三维生物打印微针:融合给药和支架科学,实现组织特异性应用。

Expert opinion on drug delivery Pub Date : 2024-11-01 Epub Date: 2024-05-09 DOI:10.1080/17425247.2024.2351928
Mershen Govender, Sunaina Indermun, Yahya E Choonara
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引用次数: 0

摘要

简介:三维(3D)微针因其多功能性、生物相容性、更强的渗透性和可预测性,最近受到了广泛关注。在这些三维结构中加入生物制剂使传统的微针发展成为一个可广泛应用的有效平台:本综述讨论了微针制造的现状,以及为潜在生物医学应用而开发的融入可溶性药剂和生物材料的三维打印微针。此外,还探讨了制备微针的机械和加工注意事项、有效三维打印微针构建体的障碍,以及微针的治疗应用和组织工程及再生应用潜力。此外,还讨论了微针审批的监管考虑因素以及当前的临床试验和专利情况:组织工程和再生医学领域正在飞速发展,研究人员一直致力于将先进的制造技术应用于多功能、复杂和生物特异性平台的开发。使用传统三维打印技术制造的三维生物打印微针,通过在三维结构中加入生物材料,提供了二维生物支架的替代品,同时还进一步提高了机械稳定性,增加了生物活性渗透,改善了对周围组织的神经支配。因此,这一进步有可能使生物仿生结构更加有效,改善组织特异性细胞生长,从而加强对需要组织再生和替代的生理状况的治疗。
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3D bioprinted microneedles: merging drug delivery and scaffold science for tissue-specific applications.

Introduction: Three-Dimensional (3D) microneedles have recently gained significant attention due to their versatility, biocompatibility, enhanced permeation, and predictable behavior. The incorporation of biological agents into these 3D constructs has advanced the traditional microneedle into an effective platform for wide-ranging applications.

Areas covered: This review discusses the current state of microneedle fabrication as well as the developed 3D printed microneedles incorporating labile pharmaceutical agents and biological materials for potential biomedical applications. The mechanical and processing considerations for the preparation of microneedles and the barriers to effective 3D printing of microneedle constructs have additionally been reviewed along with their therapeutic applications and potential for tissue engineering and regenerative applications. Additionally, the regulatory considerations for microneedle approval have been discussed as well as the current clinical trial and patent landscapes.

Expert opinion: The fields of tissue engineering and regenerative medicine are evolving at a significant pace with researchers constantly focused on incorporating advanced manufacturing techniques for the development of versatile, complex, and biologically specific platforms. 3D bioprinted microneedles, fabricated using conventional 3D printing techniques, have resultantly provided an alternative to 2D bioscaffolds through the incorporation of biological materials within 3D constructs while providing further mechanical stability, increased bioactive permeation and improved innervation into surrounding tissues. This advancement therefore potentially allows for a more effective biomimetic construct with improved tissue-specific cellular growth for the enhanced treatment of physiological conditions requiring tissue regeneration and replacement.

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