Towards Precision Medicine in Clinical Practice: Alinity C vs. UHPLC-MS/MS in Plasma Aripiprazole Determination.

Therapeutic drug monitoring improves the benefit-risk balance of antipsychotic therapy. Ultra-high-performance liquid chromatography-tandem mass spectrometry (UHPLC-MS/MS) is considered the gold-standard method for measuring plasma drug concentrations; however, the Alinity C system has emerged as a promising alternative. This is the first study aimed at comparing UHPLC-MS/MS versus Alinity C in measuring plasma concentrations of aripiprazole and dehydroaripiprazole. A total of 86 plasma samples were analyzed. The active moiety of aripiprazole was measured in 60 samples using both systems and 26 samples were analyzed twice using Alinity C with an intermediate period of 6 months to assess its reproducibility. Spearman's correlation revealed a good association between the two assays (rs = 0.96) and no significance differences were found by McNemar's test when classifying samples between infra-, supra- and therapeutic ranges. Passing-Bablock regression showed a good correlation among methods (rs = 0.93) and a slope of 1.12 indicating a slight tendency of Alinity C to measure higher values than UHPLC-MS/MS. In addition, a good intra-method correlation across the two sequential analyses with Alinity C was obtained (rs = 0.99). Nonetheless, clinical decisions could be different in 15% of the cases depending on the chosen method. No differences were found in active moiety determination by Alinity C depending on the concentration of aripiprazole and dehydroaripiprazole of the samples.

Cysteamine Eye Drops in Hyaluronic Acid Packaged in Innovative Single-Dose Systems, Part II: Long-Term Stability and Clinical Ocular Biopermanence.

BACKGROUND: Cystinosis is a rare genetic disorder characterized by the accumulation of cystine crystals in several tissues and organs causing, among others, severe eye symptoms. The high instability of cysteamine eye drops makes it difficult to develop formulations with an acceptable shelf life to be prepared in hospital pharmacy departments. Previously, a new compounded formulation of cysteamine eye drops in hyaluronic acid (HA) packaged in innovative single-dose systems was developed. METHODS: Long-term stability at -20 °C of this formulation was studied considering the content of cysteamine, pH, osmolality, viscosity, and microbiological analysis. The oxygen permeability of single-dose containers was also studied and an ocular biopermanence study was conducted in healthy volunteers measuring lacrimal stability and volume parameters. RESULTS: Data confirm that cysteamine concentration remained above 90% for 120 days, all parameters remaining within the accepted range for ophthalmic formulations. The permeability of the containers was reduced over time, while ocular biopermanence was maintained despite the freezing process and storage time. CONCLUSIONS: 0.55% cysteamine hydrochloride formulation in HA and packaged in single-dose containers preserved at -20 °C is stable for 120 days protected from light, presenting high potential for its translation into clinical practice when commercial presentations are not available.

Ampicillin Stability in a Portable Elastomeric Infusion Pump: A Step Forward in Outpatient Parenteral Antimicrobial Therapy.

Outpatient parenteral antimicrobial therapy (OPAT) with continuous infusion pumps is postulated as a very promising solution to treat complicated infections, such as endocarditis or osteomyelitis, that require patients to stay in hospital during extended periods of time, thus reducing their quality of life and increasing the risk of complications. However, stability studies of drugs in elastomeric devices are scarce, which limits their use in OPAT. Therefore, we evaluated the stability of ampicillin in sodium chloride 0.9% at two different concentrations, 50 and 15 mg/mL, in an elastomeric infusion pump when stored in the refrigerator and subsequently in real-life conditions at two different temperatures, 25 and 32 °C, with and without the use of a cooling device. The 15 mg/mL ampicillin is stable for up to 72 h under refrigeration, allowing subsequent dosing at 25 °C for 24 h with and without a cooling device, but at 32 °C its concentration drops below 90% after 8 h. In contrast, 50 mg/mL ampicillin only remains stable for the first 24 h under refrigeration, and subsequent administration at room temperature is not possible, even with the use of a cooling system. Our data support that 15 mg/mL AMP is suitable for use in OPAT if the volume and rate of infusion are tailored to the dosage needs of antimicrobial treatments.

Stability of insulin eye drops in the treatment of refractory corneal ulcers.

OBJECTIVE: To determine and compare the physicochemical and microbiological stability of two 25 IU/mL insulin eye drop formulations made with normal saline and a balanced salt solution, respectively, stored for 120 days under various conditions. METHOD: Eye drops were compounded in triplicate with 100 IU/mL Actrapid®  insulin and either normal saline or a balanced salt solution as vehicles, and  they were stored alternatively at room temperature (25 °C), in a refrigerator  (2-8 °C) or in a freezer (-20 °C) for 120 days. Insulin concentrations were  determined by ultra-high resolution liquid chromatography, and osmolality and  pH values were measured at days 0, 3, 7, 15, 30, 60, 90 and 120. Likewise,  samples were extracted for microbiological studies on days 0, 30, 60, 90 and  120. RESULTS: The formulation made with normal saline maintained insulin concentrations above 90% of the baseline level after 120 days across all  temperature conditions. In the case of the balanced salt solution- based eye drops, insulin concentration when stored at room temperature or in the freezer remained stable after 120 days, although insulin concentration when stored in the refrigerator fell below 90% on day 90 of the  study. Osmolality and pH values remained constant in both formulations and across all storage conditions. No microbiological growth was observed in any of the samples. CONCLUSIONS: 25 IU/mL insulin eye drops made with normal saline remain  stable for 120 days whether they are stored at room temperature, in a  refrigerator or in a freezer, provided that they are protected from light. When  made with a balanced salt solution, they remain stable for 120 days at room  temperature and in a freezer, their shelf life being reduced to 90 days in the  case of storage in a refrigerator.

OBJETIVO: Determinar y comparar la estabilidad físico-química y microbiológica de dos colirios de insulina 25 UI/ml elaborados con suero fisiológico o balanced salt solution bajo diferentes condiciones de  conservación durante 120 días.Método: Los colirios se elaboraron por triplicado con insulina Actrapid® 100  Ul/ml y balanced salt solution o suero fisiológico como vehículo, y fueron  conservados a temperatura ambiente (25 °C), en nevera (2-8 °C) o congelador  (­20 °C) durante 120 días. Se determinó la concentración de  insulina mediante cromatografía liquida de ultra alta resolución, la osmolalidad  y el pH a días 0, 3, 7, 15, 30, 60, 90 y 120. Asimismo, se extrajeron muestras  para estudios microbiológicos en los días 0, 15, 30, 60, 90 y 120. RESULTADOS: La formulación elaborada con suero fisiológico mantuvo la  concentración de insulina por encima del 90% con respecto a la inicial tras 120  días de estudio en todas las condiciones de temperatura. En el caso del  colirio elaborado con balanced salt solution, la concentración se mantuvo  estable en ambiente y congelador tras 120 días, aunque en nevera descendió  por debajo del 90% a día 90 de estudio. Los valores de osmolalidad y pH se  mantuvieron constantes en ambas formulaciones y condiciones de  conservación. No se observó crecimiento microbiológico en ninguna de las  muestras retiradas. CONCLUSIONES: El colirio de insulina 25 UI/ml elaborado con suero fisiológico  es estable 120 días, conservado tanto a temperatura ambiente como en nevera  o congelador, protegido de la luz. Con balanced salt solution  permanece estable 120 días a temperatura ambiente y congelador, reduciéndose el periodo de validez a 90 días en el caso de la conservación en nevera.

Estabilidad del colirio de insulina para el tratamiento de úlceras corneales refractarias / Stability of insulin eye drops in the treatment of refractory corneal ulcers

Objetivo: Determinar y comparar la estabilidad físico-química y microbiológica de dos colirios de insulina 25 UI/ml elaborados con suerofisiológico o balanced salt solution bajo diferentes condiciones de conservación durante 120 días.Método: Los colirios se elaboraron por triplicado con insulina Actrapid®100 Ul/ml y balanced salt solution o suero fisiológico como vehículo, yfueron conservados a temperatura ambiente (25 °C), en nevera (2-8 °C)o congelador (–20 °C) durante 120 días. Se determinó la concentraciónde insulina mediante cromatografía liquida de ultra alta resolución, laosmolalidad y el pH a días 0, 3, 7, 15, 30, 60, 90 y 120. Asimismo, seextrajeron muestras para estudios microbiológicos en los días 0, 15, 30,60, 90 y 120.Resultados: La formulación elaborada con suero fisiológico mantuvola concentración de insulina por encima del 90% con respecto a la inicialtras 120 días de estudio en todas las condiciones de temperatura. En elcaso del colirio elaborado con balanced salt solution, la concentraciónse mantuvo estable en ambiente y congelador tras 120 días, aunque ennevera descendió por debajo del 90% a día 90 de estudio. Los valoresde osmolalidad y pH se mantuvieron constantes en ambas formulacionesy condiciones de conservación. No se observó crecimiento microbiológico en ninguna de las muestras retiradas.Conclusiones: El colirio de insulina 25 UI/ml elaborado con suerofisiológico es estable 120 días, conservado tanto a temperatura ambientecomo en nevera o congelador, protegido de la luz. Con balanced saltsolution permanece estable 120 días a temperatura ambiente y congelador, reduciéndose el periodo de validez a 90 días en el caso de laconservación en nevera. (AU)

Objective: To determine and compare the physicochemical and microbiological stability of two 25 IU/mL insulin eye drop formulations madewith normal saline and a balanced salt solution, respectively, stored for120 days under various conditions.Method: Eye drops were compounded in triplicate with 100 IU/mLActrapid® insulin and either normal saline or a balanced salt solution asvehicles, and they were stored alternatively at room temperature (25 °C),in a refrigerator (2-8 °C) or in a freezer (–20 °C) for 120 days. Insulinconcentrations were determined by ultra-high resolution liquid chromatography, and osmolality and pH values were measured at days 0, 3, 7,15, 30, 60, 90 and 120. Likewise, samples were extracted for microbiological studies on days 0, 30, 60, 90 and 120.Results: The formulation made with normal saline maintained insulinconcentrations above 90% of the baseline level after 120 days acrossall temperature conditions. In the case of the balanced salt solution-basedeye drops, insulin concentration when stored at room temperature or inthe freezer remained stable after 120 days, although insulin concentrationwhen stored in the refrigerator fell below 90% on day 90 of the study.Osmolality and pH values remained constant in both formulations andacross all storage conditions. No microbiological growth was observedin any of the samples. Conclusions: 25 IU/mL insulin eye drops made with normal salineremain stable for 120 days whether they are stored at room temperature,in a refrigerator or in a freezer, provided that they are protected fromlight. When made with a balanced salt solution, they remain stable for120 days at room temperature and in a freezer, their shelf life being reduced to 90 days in the case of storage in a refrigerator. (AU)

Cysteamine Eye Drops in Hyaluronic Acid Packaged in Innovative Single-Dose Systems: Stability and Ocular Biopermanence.

Cystinosis is a rare genetic disorder characterized by the accumulation of cystine crystals in different tissues and organs causing, among other symptoms, severe ocular manifestations. Cysteamine eye drops are prepared in hospital pharmacy departments to facilitate access to treatment, for which vehicles that provide adequate biopermanence, as well as adaptable containers that maintain its stability, are required. Difficulties related to cysteamine preparation, as well as its tendency to oxidize to cystamine, show the importance of conducting rigorous galenic characterization studies. This work aims to develop and characterize an ophthalmic compounded formulation of cysteamine prepared with hyaluronic acid and packaged in innovative single-dose systems. For this task, the effect of different storage temperatures and the presence/absence of nitrogen on the physicochemical stability of the formulation and its packaging was studied in a scaled manner, until reaching the optimal storage conditions. The results showed that 0.55% cysteamine, prepared with hyaluronic acid and packaged in single-dose containers, is stable for 30 days when stored at -20 °C. In addition, opening vials every 4 h at room temperature after 30 days of freezing maintains the stability of the cysteamine formulation for up to 16 h. Moreover, ocular biopermanence studies were conducted using molecular imaging, concluding that the biopermanence offered by the vehicle is not affected by the freezing process, where a half-life of 31.11 min for a hyaluronic acid formulation stored for 30 days at -20 °C was obtained, compared with 14.63 min for 0.9% sodium chloride eye drops.

Recent Research in Ocular Cystinosis: Drug Delivery Systems, Cysteamine Detection Methods and Future Perspectives.

Cystinosis is a rare genetic disorder characterized by the accumulation of cystine crystals in different tissues and organs. Although renal damage prevails during initial stages, the deposition of cystine crystals in the cornea causes severe ocular manifestations. At present, cysteamine is the only topical effective treatment for ocular cystinosis. The lack of investment by the pharmaceutical industry, together with the limited stability of cysteamine, make it available only as two marketed presentations (Cystaran® and Cystadrops®) and as compounding formulations prepared in pharmacy departments. Even so, new drug delivery systems (DDSs) need to be developed, allowing more comfortable dosage schedules that favor patient adherence. In the last decades, different research groups have focused on the development of hydrogels, nanowafers and contact lenses, allowing a sustained cysteamine release. In parallel, different determination methods and strategies to increase the stability of the formulations have also been developed. This comprehensive review aims to compile all the challenges and advances related to new cysteamine DDSs, analytical determination methods, and possible future therapeutic alternatives for treating cystinosis.