View clinical trials related to Microbial Colonization.
Filter by:PrePhage - Fecal bacteriophage transfer for enhanced gastrointestinal tract maturation in preterm infants This pilot triol has the primary goal of demonstrating the safety of transferring viruses and proteins from healthy term infants to preterm infants born between gestational age (GA) 26 + 0 and 30+6. The long-term goal is to develop a safe and effective treatment to prevent the severe gut disease called necrotizing enterocolitis (NEC). NEC is a common disease in neonatal intensive care units affecting 5-10% of all admitted patients. 15-30% of the affected children die from the disease, and many of the survivors suffer from the effects of extensive gut surgery. While the disease is caused by many different factors, recent research has shown the gut microbiome to be a central factor in the development of NEC. Furthermore, in the recent years special viruses called bacteriophages have shown potential in the treatment of various diseases. By collecting feces from healthy, term infants and filtering it thoroughly, the investigators can provide a treatment that contains practically only viruses, proteins and nutrients. It is our belief that giving the preterm infants a mix of viruses including bacteriophages will prevent NEC. To do this, the investigators will go through 3 stages: Recruiting and following healthy donor infants to study the microbiota and use feces from them to donate in stage 2 and 3 Examining the safety of the treatment as well as how it works in preterm piglets STAGE 3 will be performed only if stage 2 shows no serious risks for the infants Testing the treatment in preterm infants. 10 preterm infants will receive the treatment and 10 preterm infants will receive placebo. The investigators expect to see no serious side effects to the treatment. The investigators hope, but do not expect to be able to see a beneficial effect of the treatment. If this pilot trial shows promising results, it will be followed be a larger clinical trial.
An observational study was performed on 48 women wearing hijab and 48 women not wearing hijab to compare the scalp microbiome.
Sepsis is a life-threatening clinical syndrome and a leading cause of neonatal deaths worldwide. The burden of neonatal sepsis and severe infection (SI) is particularly high in areas of South Asia and other resource-limited settings. The goal of the Synbiotics for the Early Prevention of Severe Infections in Infants (SEPSIS) phase II L. plantarum trial is to generate knowledge on the safety, tolerability and effects on the microbiome of Lactiplantibacillus plantarum, with or without fructooligosaccharide, in infants (birth to 60 days of age) in Dhaka, Bangladesh. All data generated will support the design and implementation of a phase III trial to test the efficacy of the probiotic/synbiotic or other interventions for the prevention of SI, promotion of optimal growth and development, and effects on other health outcomes in early infancy.
Background and aims: Patients with severe Coronavirus Disease 2019 (COVID-19) are prone to secondary bacterial pneumonia. The use of probiotics against oral pathogens might prevent lung colonization and progression to bacterial pneumonia. This study aimed to assess the effect of Streptococcus salivarius K12 combined with Lactobacillus brevis CD2 in preventing secondary bacterial pneumonia in patients with severe COVID-19. Methods: This randomized placebo-controlled phase 2 trial involved 70 patients with severe COVID-19 admitted to the intensive care unit (ICU). Patients were randomly assigned to a 7-day course of oral gel containing Streptococcus salivarius K12 2 billion colony-forming units (CFU) and Lactobacillus brevis CD2 4 billion CFU every 8 hours or placebo, starting in the first ICU day. The primary outcome was bacterial pneumonia, established according to clinical, laboratory, radiological, and microbiological findings, whereas secondary outcomes were ICU stay in days and hospital mortality.
Antibiotics are a mainstay of life-saving interventions used frequently in medical practice to combat infections. These medications not only target the pathogenic bacteria for which they are prescribed but also function against commensal bacterial communities that inhabit the gut, skin, and oropharynx. The role that these native bacterial communities play in normal host function, such as in nutrition and host immunity, is only beginning to be explored, as are the changes in the communities and their function as a result of various alterations of antibiotic use. Short courses of antibiotics have been shown to affect the diversity of native bacterial communities, and to affect the abundance of antibiotic resistance genes present. For example, use of clindamycin in human subjects for 7 days has been demonstrated to result in persistent clindamycin resistance for months or years. The impact of prolonged antibiotic therapy on the host microbiome including both those organisms present and the diversity of antibiotic genes has not been studied, and we have very little understanding of the longitudinal effects of antimicrobial therapy on the genetic repertoire present in human microbial communities. In this study, we will examine changes in the microbiota as well as frequency of antibacterial resistance genes harbored in skin, saliva, and colonic microbiomes longitudinally in subjects on prolonged antimicrobial therapy, as well as household members of the person on antibiotic therapy. Previously well patients with minimal prior antibiotic exposure will be enrolled upon diagnosis of an infection requiring long-term antibiotic therapy, such as osteomyelitis or prosthetic joint infection, prior to starting antibiotic therapy. We will examine the microbiota of the skin, saliva, and gut prior to antibiotics as well as the frequency of antibiotic resistance genes harbored within these microbial communities. We will compare microbial communities and antibiotic resistance gene frequencies before, during and after prolonged course of antibiotics in patients on antibiotics. We will also look for alterations that occur among microbiomes or antibiotic resistance genes among household members of people on antibiotics.
Group A Streptococcus (GAS) is a bacteria which causes severe infections and leads to deadly diseases such as rheumatic heart disease which kills over 300,000 people a year globally, particularly in low-income countries. It is not know how GAS is spread between people, how often people carry GAS in their throat or on their skin without having symptoms, or what factors increase the chance of this occurring. It is important to understand these factors in order to know how to reduce GAS-related disease. This study will follow 444 people in The Gambia, over 12 months, taking samples from the throats and skin of people living in the same households, and asking questions about themselves and their behaviour, at regular intervals. By taking samples over time, the investigators hope to understand how common it is to carry GAS without having symptoms, how GAS is spread between people, and whether carrying GAS leads to more GAS infections in people or their household members. The study will use state-of-the-art techniques to look at the DNA of GAS bacteria that we find, and combine this with a mathematical model to investigate how different strains spread to people within and between households in the community.
The purpose of the study is to assess the effect of an enzyme containing lozenge on dental plaque accumulation in healthy adults.
In this randomised controlled trial the investigators will determine whether taking iron supplements compared to placebo for 21 days alters the bacteria (microbiome) in the large intestine of non-pregnant female participants.
Evaluating the user (pregnant women and parents of young children) experience of the OneBiome consumers value journey service offered to the 1000 days and young children consumers market
Chronic kidney disease (CKD) is associated with an increased cardiovascular mortality. In particular children with early-onset CKD have a lifelong increased risk to suffer from cardiovascular disease (CVD). Therefore, children with CKD deserve our attention. The immune system in children with CKD is disturbed, exhibiting pro-inflammatory features. Therefore, we aim to learn more about the characteristics of the immune system in early-onset CKD. In this project PBMC of pediatric CKD patients and age-matched healthy controls will be analysed and compared using CITE-Seq as a multimodal scRNAseq phenotyping method. All patients will be clinically characterized to integrate cardiovascular and immunological data.