View clinical trials related to Bacterial Infections.
Filter by:The goal of this observational study is to investigate how bacterial populations from the intestine and mouth of patients change during the hospitalization period and evaluate if some populations of specific bacteria increase or decrease the risk of acquiring an infection or becoming colonized by pathogenic bacteria. Participants will have the following samples collected during enrollment: stool samples (maximum 2x/week), blood draws (1x/week), oral swab (1x/week).
Multidrug resistant bacteria (MDR) pose a threat to the safety of patients worldwide. Drug resistant bacteria are commonly present in hospital environments and can cause infections, often leading to outbreaks within hospitals. Cross transmission through medical staff has been proven to be a significant cause of MDR bacterial transmission in hospitals. Although some studies have shown that the detection of gut drug-resistant bacteria in healthcare workers is similar to that in healthy individuals, these studies are limited to small sample sizes and detection methods. Here, the investigator characterize the differences between ARG colonization among healthcare workers and healthy populations through deep metagenomics.
Objectives: 1. To compare the immune response of patients with or without sepsis presenting to the ED with a(n) (suspected) infection. 2. To determine immune response aberrations that are associated with an increased risk of developing sepsis in patients presenting to the ED with a(n) (suspected) infection without sepsis. 3. To determine the long term cognitive and physical sequelae of sepsis after admission.
Outpatients with short-term antibiotic treatment should start and finish the treatment according to medical advise that is, the intake pattern (named adherence) should be regular. The research question is: Can a smartphone-based program including intake reminder and two text messages improve adherence to a short-term antibiotic treatment in ambulatory setting? Participants will be asked to record every antibiotic intake in an app on their smartphone over the prescribed therapy duration and to note their symptoms once daily. One group will obtain reminder + text messages, and the control group will have no reminder + no text messages.
In chronic hemodialysis patients, bacteremia is most commonly caused by dialysis catheter infections. It is estimated that the vast majority (52-84%) of these infections are due to Gram-positive cocci, particularly Staphylococcus aureus (21-43%). Penicillin M (oxacillin and cloxacillin in France) is the reference beta-lactam for the treatment of invasive methicillin-sensitive S. aureus (MSSA) infections, but has not shown a prognostic benefit in large retrospective cohorts comparing penicillin M and cefazolin, at the expense of more frequent adverse events. Dosage in the chronic hemodialysis population is unclear because it is based on old studies.
The primary purpose of this study is to understand the pharmacokinetics (PK) of single and multiple doses of cefiderocol in children from birth to less than 3 months of age with suspected or confirmed aerobic Gram-negative bacterial infections.
A Phase 1, Open-Label, Drug-drug Interaction, and Randomized, Double-blind, Controlled, Multiple-dose Pharmacokinetics and Safety Study of Xeruborbactam Oral Prodrug (QPX7831) in Combination with Ceftibuten in Healthy Adult Participants
The goal of this observational study is to investigate whether intravenous polymyxin B combined with nebulisation achieves better antimicrobial efficacy and clinical outcomes than intravenous use alone in patients with multidrug-resistant gram-negative bacilli infected with ventilator-associated pneumonia. The main questions it aims to answer are: - When using intravenous polymyxin B to treat patients with ventilator-associated pneumonia caused by multidrug-resistant bacteria in clinical practice, is it necessary to assist with polymyxin B nebulization therapy? - If necessary, how much dose of nebulization is better? Participants will be divided into two groups based on whether they have received nebulization treatment with polymyxin B in clinical practice. Blood and alveolar lavage fluid samples will be collected after the first dose injection and reaching the steady-state dose, and the drug concentration differences in blood and ELF will be measured in patients who have received intravenous injection of polymyxin B alone and those who have received adjuvant nebulization of polymyxin B, as well as differences in clinical outcomes and side effects. Researchers will compare the differences in blood and ELF drug concentrations, clinical outcomes, and incidence of side effects between two groups of patients, to see if is it necessary to assist with polymyxin B nebulization therapy in patients with multidrug-resistant gram-negative bacilli infected with ventilator-associated pneumonia.
The goal of this observational study is to learn about infectious complications in patients affected by B-cell acute lymphoblastic leukemia treated with inotuzumab-ozogamicin (INO). The main question it aims to answer is: • incidence of infectious complications (bacterial, fungal, viral) in patients receiving inotuzumab ozogamicin up to 60 days after the end of treatment
Babies and children have an increased risk of getting an infection with a bacteria in the bloodstream (sepsis). It is often difficult for the doctor to determine whether a child has an infection of the bloodstream, because the symptoms are often unclear and can also occur in children who are not sick. To determine whether there is an infection, a little blood is currently taken for a blood test (the blood culture) to investigate whether there is a bacteria in the blood. However, it often takes at least 36 hours before the results of this blood culture are available. That is why antibiotics are usually started immediately to treat the possible infection. However, it often turns out that the blood culture is negative after 36 hours, which means that no bacteria have been found in the blood. Usually the antibiotics are then stopped because it turns out that there was no infection at all. There is currently no good test that can predict whether (newborn) children have an infection or not. That is why too many children are currently wrongly receiving antibiotics. These antibiotics can damage the healthy bacteria in the intestines. There are many billions of 'beneficial bacteria' in the intestine. These play an important role in the digestion of food and protect against external infections. Antibiotics aim to kill bacteria that cause inflammation or infection. Unfortunately, antibiotics also kill some of these beneficial bacteria. In addition, unnecessary use of antibiotics contributes to antibiotic resistance. The aim of this research is to investigate whether Molecular Culture, a PCR based test that can identify bacterial pathogens in bodily fluids within 4 hours, has greater accuracy than traditional culturing techniques for bacteria in blood. If proven, this could lead to faster identification or exclusion of sepsis in children.