中文摘要:
納米顆粒 (NPs) 目前被開發(fā)用于藥物遞送和分子成像。然而,它們經(jīng)常在到達目標之前被攔截,導致瞄準效率和信噪比低下。它們往往會積聚在肺、肝、腎和脾臟等器官中。補救措施是迭代設計 NP 表面特性和給藥策略,目前是一個耗時的過程,包括在不同時間點進行器官解剖。為了改善這一點,我們提出了一種快速迭代方法,使用全動物X射線熒光(XRF)成像來系統(tǒng)地評估體內(nèi)NP分布。我們將這種方法應用于鉬基NPs和氯膦酸鹽脂質(zhì)體(Clodronate Liposomes),用于腫瘤靶向與瞬時巨噬細胞耗竭,從而減少肺和肝臟中的積累并最終檢測腫瘤。XRF 計算機斷層掃描 (XFCT) 提供了腫瘤內(nèi) NP 分布的 3D 洞察。我們使用多尺度成像方法驗證了結(jié)果,該方法具有染料摻雜的NPs和用于納米毒理學分析的基因表達分析。XRF成像在推進臨床前藥代動力學研究中的治療和診斷方面具有潛力。
Abstract
Nanoparticles (NPs) are currently developed for drug delivery and molecular imaging. However, they often get intercepted before reaching their target, leading to low targeting efficacy and signal-to-noise ratio. They tend to accumulate in organs like lungs, liver, kidneys, and spleen. The remedy is to iteratively engineer NP surface properties and administration strategies, presently a time-consuming process that includes organ dissection at different time points. To improve this, we propose a rapid iterative approach using whole-animal x-ray fluorescence (XRF) imaging to systematically evaluate NP distribution in vivo. We applied this method to molybdenum-based NPs and clodronate liposomes(Liposoma) for tumor targeting with transient macrophage depletion, leading to reduced accumulations in lungs and liver and eventual tumor detection. XRF computed tomography (XFCT) provided 3D insight into NP distribution within the tumor. We validated the results using a multiscale imaging approach with dye-doped NPs and gene expression analysis for nanotoxicological profiling. XRF imaging holds potential for advancing therapeutics and diagnostics in preclinical pharmacokinetic studies.
論文題目:Iterative nanoparticle bioengineering enabled by x-ray fluorescence imaging
期刊名稱:SCIENCE ADVANCES
期卷日期:22 Mar 2024, Vol 10, Issue 12
實驗數(shù)據(jù):
靶點科技(北京)有限公司
地址:中關(guān)村生命科學園北清創(chuàng)意園2-4樓2層
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