An increased incidence of reproductive problems, including infertility, miscarriage, low birth weight newborns, and shorter duration of breast-feeding, are known to exist in women with coeliac disease; some of these conditions are improved by a gluten-free diet. We have tried to ascertain the prevalence of coeliac disease in 99 couples who were being evaluated for infertility, compared with the known prevalence of silent disease in the population of Northern Sardinia, in which it is endemic. Of all women, four tested positive for at least two out of three markers: immunoglobulin A (IgA) antigliadin, immunoglobulin (IgG) antigliadin, and anti-endomysium antibodies, and underwent a jejunal biopsy; three had histological evidence of coeliac disease. One male partner was positive for two markers, and had a diagnostic jejunal biopsy. The prevalence of coeliac disease in infertile women seems higher (three out of 99, 3. 03%) in the study group than in the general population (17 out of 1607, 1.06%), and particularly in the subgroup with unexplained infertility (two out of 25, 8%, P < 0.03). Screening for coeliac disease should be part of the diagnostic work-up of infertile women, particularly when no apparent cause can be ascertained after standard evaluation.
Ethical and practical constraints encourage the optimal use of resources in pediatric drug development. Modeling and simulation has emerged as a promising methodology acknowledged by industry, academia, and regulators. We previously proposed a paradigm in pediatric drug development, whereby modeling and simulation is used as a decision tool, for study optimization and/or as a data analysis tool. Three and a half years since the Paediatric Regulation came into force in 2007, the European Medicines Agency has gained substantial experience in the use of modeling and simulation in pediatric drug development. In this review, we present examples on how the proposed paradigm applies in real case scenarios of planned pharmaceutical developments. We also report the results of a pediatric database search to further 'validate' the paradigm. There were 47 of 210 positive pediatric investigation plan (PIP) opinions that made reference to modeling and simulation (data included all positive opinions issued up to January 2010). This reflects a major shift in regulatory thinking. The ratio of PIPs with modeling and simulation rose to two in five based on the summary reports. Population pharmacokinetic (POP-PK) and pharmacodynamics (POP-PD) and physiologically based pharmacokinetic models are widely used by industry and endorsed or even imposed by regulators as a way to circumvent some difficulties in developing medicinal products in children. The knowledge of the effects of age and size on PK is improving, and models are widely employed to make optimal use of this knowledge but less is known about the effects of size and maturation on PD, disease progression, and safety. Extrapolation of efficacy from different age groups is often used in pediatric medicinal development as another means to alleviate the burden of clinical trials in children, and this can be aided by modeling and simulation to supplement clinical data. The regulatory assessment is finally judged on clinical grounds such as feasibility, ethical issues, prioritization of studies, and unmet medical need. The regulators are eager to expand the use of modeling and simulation to elucidate safety issues, to evaluate the effects of disease (e.g., renal or hepatic dysfunction), and to qualify mechanistic models that could help shift the current medicinal development paradigm.
The year 2017 marks the tenth anniversary of entry into force of the Paediatric Regulation in the European Union (EU). This law aimed to stimulate the development of paediatric medicines and provide more information on their use, as a response to the lack of evidence and approval of medicines for children. The European Medicines Agency (EMA) has had a central role in the implementation of the Regulation. Pharmaceutical companies need to submit a paediatric investigation plan (PIP) to the EMA's Paediatric Committee (PDCO) for every new medicine, unless an exemption (waiver) is granted. The plans, which describe the development of drugs for children, must be agreed well in advance of the request for marketing authorization of the medicine. Deferrals of studies can be granted to allow approval in adults before the completion of paediatric studies. Between January 2007 and December 2016, a total of 273 new medicines and 43 additional pharmaceutical forms appropriate for use in children were authorized in the EU, and 950 PIPs were agreed by the EMA. In addition, 486 waivers of the development of a medicine in one or more medical conditions were agreed. The Paediatric Regulation has had a very positive impact on paediatric drug development, as exemplified by a comparison of two periods of 3 years before and after entry into force of the Regulation. We conclude that the Regulation has resulted in more medicines for children and more information on the pediatric use of medicines in the EU being available to clinicians.
Pediatric legislation in the US and the EU is driving pediatric product development on an international scale. To facilitate harmonization and global development of pediatric medicines, it is important to understand the legislative requirements that must be met along with incentives that exist in the US and the EU to include pediatric patients in therapeutic clinical trials. Although there are many similarities, differences exist. This review is an effort to enhance understanding of the pediatric legislation in both regions. It is intended as an overview to supplement the region-specific legislation and guidance documents that are available on the websites of the US Food and Drug Administration (FDA) and the European Medicines Agency (EMA). Despite differences, the goal of the legislation in both the EU and the US is to incentivize and require timely, ethical, and sound scientific development of pharmaceutical products for the pediatric population and to provide information for their safe and effective use.
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