Population pharmacodynamic model for low molecular weight heparin nadroparin in morbidly obese and non-obese patients using anti-Xa levels as endpoint

In absence of specific dosing guidelines, the optimal dose of low molecular weight heparins for thrombosis prophylaxis in morbidly obese patients (BMI>40 kg/m(2)) remains unknown. In order to guide dosing in this patient group, a pharmacodynamics model is developed for nadroparin in morbidly obese and non-obese patients using anti-Xa levels as an endpoint, thereby characterizing the influence of excessive body weight on different pharmacodynamic model parameters.\nTwenty-eight morbidly obese and seven non-obese patients receiving 5700 IU and 2850 IU subcutaneous (s.c.) nadroparin for surgery, respectively, were included with a mean total body weight (TBW) of 135 kg (range 72-252 kg). Up to 11 anti-Xa levels were collected from the start until 24 h after nadroparin administration. Population pharmacodynamic modelling with covariate analysis was performed using NONMEM.\nIn a two-compartment pharmacodynamic model with baseline endogenous anti-Xa levels, the effect of nadroparin was found to be delayed and could be best described using a transit compartment. TBW was the most predictive covariate for clearance (CL=23.0 mL/min × (TBW/70)), while lean body weight (LBW) proved the most predictive covariate for central volume of distribution (V1=7.0 L × (LBW/60)).\nA pharmacodynamic model was developed characterizing anti-Xa levels after s.c. administration of nadroparin in patients weighing between 72 and 252 kg with TBW and LBW as the major determinants for clearance and volume of distribution, respectively.\nPURPOSE\nMETHODS\nRESULTS\nCONCLUSIONSPharmacolog

Phenylketonuria in the Netherlands: 93% of the mutations are detected by single-strand conformation analysis.

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TCERG1L allelic variation is associated with cisplatin-induced hearing loss in childhood cancer, a PanCareLIFE study

In children with cancer, the heterogeneity in ototoxicity occurrence after similar treatment suggests a role for genetic susceptibility. Using a genome-wide association study (GWAS) approach, we identified a genetic variant in TCERG1L to be associated with hearing loss in 390 non-cranial irradiated, cisplatin-treated children with cancer. These results were replicated in two independent, similarly treated cohorts. Modulating TCERG1L expression in cultured human cells revealed significantly altered cellular responses to cisplatin-induced cytokine secretion and toxicity. These results contribute to insights into the genetic and pathophysiological basis of cisplatin-induced ototoxicity.</p