脂质纳米颗粒和脂质体合成与研究服务

脂质纳米粒 (LNP) 或固体脂质纳米粒 (SLNs, sLNPs) 是由脂质组成的纳米粒子，具有固体脂质核心矩阵能够溶解亲脂性的分子。通常它们是球形的，平均直径在 10 到 1000 纳米之间。

脂质纳米颗粒已成为整个制药行业的一种有前途的载体，可以提供多种治疗方法。它们是一种新型药物给药系统和制剂。 LNP 在 2020 年底变得更加广为人知，因为一些使用 RNA 疫苗技术的 COVID-19 疫苗用聚乙二醇化脂质纳米粒子作为其运载工具来包裹脆弱的 mRNA 链。

脂质体是 LNP 的早期版本，是一种多功能的纳米药物递送平台。许多脂质体药物已被批准并应用于医疗实践。脂质体是具有至少一个脂质双层的球形囊泡。该脂质体可用作营养素和药物给药的载体。脂质体是复合结构，由磷脂组成，尤其是磷脂酰胆碱。它可能含有少量其他分子。尽管脂质体的尺寸范围可以从低微米到几十微米不等，但单层脂质体（如下图所示）通常在具有各种靶向配体的较低尺寸范围内。配体附着在它们的表面上，允许它们在病理区域进行表面附着和积累以治疗疾病。

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脂质纳米粒 (LNP) 或固体脂质纳米粒 (SLNs, sLNPs) 是由脂质组成的纳米粒子，具有固体脂质核心矩阵能够溶解亲脂性的分子。通常它们是球形的，平均直径在 10 到 1000 纳米之间。

脂质纳米颗粒已成为整个制药行业的一种有前途的载体，可以提供多种治疗方法。它们是一种新型药物给药系统和制剂。 LNP 在 2020 年底变得更加广为人知，因为一些使用 RNA 疫苗技术的 COVID-19 疫苗用聚乙二醇化脂质纳米粒子作为其运载工具来包裹脆弱的 mRNA 链。

脂质体是 LNP 的早期版本，是一种多功能的纳米药物递送平台。许多脂质体药物已被批准并应用于医疗实践。脂质体是具有至少一个脂质双层的球形囊泡。该脂质体可用作营养素和药物给药的载体。脂质体是复合结构，由磷脂组成，尤其是磷脂酰胆碱。它可能含有少量其他分子。尽管脂质体的尺寸范围可以从低微米到几十微米不等，但单层脂质体（如下图所示）通常在具有各种靶向配体的较低尺寸范围内。配体附着在它们的表面上，允许它们在病理区域进行表面附着和积累以治疗疾病。

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Therapeutic strategy of targeting SLPI-mediated KC reprogramming to alleviate RILD.

(A) Transmission electron microscopy (TEM) image of liposomes stained with phosphotungstic acid, revealing uniform spherical morphology.

(B) Dynamic light scattering analysis showing the particle size of blank liposomes (left, 79 nm) and siSLPI-loaded liposomes (right, 78 nm).

(C) Excitation spectrum of DiD-labeled liposomes.

(D) Time-dependent intracellular uptake of liposomes by Raw264.7 cells. Nuclei were stained with Hoechst (blue), liposomes were labeled with DiD (red), and cytoplasm was stained with Calcein AM (green).

(E) In vivo fluorescence imaging showing hepatic accumulation of liposomes at 1 h post-injection.

(F) CCK-8 assay evaluating the effect of liposomes on Raw264.7 cell proliferation.

(G) H&E staining of heart, liver, spleen, lung, and kidney tissues from treated mice (n = 5), showing no histopathological abnormalities.

(H) H&E staining of liver tissues from different treatment groups (n = 5). Blue arrows: normal hepatocytes; gray arrows: shrunken hepatocytes; green arrows: intact hepatocytes; black arrows: cytoplasmic disruption and sinusoidal dilation.

(I) Immunohistochemistry analysis of hepatic IL-1β, IL-6, and TNF-α expression in RILD mice treated with siSLPI-loaded liposomes.

(J) ELISA quantification of hepatic IL-1β, IL-6, and TNF-α levels in RILD mice treated with siSLPI-liposomes.

Reference: Int. J. Mol. Sci. 2026, 27(5), 2517

LNP mouse study from paper Synthesis and Translational Assessment .jpg

In vivo translational activity in female CD-1 mice of Fluc mRNA-LNPs prepared with PreciGenome NanoGenerator.

(A) Representative bioluminescent images at 3, 6, 12, 24, 48, and 96 h postinjection.

(B) Bioluminescence intensity of treated groups during 96 h. See the Supporting Information for the quantitative analyses of each group and their average.
Statistical analysis was performed using one-way ANOVA followed by Tukey’s post hoc multiple-comparison test. No statistically significant
differences were detected among 9a, 43a, and 42a.

Reference: J. Med. Chem. 2026, 69, 5, 5811–5827

脂质纳米颗粒与合成：

Nanoparticle Synthesis:

NanoGenerator™ nanoparticle synthesis system employs microfluidic device for controllable and tunable nanoparticle production.