Quinelato Valquiria, Mourão Carlos Fernando, Santos Thalita Alves Barreto, Cataldo de Felipe Cordeiro Patrícia, Ladeira Bonato Leticia, Gomes Pereira Miria, Calasans-Maia Jose Albuquerque, Granjeiro Jose Mauro, Kawase Tomoyuki, Ladeira Casado Priscila
Post-Graduation Program in Dentistry, Universidade Federal Fluminense, Niteroi 24020-140, Rio de Janeiro, Brazil.
National Institute of Traumatology and Orthopedics, Rio de Janeiro 20940-070, Rio de Janeiro, Brazil.
Int J Mol Sci. 2025 Mar 22;26(7):2891. doi: 10.3390/ijms26072891.
Extracellular vesicles (EVs) are emerging as crucial biomarkers in molecular diagnostics, providing early detection of disease progression. Although ultracentrifugation remains the gold standard for vesicle isolation from biofluids, it has limitations in scalability and accessibility. This study presents lyophilization as an innovative method for preserving EVs and isolating microRNAs from saliva, utilizing its proven ability to maintain biological activity and prevent unwanted chemical reactions. We assessed five different sample preparation protocols combined with a dual-purification strategy. Structural and molecular integrity analyses revealed that lyophilized samples retained essential EV characteristics, including CD63/CD9 membrane localization. QELS analysis and electron microscopy confirmed distinct vesicle populations in both ultracentrifuged (30-50 nm and 320-360 nm) and lyophilized samples (50-70 nm and 360-380 nm). Importantly, lyophilized samples exhibited higher total RNA concentrations ( < 0.0001) while preserving key microRNA signatures (miR-16, miR-21, miR-33a, and miR-146b) with high fidelity. The efficacy of lyophilization is linked to its ability to systematically reduce solvent content through sublimation while maintaining vesicle integrity and molecular cargo. This method offers a practical, scalable alternative for EV isolation with significant implications for biomarker-based diagnostics.
细胞外囊泡(EVs)正在成为分子诊断中至关重要的生物标志物,可实现疾病进展的早期检测。尽管超速离心仍然是从生物流体中分离囊泡的金标准,但它在可扩展性和可及性方面存在局限性。本研究提出冻干法是一种保存EVs并从唾液中分离微小RNA的创新方法,利用其已证实的保持生物活性和防止不必要化学反应的能力。我们评估了五种不同的样品制备方案并结合双重纯化策略。结构和分子完整性分析表明,冻干样品保留了基本的EV特征,包括CD63/CD9膜定位。动态光散射分析和电子显微镜证实了超速离心样品(30 - 50纳米和320 - 360纳米)和冻干样品(50 - 70纳米和360 - 380纳米)中存在不同的囊泡群体。重要的是,冻干样品表现出更高的总RNA浓度(<0.0001),同时以高保真度保留关键的微小RNA特征(miR - 16、miR - 21、miR - 33a和miR - 146b)。冻干的有效性与其通过升华系统降低溶剂含量同时保持囊泡完整性和分子载荷的能力有关。该方法为EV分离提供了一种实用、可扩展的替代方案,对基于生物标志物的诊断具有重要意义。
