作者承认在中国科学院基础医学与肿瘤研究所（IBMC）的共享仪器核心设施中使用仪器。本研究得到了国家自然科学基金（NSFC;82172598）、浙江省自然科学基金（LZ22H310001）、浙江省卫生健康委员会551卫生人才培养项目、杭州市科技局农业与社会发展研究项目（2022ZDSJ0474）和钱塘交叉学科研究基金的资助。

注：该方法的示意图如 图1所示。
1. 电磁脉冲制备与隔离
<ol><li>MNP的细胞内化<ol><li>细胞培养<ol><li>将 1 × 106 只大鼠骨髓间充质干细胞 （BMSC）、293T 细胞或小鼠卵巢上皮癌细胞 （ID8） 悬浮在含有 10% 胎牛血清 （FBS） 和 5% 青霉素-链霉素溶液 （P/S） 的 DMEM 完全培养基中，溶于 2 mL 每 6 孔板（参见 材料表）。</li>
			<li>将细胞在37°C和5%CO2下培养过夜。 注意：粘附后的细胞数约为 1 ×10 6。</li>
		</ol></li>
		<li>MNP的内吞作用<ol><li>将每个六孔板的培养基体积减小至 1 mL。用浓度为100μg/ 1×106个细胞的10nm聚赖氨酸修饰的氧化铁纳米颗粒（IONP）（参见材料表）共同培养细胞，并在37°C下在含有5%CO2的气氛中孵育12小时，以使细胞完全内吞IONPs。</li>
		</ol></li>
	</ol></li>
	<li>内体的分离和均质化<ol><li>细胞低渗治疗<ol><li>用 0.5 mL/孔胰蛋白酶消化已完全内化 IONP 的细胞 3 分钟，并通过加入 1 mL/孔完全培养基终止消化。</li>
			<li>以1000× g 离心5分钟，弃去上清液。将细胞重悬于磷酸盐缓冲盐水 （PBS） 中并离心，重复两次以洗掉残留的培养基和未吸收的 IONP。</li>
			<li>最后，将沉淀重悬于预先制备的低渗溶液（71.4mM氯化钾，1.3mM柠檬酸钠，pH 7.2-7.4）中15分钟（参见 材料表）。</li>
		</ol></li>
		<li>通过低速均质化释放细胞器<ol><li>将低渗溶液中的细胞悬浮液转移到玻璃试管中，并使用玻璃匀浆器（参见 材料表）以1000rpm的速度冲击20次释放细胞器。</li>
		</ol></li>
		<li>磁分离以获得内体<ol><li>将 1 mL 匀浆细胞溶液转移到 1.5 mL 微量离心管中，并置于磁性分离器中 1 小时，以将负载 IONP 的内体与其他细胞器（如细胞核和线粒体）和细胞碎片完全分离。</li>
			<li>将棕色颗粒收集在磁架旁边的微量离心管的接触表面上（参见 材料表），即IONP负载的内体。丢弃微量离心管中的液体，加入 3 mL PBS 以重悬内体。</li>
		</ol></li>
	</ol></li>
	<li>高速均质化<ol><li>将含有内体的溶液转移到液体体积在 3-10 mL 之间的 15 mL 离心管中。</li>
		<li>将高速均质机的 10 毫米探头（参见材料表）伸至离心管底部，不要接触底部。调整屏幕下方的速度按钮，将速度设置为 140 x g，调整时间按钮设置为 5 分钟的时间，然后按 OK 按钮。</li>
		<li>按下 开始 按钮，在样品下方放置冰盒后进行均质化。</li>
	</ol></li>
	<li>电磁场的磁性分选<ol><li>将含有高速均质化获得的纳米囊泡的溶液转移到1.5mL微量离心管中，并将其置于磁选机中1小时。</li>
		<li>收集含有所需 EM 的液体。小心不要触摸磁性框架旁边的管子表面，磁性框架吸附了游离的 IONP 和 IONP 负载的 EM。</li>
	</ol></li>
</ol>2. EM表征（图2和图3）
<ol><li>动态光散射 （DLS） 分析<ol><li>沿壁将 1 mL EMs 样品 （20 μg/mL） 注入比色皿中，并将其放入 DLS 仪器的仪器样品槽中（参见 材料表）。</li>
		<li>打开DLS软件，选择 粒度测试，然后开始测试。</li>
		<li>使用BCA蛋白测定试剂盒测量蛋白质浓度（参见 材料表）。</li>
	</ol></li>
	<li>纳米颗粒跟踪分析（NTA）<ol><li>用PBS稀释EM至1×107-1×108 颗粒/mL的溶液，然后使用1mL注射器以500-1000μL/min的流速将其注入NTA仪器的腔室（参见 材料表）。</li>
		<li>打开 488 个激光通道，确保软件界面中的 EM 数量在 100-300 个以内且呈布朗运动。</li>
		<li>根据制造商的协议，选择合适的 SOP （EV-488） 以确保仪器的灵敏度适合 EM 检测。</li>
	</ol></li>
	<li>透射电子显微镜（TEM）<ol><li>用等体积的5%戊二醛固定EM（1mg / mL）30分钟，并通过BCA蛋白测定试剂盒将EM的浓度定量为1mg / mL。</li>
		<li>将 10 μL 的 EM 滴在铜网的碳侧，并在 10 分钟后用滤纸从侧面去除多余的液体。加入 10 μL PBS 并立即用滤纸吸干。重复两次以去除多余的戊二醛。</li>
		<li>滴入 5 μL 醋酸铀酰造影剂并负染色 1 分钟，然后去除多余的造影剂。用去离子水洗涤三次，并在室温 （RT） 下干燥。</li>
		<li>在100 kV的加速电压下通过TEM记录图像。</li>
	</ol></li>
	<li>蛋白质印迹<ol><li>向样品中加入 100 μL 细胞裂解缓冲液和 5 μL 50 倍蛋白酶抑制剂混合物（参见 材料表）。用移液枪轻轻混合，放在冰上30分钟。</li>
		<li>将溶液在4°C下以1000× g 离心10分钟，用BCA蛋白测定试剂盒定量上清液的蛋白质浓度，并收集。</li>
		<li>将100μL上清液与25μL5x蛋白上样缓冲液混合，并在95°C下加热10分钟。</li>
		<li>根据预制凝胶的说明制备凝胶。每孔加载15μg蛋白质，并在80 V下通过凝胶电泳运行，等待样品运行到分离凝胶，更改为100 V，然后将蛋白质转移到100 V的硝酸纤维素膜上，在冰浴下60分钟。</li>
		<li>通过蛋白质印迹检测非 EV 特异性标志物 （Calnexin） 和 EV 生物标志物 （Annexin 和 CD63）（参见 材料表）。 注意：根据制造商的建议稀释抗体。</li>
	</ol></li>
</ol>3. 体外EM 功能检测
<ol><li>EM 标签<ol><li>将 1 μL PKH26 与 250 μL 稀释剂 C （1：250） 混合，制成 2x 染色溶液（4 × 10-6 M）（参见 材料表）。</li>
		<li>将 250 μL EM （1 mg/mL） 与 250 μL 2x 染色溶液混合，并用移液枪快速吹气。</li>
		<li>在室温下孵育2-5分钟，同时轻轻倒置离心管。</li>
		<li>加入等体积的血清或 1% 牛血清蛋白并孵育 1 分钟以终止消化。</li>
		<li>用1000 KD超滤管以3000× g 超滤除去多余的PKH26 30分钟，并通过加入PBS重复三次。用PBS将剩余液体重悬至500μL，并通过0.22μm过滤器过滤。</li>
	</ol></li>
	<li>细胞摄取检测<ol><li>细胞接种：在含有10%FBS和5%P/S的1mLDMEM中，在35mm共聚焦培养皿中接种1个×10个6 个细胞，并在37°C和5%CO2 下孵育过夜。</li>
		<li>用 0.22 μm 无菌针式过滤器过滤 EM 以去除潜在的污染。</li>
		<li>用PKH26标记的EM（109 粒/ mL）处理细胞8小时。</li>
		<li>用 PBS 洗涤 3 次，加入 DAPI （10 ng/mL），并在室温下孵育 10 分钟。</li>
		<li>使用 405 nm 和 561 nm 激光通道在共聚焦激光扫描荧光显微镜中获取荧光图像（参见 材料表）。</li>
	</ol></li>
</ol>

优化内体衍生的纳米囊泡的磁性高产率生产

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D.W.和P.G.是中国科学院基础医学与肿瘤研究所（IBMC）提交的一项专利申请的共同发明人。另一位作者声明没有利益冲突。

作为无细胞疗法和纳米级药物递送系统的替代品，EV尚未达到其临床预期，主要障碍是缺乏可扩展和可重复的生产和纯化方法6。因此，各种类型的 EM 已被开发为具有相似生物复杂性的 EV 类似物14。迄今为止，最常用的EM例子是细胞质膜衍生的纳米囊泡。通过直接挤出整个母体细胞17，这种纳米囊泡的制备相对容易和直接。然而，由于两个缺点?...

细胞外囊泡 （EV） 是几乎所有细胞分泌的小囊泡，大小范围为 30-150 nm，含有丰富的生物活性物质。根据来源细胞的不同，EV 表现出高度异质性，具有亲本细胞特异性的多种成分1。EV 被释放到体液中并运输到远处，在那里它们被靶细胞吸收以发挥作用2，可用于递送用于组织修复、肿瘤诊断和治疗以及免疫调节的各种生物活性分子和药物 3,4。然而，体液中具有相似生物物理特性的其他生物纳米颗粒（例如脂蛋白）和纳米囊泡（例如，来自非内体途径的 EV）不可避免地会影响 EV 的分离和纯化。迄今为止，超速离心仍然是 EV 分离的金标准，并且已经开发了其他分离方法，包括蔗糖密度梯度离心、超滤、聚乙二醇沉淀、色谱和免疫磁珠分离5。目前限制 EV 疗法临床转化和商业化的瓶颈是严重缺乏能够实现 EV 高度可扩展和可重复分离的分离技术 6,7,8。传统的EV分离技术（如超速离心和尺寸排阻色谱）产量低（1 x 107-1 x 108/1 x 106个细胞）、生产周期长（24-48 h）、产品质量重现性差，需要昂贵且能源密集型的生产设备，无法满足目前对EV的临床需求6。
外泌体模拟物 （EM） 是天然电动汽车的合成替代品，由于它们在生产中的结构、功能和可扩展性高度相似，因此引起了人们的广泛关注。EM 的主要来源是连续切片的整个亲本细胞的直接挤出 9,10，显示出作为天然 EV 的强大生物学功能11,12。例如，源自人脐带间充质干细胞 （hUCMSCs） 的 EM 具有与天然 EV 相似的伤口愈合作用，并且蛋白质组成更丰富13。虽然来自全细胞的EM具有EV的生物学复杂性，但它们的主要缺点是产物的异质性，因为它们不可避免地受到各种细胞器和细胞碎片的污染。蛋白质定位分析进一步表明，源自全细胞挤出的 EM 含有许多来自线粒体和内质网的非 EVs 特异性蛋白质13。此外，大多数制造电磁镜的方法仍然需要超速离心，这是一个非常耗时和耗能的过程14。考虑到外泌体完全来源于细胞内体这一事实，我们假设与全细胞挤出方法产生的成熟细胞膜衍生的 EM 相比，生物工程内体衍生的纳米囊泡可能更好地概括外泌体和 EM 之间的生物学同源性14。然而，由于缺乏可行的方法，内体衍生的纳米囊泡的制造是困难的。
临床研究是利用EV作为无细胞疗法的替代品和用于治疗各种疾病的纳米级药物递送系统进行的。例如，源自骨髓间充质干细胞的 EV 已被用于治疗由 COVID-19 引起的严重肺炎，并取得了可喜的结果。最近，携带 CD24 蛋白的基因工程 EV 也显示出治疗 COVID-19 患者的有效治疗效果15,16。然而，由于产量低、成本低，传统分离方法仍无法满足EV治疗的临床需求。本研究报道了通过磁分离辅助高速均质化方法大规模生产内体衍生的纳米囊泡。它利用MNPs的内吞途径，通过磁分离分离MNP负载的内体，然后进行高速匀浆，将内体配制成单分散的纳米囊泡。由于该协议收集的内体类型多种多样，因此仍需要进一步深入研究以建立行业内的良好生产规范（GMP）。这种新颖的EM制备方法更省时（5分钟的高速均质化），以获得与天然EV同源的纳米囊泡。与超速离心相比，它从相同数量的细胞中产生更多的囊泡，超速离心通常可以应用于各种细胞类型。

<table border="1" fo:keep-together.within-page="1" fo:keep-with-next.within-page="always">
	<tbody>
		<tr>
			<td>Annexin antibody</td>
			<td>ABclonal</td>
			<td>A11235</td>
			<td>Western blotting</td>
		</tr>
		<tr>
			<td>BCA assay kit</td>
			<td>Beyotime</td>
			<td>P0012</td>
			<td>Protein concentration assay</td>
		</tr>
		<tr>
			<td>Calnexin</td>
			<td>GeneTex</td>
			<td>HL1598</td>
			<td>Western blotting</td>
		</tr>
		<tr>
			<td>CD63 antibody</td>
			<td>ABclonal</td>
			<td>A19023</td>
			<td>Western blotting</td>
		</tr>
		<tr>
			<td>Cell lysis buffer for Western and IP</td>
			<td>Beyotime</td>
			<td>P0013</td>
			<td>Western blotting</td>
		</tr>
		<tr>
			<td>Centrifuge</td>
			<td>Beckman</td>
			<td>Allegra X-30R</td>
			<td>Cell centrifuge</td>
		</tr>
		<tr>
			<td>CO2 incubator</td>
			<td>Thermo</td>
			<td></td>
			<td>Cell culture</td>
		</tr>
		<tr>
			<td>Confocal laser scanning fluorescence microscopy</td>
			<td>NIKON</td>
			<td>A1 HD25</td>
			<td>Photo the fluorescence picture</td>
		</tr>
		<tr>
			<td>DMEM basic (1x)</td>
			<td>GIBCO</td>
			<td>C11995500BT</td>
			<td>Cell culture</td>
		</tr>
		<tr>
			<td>Dynamic light scattering (DLS)</td>
			<td>Malvern</td>
			<td>Zetasizer Nano ZS ZEN3600</td>
			<td>Diameter analysis</td>
		</tr>
		<tr>
			<td>Electric glass homogenizer</td>
			<td>SCIENTZ(Ningbo, China)</td>
			<td>DY89-II</td>
			<td>Low-speed homogenization</td>
		</tr>
		<tr>
			<td>Exosome-depleted FBS</td>
			<td>system Bioscience</td>
			<td>EXO-FBS-50A-1</td>
			<td>Cell culture</td>
		</tr>
		<tr>
			<td>High-speed homogenizer</td>
			<td>SCIENTZ(Ningbo, China)</td>
			<td>XHF-DY</td>
			<td>High-speed homogenization</td>
		</tr>
		<tr>
			<td>Magnetic grate</td>
			<td>Tuohe Electromechanical Technology (Shanghai, China)</td>
			<td>NA</td>
			<td>Magnetic separation</td>
		</tr>
		<tr>
			<td>PKH26 Red Fluorescent Cell Linker Kit for General Cell Membrane Labeling</td>
			<td>Sigma-Aldrich</td>
			<td>PKH26GL-1KT</td>
			<td>The kit contains PKH26 cell linker in ethanol and Diluent C</td>
		</tr>
		<tr>
			<td>Polylysine-modified iron oxide nanoparticles (IONPs)</td>
			<td>Zhongke Leiming Technology (Beijing, China)</td>
			<td>Mag1100-10</td>
			<td>Cell culture</td>
		</tr>
		<tr>
			<td>Potassium chloride</td>
			<td>Aladdin</td>
			<td>7447-40-7</td>
			<td>Cell hypotonic treatment</td>
		</tr>
		<tr>
			<td>Protease inhibitor cocktail</td>
			<td>Beyotime</td>
			<td>P1030</td>
			<td>Proteinase inhibitor</td>
		</tr>
		<tr>
			<td>Sodium citrate</td>
			<td>Aladdin</td>
			<td>7447-40-7</td>
			<td>Cell hypotonic treatment</td>
		</tr>
		<tr>
			<td>Transmission electron microscopy (TEM)</td>
			<td>JEOL</td>
			<td>JEM-2100plus</td>
			<td>Morphology image</td>
		</tr>
		<tr>
			<td>Ultracentrifuge</td>
			<td>Beckman</td>
			<td>Optima XPN-100</td>
			<td>Exosome centrifuge</td>
		</tr>
		<tr>
			<td>ZetaView nanoparticle&#160; tracking analyzers</td>
			<td>Particle Metrix</td>
			<td>PMX120</td>
			<td>Nanoparticle tracking analysis</td>
		</tr>
	</tbody>
</table>

a magnetic separation-assisted high-speed homogenization method for large-scale production of endosome-derived vesicles

细胞外囊泡（EVs）在生理病理研究、疾病诊断和治疗中备受关注;然而，由于缺乏放大生产方法，它们的临床转化受到限制。因此，该协议为大规模生产内体衍生的纳米囊泡提供了一种磁分离辅助的高速均质化方法，作为一种源自内体的新型外泌体模拟物（EMs），其产率比传统的超速离心方法高出约100倍。在这种方法中，磁性纳米颗粒（MNPs）通过内吞作用被亲本细胞内化，随后在其内体中积累。然后，收集负载MNPs的内体，并通过低渗处理和磁分离进行纯化。使用高速均质器将负载MNP的内体分解成单分散的纳米囊泡。由此产生的内体衍生囊泡具有相同的生物起源和结构，其特征是纳米颗粒跟踪分析、透射电子显微镜和蛋白质印迹。它们的形态和蛋白质组成与天然 EV 相似，表明 EM 可能作为天然 EV 的低成本和高产量替代品，用于临床转化。

Extracellular vesicles (EVs) are small vesicles secreted by almost all cells with a size range of 30-150 nm, containing abundant bioactive substances. Depending on the cell of origin, EVs show high heterogeneity, possessing multiple components specific to parent cells1. EVs are released into body fluids and transported to distant sites where they are taken up by target cells for action2, which can be utilized to deliver a wide range of bioactive molecules and drugs for tissue repairing, tumor diagnosis and treatment, and immune modulation3,4. However, other biological nanoparticles (e.g., lipoproteins) and nanovesicles (e.g., EVs derived from non-endosomal pathways) with similar biophysical properties in body fluids inevitably affect EV isolation and purification. To date, ultracentrifugation remains the gold standard for EV isolation, and other isolation methods, including sucrose density gradient centrifugation, ultrafiltration, polyethylene glycol precipitation, chromatography, and immunomagnetic bead isolation, have been developed5. The current bottleneck limiting clinical translation and commercialization of EV therapeutics is the severe lack of isolation techniques that allow for highly scalable and reproducible isolation of EVs6,7,8. Traditional EV isolation techniques (e.g., ultracentrifugation and size exclusion chromatography) suffer from low yield (1 x 107-1 x 108/1 x 106 cells), long production cycle (24-48 h), poor reproducibility of product quality, and require expensive and energy-intensive production equipment that cannot meet the current clinical demand for EVs6.
Exosome mimics (EMs), synthetic surrogates of native EVs, have attracted important attention due to their highly similar structure, function, and scalability in production. The main source of EMs is from the direct extrusion of whole parental cells with continuous sectioning9,10, demonstrating potent biological functions as native EVs11,12. For instance, EMs derived from human umbilical cord mesenchymal stem cells (hUCMSCs) exert similar wound-healing effects as native EVs and are richer in protein composition13. Though EMs derived from whole cells have the biological complexity of EVs, their main drawback is the heterogeneity of products because they are inevitably contaminated by various cellular organelles and cell debris. Protein localization analysis further revealed that EMs derived from whole-cell extrusion contain many non-EVs-specific proteins from mitochondria and the endoplasmic reticulum13. Moreover, most methods for manufacturing EMs still require ultracentrifugation, a highly time and energy-consuming process14. Considering the fact that exosomes are exclusively derived from cellular endosomes, we hypothesized that bioengineered endosome-derived nanovesicles may better recapitulate the biological homology between exosomes and EMs in comparison with the well-established cell membrane-derived EMs produced by whole cell extrusion method14. Nevertheless, the manufacture of endosome-derived nanovesicles is difficult due to the lack of viable approaches.
Clinical studies have been carried out by utilizing EVs as a surrogate of cell-free therapy and a nanoscale drug delivery system for the treatment of various diseases. For instance, EVs derived from bone marrow mesenchymal stem cells have been used to treat severe pneumonia caused by COVID-19 and have achieved promising results. Recently, genetically engineered EVs carrying CD24 proteins have also demonstrated potent therapeutic benefits for treating COVID-19 patients15,16. However, the clinical requirement of EV therapy still cannot be met with traditional isolation methods because of the low yield and cost. This study reports the large-scale production of endosome-derived nanovesicles via a magnetic separation-assisted high-speed homogenization approach. It takes advantage of the endocytosis pathway of MNPs to isolate MNP-loaded endosomes via magnetic separation, followed by high-speed homogenization to formulate endosomes into monodisperse nanovesicles. Since the types of endosomes collected by this protocol are diverse, further in-depth research is still required to establish good manufacturing practices (GMP) in the industry. This novel EM preparation approach is more time efficient (5 min of high-speed homogenization) to obtain nanovesicles homologous to native EVs. It produces exponentially more vesicles from the same amounts of cells than ultracentrifugation, which can be generally applied to various cell types.

作者聚焦：使用磁性纳米颗粒开发大规模、可重现的外泌体模拟物生产方法 

一种用于大规模生产内体衍生囊泡的磁分离辅助高速均质化方法

In this study, we try to address a critical unmet need in exosome research, which is developing a large-scale and reproducible production method for exosome mimetics. Due to the notion of native evades, exosome mimetics, EMS, has been produced as surrogates by methods such as real exclusion and ultracentrifugation based filtration. Certainly most exosome mimetics are from the direct exclusion of whole cells, which demonstrates minimal biologic functions, but are inevitable contaminated by cell debris and organelles.Extracellular vesicles have attracted significant attention in biomedical research, especially in disease treatment. However, traditional EV isolation techniques like ultrasensitive filtration, inside exclusion, catamental glyphic start from low-yield poor productibility of plow down quality and require expensive and engineer intensive production equipment that cannot meet the clinical demand for EVs. Our study provided a simple and no cost method for scan up production of exosomes mimetics.We take advantage of unique biological finding that magnetic nanoparticles can be only endonized within cell endosomes, not other organelles. Thus, we can formulate the endosomes into uniform nanosescose. This method effectively improve EME and reduces cost.

通过磁分离辅助高速均质制备EM的工作流程如 图1所示。细胞内化 10 nm 聚赖氨酸修饰的 IONP，其通过内吞作用特异性积累在内体中（图 3A）。在用低渗缓冲液处理并匀浆后，负载IONP的内体从细胞中释放出来，随后通过磁分离收集。通过高速均质化，分离的内体进一步重组为单分散纳米囊泡，也称为 EM。我们探索了多个关键参数（例如，均质化速度和时?...

Watch this Scientific Journal Video about Development of a Large-Scale, Reproducible Production Method for Exosome Mimetics Using Magnetic Nanoparticles at JoVE.com

在这里，我们描述了一种用于大规模生产内体衍生纳米囊泡的磁分离辅助高速均质化方法，作为一种新型的外泌体模拟物 （EM），它们具有相同的生物学起源和相似的结构、形态和蛋白质组成天然细胞外囊泡 （EVs）。

Extracellular vesicles (EVs) have attracted significant attention in physiological and pathological research, disease diagnosis, and treatment; however, ...

在这项研究中，我们试图解决外泌体研究中一个关键的未满足需求，即开发一种大规模且可重复的外泌体模拟物生产方法。由于天然逃逸的概念，外泌体模拟物 EMS 已通过真正的排除和基于超速离心的过滤等方法作为替代物产生。当然，大多数外泌体模拟物都是直接排除的，全细胞表现出最小的生物学功能，但不可避免地被细胞碎片和细胞器污染。细胞外囊泡在生物医学研究中引起了极大的关注，特别是在疾病治疗中。然而，传统的电动汽车隔离技术，如超灵敏过滤、内部排除、催化字形，都是从低产量、低产率和犁地质量开始的，需要昂贵的工程密集型生产设备，无法满足电动汽车的临床需求。我们的研究为扫描外泌体模拟物的生产提供了一种简单且免费的方法。我们利用独特的生物学发现，即磁性纳米颗粒只能在细胞内体内被内植，而不能被其他细胞器所感染。因此，我们可以将内体配制成均匀的纳糖糖。该方法有效改善了EME，降低了成本。

a-magnetic-separation-assisted-high-speed-homogenization-method-for

Research

JoVE Journal

Biology

A Magnetic Separation-Assisted High-Speed Homogenization Method for Large-Scale Production of Endosome-Derived Vesicles

970 次观看.  Tianjin University. 在这项研究中，我们试图解决外泌体研究中一个关键的未满足需求，即开发一种大规模且可重复的外泌体模拟物生产方法。由于天然逃逸的概念，外泌体模拟物 EMS 已通过真正的排除和基于超速离心的过滤等方法作为替代物产生。当然，大多数外泌体模拟物都是直接排除的，全细胞表现出最小的生物学功能，但不可避免地被细胞碎片和细胞器污染。细胞外囊泡在生物医?...