract is becoming a widely used technique in the clinic to examine the molecular changes in the diseased airway; however, it is unclear as to whether the responses in the upper respiratory tract (i.e. the nasal turbinates) reflect the changes that occur in the lower respiratory tract (i.e. trachea and lungs). Here, we assessed the responses to poly I:C, a synthetic double-stranded RNA molecule that is meant to mimic the acute effects of a viral infection, in both the upper and lower respiratory tracts of cynomolgus macaques. To do this, we compared the in vivo response after a nasal poly I:C challenge in a nasal scrape samples (performed using a nasal curette) to responses that occurred after ex vivo poly I:C stimulation in nasal scrapes, tracheal epithelial brushings, and lung tissue explants in non-human primates.

Project description:The respiratory epithelium is the body’s first line of defense to pathogens, pollutants, and other potentially injurious agents that can be inhaled. Sampling the upper respiratory tract is becoming a widely used technique in the clinic to examine the molecular changes in the diseased airway; however, it is unclear as to whether the responses in the upper respiratory tract (i.e. the nasal turbinates) reflect the changes that occur in the lower respiratory tract (i.e. trachea and lungs). Here, we assessed the responses to poly I:C, a synthetic double-stranded RNA molecule that is meant to mimic the acute effects of a viral infection, in both the upper and lower respiratory tracts of cynomolgus macaques. To do this, we compared the in vivo response after a nasal poly I:C challenge in a nasal scrape samples (performed using a nasal curette) to responses that occurred after ex vivo poly I:C stimulation in nasal scrapes, tracheal epithelial brushings, and lung tissue explants in non-human primates.

Project description:The respiratory epithelium is the body’s first line of defense to pathogens, pollutants, and other potentially injurious agents that can be inhaled. Sampling the upper respiratory tract is becoming a widely used technique in the clinic to examine the molecular changes in the diseased airway; however, it is unclear as to whether the responses in the upper respiratory tract (i.e. the nasal turbinates) reflect the changes that occur in the lower respiratory tract (i.e. trachea and lungs). Here, we assessed the responses to poly I:C, a synthetic double-stranded RNA molecule that is meant to mimic the acute effects of a viral infection, in both the upper and lower respiratory tracts of cynomolgus macaques. To do this, we compared the in vivo response after a nasal poly I:C challenge in a nasal scrape samples (performed using a nasal curette) to responses that occurred after ex vivo poly I:C stimulation in nasal scrapes, tracheal epithelial brushings, and lung tissue explants in non-human primates.

Project description:The respiratory epithelium is the body’s first line of defense to pathogens, pollutants, and other potentially injurious agents that can be inhaled. Sampling the upper respiratory tract is becoming a widely used technique in the clinic to examine the molecular changes in the diseased airway; however, it is unclear as to whether the responses in the upper respiratory tract (i.e. the nasal turbinates) reflect the changes that occur in the lower respiratory tract (i.e. trachea and lungs). Here, we assessed the responses to poly I:C, a synthetic double-stranded RNA molecule that is meant to mimic the acute effects of a viral infection, in both the upper and lower respiratory tracts of cynomolgus macaques. To do this, we compared the in vivo response after a nasal poly I:C challenge in a nasal scrape samples (performed using a nasal curette) to responses that occurred after ex vivo poly I:C stimulation in nasal scrapes, tracheal epithelial brushings, and lung tissue explants in non-human primates.

Project description:Lower respiratory tract microbiota Raw sequence reads

Project description:Nasopharyngeal microbiota of children with lower respiratory tract infection and healthy controls