Developmental Pharmacokinetics of Antibiotics Used in Neonatal ICU: Focus on Preterm Infants

Physiologically-based pharmacokinetic modeling to predict the exposure and to assess pharmacodynamics of daptomycin in infants within 1 year old

Daptomycin is widely used in pediatric patients for serious infections caused by Gram-positive bacteria, however, studies regarding its safety and efficacy in infants within 1 year old are very limited. A physiologically-based pharmacokinetic (PBPK) model of daptomycin was built for children aged 1-17 years old and extrapolated to infants within 1 year old to evaluate pharmacodynamics (PD) based on efficacy and safety considerations. Monte Carlo Simulations (MCSs) were conducted to determine the probabilities of target attainment (PTA) and cumulative fractions of response (CFR) of daptomycin. The pharmacokinetic (PK) of daptomycin did not differ much in the population of infants within 1 year of age, with peak plasma concentration (Cmax) and area under the curve (AUC) maintained at an approximate level at all months of age, while the average trough concentration of daptomycin was 3.49 μg/mL when 10 mg/kg daptomycin was given, and 4.98 ug /mL at 15 mg/kg. According to the results of the MCSs, 10mg/kg daptomycin provides good antimicrobial effect for S.pneumoniae and MSSA. With the increase of dosage, the CFR value of daptomycin against MRSA, E.faecalis and E.faecium also gradually reached >90 %, except for E.faecalis with an average CFR of only 82.94 % at 12mg/kg. This is a daptomycin PBPK model in infants within 1 year of age, dose regimen higher than 10 mg/kg should be recommended for this population in the treatment of MRSA, E. faecalis, and E. faecalis.

The Role of Rifampin in Prosthetic Joint Infections: Efficacy, Challenges, and Clinical Evidence

Rifampin is a crucial antibiotic in the management of prosthetic joint infections (PJI), particularly due to its effectiveness against staphylococcal bacteria and its ability to penetrate and disrupt biofilms. This review evaluates rifampin's role by examining its mechanism of action, clinical efficacy, and integration into treatment regimens based on recent evidence and guidelines. Rifampin's synergistic effects with other antibiotics, such as β-lactams and vancomycin, enhance bacterial eradication, and some evidence shows that it improves patient outcomes. However, evidence supporting its use is limited by the scarcity of robust human clinical trials, and challenges such as potential drug interactions and resistance development necessitate careful management. Ongoing research is needed to refine its use and address existing limitations in clinical practice.

Drug-Drug Interactions in Nosocomial Infections: An Updated Review for Clinicians

Prevention, assessment, and identification of drug-drug interactions (DDIs) represent a challenge for healthcare professionals, especially in nosocomial settings. This narrative review aims to provide a thorough assessment of the most clinically significant DDIs for antibiotics used in healthcare-associated infections. Complex poly-pharmaceutical regimens, targeting multiple pathogens or targeting one pathogen in the presence of another comorbidity, have an increased predisposition to result in life-threatening DDIs. Recognising, assessing, and limiting DDIs in nosocomial infections offers promising opportunities for improving health outcomes. The objective of this review is to provide clinicians with practical advice to prevent or mitigate DDIs, with the aim of increasing the safety and effectiveness of therapy. DDI management is of significant importance for individualising therapy according to the patient, disease status, and associated comorbidities.

Gut microbiota genome features associated with brain injury in extremely premature infants

Severe brain damage is common among premature infants, and the gut microbiota has been implicated in its pathology. Although the order of colonizing bacteria is well described, the mechanisms underlying aberrant assembly of the gut microbiota remain elusive. Here, we employed long-read nanopore sequencing to assess abundances of microbial species and their functional genomic potential in stool samples from a cohort of 30 extremely premature infants. We identify several key microbial traits significantly associated with severe brain damage, such as the genomic potential for nitrate respiration and iron scavenging. Members of the Enterobacteriaceae were prevalent across the cohort and displayed a versatile metabolic potential, including pathogenic and nonpathogenic traits. Predominance of Enterobacter hormaechei and Klebsiella pneumoniae were associated with an overall loss of genomic functional redundancy as well as poor neurophysiological outcome. These findings reveal microbial traits that may be involved in exacerbating brain injury in extremely premature infants and provide suitable targets for therapeutic interventions.

Pharmacokinetic and Pharmacodynamic Considerations of Antibiotic Use in Neonates

The selection of an appropriate dose of a given antibiotic for a neonate not only requires knowledge of the drug's basic pharmacokinetic (PK) and pharmacodynamic (PD) properties but also the profound effects that organ development might have on the volume of distribution and clearance, both of which may affect the PK/PD of a drug. Interest has grown in alternative antibiotic dosing strategies that are better aligned with the antibiotic's PK and PD properties. These strategies should be used in conjunction with minimum inhibitory concentration measurements and therapeutic drug monitoring to measure their potential success. They can also guide the clinician in tailoring the delivery of antibiotics to suit an individual patient's needs. Model-informed precision dosing, such as Bayesian forecasting dosing software (which incorporates PK/PD population models), may be utilized to optimize antibiotic exposure in neonatal populations. Consequently, optimizing the antibiotic dose and exposure in each newborn requires expertise in different fields. It drives the collaboration of physicians together with lab technicians and quantitative clinical pharmacologists.

Improving the Treatment of Neonatal Sepsis in Resource-Limited Settings: Gaps and Recommendations

Neonatal sepsis causes significant global morbidity and mortality, with the highest burden in resource-limited settings where 99% of neonatal deaths occur. There are multiple challenges to achieving successful treatment of neonates in this setting. Firstly, reliable and low-cost strategies for risk identification are urgently needed to facilitate treatment as early as possible. Improved laboratory capacity to allow identification of causative organisms would support antimicrobial stewardship. Antibiotic treatment is still hampered by availability, but also increasingly by antimicrobial resistance - making surveillance of organisms and judicious antibiotic use a priority. Finally, supportive care is key in the management of the neonate with sepsis and has been underrecognized as a priority in resource-limited settings. This includes fluid balance and nutritional support in the acute phase, and follow-up care in order to mitigate complications and optimise long-term outcomes. There is much more work to be done in identifying the holistic needs of neonates and their families to provide effective family-integrated interventions and complete the package of neonatal sepsis management in resource-limited settings.

Physiologically Based Pharmacokinetic Modeling in Neonates: Current Status and Future Perspectives

Rational drug use in special populations is a clinical problem that doctors and pharma-cists must consider seriously. Neonates are the most physiologically immature and vulnerable to drug dosing. There is a pronounced difference in the anatomical and physiological profiles be-tween neonates and older people, affecting the absorption, distribution, metabolism, and excretion of drugs in vivo, ultimately leading to changes in drug concentration. Thus, dose adjustments in neonates are necessary to achieve adequate therapeutic concentrations and avoid drug toxicity. Over the past few decades, modeling and simulation techniques, especially physiologically based pharmacokinetic (PBPK) modeling, have been increasingly used in pediatric drug development and clinical therapy. This rigorously designed and verified model can effectively compensate for the deficiencies of clinical trials in neonates, provide a valuable reference for clinical research design, and even replace some clinical trials to predict drug plasma concentrations in newborns. This review introduces previous findings regarding age-dependent physiological changes and pathological factors affecting neonatal pharmacokinetics, along with their research means. The application of PBPK modeling in neonatal pharmacokinetic studies of various medications is also reviewed. Based on this, we propose future perspectives on neonatal PBPK modeling and hope for its broader application.

Pharmacokinetics of Antibacterial Agents in the Elderly: The Body of Evidence

Infections are important factors contributing to the morbidity and mortality among elderly patients. High rates of consumption of antimicrobial agents by the elderly may result in increased risk of toxic reactions, deteriorating functions of various organs and systems and leading to the prolongation of hospital stay, admission to the intensive care unit, disability, and lethal outcome. Both safety and efficacy of antibiotics are determined by the values of their plasma concentrations, widely affected by physiologic and pathologic age-related changes specific for the elderly population. Drug absorption, distribution, metabolism, and excretion are altered in different extents depending on functional and morphological changes in the cardiovascular system, gastrointestinal tract, liver, and kidneys. Water and fat content, skeletal muscle mass, nutritional status, use of concomitant drugs are other determinants of pharmacokinetics changes observed in the elderly. The choice of a proper dosing regimen is essential to provide effective and safe antibiotic therapy in terms of attainment of certain pharmacodynamic targets. The objective of this review is to perform a structure of evidence on the age-related changes contributing to the alteration of pharmacokinetic parameters in the elderly.