Your search keyword '"Whomsley R"' showing total 7 results

1. In vitro inhibition of human liver drug metabolizing enzymes by second generation antihistamines

Author

Nicolas, J.-M., Whomsley, R., Collart, P., and Roba, J.

Published

1999

2. Prioritisation of data-poor pharmaceuticals for empirical testing and environmental risk assessment.

Author

Cannata C, Backhaus T, Bramke I, Caraman M, Lombardo A, Whomsley R, Moermond CTA, and Ragas AMJ

Subjects

Animals, Humans, Ecosystem, Risk Assessment methods, Fishes, Pharmaceutical Preparations, Environmental Monitoring methods, Water Pollutants, Chemical analysis

Abstract

There are more than 3,500 active pharmaceutical ingredients (APIs) on the global market for human and veterinary use. Residues of these APIs eventually reach the aquatic environment. Although an environmental risk assessment (ERA) for marketing authorization applications of medicinal products is mandatory in the European Union since 2006, an ERA is lacking for most medicines approved prior to 2006 (legacy APIs). Since it is unfeasible to perform extensive ERA tests for all these legacy APIs, there is a need for prioritization of testing based on the limited data available. Prioritized APIs can then be further investigated to estimate their environmental risk in more detail. In this study, we prioritized more than 1,000 APIs used in Europe based on their predicted risk for aquatic freshwater ecosystems. We determined their risk by combining an exposure estimate (Measured or Predicted Environmental Concentration; MEC or PEC, respectively) with a Predicted No Effect Concentration (PNEC). We developed several procedures to combine the limited empirical data available with in silico data, resulting in multiple API rankings varying in data needs and level of conservativeness. In comparing empirical with in silico data, our analysis confirmed that the PEC estimated with the default parameters used by the European Medicines Agency often - but not always - represents a worst-case scenario. Comparing the ecotoxicological data for the three main taxonomic groups, we found that fish represents the most sensitive species group for most of the APIs in our list. We furthermore show that the use of in silico tools can result in a substantial underestimation of the ecotoxicity of APIs. After combining the different exposure and effect estimates into four risk rankings, the top-ranking APIs were further screened for availability of ecotoxicity data in data repositories. This ultimately resulted in the prioritization of 15 APIs for further ecotoxicological testing and/or exposure assessment., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Cristiana Cannata reports financial support was provided by PREMIER (Prioritisation and Risk Evaluation of Medicines in the EnviRonment). Irene Bramke reports a relationship with AstraZeneca that includes: employment., (Copyright © 2023 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024

3. EMA commentary on the ICH guideline for testing for carcinogenicity of pharmaceuticals.

Author

van der Laan JW, Andersson M, Beken S, Bonelli M, Brendler-Schwaab S, Kane R, Pasanen M, Ponzano S, Paur J, Siezen C, Soleng A, and Whomsley R

Subjects

Humans, Pharmaceutical Preparations, Risk Assessment

Published

2023

4. The EU Response to the Presence of Nitrosamine Impurities in Medicines.

Author

Ruepp R, Frötschl R, Bream R, Filancia M, Girard T, Spinei A, Weise M, and Whomsley R

Abstract

The unexpected detection of nitrosamine impurities in human medicines has recently seen global regulators act to understand the risks of these contaminations to patients and to limit their presence. Over 300 nitrosamines are known, many of which are highly potent mutagenic carcinogens. Regulators first became aware of the presence of nitrosamines in EU medicines in 2018, with reports of detection of N -nitroso-dimethylamine (NDMA) in valsartan from one manufacturer. A subsequent EU review of all valsartan medicines was triggered by the European Medicines Agency (EMA) and was later extended to other angiotensin receptor blockers/sartans. A separate review was also started for ranitidine medicines. This was followed by an EU-wide examination of the risk of presence of nitrosamines in all human medicines. This article reflects on the investigation of the EU regulatory network into the presence of nitrosamines and the scientific knowledge informing recommendations for developers on how to limit nitrosamines in medicines., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Ruepp, Frötschl, Bream, Filancia, Girard, Spinei, Weise and Whomsley.)

Published

2021

5. Environmental risk assessment of advanced therapies containing genetically modified organisms in the EU.

Author

Whomsley R, Palmi Reig V, and Hidalgo-Simon A

Subjects

European Union, Humans, Organisms, Genetically Modified, Risk Assessment, Genetic Therapy

Abstract

Gene therapy medicinal products have the potential to provide curative treatment for many diseases with current limited therapeutic options. As advanced therapy medicinal products (ATMPs), these therapies undergo a centralised, single European Union authorisation by the European Medicines Agency (EMA), but the risks and potential harm to the environment and population at large are weighted in each application, and different interpretations at national level exist. A streamlined procedure is now in place to facilitate a consistent approach for the assessment of the environmental risks of medicines containing genetically modified organisms for both clinical trial applications and marketing authorisation applications. This article provides an overview of basic requirements across the EU, an overview of the new streamlined process and discusses available guidance for developers with particular emphasis on marketing authorisation applications. All these initiatives are aimed to remove hurdles for ATMP developers and facilitate faster access to patients., (© 2021 British Pharmacological Society.)

Published

2021

6. Vandetanib-eluting Radiopaque Beads: In vivo Pharmacokinetics, Safety and Toxicity Evaluation following Swine Liver Embolization.

Author

Denys A, Czuczman P, Grey D, Bascal Z, Whomsley R, Kilpatrick H, and Lewis AL

Subjects

Animals, Contrast Media administration & dosage, Injections, Intra-Arterial, Liver diagnostic imaging, Models, Animal, Piperidines administration & dosage, Quinazolines administration & dosage, Radiography, Abdominal, Swine, Tomography, X-Ray Computed, Contrast Media adverse effects, Contrast Media pharmacokinetics, Embolization, Therapeutic methods, Liver pathology, Piperidines adverse effects, Piperidines pharmacokinetics, Quinazolines adverse effects, Quinazolines pharmacokinetics

Abstract

Purpose: To evaluate the plasma and tissue pharmacokinetics, safety and toxicity following intra-arterial hepatic artery administration of Vandetanib (VTB)-eluting Radiopaque Beads (VERB) in healthy swine., Materials and Methods: In a first phase, healthy swine were treated with hepatic intra-arterial administration of VERB at target dose loading strengths of 36 mg/mL (VERB36), 72 mg/mL (VERB72) and 120 mg/mL (VERB120). Blood and tissue samples were taken and analysed for VTB and metabolites to determine pharmacokinetic parameters for the different dose forms over 30 days. In a second phase, animals were treated with unloaded radiopaque beads or high dose VTB loaded beads (VERB100, 100 mg/mL). Tissue samples from embolized and non-embolized areas of the liver were evaluated at necropsy (30 and 90 days) for determination of VTB and metabolite levels and tissue pathology. Imaging was performed prior to sacrifice using multi-detector computed tomography (MDCT) and imaging findings correlated with pathological changes in the tissue and location of the radiopaque beads., Results: The peak plasma levels of VTB (C max ) released from the various doses of VERB ranged between 6.19-17.3 ng/mL indicating a low systemic burst release. The plasma profile of VTB was consistent with a distribution phase up to 6 h after administration followed by elimination with a half-life of 20-23 h. The AUC of VTB and its major metabolite N-desmethyl vandetanib (NDM VTB) was approximately linear with the dose strength of VERB. VTB plasma levels were at or below limits of detection two weeks after administration. In liver samples, VTB and NDM VTB were present in treated sections at 30 days after administration at levels above the in vitro IC 50 for biological effectiveness. At 90 days both analytes were still present in treated liver but were near or below the limit of quantification in untreated liver sections, demonstrating sustained release from the VERB. Comparison of the reduction of the liver lobe size and associated tissue changes suggested a more effective embolization with VERB compared to the beads without drug., Conclusions: Hepatic intra-arterial administration of VERB results in a low systemic exposure and enables sustained delivery of VTB to target tissues following embolization. Changes in the liver tissue are consistent with an effective embolization and this study has demonstrated that VERB100 is well tolerated with no obvious systemic toxicity., Competing Interests: Competing Interests: The authors have declared that no competing interest exists.

Published

2017

7. Defence mechanisms of olfactory neuro-epithelium: mucosa regeneration, metabolising enzymes and transporters.

Author

Watelet JB, Strolin-Benedetti M, and Whomsley R

Subjects

Humans, Olfactory Mucosa cytology, Enzymes metabolism, Membrane Transport Proteins metabolism, Neuroepithelial Cells physiology, Olfactory Mucosa metabolism, Olfactory Pathways physiology, Regeneration physiology, Smell physiology

Abstract

The olfactory neuro-epithelium is highly sensitive to chemicals and its direct microbiological environment. It also plays a role as an interface between the airways and the nervous system, and so it has developed several defence instruments for rapid regeneration or for the detoxification of the immediate environment. This review illustrates three of these defence mechanisms: regeneration of the epithelium, local production of metabolising enzymes and xenobiotic transporters. Toxicants can inflict damage by a direct toxic response. Alternatively, they may require metabolic activation to produce the proximate toxicant. In addition to detoxifying inhaled and systemically derived xenobiotics, the local olfactory metabolism may fulfil multiple functions such as the modification of inhaled odorant, the modulation of endogenous signalling molecules and the protection of other tissues such as the CNS and lungs from inhaled toxicants. Finally, the permeability of nasal and olfactory mucosa is an important efficacy parameter for some anti-allergic drugs delivered by intranasal administration or inhalation. Efflux or update transporters expressed in these tissues may therefore significantly influence the pharmacokinetics of drugs administered topically.

Published

2009