The main aim of the study is to describe plasma pharmacokinetics (PK) and pulmonary diffusion of high-dose ceftobiprole (500 mg loading dose followed by 2.5 g under continuous infusion for 24h) for mechanically-ventilated adult patients with severe community-acquired pneumonia, using population PK modelling. The secondary aims are : A- To determine whether the pharmacokinetic / pharmacodynamic (PK/PD) targets can be achieved in the plasma and epithelial lining fluid with the recommended doses of ceftobiprole. B- To define the optimal dose regimen for ceftobiprole in this population. C- To evaluate clinical recovery (at Day 3 and Day 8) and microbiological recovery (at Day 3). D- To evaluate the clinical evolution. E- To evaluate the clinical and biological tolerance.
Pneumonia is still associated with high morbi-mortality, and rapid treatment with suitable antibiotics is required, i.e. with a broad enough spectrum to cover the activity of all the potentially-incriminated pathogens. These antibiotics must be administered at efficient doses and diffused in sufficient quantity at the infection site. Unlike other beta-lactams, ceftobiprole is a new-generation broad-spectrum cephalosporin which is active on the majority of pathogens encountered in acute, community-acquired pneumonia (CAP) and also on methicillin-resistant staphylococcus aureus (MRSA) and non-fermenting Gram-negative bacilli (GNB) like pseudomonas aeruginosa. It is indicated for the treatment of CAP and also healthcare-associated pneumonia, other than that acquired under mechanical ventilation. For any antibiotic administered to critically ill patients it is necessary to ensure that the pharmacokinetic/pharmacodynamic (PK/PD) targets correlated with clinical efficacy can be reached with the recommended doses. The DALI study published in 2014 was the first study to alert on the risk of plasma under-dosing when the standard doses of beta lactams were administered in severely ill patients. Since then, several PK studies performed in the intensive care unit have confirmed the significant risk of non-optimal doses in this population, linked to physiopathological alterations caused by sepsis. So far there have been no studies specifically aimed at the pharmacokinetics of ceftobiprole in those patients with CAP requiring mechanical ventilation. Furthermore, although there is increasing use in the pharmaceutical industry and in the post-developmental phases of medicines, a population PK analysis to help describe the factors influencing the PK of a molecule and establish new dose regimens optimised for a given population (in this case an ICU population) using Monte Carlo simulations, has never been developed for ceftobiprole given by continuous infusion. The ultimate aim of so-called adequate antibiotic therapy is to obtain the right therapeutic concentrations at the infection site. During a pulmonary infection, the targeted concentrations of antibiotics in the alveolar liquid must be above the minimal inhibitory concentration value at the end of the dose interval for so-called " time-dependent " antibiotics like cephalosporins. Obtaining these efficient concentrations is often made difficult by the beta-lactams' mediocre pulmonary diffusion and can require an increase in doses in order to reach the PK/PD target at the infection site and/or the use of continuous administration of beta-lactamines. Indeed, this way of administrating is being privileged more and more in order to optimise the time spent above the minimal inhibitory concentration. This pharmacokinetic study is the first to be carried out among a population of ICU patients and one that focuses on pulmonary diffusion of ceftobiprole for the treatment of severe CAP. The main benefits expected are to determine the most suitable doses of ceftobiprole when this molecule is used to treat ICU patients suffering from CAP. With the help of this population analysis, the main aim of the study is therefore to describe the pharmacokinetics (PK) of the plasma and pulmonary diffusion of ceftobiprole administered at high-dosage (500 mg loading dose followed by 2.5 g under continuous infusion for 24h) for severe community-acquired pneumonia under mechanical ventilation. The secondary aims are : A- Determine whether the pharmacokinetic / pharmacodynamic (PK/PD) targets can be achieved in the plasma and epithelial lining fluid with the recommended doses of ceftobiprole. B- Define the optimal dose regimen for ceftobiprole in this population. C- Evaluate the clinical recovery (at Day 3 and Day 8) and microbiological recovery (at Day 3). D- Evaluate the clinical evolution. E- Evaluate the clinical and biological tolerance.
Study Type
INTERVENTIONAL
Allocation
NA
Purpose
TREATMENT
Masking
NONE
Enrollment
12
High-dose ceftobiprole (500mg loading dose) will be administered to patients for 30 minutes followed by 2.5g under continuous infusion for 24 hours.
Centre Hospitalier Lyon Sud,
Pierre-Bénite, Auvergne-Rhône-Alpes, France
CHU de Nîmes
Nîmes, Gard, France
Plasma concentration of ceftobiprole on Day 1
A blood test is performed upon admission to the Intensive Care Unit, BEFORE beginning antibiotic therapy with Ceftobiprole
Time frame: Day 1
Blood test after injection of loading-dose Ceftobiprole (Cmax) for 30 minutes
A 3ml blood sample is taken after injection of 500g of Ceftobiprole for 30 minutes, for pharmacological dosage.
Time frame: Day 1 (after the 30-minute injection)
Blood test 2 hours AFTER beginning antibiotic therapy with ceftobiprole
After injection of loading-dose Ceftobiprole (Cmax) for 30 minutes followed by 2.5g by continuous infusion of ceftobiprole, a sample is taken at 2 hours from the start of treatment.
Time frame: Day 1, 2 hours from start of treatment
Blood test 6 hours AFTER beginning antibiotic therapy with ceftobiprole
After injection of loading-dose Ceftobiprole (Cmax) for 30 minutes followed by 2.5g by continuous infusion of ceftobiprole, a sample is taken at 6 hours from the start of treatment.
Time frame: Day 1, 6 hours from start of treatment
Blood test 8 hours AFTER beginning antibiotic therapy with ceftobiprole
After injection of loading-dose Ceftobiprole (Cmax) for 30 minutes followed by 2.5g by continuous infusion of ceftobiprole, a sample is taken at 8 hours from the start of treatment.
Time frame: Day 1, 8 hours from start of treatment
Blood test 12 hours AFTER beginning antibiotic therapy with ceftobiprole
After injection of loading-dose Ceftobiprole (Cmax) for 30 minutes followed by 2.5g by continuous infusion of ceftobiprole, a sample is taken at 12 hours from the start of treatment.
Time frame: Day 1, 12 hours from start of treatment
Time 2 blood test on third day of antibiotic therapy with ceftobiprole
Patient is on 2.5g of ceftobiprole by continuous infusion. Samples are taken at regular intervals on Day 3.
Time frame: Day 3 at Time 2
Time 6 blood test on third day of antibiotic therapy with ceftobiprole
Patient is on 2.5g of ceftobiprole by continuous infusion. Samples are taken at regular intervals on Day 3.
Time frame: Day 3 at Time 6
Time 8 blood test on third day of antibiotic therapy with ceftobiprole
Patient is on 2.5g of ceftobiprole by continuous infusion. Samples are taken at regular intervals on Day 3.
Time frame: Day 3 at Time 8
Time 12 blood test on third day of antibiotic therapy with ceftobiprole
Patient is on 2.5g of ceftobiprole by continuous infusion. Samples are taken at regular intervals on Day 3.
Time frame: Day 3 at Time 12
Pulmonary concentration of ceftobiprole on Day 3
Pulmonary concentrations of ceftobiprole are measured by bronchoalveolar lavage at the same time as any one of the blood samples are taken on Day 3
Time frame: On Day 3 of treatment with ceftobiprole
Plasma concentration BEFORE treatment
A blood test is performed upon admission to the Intensive Care Unit, BEFORE beginning antibiotic therapy with Ceftobiprole to evaluate plasma concentration.
Time frame: Day 1
Plasma concentration AFTER maximum dose of ceftobiprole on Day 1
Patient has now begun antibiotic therapy with Ceftobiprole and has been injected with 500g of Ceftobiprole for 30 minutes. A blood sample is taken to evaluate plasma concentration.
Time frame: Day 1
Plasma concentration after two hours at the steady-state
The dosage of Ceftobiprole has now been reduced. Patient is on 2.5g of ceftobiprole by continuous infusion and plasma concentration is measured after 2 hours.
Time frame: Day 1
Plasma concentration after 6 hours at the steady-state
Patient is on 2.5g of ceftobiprole by continuous infusion and plasma concentration is measured after 6 hours.
Time frame: Day 1
Plasma concentration after 8 hours at the steady-state
Patient is on 2.5g of ceftobiprole by continuous infusion and plasma concentration is measured after 8 hours.
Time frame: Day 1
Plasma concentration after 12 hours at the steady-state
Patient is on 2.5g of ceftobiprole by continuous infusion and plasma concentration is measured after 12 hours.
Time frame: Day 1
Plasma concentration at Time 2 on Day 2 of the steady-state
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Patient is on 2.5g of ceftobiprole by continuous infusion and plasma concentration is measured at Time 2
Time frame: Day 2 at Time 2
Plasma concentration at Time 6 on Day 2 of the steady-state
Patient is on 2.5g of ceftobiprole by continuous infusion and plasma concentration is measured at Time 6
Time frame: Day 2 at Time 6
Plasma concentration at Time 8 on Day 2 of the steady-state
Patient is on 2.5g of ceftobiprole by continuous infusion and plasma concentration is measured at Time 8
Time frame: Day 2 at Time 8
Plasma concentration at Time 12 on Day 2 of the steady-state
Patient is on 2.5g of ceftobiprole by continuous infusion and plasma concentration is measured at Time 12
Time frame: Day 2 at Time 12
Plasma concentration on Day 3 (after end of 24H infusion with ceftobiprole)
3ml blood samples are taken and plasma concentration is measured at regular intervals
Time frame: Day 3 at Time 2
Plasma concentration on Day 3 (after end of 24H infusion with ceftobiprole)
3ml blood samples are taken and plasma concentration is measured at regular intervals
Time frame: Day 3 at Time 6
Plasma concentration on Day 3 (after end of 24H infusion with ceftobiprole)
3ml blood samples are taken and plasma concentration is measured at regular intervals
Time frame: Day 3 at Time 8
Plasma concentration on Day 3 (after end of 24H infusion with ceftobiprole)
3ml blood samples are taken and plasma concentration is measured at regular intervals
Time frame: Day 3 at Time 12
Presence or not of Ceftobiprole in the epithelial lining fluid on Day 3 (after end of 24H infusion with ceftobiprole)
A sample of epithelial lining fluid is taken on Day 3 by bronchoalveolar lavage and analyzed.
Time frame: Day 3
Dose regimens defined by Monte Carlo simulations
Qualitative, pharmacokinetic modelisation using Pmetrics(r) software
Time frame: After day 3
Test of cure on Day 3
The clinician in charge of the patient evaluates the clinical response as follows : Resolution:All signs and symptoms related to infection have disappeared Improvement: Marked or moderate reduction of the seriousness and/or number of signs and symptoms of the infection. Failure: Insufficient decrease in signs and symptoms related to the infection. No change in patient's condition. Death, even undetermined.
Time frame: Day 3
Test of cure on Day 8
The clinician in charge of the patient evaluates the clinical response as follows : Resolution:All signs and symptoms related to infection have disappeared Improvement: Marked or moderate reduction of the seriousness and/or number of signs and symptoms of the infection. Failure: Insufficient decrease in signs and symptoms related to the infection. No change in patient's condition. Death, even undetermined.
Time frame: Day 8
Test of microbiological cure on Day 3
Descriptive and quantitative analysis on a cultivated sample taken via bronchoalveolar lavage on Day 3 to check for presence or not of ceftobiprole in the epithelial lining fluid.
Time frame: Day 3
Duration of stay at the intensive care unit.
28 days from the beginning of treatment, the number of days that the patient spent in the ICU are noted in the patient's medical file.
Time frame: Day 28
Vital status
28 days from the beginning of treatment, the patient's vital status is noted in the patient's medical file (dead/alive).
Time frame: Day 28
Number of days alive without mechanical ventilation
28 days from the beginning of treatment, the number of days that the patient has remained alive without mechanical ventilation is noted from the patient's medical file.
Time frame: Day 28
Renal function on Day 1
Creatinine clearance is measured in ML/min to evaluate the patient's renal function
Time frame: Day 1
Renal function on Day 2
Creatinine clearance is measured in ML/min to evaluate the patient's renal function
Time frame: Day 2
Evaluation of renal function on Day 3
Creatinine clearance is measured in ML/min to evaluate the patient's renal function
Time frame: Day 3
Evaluation of renal function on Day 8
Creatinine clearance is measured in ML/min to evaluate the patient's renal function
Time frame: Day 8
Evaluation of liver function on Day 1
The following measurements are taken in order to evaluate the patient's liver function: albumin level (in g/L) and transaminase doses (ALAT, ASAT).
Time frame: Day 1
Evaluation of liver function on Day 2
The following measurements are taken in order to evaluate the patient's liver function: albumin level (in g/L) and transaminase doses (ALAT, ASAT).
Time frame: Day 2
Evaluation of liver function on Day 3
The following measurements are taken in order to evaluate the patient's liver function: albumin level (in g/L) and transaminase doses (ALAT, ASAT).
Time frame: Day 3
Evaluation of liver function on Day 8
The following measurements are taken in order to evaluate the patient's liver function: albumin level (in g/L) and transaminase doses (ALAT, ASAT).
Time frame: Day 8