Instantaneous topical drug quantification using a 3D printed microfluidic device and coherent Raman imaging

Q2 Pharmacology, Toxicology and Pharmaceutics
Benjamin A. Kuzma , Dandan Tu , Avery Goss, Fotis Iliopoulos, Julian Byrne Slade, Anna Wiatrowski, Amin Feizpour, Conor L. Evans
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引用次数: 1

Abstract

Cutaneous drug concentration quantification after topical application remains an active, yet challenging research area for topical drug development. Macroscale approaches quantify cutaneous pharmacokinetics 30  min to hours after application and miss rapid temporal and spatial dynamics that are vital to comprehend drug disposition. We have developed a 3D-printed applicator coupled with an inverted microscope and a rapidly-tunable fiber optic laser to quantify active pharmaceutical ingredients via sparse spectral sampling stimulated Raman scattering. The 3D-printed applicator is cost-effective (< $0.70/applicator) and utilizes a small formulation volume (20 µL). Ruxolitinib was formulated in two known permeation enhancers (propylene glycol and diethylene glycol monoethyl ether) that are known to display different permeation profiles to validate device capabilities. Results indicated that the applicator enabled relative-concentration monitoring immediately following drug product application. This approach has significant potential for investigating novel excipients, active pharmaceutical ingredients, and formulations to understand the permeation and biodistribution of these compounds.

Abstract Image

使用3D打印微流体装置和相干拉曼成像的瞬时局部药物定量
外用药物后皮肤药物浓度定量仍然是外用药物开发的一个活跃但具有挑战性的研究领域。宏观尺度方法量化了施用后30分钟至几小时的皮肤药代动力学,而忽略了对理解药物处置至关重要的快速时间和空间动力学。我们开发了一种3d打印的涂抹器,结合倒置显微镜和快速可调光纤激光器,通过稀疏光谱采样刺激拉曼散射来量化活性药物成分。3d打印涂抹器具有成本效益(<$0.70/涂抹器),并利用小的配方体积(20µL)。Ruxolitinib是在两种已知的渗透增强剂(丙二醇和二甘醇单乙醚)中配制的,这两种已知的渗透增强剂显示不同的渗透曲线,以验证设备的能力。结果表明,该涂药器可在药品涂药后立即进行相对浓度监测。这种方法在研究新型赋形剂、活性药物成分和配方以了解这些化合物的渗透和生物分布方面具有重要的潜力。
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来源期刊
OpenNano
OpenNano Medicine-Pharmacology (medical)
CiteScore
4.10
自引率
0.00%
发文量
63
审稿时长
50 days
期刊介绍: OpenNano is an internationally peer-reviewed and open access journal publishing high-quality review articles and original research papers on the burgeoning area of nanopharmaceutics and nanosized delivery systems for drugs, genes, and imaging agents. The Journal publishes basic, translational and clinical research as well as methodological papers and aims to bring together chemists, biochemists, cell biologists, material scientists, pharmaceutical scientists, pharmacologists, clinicians and all others working in this exciting and challenging area.
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