9 Clinical Trials for Various Conditions
This research will test a new ultra-rapid technology (called ID/AST Accelerate system) that uses a digital microscope to identify bacteria based on their growth patterns. This method does not have to wait for bacteria to grow in a lab. The new method can identify the type of bacteria within 2 hours of receiving a specimen. The new method also shows the effect of selected antibiotics on the bacteria including multidrug resistant bacteria so that doctors know within 6 hours from specimen collection which antibiotic kills the bacteria. To check the accuracy, speed and impact of the new method on antibiotic prescribing, investigators are proposing a study with two parts; The first part will test the accuracy and speed of the results obtained by the new method. The second part will test if having the results from the new method early would change the antibiotics prescribed to a patient in a simulation experiment. An independent infectious disease physician will be shown the results from the new method and asked if the results were accurate, would it change the antibiotic treatment for the patient.
Military service members and the U.S. veteran population face a growing and serious health threat: widespread antibiotic resistance resulting from resistant bacteria and a dwindling pipe-line of sufficiently potent antibiotics. Infections with antibiotic resistant bacteria are increasing significantly. They cause major complications and mortality, and drive up healthcare costs. Powerful but non-targeted antibiotics, while in widespread use, can actually pressure bacteria to develop resistance.
The objective is to conduct a prospective, sham controlled, double-blinded, interventional crossover trial to compare standard terminal cleaning plus PX-UV (intervention) with standard terminal cleaning plus sham PX-UV (control) with crossover at 12 months, following a 6-month washout period. Outcome measures include the rates of HAIs, as well as the recurrence of genetically identical clinical strains of HAIs among patients on study units. The study will be conducted in 2 hospitals covering 16 total hospital units at Detroit Medical Center. Our central hypothesis is that the addition of PX-UV to standard terminal cleaning will be associated with a significant reduction in the rate of HAIs, as well as a reduction in the recovery of genetically identical strains of MDROs. The impact of PX-UV disinfection on rates of HAIs on study units will be determined by comparing rates of HAIs on a) study units where PX-UV is added to standard terminal cleaning practices to b) units where a sham UV disinfection system is added to standard terminal cleaning; and by comparing rates of HAIs on the same medical ward during each of two 12-month phases of a crossover study (one phase when a PX-UV device is added and one when a sham device is added to standard terminal cleaning). The long-term goal of this project is to establish the efficacy of terminal cleaning plus PX-UV in reducing rates of HAIs due to the following multi-drug resistant organisms (MDROs): C. difficile, vancomycin-resistant enterococci (VRE), Klebsiella pneumoniae and Escherichia coli producing extended-spectrum beta-lactamases (ESBLs), methicillin-resistant Staphylococcus aureus (MRSA) and Acinetobacter baumannii. At the conclusion of the proposed project, novel data will be generated from this rigorously controlled study regarding the effectiveness of PX-UV in reducing HAIs in a representative, real-world healthcare setting.
Carbapenems are a class of antibiotic agents which kill a broad spectrum of bacteria. Infections due to gram-negative bacteria which have acquired resistance to carbapenems are increasing, especially with Klebsiella pneumoniae, Acinetobacter baumannii and Pseudomonas aeruginosa . The optimal treatment of such infections is not known. Antibiotics like polymyxin, tigecycline and rifampin are used alone or in combination with other antibiotics. The outcome of using these new and old drugs is not well studied. This observational study aims to study the clinical and microbiological outcomes of these infections and treatment at our institution.
Arbekacin for the use of infection caused by multidrug-resistant organisms
This study will treat pediatric patients who have infections that are due to a specific bacteria (Vancomycin-Resistant Enterococcus)
A multi-center, retrospective study of cases of serious bacterial infections including complicated Urinary Tract Infection (cUTI) or Acute Pyelonephritis (AP), Hospital Acquired Bacterial Pneumonia (HABP), Ventilator Acquired Bacterial Pneumonia (VABP), and/or bacteremia caused by Carbapenem-Resistant Enterobacteriaceae (CRE)
A Phase 3 comparative study to determine the efficacy, safety and tolerability of Aztreonam-Avibactam (ATM-AVI) ± Metronidazole (MTZ) versus Meropenem (MER) ± Colistin (COL) for the treatment of serious infections due to Gram negative bacteria.
The purpose of this study is to provide further evidence of the clinical and bacteriological efficacy of retapamulin in the treatment of subjects with SITL or impetigo due to MRSA. Subjects aged 2 months and older will be treated with either topical retapamulin for 5 days or oral linezolid for 10 days. The primary endpoint is the clinical response at follow-up (7-9 days after the end of therapy) in subjects who have a MRSA infection at baseline. The primary population is the per-protocol MRSA population. It is anticipated that approximately 500 subjects may be enrolled in order to obtain approximately 105 subjects who have a baseline MRSA infection.