Betamethasone Sodium Phosphate Injection

Background: Epidural injection of corticosteroids is a commonly used treatment for radicular pain. However, the benefits are often short lived, and repeated injections are often limited secondary to concerns of side effects from cumulative steroid doses. In addition, rare, catastrophic complications, including brain and spinal cord embolic infarcts have been attributed to particulate steroid injections. A previous study has shown that dexamethasone has less particulate than other corticosteroids, possibly reducing embolic risk. Furthermore, a recent study indicated that clonidine may be useful in the treatment of radicular pain when administered via epidural steroid injection. The combination of corticosteroid and clonidine is an intriguing, yet unstudied, alternative to traditional treatment. Objective: Our study examines whether mixing clonidine and various corticosteroids results in increased particle size or aggregation. Methods: Evaluations under light microscopy for particle size were made of samples of clonidine alone and clonidine mixed with equal parts of 3 corticosteroids solutions: dexamethasone sodium phosphate injection, triamcinolone acetonide injectable suspension, and betamethasone sodium phosphate and betamethasone acetate injectable suspension. Four mL each of clonidine (100 μcg/ mL), clonidine (100 μcg/mL) + dexamethasone sodium phosphate injection (4 mg/mL), clonidine (100 μcg/mL) + triamcinolone acetonide injectable suspension (40 mg/mL), and clonidine (100 μcg/mL) + betamethasone sodium phosphate and betamethasone acetate injectable suspension (6 mg/mL) were examined Their particle sizes were compared to measurements taken when each steroid solution was examined alone. Results: Clonidine was determined to be nonparticulate when examined by light microscopy. Clonidine mixed with equal parts of each of the 3 corticosteroids mentioned above did not result in increased clumping or increased particle size over each of the corticosteroids measured alone. Conclusion: Mixing clonidine with corticosteroids did not increase particulation compared to corticosteroids alone. Combining clonidine and corticosteroids for epidural injection may prove to be a useful treatment for radicular pain. The combination of these is unlikely to result in a solution that is more likely to cause embolic infarcts than the use of corticosteroids alone. Key words: steroid, epidural, clonidine, injection, particulate, aggregation

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Betamethasone Sodium Phosphate and Betamethasone Acetate Injectable Suspension

10.31003/uspnf_m9125_03_01 ◽

2021 ◽

Keyword(s):

Sodium Phosphate ◽

Betamethasone Sodium Phosphate

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Comparison of the Particle Sizes of Different Steroids and the Effect of Dilution

Anesthesiology ◽

10.1097/00000542-200702000-00022 ◽

2007 ◽

Vol 106 (2) ◽

pp. 331-338 ◽

Cited By ~ 132

Author(s):

Honorio T. Benzon ◽

Teng-Leong Chew ◽

Robert J. McCarthy ◽

Hubert A. Benzon ◽

David R. Walega

Keyword(s):

Sodium Phosphate ◽

Laser Scanning ◽

Pure Liquid ◽

Particle Sizes ◽

Bonferroni Correction ◽

Chi Square ◽

Laser Scanning Confocal Microscope ◽

Epidural Steroid Injections ◽

Epidural Steroid ◽

Betamethasone Sodium Phosphate

Background Central nervous system injuries after transforaminal epidural steroid injections have been ascribed to occlusion of the blood vessels supplying the spinal cord and brain by the particulate steroid. Methods The authors compared the sizes of the particles of the steroids methylprednisolone acetate, triamcinolone acetonide, dexamethasone sodium phosphate, betamethasone sodium phosphate/betamethasone acetate (both Celestone Soluspan; Schering-Plough, Kenilworth, NJ, the commercial betamethasone; and betamethasone repository, a betamethasone preparation that can be ordered from a compounding company), and betamethasone sodium phosphate. Both undiluted and diluted samples were examined. The samples were examined with a laser scanning confocal microscope, and images were analyzed and measured. The particles were categorized (or tabulated) into groups: 0-20, 21-50, 51-1000, and greater than 1000 mu. Chi-square analyses, with Bonferroni correction, were used to compare the proportion of particles among the undiluted and diluted drug formulations. Results Dexamethasone and betamethasone sodium phosphate were pure liquid. The proportion of larger particles was significantly greater in the methylprednisolone and the compounded betamethasone preparations compared with the commercial betamethasone. There was no statistical difference between the commercial betamethasone and triamcinolone, although betamethasone had a smaller percentage of the larger particles. Increased dilution of the compounded betamethasone with lidocaine decreased the percentage of the larger particles, whereas increased dilution of methylprednisolone 80 mg/ml with saline increased the proportion of larger particles. Conclusion Commercial betamethasone is the recommended preparation if a nonsoluble steroid is preferred. Dexamethasone is a nonparticulate steroid, but its routine use awaits further studies on its safety and efficacy.

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Stability of Diluted Dexamethasone Sodium Phosphate Injection at Two Temperatures

Annals of Pharmacotherapy ◽

10.1177/106002809402800903 ◽

1994 ◽

Vol 28 (9) ◽

pp. 1018-1019 ◽

Cited By ~ 6

Author(s):

Ralph A. Lugo ◽

Milap C. Nahata

Keyword(s):

Lung Disease ◽

Bronchopulmonary Dysplasia ◽

Chronic Lung Disease ◽

Sodium Phosphate ◽

Hplc Method ◽

Dexamethasone Sodium Phosphate ◽

Usp 4 ◽

Two Temperatures ◽

Phosphate Injection ◽

The Stability

OBJECTIVE: Premature neonates with bronchopulmonary dysplasia frequently are treated with intravenous dexamethasone for their chronic lung disease. The injection volumes of the commercially available products often are too small to measure accurately. The objective of this study was to evaluate the stability over 28 days of dexamethasone sodium phosphate injection 4 mg/mL diluted with bacteriostatic NaCl 0.9% to 1 mg/mL. DESIGN: Ten vials of dexamethasone 1 mg/mL were prepared from dexamethasone sodium phosphate injection, USP 4 mg/mL and bacteriostatic NaCl 0.9% injection. Five vials were stored at 4 °C and five at 22 °C. Dexamethasone was measured on days 0, 1, 3, 7, 14, 21, and 28 by an accurate, reproducible, and stability-indicating HPLC method. Samples were also inspected visually for precipitation or discoloration on each study day. RESULTS: The samples retained at least 97.7 percent of the original concentration of dexamethasone sodium phosphate when stored at either 4 or 22 °C for 28 days. No discoloration or precipitation was observed. CONCLUSIONS: Dexamethasone sodium phosphate injection 1 mg/mL in bacteriostatic NaCl 0.9% was stable for 28 days at 4 and 22 °C.

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Extended Stability of Sodium Phosphate Solutions in Polyvinyl Chloride Bags

The Canadian Journal of Hospital Pharmacy ◽

10.4212/cjhp.v70i1.1622 ◽

2017 ◽

Vol 70 (1) ◽

Author(s):

William Perks ◽

John Iazzetta ◽

Pak Cheung Chan ◽

Athina Brouzas ◽

Shirley Law ◽

...

Keyword(s):

United States ◽

Polyvinyl Chloride ◽

Chemical Stability ◽

Sodium Phosphate ◽

United States Pharmacopeia ◽

Moisture Loss ◽

Initial Concentration ◽

Phosphate Injection ◽

Phosphate Solutions ◽

States Pharmacopeia

ABSTRACTBackground: Sodium phosphate injection is used to treat moderate to severe hypophosphatemia. There have been no published reports documenting the physical compatibility or chemical stability of sodium phosphate injection in IV solutions.Objective: To evaluate the physical compatibility and chemical stability of 30 and 150 mmol/L solutions of phosphate, prepared from sodium phosphate injection, in 5% dextrose in water (D5W) and in 0.9% sodium chloride (normal saline [NS]) and stored in polyvinyl chloride (PVC) bags at 23°C or 4°C over 63 days.Methods: On study day 0, solutions of phosphate 30 and 150 mmol/L in D5W or NS were prepared in PVC bags and stored at 4°C and 23°C. On prespecified days during the 63-day study period, the concentrations of sodium and phosphate were determined, and admixture weight was checked to assess moisture loss during storage without a plastic overwrap. Chemical stability was calculated from the intersection of the lower 95% confidence limit of the degradation rate and the lower limit of acceptability (90%) for concentration remaining.Results: The analytical methods for both sodium and phosphate were found to be precise (coefficient of variation averaging less than 1% for pre-study validation samples). Both sodium and phosphate retained more than 94% of the initial concentration over the 63-day study period. With 95% confidence, the time to achieve 90% of the initial concentration of both sodium and phosphate approached or exceeded the 63-day study period, regardless of temperature, concentration, or base solution.Conclusions: Sodium phosphate solutions at a phosphate concentration of 30 or 150 mmol/L in either NS or D5W retained more than 94% of the initial concentration of both sodium and phosphate over 63 days when stored at 23°C or 4°C. In compliance with United States Pharmacopeia General Chapter <797> recommendations, a beyond-use date of 14 days (with refrigeration) or 48 h (room temperature) may be applied. Extending the beyond-use date beyond these limits may be considered, if a validated sterility test is performed.RÉSUMÉContexte : Le phosphate de sodium injectable est employé pour traiter l’hypophosphatémie modérée et grave. À ce jour, aucun rapport portant sur la compatibilité physique ou la stabilité chimique du phosphate de sodium injectable contenu dans les solutions intraveineuses n’a été publié. Objectif : Évaluer la compatibilité physique et la stabilité chimique de solutions de phosphate à des concentrations de 30 et de 150 mmol/L préparées à partir de phosphate de sodium injectable dilué dans du dextrose à 5 % dans l’eau (D5E) ou du chlorure de sodium à 0,9 % (solution physiologique salée [SP]) puis rangées dans des sacs de polychlorure de vinyle (PVC) à des températures de 4 °C ou de 23 °C pendant 63 jours.Méthodes : Au jour 0 de l’étude, les solutions de phosphate à des concentrations de 30 et de 150 mmol/L ont été préparées avec du D5E ou de la SP dans des sacs de PVC, puis entreposées à des températures de 4 °C ou de 23 °C. À des jours donnés pendant la période de 63 jours de l’étude, on a évalué les concentrations de sodium et de phosphate et l’on a pesé les mélanges pour vérifier la perte d’humidité pendant un entreposage n’utilisant pas de suremballage de plastique. La stabilité chimique était calculée au point d’intersection entre la limite inférieure de confiance à 95 % du taux de dégradation et la limite inférieure d’acceptabilité (90 %) de la concentration restante.Résultats : Les méthodes analytiques employées pour évaluer le sodium et le phosphate se sont révélées précises (coefficient de variation moyen inférieur à 1 % pour les échantillons aux fins de validation avant l’étude). Le sodium et le phosphate conservaient chacun plus de 94 % de leurs concentrations initiales pendant la période d’étude de 63 jours. Avec un niveau de confiance de 95 %, le temps nécessaire pour atteindre 90 % de la concentration initiale pour le sodium et pour le phosphate approchait ou dépassait les 63 jours de la période d’étude, peu importe la température, la concentration ou la solution de base.Conclusions : Les solutions de phosphate de sodium dont la concentration en phosphate est de 30 ou de 150 mmol/L, qu’elles soient à base de D5E ou de SP, conservaient plus de 94 % des concentrations initiales de sodium et de phosphate pendant 63 jours, qu’elles soient entreposées à des températures de 4 °C ou de 23 °C. Conformément aux recommandations contenues dans le chapitre <797> de la United States Pharmacopeia, une date limite d’utilisation de 14 jours (sous réfrigération) ou de 48 heures (à température ambiante) peut être utilisée. Allonger la date limite d’utilisation au-delà des bornes fixées par l’organisme américain peut être envisageable si une épreuve validée de stérilité est réalisée.

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