Erick E Rocher, Kathryn M Luly, Stephany Y Tzeng, Joel C Sunshine, Jordan J Green
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引用次数: 0
摘要
聚(β-氨基酯)(PBAE)纳米粒子(NPs)在非病毒基因递送方面前景广阔。最近的研究表明,支化聚(β-氨基酯)比线性聚(β-氨基酯)更具优势,但对聚合物结构对多种化学成分的影响尚未进行深入研究。在这里,我们合成了一个具有三官能团和四官能团分支的 BPBAEs 库。这些聚合物能与 DNA 自组装,形成高度阳离子、单分散的 NPs,且尺寸极小(50 nm)。具有适度 PBAE 分支的聚合物结构可实现最佳转染效果,从而在 DNA 剂量和聚合物用量较低的情况下实现 DNA 的完全包裹、NP 的快速吸收和强健表达。优化后的 NP 能在体外将 DNA 有效地输送到不同类型的细胞,同时保持较高的细胞活力,与性能良好的线性 PBAE 相比有了显著改善。BPBAEs 还有助于高效递送 mRNA 和 siRNA,突出了这些结构的多功能性,证明了 BPBAE NPs 作为核酸递送载体的广泛用途。
Efficient Polymeric Nanoparticle Gene Delivery Enabled Via Tri- and Tetrafunctional Branching.
Poly(β-amino ester) (PBAE) nanoparticles (NPs) show great promise for nonviral gene delivery. Recent studies suggest branched PBAEs (BPBAEs) offer advantages over linear counterparts, but the effect of polymer structure has not been well investigated across many chemical constituents. Here, a library of BPBAEs was synthesized with tri- and tetrafunctional branching. These polymers self-assemble with DNA to form highly cationic, monodisperse NPs with notably small size (∼50 nm). Optimal transfection occurred with polymer structures that featured moderate PBAE branching, enabling complete DNA encapsulation, rapid NP uptake, and robust expression at low DNA doses and polymer amounts. Optimized NPs enabled efficient DNA delivery to diverse cell types in vitro while maintaining high cellular viability, demonstrating significant improvements over a well-performing linear PBAE counterpart. BPBAEs also facilitated efficient mRNA and siRNA delivery, highlighting the versatility of these structures and demonstrating the broad utility of BPBAE NPs as vectors for nucleic acid delivery.
期刊介绍:
Biomacromolecules is a leading forum for the dissemination of cutting-edge research at the interface of polymer science and biology. Submissions to Biomacromolecules should contain strong elements of innovation in terms of macromolecular design, synthesis and characterization, or in the application of polymer materials to biology and medicine.
Topics covered by Biomacromolecules include, but are not exclusively limited to: sustainable polymers, polymers based on natural and renewable resources, degradable polymers, polymer conjugates, polymeric drugs, polymers in biocatalysis, biomacromolecular assembly, biomimetic polymers, polymer-biomineral hybrids, biomimetic-polymer processing, polymer recycling, bioactive polymer surfaces, original polymer design for biomedical applications such as immunotherapy, drug delivery, gene delivery, antimicrobial applications, diagnostic imaging and biosensing, polymers in tissue engineering and regenerative medicine, polymeric scaffolds and hydrogels for cell culture and delivery.
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