Optimising insulin aspart practices in a neonatal intensive care unit: a clinical and pharmaco-technical study.

Neonatal hyperglycaemia is frequent and requires insulin therapy. To resolve the difficulties encountered by paediatricians in stabilising glycaemia, the preparation and administration of insulin aspart were assessed and optimised. After high-performance liquid chromatography (HPLC-UV) assessment of insulin aspart preparations made according to the old protocol, a new protocol was drawn up. Dosage reliability of solutions prepared by paediatric nurses was evaluated by HPLC-UV. This new protocol was also tested in a Y-infusion situation and the need to saturate infusion tubes assessed. Wide deviations in insulin aspart concentrations were found between theoretical concentrations and preparations made according to the old protocol. Glycated insulin aspart was found in the majority of these preparations. The new protocol significantly reduced the variability of data and relative deviations around the target value. It also eliminated the formation of glycated insulin even in the case of co-infusion of parenteral nutrition and confirmed the need to saturate infusion tubes.Conclusion: The revision of the insulin therapy protocol reduced the variability of insulin concentration in preparations and avoided the administration of glycated derivatives potentially toxic for neonates. What is Known: • Insulin preparation in NICUs is a risky task because it is a two-step preparation • Diluted in dextrose, insulin aspart is unstable, with formation of potentially toxic glycated derivatives What is New: • This work proposes a new insulin therapy protocol validated by HPLC-UV for NICU allowing suppression of the formation of glycated insulin, to significantly reduce deviations from theoretical concentrations and to limit adsorption phenomena • This protocol is validated in case of co-infusion of parenteral nutrition.

Intraventricular dopamine infusion alleviates motor symptoms in a primate model of Parkinson's disease.

BACKGROUND: Continuous compensation of dopamine represents an ideal symptomatic treatment for Parkinson's disease (PD). The feasibility in intracerebroventricular administration (i.c.v.) of dopamine previously failed because of unresolved dopamine oxidation. OBJECTIVES: We aim to test the feasibility, safety margins and efficacy of continuous i.c.v. of anaerobic-dopamine (A-dopamine) with a pilot translational study in a non-human primate model of PD. METHODS: Continuous and circadian i.c.v. of A-dopamine was administered through a micro-pump connected to a subcutaneous catheter implanted into the right frontal horn of 8 non-human primates treated with 1-methyl-4- phenyl-1,2,3,6-tetrahydropyridine (MPTP). A-dopamine was assessed at acute doses previously reported for dopamine as well as evaluating the long term therapeutic index of A-dopamine in comparison to anaerobically prepared L-dopa or methyl ester L-dopa. RESULTS: Over 60 days of a continuous circadian i.c.v. of A-dopamine improved motor symptoms (therapeutic index from 30 to 70 mg/day) without tachyphylaxia. No dyskinesia was observed even with very high doses. Death after 1 to 10 days (without neuronal alteration) was only observed with doses in excess of 160 mg whereas L-dopa i.c.v. was not effective at any dose. The technical feasibility of the administration regimen was confirmed for an anaerobic preparation of dopamine and for administration of a minimal infusion volume by micro-pump at a constant flow that prevented obstruction. CONCLUSION: Continuous circadian i.c.v. of A-dopamine appears to be feasible and shows efficacy without dyskinesia with a safe therapeutic index.

Long-term stability of 10 mg/mL dobutamine injectable solutions in 5% dextrose and normal saline solution stored in polypropylene syringes and cyclic-oleofin-copolymer vials.

OBJECTIVE: Dobutamine is an inotropic agent given to patients with low cardiac output or undergoing cardiac surgery in intensive care units. Routine clinical care protocols recommend a target dilution concentration of 10 mg/mL dobutamine from the 250 mg/20 mL commercial solution.This study aimed to assess the 1-year stability of ready-to-use 10 mg/mL diluted dobutamine solutions. Two types of 50 mL conditioning, polypropylene (PP) syringes or cyclic-oleofin-copolymer (COC) vials and two diluents (5% dextrose (D5W) and normal saline (NS)) were tested. METHODS: Reversed-phase liquid chromatography coupled with an ultraviolet detection stability-indicating method was developed for dobutamine and validated according to selectivity, linearity, sensitivity, accuracy and precision. Chemical stability was considered to have been maintained if the measured concentrations were >90% of the initial concentration with no colour change. Physical stability was assessed through sterility tests, pH and osmolality monitoring, and subvisible particle counting. Containers were stored at -20±5°C, +5±3°C and +25±2°C with 60%±5% relative humidity in a dark, closed environment. RESULTS: According to this study, the physicochemical stability of 10 mg/mL dobutamine solutions prepared with D5W or NS is constant throughout a 365-day period when stored in COC vials, at all the aforementioned temperatures, whereas solutions in PP syringes required a refrigerated temperature and should not be administered after 21 days or 3 months when prepared with D5W or NS, respectively, or after 1 month at ambient temperature whatever the diluent. CONCLUSION: Our results argue in favour of adopting the compounding of ready-to-use 10 mg/mL dobutamine solutions in COC vials in centralised intravenous additive services.

Factors influencing accuracy when preparing injectable drug concentrations in appliance with clinical practice: a norepinephrine case study.

Errors in injectable preparations with high-risk drugs can be fatal. This study aimed to identify the factors influencing the accuracy of high-risk injectable drug concentrations in appliances used for intensive care unit preparation practices. Norepinephrine (NE) was chosen as an example of a high-risk medication drug. The concentration (0.2 and 0.5 mg/mL), the diluent (sodium chloride 0.9% and 5% dextrose), and the container type (prefilled- and empty-infusion bag and syringe) were tested as potential variability factors. An ultraviolet spectrophotometric method was used for NE dosage. 108 NE solutions were prepared by five individuals (pharmacists or laboratory technicians) with clinical experience as well as experience in the aseptic preparation of solutions. The container type was found to be the only factor influencing the accuracy of NE concentration. NE solutions in syringes proved to be the most accurate while preparations in prefilled bags tended to underdose NE.

Simultaneous infusion of two incompatible antibiotics: Impact of the choice of infusion device and concomitant simulated fluid volume support on the particulate load and the drug mass flow rates.

Vancomycin and piperacillin/tazobactam are known to be incompatible. The objectives of the present study were to evaluate the impact of their simultaneous infusion on mass flow rates and particulate load and identify preventive strategies. We assessed both static conditions and a reproduction of an infusion line used in a hospital's critical care unit. A high-performance liquid chromatography/UV diode array system and static and dynamic laser diffraction particle counters were used. The mass flow rates were primarily influenced by the choice of the infusion device and the presence of simulated fluid volume support. Drug incompatibility also appeared to affect vancomycin's mass flow rate, and the dynamic particulate load increased during flow rate changes - especially in the infusion set with a large common volume line and no concomitant simulated fluid volume support. Only discontinuation of the piperacillin/tazobactam infusion was associated with a higher particulate load in the infusion set with a large common volume line and no concomitant simulated fluid volume support. A low common volume line and the use of simulated fluid volume support were associated with smaller fluctuations in the mass flow rate. The clinical risk associated with a higher particulate load must now be assessed.