通过点击化学实现体内靶向。

In vivo targeting through click chemistry.

作者信息

Brudno Yevgeny, Desai Rajiv M, Kwee Brian J, Joshi Neel S, Aizenberg Michael, Mooney David J

机构信息

Wyss Institute for Biologically Inspired Engineering, Harvard University, 3 Blackfan Cir., Boston, MA 02115 (USA); School of Engineering and Applied Sciences, Harvard University, 29 Oxford St., Cambridge, MA 02138 (USA).

出版信息

ChemMedChem. 2015 Apr;10(4):617-20. doi: 10.1002/cmdc.201402527. Epub 2015 Feb 20.

DOI:10.1002/cmdc.201402527

PMID:25704998

Abstract

Targeting small molecules to diseased tissues as therapy or diagnosis is a significant challenge in drug delivery. Drug-eluting devices implanted during invasive surgery allow the controlled presentation of drugs at the disease site, but cannot be modified once the surgery is complete. We demonstrate that bioorthogonal click chemistry can be used to target circulating small molecules to hydrogels resident intramuscularly in diseased tissues. We also demonstrate that small molecules can be repeatedly targeted to the diseased area over the course of at least one month. Finally, two bioorthogonal reactions were used to segregate two small molecules injected as a mixture to two separate locations in a mouse disease model. These results demonstrate that click chemistry can be used for pharmacological drug delivery, and this concept is expected to have applications in refilling drug depots in cancer therapy, wound healing, and drug-eluting vascular grafts and stents.

摘要

将小分子靶向病变组织进行治疗或诊断是药物递送领域的一项重大挑战。在侵入性手术期间植入的药物洗脱装置可实现药物在疾病部位的可控递送，但手术完成后便无法进行调整。我们证明，生物正交点击化学可用于将循环小分子靶向到病变组织中肌肉内的水凝胶。我们还证明，小分子可以在至少一个月的时间内反复靶向病变区域。最后，在小鼠疾病模型中，利用两种生物正交反应将作为混合物注射的两种小分子分离到两个不同位置。这些结果表明，点击化学可用于药理药物递送，预计这一概念将在癌症治疗、伤口愈合以及药物洗脱血管移植物和支架的药物储备补充中得到应用。

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通过点击化学实现体内靶向。

In vivo targeting through click chemistry.

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