Alqurshi Abdulmalik, Kumar Zahrae, McDonald Rebecca, Strang John, Buanz Asma, Ahmed Shagufta, Allen Elizabeth, Cameron Peter, Rickard James A, Sandhu Verity, Holt Chris, Stansfield Rebecca, Taylor David, Forbes Ben, Royall Paul G
Institute of Pharmaceutical Science, King's College London , Franklin-Wilkins Building, 150 Stamford Street, London, U.K. , SE1 9NH.
Institute of Psychiatry, Psychology & Neuroscience (IoPPN), King's College London (National Addiction Centre) , Addictions Sciences Building, 4 Windsor Walk, Denmark Hill, London, U.K. , SE5 8BB.
Mol Pharm. 2016 May 2;13(5):1688-98. doi: 10.1021/acs.molpharmaceut.6b00096. Epub 2016 Mar 28.
The aim of this study was to develop a freeze-dried buccal tablet for the rapid delivery of naloxone in opioid overdose. The tablet composition was optimized to produce an amorphous matrix, which was confirmed by the absence of peaks associated with crystallinity observed by differential scanning calorimetry and powder X-ray diffraction. Tablets with high gelatin content lacked adequate porosity. Mannitol was added to the formulation to bridge and intercalate gelatin's tight polymer aggregates, however sodium bicarbonate was also required to prevent crystallization within the tablets. A linear reduction in mannitol's recrystallization enthalpy was observed with increasing sodium bicarbonate concentration (ΔrecryH = -20.3[NaHCO3] + 220.9; r(2) = 0.9, n = 18). The minimum sodium bicarbonate concentration for full inhibition of mannitol crystallization was 10.9% w/w. Freeze-dried tablets with lower amounts of sodium bicarbonate possessed a crystalline fraction that PXRD identified as mannitol hemihydrate from the unique peak at 9.7° 2θ. Mannitol's greater affinity for both ions and residual water rather than its affinity for self-association was the mechanism for the inhibition of crystallization observed here. The optimized tablet (composition mannitol 24% w/w (4.26 mg), gelatin 65% w/w (11.7 mg), sodium bicarbonate 11% w/w (1.98 mg), and naloxone 800 μg) formed predominantly amorphous tablets that disintegrated in less than 10 s. Optimized tablets were chemically and physically stable over 9 months storage at 25 °C. As speed of drug liberation is the critical performance attribute for a solid dosage form designed to deliver drug in an emergency, a novel imaging based in vitro disintegration assay for buccal tablets was developed. The assay was optimized with regard to conditions in the buccal cavity: i.e., temperature 33-37 °C, volume of medium (0.1-0.7 mL), and use of mucin-containing biorelevant medium. The disintegration assay was sensitive to temperature, medium volume, and medium composition; naloxone tablet disintegration was extremely rapid, with full disintegration ranging from 5 to 20 s. In conclusion, rapidly disintegrating tablets have been developed which are suitable for proof-of-concept clinical trial in humans to determine the pharmacokinetics of naloxone delivered via the buccal route.
本研究的目的是开发一种冻干口腔片,用于在阿片类药物过量时快速递送纳洛酮。对片剂组成进行了优化以制备无定形基质,差示扫描量热法和粉末X射线衍射未观察到与结晶度相关的峰,从而证实了该基质的无定形性质。明胶含量高的片剂缺乏足够的孔隙率。在制剂中加入甘露醇以桥接和嵌入明胶紧密的聚合物聚集体,然而还需要碳酸氢钠来防止片剂内结晶。随着碳酸氢钠浓度的增加,观察到甘露醇重结晶焓呈线性降低(ΔrecryH = -20.3[NaHCO₃] + 220.9;r² = 0.9,n = 18)。完全抑制甘露醇结晶的最低碳酸氢钠浓度为10.9% w/w。碳酸氢钠含量较低的冻干片剂具有结晶部分,粉末X射线衍射从9.7° 2θ处的独特峰鉴定为半水合甘露醇。甘露醇对离子和残留水的亲和力大于其自缔合亲和力,是此处观察到的抑制结晶的机制。优化后的片剂(组成:甘露醇24% w/w(4.26 mg)、明胶65% w/w(11.7 mg)、碳酸氢钠11% w/w(1.98 mg)和纳洛酮800 μg)主要形成无定形片剂,在不到10秒内崩解。优化后的片剂在25℃储存9个月期间化学和物理性质稳定。由于药物释放速度是设计用于紧急情况下给药的固体剂型的关键性能属性,因此开发了一种基于成像的新型口腔片体外崩解试验。该试验针对口腔内条件进行了优化:即温度33 - 37℃、介质体积(0.1 - 0.7 mL)以及使用含粘蛋白的生物相关介质。崩解试验对温度、介质体积和介质组成敏感;纳洛酮片剂崩解极快,完全崩解时间为5至20秒。总之,已开发出快速崩解的片剂,适用于人体概念验证临床试验,以确定经口腔途径递送纳洛酮的药代动力学。
