<p>Achieving pancreatic-targeted delivery marks a breakthrough in treating pancreatic diseases, yet precise delivery remains challenging<sup><CitationRef CitationID="CR1">1</CitationRef></sup>. Here we identify an explicit and universal principle for pancreatic-selective delivery and propose a&#xa0;pancreatic-targeted lipid nanoparticle (AH-LNP) for mRNA delivery. AH-LNP exhibits size enlargement after assembly with proteins, facilitating capsule-filter-mediated pancreas-selective accumulation and receptor-mediated endocytosis, thereby boosting the pancreatic-targeted ability. Benefiting from this, AH-LNP enables precise and efficient genome editing in the pancreas through the delivery of Cas9 mRNA and single&#xa0;guide&#xa0;RNA (sgRNA), exhibiting promising potential in the treatment of autoimmune pancreatic diseases. Furthermore, pancreatic-targeted delivery of mRNA encoding therapeutic cytokines through AH-LNP demonstrates superior antitumour efficacy when combined with a cancer vaccine or chimeric antigen receptor T cell therapy in multiple pancreatic cancer models. The safety and pancreatic mRNA delivery of AH-LNP were verified in multiple animal models, including non-human primates, demonstrating great promise for clinical translation. Our findings highlight the transformative potential of this pancreatic-targeted mechanism and the derived LNP platform, opening avenues for developing precision therapeutics against diverse pancreatic diseases.</p>

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Pancreatic-targeted lipid nanoparticles based on organ capsule filtration

  • Jiaqi Lei,
  • Kai Yang,
  • Wanyue Cao,
  • Shaolong Qi,
  • Xianlong Du,
  • Hongjian Li,
  • Yangfan Wang,
  • Jinqun Gan,
  • Yunxuan Feng,
  • Yongcan Li,
  • Wenjie Zhang,
  • Bing Bai,
  • Xin Lin,
  • Xinhui Su,
  • Qi Zhang,
  • Tingbo Liang,
  • Guocan Yu

摘要

Achieving pancreatic-targeted delivery marks a breakthrough in treating pancreatic diseases, yet precise delivery remains challenging1. Here we identify an explicit and universal principle for pancreatic-selective delivery and propose a pancreatic-targeted lipid nanoparticle (AH-LNP) for mRNA delivery. AH-LNP exhibits size enlargement after assembly with proteins, facilitating capsule-filter-mediated pancreas-selective accumulation and receptor-mediated endocytosis, thereby boosting the pancreatic-targeted ability. Benefiting from this, AH-LNP enables precise and efficient genome editing in the pancreas through the delivery of Cas9 mRNA and single guide RNA (sgRNA), exhibiting promising potential in the treatment of autoimmune pancreatic diseases. Furthermore, pancreatic-targeted delivery of mRNA encoding therapeutic cytokines through AH-LNP demonstrates superior antitumour efficacy when combined with a cancer vaccine or chimeric antigen receptor T cell therapy in multiple pancreatic cancer models. The safety and pancreatic mRNA delivery of AH-LNP were verified in multiple animal models, including non-human primates, demonstrating great promise for clinical translation. Our findings highlight the transformative potential of this pancreatic-targeted mechanism and the derived LNP platform, opening avenues for developing precision therapeutics against diverse pancreatic diseases.