Details

Autor(en) / Beteiligte

• Zhang, Zi‐jie
• Zhou, Yi
• Tong, Huan
• Sun, Xi‐cheng
• Lv, Zi‐cheng
• Yong, June‐kong
• Wu, Yi‐chi
• Xiang, Xue‐lin
• Ding, Fei
• Zuo, Xiao‐lei
• Li, Fan
• Xia, Qiang
• Feng, Hao
• Fan, Chun‐hai

Titel

Programmable DNA Hydrogel Assisting Microcrystal Formulations for Sustained Locoregional Drug Delivery in Surgical Residual Tumor Lesions and Lymph Node Metastasis

Ist Teil von

• Advanced healthcare materials, 2024-04, Vol.13 (11), p.e2303762-n/a

Ort / Verlag

Germany: Wiley Subscription Services, Inc

Erscheinungsjahr

2024

Quelle

Wiley-Blackwell Journals

Beschreibungen/Notizen

• Surgical residual tumor lesions (R1 resection of surgical procedures (e.g., liver cancer infiltrating the diaphragm, surgical residual breast cancer, postoperative residual ovarian cancer) or boundary residual after ablation) and lymph node metastasis that cannot be surgically resected (retroperitoneal lymph nodes) significantly affect postoperative survival of tumor patients. This clinical conundrum poses three challenges for local drug delivery systems: stable and continuous delivery, good biocompatibility, and the ability to package new targeted drugs that can synergize with other treatments. Here, a drug‐laden hydrogel generated from pure DNA strands and highly programmable in adjusting its mesh size is reported. Meanwhile, the DNA hydrogel can assist the microcrystallization of novel radiosensitizing drugs, ataxia telangiectasia and rad3‐related protein (ATR) inhibitor (Elimusertib), further facilitating its long‐term release. When applied to the tumor site, the hydrogel system demonstrates significant antitumor activity, minimized systemic toxicity, and has a modulatory effect on the tumor‐immune cell interface. This drug‐loaded DNA‐hydrogel platform represents a novel modality for adjuvant therapy in patients with surgical residual tumor lesions and lymph node metastasis. Surgical residual tumor lesions and lymph node metastasis significantly affect postoperative survival of tumor patients. Here, a drug‐laden hydrogel platform which assists the microcrystallization of novel radiosensitizing drugs, ATR inhibitor (Elimusertib), further facilitating its long‐term release is developed. The hydrogel system demonstrates significant antitumor activity, minimized systemic toxicity, and has a modulatory effect on the tumor‐immune cell interface.