Clinical Pharmacology of Rocuronium in Infants and Children

The main clinical use of the neuromuscular blocking agents is an adjuvant in surgical anaesthesia to obtain relaxation of skeletal muscle, particularly of the abdominal wall, to facilitate surgical manipulations. Rocuronium can be used instead of suxamethonium to provide rapid muscle paralysis during tracheal intubation but the recovery is much slower. Rocuronium is administered intravenously to infants and children. In infants, rocuronium is administered at a dose of 450 µg/kg for providing muscle relaxation for laryngeal intubation. To provide sustained paralysis, rocuronium is given at a dose of 600 µg/kg. In children, the neuromuscular blockade is obtained with 600 µg/kg followed by an intravenous infusion of 150 µg/kg per hour. For assisted ventilation in intensive care, rocuronium is administered at a dose of 600 µg/kg followed by an intravenous infusion of 300 to 600 µg/kg per hour. The effects of rocuronium have been extensively studied in infants and children. Rocuronium is converted into 17-desacetyl rocuronium. The pharmacokinetics of rocuronium have been studied in infants and children and the mean residence time is 55.6 and 25.6 min (P-value < 0.01) in infant and children, respectively. Rocuronium interacts with drugs, the treatment of infants and children with rocuronium has been studied, and rocuronium poorly crosses the human placenta. The aim of this study is to review the published data on rocuronium dosing, pharmacokinetics, and treatment in infants and children, and rocuronium metabolism and transfer across the human placenta.

Clinical Pharmacology of Levetiracetam in Infants and Children

Levetiracetam inhibits focal and secondary generalized tonic-clonic seizures. The mechanism of levetiracetam action is not fully understood, however the correlation between binding affinity of levetiracetam and its analogues and their potency toward audiogenic seizures suggest that the synaptic vesicle glycoprotein 2A mediates the anticonvulsant effects of levetiracetam. The neural function of the synaptic vesicle 2A protein is not fully understood, but binding of levetiracetam to synaptic vesicle glycoprotein 2A might affect neuronal excitability by modifying the release of glutamate GABA through an action on vesicular function. Synaptic vesicle glycoprotein 2A may plain a role in vesicle recycling following exocytosis of neurotransmitter. In addition, levetiracetam inhibits N-type Ca2+ channels and Ca2+ release from intracellular stores. Levetiracetam may be administered intravenously or orally to infants and children and in children the levetiracetam dose varies according to the child age and body-weight. Levetiracetam is almost completed absorbed after oral administration and levetiracetam is found efficacy and safe in infants and children but it may induce adverse-effects. The levetiracetam elimination half-life is about 6 hours in infants and children, and in children the renal clearance is similar to the non-renal clearance. The prophylaxis, treatment, and trials with levetiracetam have been extensively studied in infants and children. Levetiracetam freely crosses the human placenta and freely migrates into the breast-milk. The aim of this study is to review the levetiracetam dosing, efficacy, safety, adverse-effects, pharmacokinetics, prophylaxis, treatment, and trials and transfer of levetiracetam across the human placenta and levetiracetam migration into the breast-milk.

Metabolic Rewiring by Human Placenta-Derived Mesenchymal Stem Cell Therapy Promotes Rejuvenation in Aged Female Rats

Aging is a degenerative process involving cell function deterioration, leading to altered metabolic pathways, increased metabolite diversity, and dysregulated metabolism. Previously, we reported that human placenta-derived mesenchymal stem cells (hPD-MSCs) have therapeutic effects on ovarian aging. This study aimed to identify hPD-MSC therapy-induced responses at the metabolite and protein levels and serum biomarker(s) of aging and/or rejuvenation. We observed weight loss after hPD-MSC therapy. Importantly, insulin-like growth factor-I (IGF-I), known prolongs healthy life spans, were markedly elevated in serum. Capillary electrophoresis-time-of-flight mass spectrometry (CE-TOF/MS) analysis identified 176 metabolites, among which the levels of 3-hydroxybutyric acid, glycocholic acid, and taurine, which are associated with health and longevity, were enhanced after hPD-MSC stimulation. Furthermore, after hPD-MSC therapy, the levels of vitamin B6 and its metabolite pyridoxal 5′-phosphate were markedly increased in the serum and liver, respectively. Interestingly, hPD-MSC therapy promoted serotonin production due to increased vitamin B6 metabolism rates. Increased liver serotonin levels after multiple-injection therapy altered the expression of mRNAs and proteins associated with hepatocyte proliferation and mitochondrial biogenesis. Changes in metabolites in circulation after hPD-MSC therapy can be used to identify biomarker(s) of aging and/or rejuvenation. In addition, serotonin is a valuable therapeutic target for reversing aging-associated liver degeneration.

Clinical pharmacology of lorazepam in infants and children

Lorazepam is a benzodiazepine has antiepileptic activity; it may be administered intravenously, intramuscularly, orally, by intranasal or buccal application and following oral dosing it is well absorbed. In infants, the initial intravenous dose of lorazepam is 100 µg/kg and in children the initial oral and intravenous dose is 50 to 100 µg/kg and the dose varies according to the child age. Lorazepam has been found efficacy and safe in infants and children but it may induce adverse-effects. Lorazepam is a racemate and the R and S enantiomers are conjugated with glucuronic acid in human liver microsomes and the respective Km and Vmax values are 29+8.9 and 36+10 µM and 7.4+1.9 and 10+3.8 pmol/min*mg. Lorazepam interacts with drugs and the interaction may affect the activity or metabolism of lorazepam. The pharmacokinetics of lorazepam have been studied in infants and children and in diseased children. In infants and children the elimination half-life is about 15 hours and it is about 24 hours and about 37 hours in children with severe malaria and convulsions following intravenous and intramuscular administration, respectively. The treatment and trials with lorazepam have been studied in infants and children. Lorazepam freely crosses the human placenta and poorly migrates into the breast-milk. The aim of this study is to review the published data on lorazepam dosing, efficacy and safety, adverse-effects, metabolism, interaction with drugs, pharmacokinetics, treatment and trials in infants and children and the lorazepam transfer across the human placenta and migration into the breast-milk.

The Impact of Oxidative Stress of Environmental Origin on the Onset of Placental Diseases

Oxidative stress (OS) plays a pivotal role in placental development; however, abnormal loads in oxidative stress molecules may overwhelm the placental defense mechanisms and cause pathological situations. The environment in which the mother evolves triggers an exposure of the placental tissue to chemical, physical, and biological agents of OS, with potential pathological consequences. Here we shortly review the physiological and developmental functions of OS in the placenta, and present a series of environmental pollutants inducing placental oxidative stress, for which some insights regarding the underlying mechanisms have been proposed, leading to a recapitulation of the noxious effects of OS of environmental origin upon the human placenta.