Extraction of niclosamide from commercial approved tablets into aqueous buffered solution creates potentially approvable oral and nasal sprays against COVID-19 and other respiratory infections.

David Needham
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引用次数: 0

Abstract

Motivation: The low solubility, weak acid drug, niclosamide is a host cell modulator with broad-spectrum anti-viral cell-activity against many viruses, including stopping the SARS-CoV-2 virus from infecting cells in cell culture. As a result, a simple universal nasal spray preventative was proposed and investigated in earlier work regarding the dissolution of niclosamide into simple buffers. However, starting with pharmaceutical grade, niclosamide represents a new 505(b)(2) application. The motivation for this second paper in the series was therefore to explore if and to what extent niclosamide could be extracted from commercially available and regulatory-approved niclosamide oral tablets that could serve as a preventative nasal spray and an early treatment oral/throat spray, with possibly more expeditious testing and regulatory approval.

Experimental: Measurements of supernatant niclosamide concentrations were made by calibrated UV-Vis for the dissolution of niclosamide from commercially available Yomesan crushed into a powder for dissolution into Tris Buffer (TB) solutions. Parameters tested were as follows: time (0-2 days), concentration (300 µM to -1 mM), pH (7.41 to 9.35), and anhydrous/hydrated state. Optical microscopy was used to view the morphologies of the initial crushed powder, and the dissolving and equilibrating undissolved excess particles to detect morphologic changes that might occur.

Results: Concentration dependence: Niclosamide was readily extracted from powdered Yomesan at pH 9.34 TB at starting Yomesan niclosamide equivalents concentrations of 300 µM, 600 µM, and 1 mM. Peak dissolved niclosamide supernatant concentrations of 264 µM, 216 µM, and 172 µM were achieved in 1 h, 1 h, and 3 h respectively. These peaks though were followed by a reduction in supernatant concentration to an average of 112.3 µM ± 28.4 µM after overnight stir on day 2. pH dependence: For nominal pHs of 7.41, 8.35, 8.85, and 9.35, peak niclosamide concentrations were 4 µM, 22.4 µM, 96.2 µM, and 215.8 µM, respectively. Similarly, the day 2 values all reduced to 3 µM, 12.9 µM, 35.1 µM, and 112.3 µM. A heat-treatment to 200 °C dehydrated the niclosamide and showed a high 3 h concentration (262 µM) and the least day-2 reduction (to 229 µM). This indicated that the presence, or formation during exposure to buffer, of lower solubility polymorphs was responsible for the reductions in total solubilities. These morphologic changes were confirmed by optical microscopy that showed initially featureless particulate-aggregates of niclosamide could grow multiple needle-shaped crystals and form needle masses, especially in the presence of Tris-buffered sodium chloride, where new red needles were rapidly made. Scale up: A scaled-up 1 L solution of niclosamide was made achieving 165 µM supernatant niclosamide in 3 h by dissolution of just one fifth (100 mg niclosamide) of a Yomesan tablet.

Conclusion: These comprehensive results provide a guide as to how to utilize commercially available and approved tablets of niclosamide to generate aqueous niclosamide solutions from a simple dissolution protocol. As shown here, just one 4-tablet pack of Yomesan could readily make 165 L of a 20 µM niclosamide solution giving 16,500 10 mL bottles. One million bottles, from just 60 packs of Yomesan, would provide 100 million single spray doses for distribution to mitigate a host of respiratory infections as a universal preventative-nasal and early treatment oral/throat sprays throughout the world.

Graphical abstract: pH dependence of niclosamide extraction from crushed Yomesan tablet material into Tris buffer (yellow-green in vial) and Tris-buffered saline solution (orange-red in vial). Initial anhydrous dissolution concentration is reduced by overnight stirring to likely monohydrate niclosamide; and is even lower if in TBSS forming new niclosamide sodium needle crystals grown from the original particles.

Supplementary information: The online version contains supplementary material available at 10.1186/s41120-023-00072-x.

从商业批准的片剂中提取氯硝沙胺到水缓冲溶液中,可产生潜在批准的针对COVID-19和其他呼吸道感染的口服和鼻喷雾剂。
动机:低溶解度、弱酸性药物,氯硝沙胺是一种宿主细胞调节剂,对多种病毒具有广谱抗病毒细胞活性,包括在细胞培养中阻止SARS-CoV-2病毒感染细胞。因此,提出了一种简单的通用鼻喷雾剂,并在早期的工作中研究了氯硝沙胺在简单缓冲液中的溶解。然而,从药物级开始,氯硝柳胺代表了一个新的505(b)(2)申请。因此,该系列第二篇论文的动机是探索是否以及在多大程度上可以从市售和监管部门批准的氯硝柳胺口服片剂中提取氯硝柳胺,这种片剂可以作为预防性鼻喷雾剂和早期治疗口服/咽喉喷雾剂,可能会更快地进行测试和监管部门的批准。实验:用标定的UV-Vis测定上清硝柳胺的浓度,以测定市售的Yomesan粉碎成粉末溶解到Tris缓冲液(TB)溶液中的硝柳胺的溶出度。测试参数如下:时间(0-2天)、浓度(300µM ~ -1 mM)、pH(7.41 ~ 9.35)、无水/水合状态。利用光学显微镜观察粉碎后的初始粉末的形态,以及溶解和平衡未溶解的多余颗粒,以检测可能发生的形态变化。结果:浓度依赖性:在pH为9.34 TB的条件下,Yomesan硝氯胺起始浓度为300µM、600µM和1 mM时,Yomesan硝氯胺很容易从粉末状的Yomesan中提取。在1 h、1 h和3 h时,溶解的硝氯胺上清的峰值浓度分别为264µM、216µM和172µM。这些峰值之后,在第2天过夜后,上清液浓度降低到平均112.3µM±28.4µM。pH依赖性:当pH值为7.41、8.35、8.85和9.35时,氯硝柳胺的峰值浓度分别为4µM、22.4µM、96.2µM和215.8µM。同样,第2天的数值均降至3µM、12.9µM、35.1µM和112.3µM。热处理至200°C使氯硝柳胺脱水,3 h浓度高(262µM),第2天还原最小(229µM)。这表明,在暴露于缓冲液期间,溶解度较低的多晶的存在或形成是导致总溶解度降低的原因。光学显微镜证实了这些形态变化,显示最初无特征的氯硝柳胺颗粒聚集体可以生长出多个针状晶体并形成针状团块,特别是在tris缓冲氯化钠存在的情况下,新的红色针状物质迅速形成。按比例放大:1升奈洛沙胺溶液在3小时内溶出约美散片的五分之一(100mg奈洛沙胺),得到165µM奈洛沙胺上清。结论:这些综合结果为如何利用市售和批准的氯硝柳胺片以简单的溶出工艺制备氯硝柳胺水溶液提供了指导。如图所示,一个4片包装的Yomesan可以很容易地制成165升20µM的氯硝柳胺溶液,相当于16,500瓶10毫升的瓶子。仅60包Yomesan就可生产100万瓶,可提供1亿次单次喷雾剂量,作为全球通用的预防性鼻用和早期治疗口服/咽喉喷雾剂分发,以减轻许多呼吸道感染。图解摘要:由美散碎片料提取的氯硝柳胺在Tris缓冲液(瓶中为黄绿色)和Tris缓冲盐水(瓶中为橙红色)中的pH依赖性。初始无水溶解浓度可通过隔夜搅拌降低为可能的一水硝柳胺;如果在TBSS中形成从原始颗粒生长出来的新的氯胺钠针状晶体,则更低。补充信息:在线版本包含补充资料,下载地址:10.1186/s41120-023-00072-x。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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