The objective was to understand the mechanism of enhancement in salbutamol sulphate (SS) respiratory deposition through addition of magnesium stearate (MgSt). The mixing of MgSt with micronized SS occurred using a Turbula mixer (101 rpm), whilst varying mixing time and MgSt concentration and size. Deposition of SS was determined by a twin-stage impinger. Particle size distributions were obtained using the Malvern Mastersizer 2000. Morphology was examined by scanning electron microscopy and surface energy determined using inverse gas chromatography. Mixing of SS with increasing concentrations of MgSt improved dispersion (FPF of 3.3% using 1% w/w MgSt, 4.5% using 5% w/w MgSt and 7.8% using 10% w/w MgSt compared with 1.4% of pure SS for 20 mg doses) when mixed for 0.5 h; SS dispersion improved further after 3.5 h of mixing. In addition to the action of the MgSt in coating SS particles, a greater understanding of the function of MgSt particles in acting as micro-carriers and in changing the mixture structure through incorporation into agglomerates has been achieved. The mechanistic understanding of improvement in drug deposition using MgSt will allow more directed strategies to be employed in designing powder formulations for inhalation.
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机译:目的是了解通过添加硬脂酸镁(MgSt)来增强硫酸沙丁胺醇(SS)呼吸沉积的机制。 MgSt与微粉化SS的混合使用Turbula混合器(101 rpm)进行,同时改变混合时间以及MgSt的浓度和大小。 SS的沉积由双级冲击器确定。使用Malvern Mastersizer 2000获得粒度分布。通过扫描电子显微镜检查形态,并使用反相气相色谱法测定表面能。 SS与浓度增加的MgSt的混合改善了分散性(FPF为3.3%,使用1%w / w MgSt,4.5%使用5%w / w MgSt,7.8%使用10%w / w MgSt,而纯SS为1.4% 20 mg剂量)混合0.5小时;混合3.5小时后,SS分散度进一步提高。除了MgSt在涂覆SS颗粒中的作用外,还获得了对MgSt颗粒作为微载体和通过掺入团聚体改变混合物结构的功能的更好理解。对使用MgSt改善药物沉积的机理的理解将允许在设计吸入粉剂时采用更直接的策略。
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