View clinical trials related to Bacterial Infections.
Filter by:Patients with bloodstream infections, hospital acquired pneumonia or ventilator-associated pneumonia caused by carbapenem-resistant Acinetobacter baumannii (CRAB) treated with cefiderocol combined with ampicillin sulbactam will be compared to patients treated treated with colistin alone or colistin combined with meropenem.
Study to comparing conventrional antibiotic strategies versus regimens guided by epidemiological surveillance in infected patients with cirrhosis.
This is a randomized, open label, comparative Phase II trial being conducted to determine whether fecal microbiota transplant using Penn Microbiome Therapy (PMT) products helps standard therapy eradicate antibiotic-resistant bacteria.
The aim of this study is to evaluate the antibacterial effect 12 hours after 4-week use of a toothpaste containing amine base, zinc lactate, and fluoride. For this, healthy people will be invited to use two different toothpaste: control - containing only fluoride; test - containing fluoride plus a combination with zinc. The primary outcome is the efficacy of the test toothpaste in the oral bacterial load reduction in samples of saliva and oral mucosa (obtained through scraping); the second outcome is effect of the test toothpaste in the expression of mucin in the oral mucosa.
This study will investigate the effects of PreforPro® (prebiotic and bacteriophages (LH01-Myoviridae, LL5-Siphoviridae, T4D-Myoviridae, and LL12-Myoviridae, greater > 6.7 X 107 PFU/gram) on bacterial vaginosis.
The purpose of this study is to evaluate the pharmacokinetics, safety or tolerability through treatment emergent adverse event (TEAE) and to explore primary and secondary clinical response of treatment with Augmentin ES in pediatric population presenting with CAP and ABRS in Brazil.
Multicenter, Retrospectivecohort study in patients with Chronic Prostatitis, Chronic Bacterial Prostatitis (Category II) and Chronic Pelvic Pain Syndrome (Category IIIA, IIIB) and 140 patients without other significant comorbidities will be participated. The aim of the study is to collect post-treatment data to evaluate inflammation, infection status and quality of life with standard antibiotic therapy with NSAID and added Treataprost effect.
Intracranial infection is one of the common clinical complications after neurosurgery, especially after external cerebrospinal fluid drainage. Postoperative intracranial infection has a very high incidence, and its incidence is about 0.34%-3.1%. Once infection occurs, it will directly affect the length of hospitalization, mortality and disability of postoperative patients. The pathogenic bacteria of postoperative intracranial infections include G-bacteria and G+ bacteria, and fungi. Common G+ bacteria are Staphylococcus aureus. Common G-bacteria are Acinetobacter baumannii, Klebsiella pneumoniae, and Pseudomonas aeruginosa Bacteria, Escherichia coli and so on. In recent years, studies have reported that postoperative intracranial infections of G-bacteria are gradually increasing. In the previous study of our research group, it was found that Acinetobacter baumannii and Klebsiella pneumoniae accounted for the top two pathogens of postoperative intracranial infections in ICU. In particular, the proportion of carbapenem-resistant G-bacteria has increased, which brings difficulty and challenge to the treatment and seriously affects the prognosis of patients. Different pathogen infections may lead to different prognosis of patients with intracranial infection after neurosurgery. With different pathogens as the starting point, there are few studies comparing the clinical features, risk factors, and prognosis of intracranial infections after neurosurgery. Therefore, it is great significant to explore and understand different pathogenic bacteria, risk factors, drug resistance, treatment options, and prognosis after neurosurgery.
BACKGROUND: The spread of multidrug-resistant bacteria represents a well-known problem, which must be face up by optimizing antibiotic therapy both in terms of choosing the most appropriate drug and of an adequate treatment duration. The method of administration is also a critical element. There are data relating to the maximization of the efficacy of Carbapenems and Piperacillin/Tazobactam by continuous infusion, able to constantly maintain adequate drug concentrations. Several studies, conducted comparing a standard administration of Carbapenem or Piperacillin/Tazobactam to an extended administration or continuous perfusion to evaluate safety and efficacy in terms of mortality reduction, have been documented. The achievement of optimal serum concentrations during continuous infusion has been documented both for Carbapenems and Piperacillin/Tazobactam, and for other types of antibiotics such as Cefepime and Vancomycin. The duration of antibiotic treatment is a critical factor for the prevention of relapses as well as the onset of resistance. The recommended duration of antibiotic treatment varies according to the site of infection and the type of pathogen and is generally between 7 and 14 days, however, in particular cases it is possible that the administration of antibiotics must be longer than one month. In general, the length of hospitalization is associated with a greater likelihood of complications for patients, with a substantial increase in the risk of developing multiple types of complications, such nosocomial infections, bed rest, bedsores, falls, malnutrition and disorientation. It should also be noted that prolonged hospitalization leads to a substantial increase in care costs. The advantage in terms of greater therapeutic success linked to the continuous infusion of some types of antibiotics has been used for the development of home infusion protocols for antibiotic therapy. There are numerous studies that show the feasibility and effectiveness of home infusion antibiotic therapy using elastomeric devices, documenting its substantial equivalence with respect to hospital treatment. The antibiotics for which there is evidence of feasibility are various, including Cefepime, Vancomycin and Piperacillin/Tazobactam. STUDY DESIGN: The study is aimed to patients with severe bacterial infections who have started an antibiotic treatment and are benefiting from such therapy. The purpose of the study is to move the continuation of antibiotic therapy to the home setting once its efficacy and tolerability during hospitalization have been documented, in order to allow the patient a potentially eradicating treatment, of adequate duration without the need of hospitalization. Patients are enrolled when the efficacy and tolerability of the ongoing antibiotic treatment based on Cefepime, Meropenem, Piperacillin/Tazobactam or Vancomycin has been documented. The protocol requires that the patient go to the hospital every morning to replace the elastomer and to carry out a medical examination. Blood chemistry tests, which include at least blood counts, electrolytes, renal function, liver function and inflammation indices are scheduled to be performed at least once a week. Exams can also be done more frequently based on clinical needs. Antibiotic therapy should be carried out until the infection is cured, as per current clinical practice. For the purposes of the study, the patient remains under observation for 30 days after enrollment. Blood samples for the assessment of antibiotic concentrations will be performed in correspondence with the blood chemistry tests performed routinely for patient assessment. In any case, for each patient, a sample is taken for the dosage of the antibiotic used, which will be a single sample in the event of a continuous infusion, or a downstream sample (within one hour of the new antibiotic administration) and peak (30 minutes after the end of the infusion). The pharmacokinetic sampling relating to the outpatient phase will be carried out on the third or fourth day of continuous infusion therapy at the time of the elastomer change.
This study aims to evaluate if meropenem can be administered in outpatients as a continuous infusion using elastomeric pumps and an isothermal pouch maintaining the anti-infective solution between 10° and 15°C for improved stability.