Hospital compounding to face shortage: A case study of the development of a lopinavir-ritonavir oral suspension during the first wave of SARS-COV-2 in France.

The potential usefulness of lopinavir-ritonavir on Covid 19 infection during the first wave of contamination in France had boosted Kaletra® syrup prescription to the point of causing its national shortage. In the intensive care units of Parisian hospitals in charge of patients with life-threatening viral contamination, caregivers had to resort to lopinavir-ritonavir-based tablets, crushing them and then dispersing the powder in milk to facilitate administration by nasogastric tube. The difficulties and poor control of this degraded mode, which does not always ensure control of the amount of the drug in the prepared dose and may induce insufficient antiviral exposure, led us to develop in a very short time, while ensuring quality control proportional to the risk, a liquid form as an alternative to Kaletra® oral solution shortage. For this purpose, we describe this compounding formulation and its preparation process, while justifying the quality control strategy adapted to the risk as well as its chemical and physical stability. Based on the chemical and physical studies, the preparation was showed to be stable during at least 2 months between +2°C and +8°C and 1 week at room temperature. This has resulted in the design of kits that include multi-dose packaging and a measuring device and contain the appropriate quantities of drugs to ensure at least one week's treatment for each patient, during which time the kit in use can be stored at room temperature. The intensive care team used this treatment under conditions that they considered well adapted until the imported specialty became available.

Imatinib: Major photocatalytic degradation pathways in aqueous media and the relative toxicity of its transformation products.

Imatinib (IMA) is a highly potent tyrosine kinase inhibitor used as first-line anti-cancer drug in the treatment of chronic myeloid leukemia. Due to its universal mechanism of action, IMA also has endocrine and mutagenic disrupting effects in vivo and in vitro, which raises the question of its environmental impact. However, to date, very little information is available on its environmental fate and the potential role of its transformation products (TPs) on aquatic organisms. Given the IMA resistance to hydrolysis and direct photolysis according to the literature, we sought to generate TPs through oxidative and radical conditions using the AOPs pathway. Thus, the reactivity of the cytotoxic drug IMA in water in the presence of OH and h+ was investigated for the first time in the present work. In this regard, a non-targeted screening approach was applied in order to reveal its potential TPs. The tentative structural elucidation of the detected TPs was performed by LC-HRMSn. The proposed approach allowed detecting a total of twelve TPs, among which eleven are being described for the first time in this work. Although the structures of these TPs could not be positively confirmed due to lack of standards, their chemical formulas and product ions can be added to databases, which will allow their screening in future monitoring studies. Using the quantitative structure-activity relationship (QSAR) approach and rule-based software, we have shown that the detected TPs possess, like their parent molecule, comparable acute toxicity as well as mutagenic and estrogenic potential. In addition to the in silico studies, we also found that the samples obtained at different exposure times to oxidative conditions, including those where IMA is no longer detected, retained toxicity in vitro. Such results suggest further studies are needed to increase our knowledge of the impact of imatinib on the environment.

[Standard doses applied to preparations of injectable drugs and their reconstitution in the hospital: methodology and implementation]. / Présentation d'une démarche d'aide et de réflexion pour la mise en place de doses standards appliquée aux préparations et reconstitution d'injectables en milieu hospitalier.

INTRODUCTION: Improvement of healthcare quality and safety are two main goals for hospitals. High risk preparations of injectable drugs is one of the possible areas for improvement. In this context the production of batches of standard doses is a practical solution in response to the increased demand. Some toolkits exists to facilitate the implementation of dose banding, but, to our knowledge, no complete strategy was available until today. AIM AND PURPOSE: To propose a rational approach to analyse the possibility of implementing standard doses and choose the most relevant drugs for dose standardization. METHOD: The method is based on the analysis of literature focusing on different themes: safety, international guidelines, batch production regulation and stability studies. RESULTS: An approach on the strategies to develop is detailed for pharmacists willing to implement standard doses. All key stages are discussed: the needs of care units, the analysis and risk assessment, the stability studies and the practical implementation of the standard doses preparation and quality control. CONCLUSION: The implementation of standard doses seems a rational and necessary evolution of hospital pharmacy in response to the increase of compounding activity and the requirements of quality preparation. A global and all-inclusive approach is needed for this purpose. All parameters have to be considered to avoid errors. A process and a decision aid are suggested to facilitate the development of standard doses.