Assessment of the impact of pharmacist-led intervention with antibiotics in patients with bone and joint infection.

OBJECTIVES: The management of patients with bone and joint infections (BJIs) is complex. To improve this care, we carried out pharmaceutical actions in the orthopedic unit, including pharmacist-led-intervention (PLI) for patients requiring prolonged antibiotics. Few data exist regarding patient compliance, adherence and knowledge in cases of BJI. Data on hospital readmission are likewise limited, even though it is considered as a major determinant of clinical impact. The aim of this study was to assess the effectiveness of PLI regarding six-month readmissions. PATIENTS AND METHODS: Patients were assigned to two groups, both receiving standardized care. Two periods were compared: control group (CG) without PLI and interventional group (IG) with PLI throughout. The analysis was based on patient records and included: proportion of rehospitalizations at 6 months for infectious causes, reasons for antibiotic dose modification or antibiotic switch after 6 weeks, and descriptive analysis of data on pharmaceutical interventions in care pathways. RESULTS: Analysis was performed on 164 patients: 105 CG (64 %) patients and 59 IG (36 %) patients. There were no significant differences between IG and CG in patients' socio-demographic characteristics, infectious factors and antibiotic regimens. Amongst the CG patients, 23 were readmitted (22 %) versus 3 patients in the IG (5 %), (p = 0.002). There were significantly fewer treatment changes after 6 weeks (28.6 % versus 15.3 %, p = 0.05) for IG patients. CONCLUSION: In this retrospective survey, our results suggest a positive impact of PLI on 6-month readmission for all causes in BJI patients. These results need to be confirmed in a multicentric study.

Preparation and physicochemical stability of 50 mg/mL hydroxychloroquine oral suspension in SyrSpendⓇ SF PH4 (dry).

In the context of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic, hydroxychloroquine has been proposed as a potential agent to treat patients with COVID-19 (coronavirus disease 2019) caused by SARS-CoV-2 infection. Older adults are more susceptible to COVID-19 and some patients may require admission to the intensive care unit, where oral drug administration of solid forms may be compromised in many COVID-19 patients. However, a liquid formulation of hydroxychloroquine is not commercially available. This study describes how to prepare a 50 mg/mL hydroxychloroquine oral suspension using hydroxychloroquine sulfate powder and SyrSpendⓇ SF PH4 (dry) suspending vehicle. Moreover, a fully validated stability-indicating method has been developed to demonstrate the physicochemical stability of the compounded hydroxychloroquine oral suspension over 60 days under refrigeration (5 ± 3 °C). Finally, use of the proposed oral suspension provides a reliable solution to perform safe and accurate administration of hydroxychloroquine to patients with SARS-CoV-2 infection.

Overcoming stability challenges during continuous intravenous administration of high-dose amoxicillin using portable elastomeric pumps.

While treatment of serious infectious diseases may require high-dose amoxicillin, continuous infusion may be limited by lack of knowledge regarding the chemical stability of the drug. Therefore, we have performed a comprehensive study so as to determine the chemical stability of high-dose amoxicillin solutions conducive to safe and effective continuous intravenous administration using portable elastomeric pumps. First, amoxicillin solubility in water was assessed within the range of 25 to 300 mg/mL. Then, amoxicillin solutions were prepared at different concentrations (25, 50, 125, 250 mg/mL) and stored in different conditions (5±2°C, 25±1°C, 30±1°C and 37±1°C) to investigate the influence of concentration and temperature on the chemical stability of amoxicillin. Finally, its stability was assessed under optimized conditions using a fully validated HPLC-UV stability-indicating method. Degradation products of amoxicillin were investigated by accurate mass determination using high-resolution mass spectrometry. Amoxicillin displayed limited water solubility requiring reconstitution at concentrations below or equal to 150 mg/mL. Amoxicillin degradation were time, temperature as well as concentration-dependent, resulting in short-term stability, in particular at high concentrations. Four degradation products of amoxicillin have been identified. Among them, amoxicilloic acid and diketopiperazine amoxicillin are at risk of allergic reaction and may accumulate in the patient. Optimized conditions allowing for continuous infusion of high-dose amoxicillin has been determined: amoxicillin should be reconstituted at 25 mg/mL and stored up to 12 hours at room temperature (22 ± 4°C) or up to 24 hours between 4 and 8°C.