Department of Clinical Pharmacy and Toxicology, Leiden University Medical Center, Leiden, The Netherlands.
Department of Hospital Pharmacy, Erasmus University Medical Center, Rotterdam, The Netherlands.
Clin Pharmacol Ther. 2023 May;113(5):1125-1131. doi: 10.1002/cpt.2870. Epub 2023 Mar 8.
Personalized medicine is currently hampered by the lack of flexible drug formulations. Especially for pediatric patients, manual compounding of personalized drug formulations by pharmacists is required. Three-Dimensional (3D) printing of medicines, which enables small-scale manufacturing at the point-of-care, can fulfill this unmet clinical need. This study investigates the feasibility of developing a 3D-printed tablet formulation at the point-of-care which complies to quality requirements for clinical practice, including bioequivalence. Development, manufacturing, and quality control of the 3D-printed tablets was performed at the manufacturing facility and laboratory of the department of Clinical Pharmacy and Toxicology at Leiden University Medical Center. Sildenafil was used as a model drug for the tablet formulation. Along with the 3D-printed tablets a randomized, an open-label, 2-period, crossover, single-dose clinical trial to assess bioequivalence was performed in healthy adults. Bioequivalence was established if areas under the plasma concentration curve from administration to the time of the last quantifiable concentration (AUC ) and maximum plasma concentration (C ) ratios were within the limits of 80.00-125.00%. The manufacturing process provided reproducible 3D-printed tablets that adhered to quality control requirements and were consequently used in the clinical trial. The clinical trial was conducted in 12 healthy volunteers. The 90% confidence intervals (CIs) of both AUC and C ratios were within bioequivalence limits (AUC 90% CI: 87.28-104.14; C 90% CI: 80.23-109.58). For the first time, we demonstrate the development of a 3D-printed tablet formulation at the point-of-care that is bioequivalent to its marketed originator. The 3D printing of personalized formulations is a disruptive technology for compounding, bridging the gap toward personalized medicine.
个性化医学目前受到缺乏灵活药物制剂的阻碍。特别是对于儿科患者,需要药剂师手动配制个性化药物制剂。药品的 3D 打印可以实现小规模的即时制造,可以满足这一未满足的临床需求。本研究探讨了在临床现场开发符合临床实践质量要求(包括生物等效性)的 3D 打印片剂制剂的可行性。3D 打印片剂的开发、制造和质量控制在莱顿大学医学中心临床药学和毒理学系的制造设施和实验室进行。西地那非被用作片剂制剂的模型药物。除了 3D 打印片剂外,还在健康成年人中进行了一项随机、开放标签、2 期、交叉、单次剂量临床试验,以评估生物等效性。如果给药至最后可量化浓度时间的血浆浓度曲线下面积(AUC)和最大血浆浓度(C)比值在 80.00-125.00%的范围内,则建立生物等效性。该制造工艺提供了可重复的 3D 打印片剂,符合质量控制要求,并随后用于临床试验。该临床试验在 12 名健康志愿者中进行。AUC 和 C 比值的 90%置信区间(CI)均在生物等效性范围内(AUC 90%CI:87.28-104.14;C 90%CI:80.23-109.58)。我们首次证明了在临床现场开发的 3D 打印片剂制剂与其市售原研药具有生物等效性。个性化配方的 3D 打印是一种用于混合的颠覆性技术,为个性化药物架起了桥梁。
